Hostname: page-component-cd9895bd7-gvvz8 Total loading time: 0 Render date: 2024-12-22T18:57:30.508Z Has data issue: false hasContentIssue false

Cassava whitefly, Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) in East African farming landscapes: a review of the factors determining abundance

Published online by Cambridge University Press:  13 February 2018

S. Macfadyen*
Affiliation:
CSIRO, Clunies Ross St. Acton, ACT, 2601, Australia
C. Paull
Affiliation:
CSIRO, Boggo Rd. Dutton Park, QLD, 4001, Australia
L.M. Boykin
Affiliation:
University of Western Australia, School of Molecular Sciences, 35 Stirling Highway, Crawley, WA 6009, Australia
P. De Barro
Affiliation:
CSIRO, Boggo Rd. Dutton Park, QLD, 4001, Australia
M.N. Maruthi
Affiliation:
Natural Resources Institute, University of Greenwich, Chatham Maritime, Kent, ME4 4TB, UK
M. Otim
Affiliation:
National Crops Resources Research Institute, Kampala, Uganda
A. Kalyebi
Affiliation:
National Crops Resources Research Institute, Kampala, Uganda Mikocheni Agricultural Research Institute, P.O. Box 6226 Dar es Salaam, Tanzania
D.G. Vassão
Affiliation:
Max Planck Institute for Chemical Ecology, Hans-Knoell Str. 8 D-07745 Jena, Germany
P. Sseruwagi
Affiliation:
Mikocheni Agricultural Research Institute, P.O. Box 6226 Dar es Salaam, Tanzania
W.T. Tay
Affiliation:
CSIRO, Boggo Rd. Dutton Park, QLD, 4001, Australia
H. Delatte
Affiliation:
CIRAD, UMR PVBMT, Saint Pierre, La Réunion 97410-F, France
Z. Seguni
Affiliation:
Mikocheni Agricultural Research Institute, P.O. Box 6226 Dar es Salaam, Tanzania
J. Colvin
Affiliation:
Natural Resources Institute, University of Greenwich, Chatham Maritime, Kent, ME4 4TB, UK
C.A. Omongo
Affiliation:
National Crops Resources Research Institute, Kampala, Uganda
*
*Author for correspondence Phone: +61 (02) 62464432 Fax: +61 (02) 62464094 E-mail: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) is a pest species complex that causes widespread damage to cassava, a staple food crop for millions of households in East Africa. Species in the complex cause direct feeding damage to cassava and are the vectors of multiple plant viruses. Whilst significant work has gone into developing virus-resistant cassava cultivars, there has been little research effort aimed at understanding the ecology of these insect vectors. Here we assess critically the knowledge base relating to factors that may lead to high population densities of sub-Saharan African (SSA) B. tabaci species in cassava production landscapes of East Africa. We focus first on empirical studies that have examined biotic or abiotic factors that may lead to high populations. We then identify knowledge gaps that need to be filled to deliver sustainable management solutions. We found that whilst many hypotheses have been put forward to explain the increases in abundance witnessed since the early 1990s, there are little published data and these tend to have been collected in a piecemeal manner. The most critical knowledge gaps identified were: (i) understanding how cassava cultivars and alternative host plants impact population dynamics and natural enemies; (ii) the impact of natural enemies in terms of reducing the frequency of outbreaks and (iii) the use and management of insecticides to delay the development of resistance. In addition, there are several fundamental methodologies that need to be developed and deployed in East Africa to address some of the more challenging knowledge gaps.

Type
Review Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © Cambridge University Press 2018

Introduction

Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) is a pest species complex that causes widespread damage to cassava, a staple food crop in many millions of smallholder households in Africa (Otim-Nape et al., Reference Otim-Nape, Bua, Thresh, Baguma, Ogwal, Ssemakula, Acola, Byabakama, Colvin, Cooter and Martin2000; Colvin et al., Reference Colvin, Omongo, Maruthi, Otim-Nape and Thresh2004; Legg et al., Reference Legg, Owor, Sseruwagi and Ndunguru2006; Patil et al., Reference Patil, Legg, Kanju and Fauquet2015). Bemisia tabaci causes direct feeding damage to cassava, excretes a sugar-rich honeydew, which acts as a substrate for sooty moulds that reduces both respiration and photosynthesis (Nelson, Reference Nelson2008). In addition, B. tabaci vector multiples plant viruses that cause two damaging diseases: cassava mosaic disease (CMD) and cassava brown streak disease (CBSD), that in combination lead to significant yield loss in cassava (Holt & Colvin, Reference Holt, Colvin, Jeger and Spence2001; Maruthi et al., Reference Maruthi, Colvin, Seal and Thresh2002a, Reference Maruthi, Colvin, Seal, Gibson and Cooperb). Whilst substantial effort has gone into developing virus-resistant cassava cultivars, there has been little research effort aimed at understanding this insect vector, which alone can reduce yields, by 40% (Thresh et al., Reference Thresh, Otim-Nape, Legg and Fargette1997). This disproportionate approach to managing insect-vectored plant diseases is not unusual, but has led repeatedly to management solutions that are not sustainable. Based on partial mtCO1 gene sequence phylogenetic analysis, the B. tabaci complex is composed of four major clades (a clade is a group of organisms believed to have all descended from a common ancestor). The sub-Saharan Africa (SSA) clade forms the ancestral root (Boykin et al., Reference Boykin, Bell, Evans, Small and De Barro2013) of the complex, and in recent history, species in this clade have been associated with an increased frequency of cassava viral disease outbreaks in East Africa. This review of the empirical evidence is timely and necessary as we need to identify clearly the biotic and abiotic factors that may have contributed to high population growth of B. tabaci in the past, before we can develop urgently needed and sustainable management recommendations for the future.

Whilst many hypotheses have been put forward about the factors that may be contributing to high B. tabaci populations on cassava in East Africa, there are little data available and these tend to have been collected in a piecemeal manner.

Our objectives for this review are firstly, to synthesize the existing literature on the SSA B. tabaci species’ ecology in East Africa and to review critically this knowledge base. We focused on empirical studies that have examined factors that may lead to high populations or outbreaks of the SSA B. tabaci. We then identified the gaps in knowledge and understanding that need to be filled to deliver long-term sustainable solutions to manage both the vector species and the viruses that they transmit. We started by listing factors that, from an a priori perspective, are likely to be important ecological determinants of B. tabaci abundance (table 1) in any farming context. Factors that may support or limit population growth were equally considered (as these both may facilitate outbreaks). We then searched for studies based in East African production landscapes, preferring those focused on cassava. We included the countries of Tanzania, Uganda, Rwanda, Burundi, South Sudan and Malawi as part of the geographical region of Eastern Africa. In cases where we could not find published studies based in East Africa, we cited geographically related work if relevant. We excluded studies that look solely at virus impacts on the crop, and there have been several important review articles that have summarized information on cassava virus disease epidemics and speculated on some of the likely causes (table 2). In addition, there are reviews by Fishpool & Burban (Reference Fishpool and Burban1994); Legg (Reference Legg1994) and Colvin et al. (Reference Colvin, Omongo, Govindappa, Stevenson, Maruthi, Gibson, Seal and Muniyappa2006) that provide a good baseline of ecological and biological information on what was known about B. tabaci complex and cassava viruses up until the late 1990s. A complicating factor in reviewing the evidence base for factors relating to East African B. tabaci is that our understanding of B. tabaci as a species has changed in the previous decade and so it is at times unclear as to the actual identity (as determined by their partial mtCO1 gene sequence) of the species being referred to, especially in older references. Where possible, we attempted to resolve these issues.

Table 1. Potential factors influencing Bemisia tabaci abundance on cassava included in this review (does not include interactions between these factors). We have suggested the likely direction of the effect in terms of an increase (↑) or decrease (↓) in B. tabaci abundance, but note there are many possible outcomes for some of these factors.

Table 2. Review articles with relevant information about Bemisia tabaci biology and ecology.

CMBs, cassava mosaic begomoviruses; CMD, cassava mosaic disease; CBSD, cassava brown streak disease.

African B. tabaci species complex: naming and identification

Throughout this review, we use B. tabaci to mean the B. tabaci species complex found in East Africa. However, the identification of the species involved in these outbreaks based on genetic differences has only recently been attempted (see example from Kenya in Manani et al., Reference Manani, Ateka, Nyanjom and Boykin2017). Due to morphological similarities, B. tabaci was originally thought to be one species worldwide, but based on genetic differences (Colvin et al., Reference Colvin, Omongo, Maruthi, Otim-Nape and Thresh2004; Sseruwagi et al., Reference Sseruwagi, Legg, Maruthi, Colvin, Rey and Brown2005; Boykin et al., Reference Boykin, Shatters, Rosell, McKenzie, Bagnall, De Barro and Frohlich2007; Reference Boykin, Bell, Evans, Small and De Barro2013; Wang et al., Reference Wang, Yang, Boykin, Zhao, Wang, Liu and Wang2014); and mating incompatibility (Colvin et al., Reference Colvin, Omongo, Maruthi, Otim-Nape and Thresh2004; Xu et al., Reference Xu, De Barro and Liu2010; Liu et al., Reference Liu, Colvin and De Barro2012), it is now recognized as a species complex with at least 34–36 species (Boykin et al., Reference Boykin, Armstrong, Kubatko and De Barro2012; Barbosa et al., Reference Barbosa, Yuki, Marubayashi, De Marchi, Perini, Pavan, de Barros, Ghanim, Moriones, Navas-Castillo and Krasue-Sakate2015). This discovery of further species diversity has led to many nomenclatural changes over the last 10 years causing confusion in the literature (Boykin & De Barro, Reference Boykin and De Barro2014; Boykin et al., Reference Boykin, Kinene, Wainaina, Seal, Mugerwa, Macfadyen, De Barro, Tay, Kubatko, Alicai, Omongo, Tairo, Ndunguru and Sseruwagi2018).

The SSA B. tabaci species are no exception to the nomenclatural confusion. Identification of species in the B. tabaci pest complex currently relies on the 3’ region of 657 bp partial mtDNA COI gene identity. However, many names have been used for the same SSA entities with little consistency from study to study. The naming confusion has made it difficult to compare studies of ecological importance across time or from different researchers. For example, Sseruwagi (Reference Sseruwagi2005) used ‘Ug1’, Legg et al. (Reference Legg, Sseruwagi, Boniface, Okao-Okuja, Shirima, Bigirimana, Gashaka, Herrmann, Jeremiah, Obiero, Ndyetabula, Tata-Hangy, Masembe and Brown2014a) used ‘SSA1 subgroups 1–3’ and Mugerwa et al. (Reference Mugerwa, Rey, Alicai, Ateka, Atuncha, Ndunguru and Sseruwagi2012) used ‘SSA1 subclades I–III’ based on mtCO1 data. Are these the same entity? In short, no. Relevant to this study are the SSA1 and SSA2 species of B. tabaci, where Ug1 = SSA1 and further subdivisions of that species include SSA1 subgroup 1 (Legg et al., Reference Legg, Sseruwagi, Boniface, Okao-Okuja, Shirima, Bigirimana, Gashaka, Herrmann, Jeremiah, Obiero, Ndyetabula, Tata-Hangy, Masembe and Brown2014a) = SSA1 subclade I (Mugerwa et al., Reference Mugerwa, Rey, Alicai, Ateka, Atuncha, Ndunguru and Sseruwagi2012). However, Ug2 (Sseruwagi et al., Reference Sseruwagi, Legg, Maruthi, Colvin, Rey and Brown2005) translates directly to SSA2 (Mugerwa et al., Reference Mugerwa, Rey, Alicai, Ateka, Atuncha, Ndunguru and Sseruwagi2012; Legg et al., Reference Legg, Sseruwagi, Boniface, Okao-Okuja, Shirima, Bigirimana, Gashaka, Herrmann, Jeremiah, Obiero, Ndyetabula, Tata-Hangy, Masembe and Brown2014a) with little confusion. Most of the confusion involves the SSA1 species, because most studies did not compare their SSA1 mtCO1 sequences against the then known available diversity. This meant that their data were not set firmly within a complete understanding of B. tabaci diversity at the time (Boykin et al., Reference Boykin, Kinene, Wainaina, Seal, Mugerwa, Macfadyen, De Barro, Tay, Kubatko, Alicai, Omongo, Tairo, Ndunguru and Sseruwagi2018).

Greater clarity around the species identity of individuals involved in future outbreaks may help to uncover the causes of these outbreaks. Even closely related species may differ in their host-plant use, ability to transmit viruses, fecundity and response to management actions. Conclusions and findings from past work in this region, however, are still useful to understanding the ecology of the species complex. In addition, species-specific management strategies and interventions could play a larger role in the future (see ‘Knowledge gaps’ section towards the end of this review).

Overview of the life cycle of B. tabaci

The life-history parameters of many species in the B. tabaci complex vary depending on the environmental conditions and the host plant they develop on. The published information suggests that the development period of B. tabaci from egg to adult emergence is between 19 and 29 days, and the species goes through four nymphal instars before entering a pupal phase (Colvin et al., Reference Colvin, Omongo, Govindappa, Stevenson, Maruthi, Gibson, Seal and Muniyappa2006). Depending on the environmental conditions, there can be 11–12 generations of B. tabaci per year (Asiimwe et al., Reference Asiimwe, Ecaat, Guershon, Kyamanywa, Gerling and Legg2007a; Reference Asiimwe, Ecaat, Otim, Gerling, Kyamanywa and Leggb). In East Africa, cassava is planted from cuttings twice per year in some parts of Uganda, through to one cropping season in Malawi. Depending on the cultivar used, the plant can remain in the ground for 6–12 months before the tuber is ready to be harvested. Often, cassava is planted in a mixed field with maize, coffee and banana, and multiple cassava fields of different ages can exist in one location, providing year-round host plants for B. tabaci. A description of the different developmental stages of B. tabaci on cassava, using a colony established in Uganda, is presented in Thompson (Reference Thompson2000). Adult female B. tabaci produce 4–5 eggs per day and these are oviposited on the underside of the leaves and the leaf petiole. Both the adults and nymphs have sucking mouthparts to pierce the leaf tissue and consume phloem sap. Adults prefer to congregate and alight on the immature upper leaves of the cassava plant (Sseruwagi et al., Reference Sseruwagi, Sserubombwe, Legg, Ndunguru and Thresh2004). The first nymphal stage is mobile until it finds a suitable feeding location. The nymphs exude honeydew, which falls onto the lower leaves of the plant leading to sooty mould development.

There are a range of abiotic and biotic factors (e.g. host-plant availability, weather, mortality from natural enemies, etc.) that may influence the abundance of any pest herbivore on a host plant. Understanding how these factors relate to population dynamics and distributions measured at the field level and scale-up to the regional level is critical for determining if a pest outbreak is likely to occur. We define an outbreak situation as one in which the pest herbivore or plant-virus vector has been released from control, has reached high abundances, and is causing economic injury to the crop. This problem usually manifests at the field or regional scale. Importantly, crop damage can occur at low pest abundance, especially in the case of virus transmission. Thus, whilst outbreaks are often obvious to farmers and the general community, significant yield loss and damage can occur in non-outbreak situations. Here we focus on the documented evidence of factors that influence abundance of B. tabaci on cassava in East Africa. There are likely to be a number of factors that will, in isolation or in combination, influence the abundance of B. tabaci in cassava landscapes. We have classified these into biotic (cassava cultivar, cassava age, cassava virus infection status, non-cassava host plants, natural enemies, competition with other herbivores and endosymbionts), abiotic (altitude, climate and weather) and other factors (pesticides, hybridization) in table 1.

History of B. tabaci abundance on cassava and outbreaks in East Africa

There has been a change in the abundance of B. tabaci in cassava production landscapes in East Africa in general over time (fig. 1). However, quantitative definitions of what is a high or low population abundance have also changed across time; therefore, empirical evidence documenting this change is weak. The threshold of the number of adults considered highly abundant, however, differs between studies, and we cannot translate abundance data into likely yield loss. Early research from Ivory Coast considered cassava a poor host for B. tabaci, as numbers rarely exceeded 300 adults per plant and more often there were 150 adults per plant (Fishpool & Burban, Reference Fishpool and Burban1994; Fishpool et al., Reference Fishpool, Fauquet, Fargette, Thouvenel, Burban and Colvin1995; Colvin et al., Reference Colvin, Fishpool, Fargette, Sherington and Fauquet1998;). However, other researchers might consider these to be relatively high numbers. In Legg et al. (Reference Legg, Jeremiah, Obiero, Maruthi, Ndyetabula, Okao-Okuja, Bouwmeester, Bigirimana, Tata-Hangy, Gashaka, Mkamilo, Alicai and Kumar2011) when >5 adults per top five leaves per plant were recorded, this was considered highly abundant. In contrast, Omongo et al. (Reference Omongo, Kawuki, Bellotti, Alicai, Baguma, Maruthi, Bua and Colvin2012) only considered populations >20 adults per top five leaves per plant as high. Some quantitative studies have been summarized in table 3; however, it is still challenging to compare across studies that have used different sampling methodologies to document overall trends. Sseruwagi et al. (Reference Sseruwagi, Sserubombwe, Legg, Ndunguru and Thresh2004) provides a summary of mean number of B. tabaci from top five leaves from African studies prior to 2004.

Fig. 1. Timeline of events of Bemisia tabaci and associated disease outbreaks in East Africa. CMV, cassava mosaic virus; CMD, cassava mosaic disease; CBSV, cassava brown streak virus, CBSD, cassava brown steak disease.

Table 3. Studies quantifying the mean number of adults (unless otherwise mentioned) Bemisia tabaci on cassava. General method used was counting the numbers of adults observed on the top five expanded leaves on 30 plants per field and on cassava aged 3–6 months after planting (Sseruwagi et al., Reference Sseruwagi, Sserubombwe, Legg, Ndunguru and Thresh2004). There was some variation in methods between studies.

We have summarized the available evidence on the historical outbreaks of B. tabaci, and the two major diseases of cassava, CMD and CBSD, across East African countries in fig. 1. There are records of high populations of B. tabaci causing problems for farmers since the 1990s. As with most pest outbreaks, there is a focus on data collection and analysis during the outbreak phase, until an intervention (e.g. the introduction of new cassava cultivars) or change in the environment stops the outbreak, but a lack of information in the intervening periods. This makes it challenging to assess the causes and frequency of outbreaks, both at the local level and across the East African region. It is notable that the movement of infected cuttings (between regions within countries, and between countries) was implicated in a number of historical outbreaks (Alicai et al., Reference Alicai, Omongo, Maruthi, Hillocks, Baguma, Kawuki, Bua, Otim-Nape and Colvin2007). Importantly, the introduction and dissemination of new CMD-resistant cultivars to combat food shortages because of epidemics was also facilitated through these routes. Less well documented is that disease sources can be present in endemic host plants such as Jatropha sp., and trade routes between India and Africa may have also facilitated disease spread (Swanson & Harrison, Reference Swanson and Harrison1994).

Plant virus transmission by B. tabaci

Outbreaks of CMD, which are at least partially whitefly-borne, have been occurring in East Africa since the 1960s (Jameson, Reference Jameson1964). A detailed description of both CMD and CBSD can be found in Mabasa (Reference Mabasa2007), but we will summarize some of the key points here. There are seven cassava mosaic begomoviruses (CMBs) (Geminiviridae; genus Begomovirus) that are related to CMD (Legg et al., Reference Legg, Lava Kumar, Makeshkumar, Tripathi, Ferguson, Kanju, Ntawuruhunga and Cuellar2015). The first widespread outbreaks of CMD were reported in the 1930s in East Africa (Storey & Nichols, Reference Storey and Nichols1938; fig. 1) and the presence of CMD is now confirmed in cassava across East Africa. CMBs appear to be persistent in B. tabaci; however, there may be some co-adaptation between the viruses and different vector species that alter their ability to transmit virus to cassava (see Maruthi et al., Reference Maruthi, Colvin, Seal, Gibson and Cooper2002b). Severe infection causes stunting of shoots, leaves and stems which reduce tuber growth and subsequently yield (Fauquet & Fargette, Reference Fauquet and Fargette1990; Maruthi et al., Reference Maruthi, Colvin, Seal and Thresh2002a, Reference Maruthi, Colvin, Seal, Gibson and Cooperb; Omongo, Reference Omongo2003). There is a latent period after the first leaves appear of about 1 month between time of infection by B. tabaci and CMD symptom expression in cassava (Fauquet & Fargette, Reference Fauquet and Fargette1990). Symptoms increase until approximately 60 days after planting. However, infection introduced beyond 5 months after planting (MAP) via B. tabaci has very little impact on the yield. This is because at five MAP, the tubers have started to form and the plant is still able to provide significant yield (Fargette et al., Reference Fargette, Fauquet, Grenier and Thresh1990).

The second major cassava plant disease associated with B. tabaci is CBSD. CBSD is often found together with CMD, but this was not always the case (Alicai et al., Reference Alicai, Omongo, Maruthi, Hillocks, Baguma, Kawuki, Bua, Otim-Nape and Colvin2007). Historically, CBSD was thought to be caused by two distinct viruses, cassava brown streak virus (CBSV) and Ugandan cassava brown streak virus (UCBSV), but Ndunguru et al. (Reference Ndunguru, Sseruwagi, Tairo, Stomeo, Maina, Djikeng, Kehoe and Boykin2015) have recently found more genetic diversity in both CBSV and UCBSV, suggesting that there may be more than two viruses involved. Both virus groups belong to the genus Ipomovirus, and family Potyviridae (Mbewe et al., Reference Mbewe, Kumar, Changadeya, Ntawuruhunga and Legg2015); however, CBSV has a five times faster rate of evolution, and is more virulent compared with UCBSV (Alicai et al., Reference Alicai, Ndunguru, Sseruwagi, Tairo, Okao-Okuja, Nanvubya, Kiiza, Kubatko, Kehoe and Boykin2016). Unlike CMBs, CBSVs are semi-persistent in B. tabaci (Maruthi et al., Reference Maruthi, Hillocks, Mtunda, Raya, Muhanna, Kiozia, Rekha, Colvin and Thresh2005). Symptoms of CBSD include yellow blotchy patches on the leaves and a change in the colour of the leaf veins, especially on the lower more mature leaves. Brown coloured vertical lesions occur on the stems and roots can become contorted and constricted. Cross-sections of roots from infected cassava plants show brown necrotic tissue (Nichols, Reference Nichols1950; Hillocks & Jennings, Reference Hillocks and Jennings2003; Ntawuruhunga & Legg, Reference Ntawuruhunga and Legg2007).

Bemisia tabaci species can carry and potentially transmit hundreds of different plant viruses (Morales & Jones, Reference Morales and Jones2004; Polston et al., Reference Polston, De Barro and Boykin2014). Harrison et al. (Reference Harrison, Zhou, Otim-Nape, Liu and Robinson1997) makes the argument that selection and subsequent spread of viruses by certain B. tabaci species might be possible. Different species of B. tabaci are believed to be able to transmit Geminiviruses with different coat proteins (McGrath & Harrison, Reference McGrath and Harrison1995; Maruthi et al., Reference Maruthi, Colvin, Seal and Thresh2002a; Morales & Jones, Reference Morales and Jones2004, Reference Maruthi, Colvin, Seal, Gibson and Cooperb). This may be important; however, methods to test for these synergistic virus–vector relationships are rare (Patil & Fauquet, Reference Patil and Fauquet2010). Both CMD and CBSD are spread through the propagation of infected cassava cuttings and vectored by B. tabaci in East Africa (Maruthi et al., Reference Maruthi, Hillocks, Mtunda, Raya, Muhanna, Kiozia, Rekha, Colvin and Thresh2005; Jeremiah et al., Reference Jeremiah, Ndyetabula, Mkamilo, Haji, Muhanna, Chuwa, Kasele, Bouwmeester, Ijumba and Legg2014, confirmed B. tabaci transmits CBSVs). Transmission of CMBs by B. tabaci has been confirmed in Africa (Burban et al., Reference Burban, Fishpool, Fauquet, Fargette and Thouvenel1992; Fishpool & Burban, Reference Fishpool and Burban1994; Gibson et al., Reference Gibson, Legg and Otim-Nape1996; Legg et al., Reference Legg, French, Rogan, Okao-Okuja and Brown2002; Antony et al., Reference Antony, Lisha, Palaniswami, Sugunan, Makeshkumar and Henneberry2006). Survey of cassava across Tanzania during the 1993–1994 growing season showed that on average 27% of plants had CMD symptoms, of which 3% could be attributed to B. tabaci transmission, compared with 24% of infections to the use of infected cuttings (Legg & Raya, Reference Legg and Raya1998). More recently, it has been shown that a greater proportion of CMD is cutting borne compared with being vectored by B. tabaci (Night et al., Reference Night, Asiimwe, Gashaka, Nkezabahizi, Legg, Okao-Okuja, Obonyo, Nyirahorana, Mukakanyana, Mukase, Munyabarenzi and Mutumwinka2011). A modelling study exploring CBSD spread showed that in a scenario with whitefly dispersal alone, large-scale epidemics were less likely than when trade of infected cuttings is also included in the model (McQuaid et al., Reference McQuaid, van den Bosch, Szyniszewska, Alicai, Pariyo, Chikoti and Gilligan2017). Research by Dubern (Reference Dubern1994) indicated that B. tabaci was not an efficient vector of CMBs. However, Maruthi et al. (Reference Maruthi, Colvin, Seal and Thresh2002a, Reference Maruthi, Colvin, Seal, Gibson and Cooperb) used CMB isolates and B. tabaci sourced from four different areas (three African locations and one culture from India) to show that African CMBs were transmitted by African B. tabaci to 60–79% of the cassava plants. However, inoculation was significantly less when Indian B. tabaci transmitted an African CMD isolate and vice versa when B. tabaci from Tanzania transmitted CMB isolates from India. These results were used to support the idea that there is virus and or vector co-adaptation and that there is variability in vector competence and biological traits between B. tabaci species (Maruthi et al., Reference Maruthi, Colvin, Seal, Gibson and Cooper2002b). However, there is little quantifiable evidence for this hypothesis, and what evidence there is has been drawn from data that have a small number of samples (Xu et al., Reference Xu, De Barro and Liu2010).

Factors influencing B. tabaci abundance

Below we summarized the available evidence that may demonstrate a link with each factor and change in abundance of B. tabaci populations.

Biotic factors

Cassava cultivar effects

The primary way to manage disease in cassava has been to develop cultivars that are disease resistant or tolerant (these are often referred to as ‘improved cultivars’). Observations that some cultivars were susceptible to disease have been evident since the first outbreak of CMD in the 1930s (Storey & Nichols, Reference Storey and Nichols1938). The key response to the 1990s CMD epidemic was to distribute cassava cuttings from improved cultivars (Oliveira et al., Reference Oliveira, Henneberry and Anderson2001). In recent times, greater numbers of adult B. tabaci, and sometimes nymphs, have been associated with recently developed cultivars, although the dynamics of B. tabaci populations in semi-field situations have not been well documented (e.g. Katono et al., Reference Katono, Alicai, Baguma, Edema, Bua and Omongo2015). Severity of cassava green mite (CGM; Mononychellus tanajoa) and CMD were higher on local cultivars of cassava, although B. tabaci populations were higher on improved cultivars (Night et al., Reference Night, Asiimwe, Gashaka, Nkezabahizi, Legg, Okao-Okuja, Obonyo, Nyirahorana, Mukakanyana, Mukase, Munyabarenzi and Mutumwinka2011). To determine which cultivars showed some level of phenotypic resistance or tolerance to B. tabaci, 19 cultivars were exposed to B. tabaci for colonization. Numbers of nymphs, eggs, damage and sooty mould were greatest for cultivar I92/0067 and least for Njule Red (a local cultivar) (Omongo et al., Reference Omongo, Kawuki, Bellotti, Alicai, Baguma, Maruthi, Bua and Colvin2012). Cassava leaf area did affect the severity of sooty mould (i.e. a cultivar with a lower number of B. tabaci could have a higher sooty mould severity score, presumably due to broader leaves). However, there was no obvious correlation between the numbers of B. tabaci adults and cultivar plant traits such as leaf width or colour (Omongo et al., Reference Omongo, Kawuki, Bellotti, Alicai, Baguma, Maruthi, Bua and Colvin2012).

Beyond the obvious differences in plant morphology seen between different cassava cultivars, plant biochemistry may also play a role in determining suitability for growth and development of B. tabaci populations. Research on the phytochemistry of cassava has largely concentrated on defensive metabolites such as flavonoids, hydroxycoumarins, terpenoids and cyanogenic glucosides and their distribution within plant tissue. This work was recently reviewed by Blagbrough et al. (Reference Blagbrough, Bayoumi, Rowan and Beeching2010). Cassava phytochemistry can impact phloem feeders, with examples including the effect of its flavonoids and cyanogenic glucosides on the cassava mealybug, Phenacoccus manihoti (Calatayud et al., Reference Calatayud, Rahbé, Delobel, Khuong-Huu, Tertuliano and Le Rü1994a, Reference Calatayud, Rahbé, Tjallingii, Tertuliano and Le Rüb, Reference Calatayud, Rouland and Le Rü1997) and the cassava hemipteran pest, Cyrtomenus bergi (Riis et al., Reference Riis, Bellotti, Bonierbale and O'Brien2003). Bemisia tabaci can also be affected, and has been shown to induce cyanide-metabolizing enzymes when feeding on cassava compared with sweet potato (Antony et al., Reference Antony, Lisha, Palaniswami, Sugunan, Makeshkumar and Henneberry2006). These results provide evidence that defensive plant metabolites play an important role in cassava colonization by phloem feeders including B. tabaci. However, how the phytochemistry of different cassava cultivars and tissues influences B. tabaci resistance remains unknown. Future efforts should be directed at confirming these mechanisms and explaining the effect of cassava plant chemistry on phloem feeders and other herbivores within the East African cassava environment.

Cassava age

As cassava matures, the degree to which it is a suitable host plant for B. tabaci changes. There are likely to be several factors associated with the ageing process such as changes to leaf morphology, plant biochemistry and B. tabaci preference and learning that impact this process. The population of B. tabaci builds up starting at three MAP and peaks between five and seven MAP (Sseruwagi et al., Reference Sseruwagi, Otim-Nape, Osiru and Thresh2003), when the foliage is very well formed and succulent after which it drops drastically as the plants grow taller, become more woody (less succulent) and shade the leaves. However, overall, the dynamics of B. tabaci populations in the field in response to factors that change as cassava ages have not been well documented.

All the cultivars surveyed in Uganda in 1990–1992 were susceptible to CMD (Otim-Nape et al., Reference Otim-Nape, Thresh and Shaw1998), but as cassava plants age, the rate at which the CMD spreads is reduced (Fargette et al., Reference Fargette, Jeger, Fauquet and Fishpool1993). Cuttings taken from the top of the plant are more likely to be virus-free for CBSD compared with those taken from the bottom of the plant (Mohammed et al., Reference Mohammed, Ghosh and Maruthi2016), which may be related to plant age. During sampling for virus detection, virus titre is always highest in the older leaves for CBSVs, especially in the young (<6 months old) cassava plants. Research to identify the resistance mechanisms in cassava cultivars shows that some cultivars can recover as the plants age (known as reversion, Adriko et al., Reference Adriko, Sserubombwe, Adipala, Bua, Thresh and Edema2011). CMD symptoms disappeared and cuttings taken from initially infected plants developed without disease symptoms (Gibson & Otim-Nape, Reference Gibson and Otim-Nape1997; Adriko et al., Reference Adriko, Sserubombwe, Adipala, Bua, Thresh and Edema2011).

Cassava virus infection status

There are some empirical studies that have tested the hypothesis that there is a relationship between disease severity in a plant and B. tabaci abundance (Gregory, Reference Gregory1948; Leuschner, Reference Leuschner, Brekelbaum, Bellotti and Lozano1977; Robertson, Reference Robertson1987; Fargette et al., Reference Fargette, Jeger, Fauquet and Fishpool1993; Otim-Nape et al., Reference Otim-Nape, Thresh, Fargette, Gerling and Mayer1995; Colvin et al., Reference Colvin, Omongo, Maruthi, Otim-Nape and Thresh2004). If this is due to correlation or causation it is often hard to untangle. The abundance of B. tabaci adults was shown to be significantly higher on healthy cassava plants compared with infected plants, but adults stayed longer on diseased plants and aggregated on the green plant tissue. This resulted in higher density of adults by photosynthetic leaf area (area of living leaf tissue) compared with plants without disease. Omongo (Reference Omongo2003) posits that this increased density might trigger the adults to disperse. Results also show that adults are more likely to move from clean to infected plants, and diseased plants increased fecundity (Omongo, Reference Omongo2003).

Cassava plants infected with CMBs have been reported to be more suitable for growth and development of B. tabaci. A summary of the studies showing the effect of virus infection of host plants on B. tabaci population growth, development and behaviour can be found in Colvin et al. (Reference Colvin, Omongo, Govindappa, Stevenson, Maruthi, Gibson, Seal and Muniyappa2006). Concentrations of amino acids have been shown to be greater in infected cassava, and these may benefit B. tabaci fitness (Colvin et al., Reference Colvin, Otim-Nape, Holt, Omongo, Seal, Stevenson, Cooter and Thresh1999, Reference Colvin, Omongo, Govindappa, Stevenson, Maruthi, Gibson, Seal and Muniyappa2006). However, other laboratory studies have found that the status of cassava disease and B. tabaci (i.e. viruliferous or non-viruliferous) had no significant effect on life-history factors, sex ratio and developmental period, or per cent adult emergence (Thompson, Reference Thompson and Thompson2011). Additionally, the longevity of B. tabaci was shown to be reduced when they carry viruses such as tomato yellow leaf curl virus (Berlinger et al., Reference Berlinger, Lehmann-Sigura and Taylor1996). Therefore, whilst infection status plays some role in altering the bottom–up resources for B. tabaci, we cannot say when and how this will lead to high abundance in a field situation.

Non-cassava host plants

Bemisia tabaci is a polyphagous herbivore that can potentially use a wide range of different host plants in cassava production landscapes. Evidence from outside of Africa (Bellotti et al., Reference Bellotti, Peña, Arias, Guerrero, Trujillo, Holguín, Ortega, Anderson and Morales2005) and from West Africa (Burban et al., Reference Burban, Fishpool, Fauquet, Fargette and Thouvenel1992) shows that B. tabaci can have very different associations with different host plants in different locations indicating the likelihood of host-plant associated genotypes. Research in West Africa showed two genotypes of B. tabaci; one polyphagous on a range of plants (excluding cassava) and the second found only on Euphorbia species (this group includes cassava) (Burban et al., Reference Burban, Fishpool, Fauquet, Fargette and Thouvenel1992). Laarif et al. (Reference Laarif, Saleh, Clouet and Gauthier2015) found that B. tabaci Mediterranean (MED, formally named biotype Q) preferred host plants in the families Verbenaceae and Malvaceae, and Middle East-Asia Minor 1 (MEAM1, formally named biotype B) were found on Cucurbitaceae and Solanaceae. SSA2 only occurred on Datura and eggplant (Laarif et al., Reference Laarif, Saleh, Clouet and Gauthier2015). Their results support the argument that the genetic differentiation of B. tabaci species does not operate at the plant species level, but more likely in response to broader taxonomic grouping, for example, plant families. Table 4 documents host plants that have been recorded in recent publications that included a genetic determination of the species. Most of the studies rely on adults (which are highly mobile) recorded on host plants, except Sseruwagi et al. (Reference Sseruwagi, Maruthi, Colvin, Rey, Brown and Legg2006) who used nymphs to confirm the results obtained with adults for host-plant colonization. There is a supposition that the number of eggs laid on a plant is a better indicator of a preferred host compared with counts of adults (Laarif et al., Reference Laarif, Saleh, Clouet and Gauthier2015). Further information is required that shows clear species–host-plant relationships in field contexts, such as preference tests, rate of nymphal development and mortality on host plants (not just presence or absence).

Table 4. Host plants of Bemisia tabaci in East Africa from the published literature.

*The names used here are the same as authors used in their papers, however see section on species identification.

Experiments transferring B. tabaci from natal host plants to different local host plants result in failure or variable establishment. These results were used to support the idea that there are different B. tabaci genotypes with restricted host ranges (Burban et al., Reference Burban, Fishpool, Fauquet, Fargette and Thouvenel1992). However, this research did not test the influence of host-plant transfer on ability of B. tabaci to transmit disease. Research by Antony et al. (Reference Antony, Lisha, Palaniswami, Sugunan, Makeshkumar and Henneberry2006) showed that natal host plants influence the ability of B. tabaci to transmit Indian cassava mosaic virus (ICMV). Whereas B. tabaci reared from cassava could transmit ICMV to cassava, B. tabaci reared on sweet potato were unable to transmit ICMV to cassava. There was a significant difference in the presence of the cyanide detoxifying enzymes in cassava reared B. tabaci compared with those reared on sweet potato. Together, the results show the ability of B. tabaci to adapt to different host plants.

Intercropping cassava with other crop plants (e.g. coffee, maize, sweet potato, bean, groundnut) is common practice in many parts of East Africa. However, beyond saying if a crop is likely to be a host plant or not, we cannot yet make recommendations about which intercrop would be most useful for reducing B. tabaci abundance on cassava. Intercropping cassava with maize was shown to reduce B. tabaci population abundances in the Ivory Coast (Fargette et al., Reference Fargette, Fauquet and Thouvenel1988), although the mechanism here may not be related to host-plant preferences, but rather host-plant availability and physical barriers (i.e. maize are not host plants and may create a barrier to accessing host plants). Intercropping cassava with cowpea has been shown to decrease numbers of B. tabaci in Colombia (Gold et al., Reference Gold, Altieri and Bellotti1989). Results of surveys in Uganda in 2007 showed that intercropped cassava had significantly less B. tabaci than monocrops (Night et al., Reference Night, Asiimwe, Gashaka, Nkezabahizi, Legg, Okao-Okuja, Obonyo, Nyirahorana, Mukakanyana, Mukase, Munyabarenzi and Mutumwinka2011). Experiments intercropping cassava with Vigna unguiculata and Vigna radiata (cowpea and green gram mung bean) showed reduced B. tabaci populations and severity of CMD. Disease-free cuttings of two cultivars (one susceptible local cultivar and one improved cultivar) were used in field experiments. Compared with monocrop treatments, the cultivars intercropped with mung bean had significantly less B. tabaci and disease incidence and severity for both the local and improved cultivar (Uzokwe et al., Reference Uzokwe, Mlay, Masunga, Kanju, Odeh and Onyeka2016).

Spatial and temporal arrangement of host plants

As well as the influence of intercropping per se on B. tabaci populations in cassava fields, the spatial and temporal arrangement of crops and other potential non-crop hosts around cassava fields may also influence population growth and abundance in the crop field, especially early in the growing season. In theory, if host plants surrounding cassava fields facilitated the early arrival (and high numbers of colonizers) of the first generation of B. tabaci into the cassava field in the early stages of the crop, this may lead to an outbreak. Furthermore, if the spatial and temporal arrangement of host plants negatively impacted the dynamics of natural enemies of B. tabaci, this could also lead to an outbreak.

In a farming landscape where a species of B. tabaci (MEAM1) has been shown to be polyphagous with several crops and wild host plants suitable to support population growth (Queensland, Australia, Sequeira et al., Reference Sequeira, Shields, Moore and De Barro2009; De Barro, Reference De Barro2012), it was possible to develop a landscape model to simulate how the spatial and temporal arrangement of host plants influences B. tabaci abundance and ‘outbreaks’. The model simulations indicated that peak densities of MEAM1 B. tabaci were higher for low or non-suitable crops than for crops with a medium suitability. This counter-intuitive result was explained by the fact that medium suitability winter crops supported high parasitoid (Eretmocerus hayati) populations, which can suppress B. tabaci populations in summer crops (De Barro, Reference De Barro2012; Kristensen et al., Reference Kristensen, Schellhorn, Hulthen, Howie and De Barro2013). Therefore, both the surrounding landscape and crop rotation choices had a significant effect on simulated B. tabaci population dynamics.

Understanding how the farming landscapes in East Africa offer resources for both B. tabaci and its natural enemies is challenging due to the variegated nature of the land-use patterns characteristic of smallholder farming. Often there are multiple crops planted in each field or garden and rotation practices are flexible and dependent on the family, village and regional demand for certain food types. However, studies to quantify the effect (even if small) of the spatial and temporal arrangement of host plants are needed because this knowledge may lead to easily adoptable changes in management practices.

Natural enemies

Breeding cassava cultivars that are resistant to disease has been the main approach used to manage epidemics of CMD. However, as part of an integrated management plan to control B. tabaci, identifying ways to enhance naturally occurring predators and parasitic wasps also needs to be considered (Legg et al., Reference Legg, Gerling, Neuenschwander, Neuenschwander and Langewald2003). Fishpool & Burban (Reference Fishpool and Burban1994) noted that there were 30 parasitoids of B. tabaci worldwide, and 40 generalist predators. However, the ecology and impact of parasitoids and predators of B. tabaci in East Africa remains relatively unknown.

Regarding predators, Phytoseiidae mites, such as Euseius scutalis, have been recorded predating B. tabaci populations on cassava in Kenya (Otim-Nape et al., Reference Otim-Nape, Thresh, Fargette, Gerling and Mayer1995), and mirids, such as Nesidiocoris tenuis, have predated B. tabaci on other crops such as tomato (Calvo et al., Reference Calvo, Bolckmans and Belda2012). Results from petri dish experiments with B. tabaci from cotton showed that the predatory mite Amblyseius aleyrodis Elbadry readily consumed B. tabaci eggs in a no-choice environment (Elbadry, Reference Elbadry1968). Similarly, from the work carried out in the USA, Euseius hibisci were shown to consume and complete their development on B. tabaci (Meyerdirk & Coudriet, Reference Meyerdirk and Coudriet1985). Other predators of B. tabaci nymphs from around the world include Stethorus jejunus Casey, Coccinellidae, Holoborus pallidicornis (Cameron) Staphylinidae and Scolothrips latipennis Priesner, Thysanoptera (Fishpool & Burban, Reference Fishpool and Burban1994). The Neuropteran Conwentzia africana Meinander is considered an important predator of B. tabaci (Legg et al., Reference Legg, Gerling, Neuenschwander, Neuenschwander and Langewald2003). Serangium sp. (Coleoptera: Coccinellidae) can complete their development feeding on juvenile stages of B. tabaci on cassava (Asiimwe et al., Reference Asiimwe, Ecaat, Guershon, Kyamanywa, Gerling and Legg2007a, Reference Asiimwe, Ecaat, Otim, Gerling, Kyamanywa and Leggb). No-choice laboratory experiments showed that Serangium larvae could consume over 1000 nymphs in total. The maximum number of nymphs consumed per day was mid-way through their development, when Serangium larvae consumed over 200 nymphs per day (Asiimwe et al., Reference Asiimwe, Ecaat, Guershon, Kyamanywa, Gerling and Legg2007a, Reference Asiimwe, Ecaat, Otim, Gerling, Kyamanywa and Leggb). We know that cultivars of cassava with different morphologies can influence the activities of predators such as Typhlodromalus aripo, the mite that preys on the pest CGM M. tanajoa (Zundel et al., Reference Zundel, Nagel, Hanna, Korner and Scheidegger2009).

Legg & Hillocks (Reference Legg, Hillocks, Legg and Hillocks2003) lists the parasitoids attacking Bemisia genus in SSA. Thirty-four species of Encarsia and 14 species of Eretmocerus, with Eretmocerus mundus Mercet and Encarsia sophia Girault and Dodd being the most dominant (Legg et al., Reference Legg, Gerling, Neuenschwander, Neuenschwander and Langewald2003). Surveys of B. tabaci parasitoids in cassava in Tanzania identified using a molecular approach, ten species of parasitoids (Guastella et al., Reference Guastella, Lulah, Tajebe, Cavalieri, Evans, Pedata, Rapisarda and Legg2015). Hoelmer et al. (Reference Hoelmer, Gerling and Mayer1995) summarized several papers that suggested that parasitoids may be insufficient to control B. tabaci without other control methods. However, parasitism rates of up to 58% have been recorded in Uganda (table 5). Some work has been completed to quantify the impact of parasitoids on B. tabaci.

Table 5. Records of parasitism of Bemisia tabaci from field studies in East Africa.

Eretmocerus mundus and E. sophia were shown to parasitize B. tabaci on cassava in Uganda and accounted for 34% parasitism of fourth instar nymphs (Legg, Reference Legg1995). Significantly higher number of B. tabaci and parasitoids occurred on the CMD-resistant cultivar compared with a susceptible cultivar although parasitism rate was similar. Although not tested for specifically, the cultivar and presence or absence of CMD did not seem to influence parasitism rates. Per cent parasitism was recorded as <20%, and on three occasions <50%. However, results showed a significant negative relationship between parasitism rate and nymph numbers indicating that these parasitoids did not respond in a density-dependent manner (Otim et al., Reference Otim, Legg, Kyamanywa, Polaszek and Gerling2006). Life-history studies conducted under field conditions showed that dislodgement was the key mortality factor for eggs and that parasitism (mostly by E. sophia and E. mundus) caused the highest mortality to fourth instar nymphs. There was no difference in results from the treatments exposed to, or sheltered from, the rain (Asiimwe et al., Reference Asiimwe, Ecaat, Guershon, Kyamanywa, Gerling and Legg2007a, Reference Asiimwe, Ecaat, Otim, Gerling, Kyamanywa and Leggb).

There has been little research to understand how different cassava cultivars might influence the activities of natural enemies of B. tabaci. We know that cultivars of cassava with different morphologies can influence predators such as T. aripo (the mite that preys on M. tanajoa, Zundel et al., Reference Zundel, Nagel, Hanna, Korner and Scheidegger2009), and there have been some basic experiments conducted using parasitoids (Otim et al., Reference Otim, Kyalo, Kyamanywa, Asiimwe, Legg, Guershon and Gerling2008). However, a comprehensive understanding of cultivar impacts at higher trophic levels is critically needed.

Competition with other herbivores on cassava

Competition between B. tabaci and other herbivores on cassava may impact the abundance of B. tabaci. For example, the CGM M. tanajoa is often found on the top leaves of the cassava plant, making these leaves less suitable for B. tabaci adults (Legg et al., Reference Legg, Lava Kumar, Makeshkumar, Tripathi, Ferguson, Kanju, Ntawuruhunga and Cuellar2015). Interspecific interactions between pests on the same crop can significantly influence invertebrate behaviour and host-plant defences; for example, the duration and density of the aphid Myzus persicae on tomato significantly affected the number of B. tabaci (Tan et al., Reference Tan, Wang, Ridsdill-Smith and Liu2014). We could find no studies that examine the interactions between the community of pest and non-pest herbivores on cassava in East Africa.

Endosymbionts

Some evidence exists that endosymbiotic bacteria within B. tabaci can have both positive and negative effects on B. tabaci fitness (Kontsedalov et al., Reference Kontsedalov, Zchori-Fein, Chiel, Gottlieb, Inbar and Ghanim2008; Himler et al., Reference Himler, Adachi-Hagimori, Bergen, Kozuch, Kelly, Tabashnik, Chiel, Duckworth, Dennehy, Zchori-Fein and Hunter2011; Ghosh et al., Reference Ghosh, Bouvaine and Maruthi2015). Portiera aleyrodidarum is a primary obligate bacterial endosymbiont of B. tabaci, and is essential to their development. As well as obligate bacteria, they have an association with many facultative bacteria or secondary endosymbionts. In theory, these bacteria may confer some advantage for transmission of CMBs by B. tabaci and help them adapt to new host plants (Gottlieb et al., Reference Gottlieb, Zchori-Fein, Mozes-Daube, Kontsedalov, Skaljac, Brumin, Sobol, Czosnek, Vavre, Fleury and Ghanim2010; Kliot et al., Reference Kliot, Cilia, Czosnek and Ghanim2014).

The association between facultative secondary endosymbionts and various species of B. tabaci was explored using samples collected in Tanzania from cassava and adjacent host plants, mostly crops and one weed (Tajebe et al., Reference Tajebe, Boni, Guastella, Cavalieri, Lund, Rugumamu, Rapisarda and Legg2015, see graphic depicting relationships between different groups of B. tabaci such as SSA1-SG1). Most B. tabaci collected from cassava were SSA1 and most were uninfected by any of the secondary symbionts. A later study found contrasting results (Ghosh et al., Reference Ghosh, Bouvaine and Maruthi2015). Samples of B. tabaci were collected from cassava crops across East African countries were found to be infected with a range of endosymbionts, with the predominant species being Wolbachia, Rickettsia and Arsenophonus. The prevalence of these secondary endosymbionts including Wolbachia varied characteristically across each B. tabaci population (Ghosh et al., Reference Ghosh, Bouvaine and Maruthi2015). Association of the endosymbionts varied across geographical boundaries and the B. tabaci species. SSA1-SG3 in coastal Eastern Africa had high levels of Arsenophonus and Rickettsia in single or mixed infections (84%), while a small proportion (13%) was free of detectable secondary endosymbionts (Ghosh et al., Reference Ghosh, Bouvaine and Maruthi2015). In contrast, SSA1-SG1 collected in the highland regions of Uganda and around Lake Victoria had different secondary endosymbiont profiles. About 25% of SSA1-SG1 individuals were infected with Arsenophonus and Rickettsia in single or mixed infections, while equal proportion of endosymbiont-free (38%) and Wolbachia-infected individuals (37%) were found in Uganda. In laboratory studies, all three bacteria (Wolbachia, Arsenophonus and Rickettsia) were shown to negatively impact B. tabaci population development by reducing adult emergence and simultaneously increasing nymph development time, thereby reducing number of adults and the number of generations that can be developed per unit time (Ghosh et al., Reference Ghosh, Bouvaine and Maruthi2015). In addition to several factors discussed above, it has been proposed that high levels of bacteria-free B. tabaci, which are fitter and more fecund, may have contributed to high abundances in certain regions. Similar effects have been observed in Drosophila and mosquitoes infected with Wolbachia (McMeniman & O'Neill, Reference McMeniman and O'Neill2010). Thus, it is possible that the negative effects of endosymbionts in B. tabaci have been important population control mechanisms in these regions.

Abiotic factors

Altitude

There is evidence in the literature that altitude relates to population abundance of B. tabaci. However, the mechanism underlying any altitudinal variations seen in the few studies available (e.g. temperature, rainfall gradients, change in farming systems and crops grown) have not been tested (or in some cases even described). There is some evidence to suggest that cassava virus infection was lower in areas above 800 m above sea level (Legg (Reference Legg1994)). Legg & Raya (Reference Legg and Raya1998) found a significant negative correlation between CMD incidence and altitude in Tanzania. Historically, it has been noted that at high altitudes (>1000 m above sea level), there are less plant disease problems and an absence of B. tabaci in cassava, presumably due to cold temperatures. In general, there is evidence of a trend of declining CBSD incidence with increasing altitude in the coastal zone of Tanzania, but not in the lake zone (Jeremiah et al., Reference Jeremiah, Ndyetabula, Mkamilo, Haji, Muhanna, Chuwa, Kasele, Bouwmeester, Ijumba and Legg2015).

Climate and weather

As with all invertebrate pest species, long-term climate patterns and short-term weather events will influence population growth and development of B. tabaci. However, drawing conclusions beyond general statements is challenging due to a lack of information for the species associated with cassava in East Africa. In general, B. tabaci populations are favoured by high temperatures and moderate rainfall (Sseruwagi et al., Reference Sseruwagi, Sserubombwe, Legg, Ndunguru and Thresh2004). Robertson (Reference Robertson1987) described increases in the abundance of B. tabaci along coastal Kenya related to an increase in annual rainfall, and increased activity of flying adults after the end of rainy periods. Recent analyses of B. tabaci adult abundance and environmental factors have shown that abundance was higher with high minimum temperatures and lower mean annual rainfall in the coastal zone of Tanzania (Jeremiah et al., Reference Jeremiah, Ndyetabula, Mkamilo, Haji, Muhanna, Chuwa, Kasele, Bouwmeester, Ijumba and Legg2015). However, in the lake zone of Tanzania, mean annual rainfall and the length of the growing season were the most important environmental factors. Some studies note generally when numbers of B. tabaci are likely to be low in cassava fields based on the time of the year when temperatures are low and the environment is unsuitable for B. tabaci (Mbewe et al., Reference Mbewe, Kumar, Changadeya, Ntawuruhunga and Legg2015). At a finer scale, we know that micro-climate variability within a field can influence the numbers of B. tabaci found on cassava plants. Bemisia tabaci adults decrease as planting density decreased and canopy temperatures increased (Otim-Nape & Ingroot, Reference Otim-Nape, Ingroot, Terry, Akoroda and Arene1986).

If we examine studies that include B. tabaci species more broadly (i.e. not just East African studies), humidity extremes (low humidity <20% and high humidity >80%) can increase mortality of immature stages, and development rate of multiple life stages decreases dramatically with temperatures above 30–33°C (Gerling et al., Reference Gerling, Horowitz and Baumgaertner1986). Drost et al. (Reference Drost, van Lenteren and van Roermund1998) used an upper lethal temperature of 36°C to fit a development rate model for immature B. tabaci on cotton. Laboratory studies have shown that B. tabaci survival ranges from ~90% survival at 25°C and 100% RH, to <2% survival at 41°C and 20% RH (during a 2 h exposure) (Berlinger et al., Reference Berlinger, Lehmann-Sigura and Taylor1996).

Other factors and hypotheses

Pesticides

The overuse of pesticides and rapid development of resistance in B. tabaci has been shown to cause high abundance and change the identity of the common B. tabaci species in other cropping systems around the world (e.g. Crowder et al., Reference Crowder, Ellers-Kirk, Yafuso, Dennehy, Degain, Harpold, Tabashnik and Carrière2008). For example, a shift from B. tabaci MEAM1 species to MED species was found in cotton fields in Israel and this change in species composition had an impact on resistance to insecticides, with one population showing less resistance to insect growth regulators (Horowitz & Ishaaya, Reference Horowitz and Ishaaya2014). However, the use of pesticides by East African smallholder farmers has historically been low due to their cost and availability, although their use is increasing each year (de Bon et al., Reference de Bon, Huat, Parrot, Sinzogan, Martin, Malézieux and Vayssières2014). Insecticide application in cassava production landscapes in East Africa is limited to crops such as tomatoes and other fruit and vegetables (de Bon et al., Reference de Bon, Huat, Parrot, Sinzogan, Martin, Malézieux and Vayssières2014). Documented statistics on pesticides use (and especially insecticide use) patterns in cassava by smallholder farmers in East Africa is rare. Surveys of honeybee hives throughout Kenya showed low levels of pesticide contamination in the hives (Muli et al., Reference Muli, Patch, Frazier, Frazier, Torto, Baumgarten, Kilonzo, Kimani, Mumoki, Masiga, Tumlinson and Grozinger2014). Documentation of the change in insecticide use patterns over time (products, active ingredients, crops, application rates and baseline levels of resistance) may help predict the onset of resistance development and help in the development of an integrated resistance management strategy.

A new invasive species in East Africa

Given the confusion surrounding the taxonomy of species in the B. tabaci complex, we cannot rule out that there have been one or multiple incursions of an entirely new species into this region over the recent historical period. As an analogous example from outside of East Africa, the exotic pest B. tabaci MEAM1 was first detected in Australia on ornamental plants in 1994, but it was not until 2001 that high numbers on fruit and vegetable required control (Gunning et al., Reference Gunning, Byrne, Condé, Connelly, Hergstrom and Devonshire1995; Sequeira et al., Reference Sequeira, Shields, Moore and De Barro2009). After this new species entered East Africa, it may have been better able to exploit resources in cassava production landscapes, avoid attack by natural enemies, and outcompete domestic B. tabaci species. In addition to natural spread within the African continent, movement of species into new areas is possible via human-assisted transport (Caciagli, Reference Caciagli and Czosnek2007). Yet there is no empirical evidence to support this idea in East Africa (table 1).

Hybridization

The B. tabaci abundance associated with the spread of the severe CMD pandemic in Uganda in the late 1990s was believed to be due to the appearance of an invasive SSA2 B. tabaci species (Legg et al., Reference Legg, French, Rogan, Okao-Okuja and Brown2002;). However, subsequent studies by Sseruwagi (Reference Sseruwagi2005) and Mugerwa et al. (Reference Mugerwa, Rey, Alicai, Ateka, Atuncha, Ndunguru and Sseruwagi2012) showed SSA2 to be less abundant in Uganda post-invasion. Instead, the areas with high B. tabaci populations had a distinct clade of SSA1 (SSA1-SG1), and what was believed to be a hybrid of SSA2 and SSA1. More recently, Tajebe et al. (Reference Tajebe, Boni, Guastella, Cavalieri, Lund, Rugumamu, Rapisarda and Legg2015) also suggested hybridization as the underlying cause in the change from B. tabaci SSA2 to B. tabaci SSA1-SG1 in Tanzania, and that the CMD pandemic was now associated with high abundances of B. tabaci SSA1-SG1 genotype. However, empirical studies to confirm this hypothesis in East Africa have not yet occurred.

Empirically detecting such changes in field studies on a pest complex can be very challenging (but not impossible, see discussion in Liu et al., Reference Liu, Colvin and De Barro2012). The process of hybridization is unlikely to be reflected by the mtDNA COI gene currently used for identification purposes. Given the mitochondrial DNA genome's overall maternal inheritance property and its general lack of recombination hybridization between a population carrying the SSA2 mtDNA COI haplotypes with the SSA1 mtDNA COI haplotypes would result in the hybrid offspring being either SSA2 or SSA1 mtDNA COI haplotypes, but is unlikely to generate the SSA1-SG1 mtDNA COI haplotype signature. To show evidence of hybridization, we need to focus on changes in patterns in the nuclear genome, and then link these patterns with ecologically relevant fitness traits that may increase population growth and abundance on cassava.

Knowledge gaps

Given that many of the factors that potentially influence B. tabaci abundance listed in table 1 have had very little research surrounding them in East Africa, and may interact with each other in antagonistic or synergistic ways; therefore, identifying which are the critical knowledge gaps is challenging. Our focus here is on identifying knowledge gaps, which if filled, may lead to more sustainable and durable solutions to B. tabaci-associated crop damage in East Africa. Underpinning all the knowledge gaps highlighted below is the species identification issue. Without well-documented species nomenclature, set within a robust framework for identifying new species, the biological and ecological information generated may be lost rapidly. The high priority knowledge gaps are outlined below.

Which East African B. tabaci species commonly use cassava as a reproductive host plant?

Whilst B. tabaci adults are highly mobile and can be found on a number of plants, establishing which species commonly use cassava as a reproductive host plant (i.e. they can oviposit and complete nymphal development) is important. It is these species for which we need to devise targeted management interventions to control. To address this research question requires the identification of large numbers of field-collected nymphs using nuclear molecular markers, and reciprocal crossing experiments using cultures developed from nymphs reared through to adults. Laboratory studies looking at basic life-history parameters of the different species under different temperatures and humidities could then be conducted. This is also the first step in establishing if these target species also use alternate host plants besides cassava.

To what extent do non-cassava host plants contribute to the population dynamics of B. tabaci and the spread of cassava diseases?

Whilst establishing the diversity of potential host plants that can be used by B. tabaci in production landscapes is important, we must take this one step further and establish if, when and how, these alternate host plants impact B. tabaci abundance and disease spread in cassava crops. For example, can alternate host plants for B. tabaci serve as reservoirs of viruses that may be transmitted to cassava (Alabi et al., Reference Alabi, Ogbe, Bandyopadhyay, Kumar, Dixon, Hughes and Naidu2008)? If an alternative host plant is identified, but is relatively rare in the landscape, will it impact the population dynamics in cassava? Conversely, if an alternate host plant is common in the landscape, will its removal impact population dynamics in cassava? There are straightforward management recommendations that can be developed from improved understanding about alternate host plants and the role they play in an agricultural landscape.

How does the proportional availability of infected vs. uninfected cassava plants in a landscape influence disease risk and spread?

It has been suggested that B. tabaci shows preferences for infected cassava plants, and infection can alter the performance of B. tabaci at the population level. However, we do not understand how this manifests in real cassava production landscapes, with a diversity of cassava cultivars, showing different levels of disease. Modelling the spread of CMD via infected cuttings assuming that B. tabaci prefer infected over uninfected plants, in combination with the proportion of infected plants available, indicated this could have major implications for disease spread. Incorporating information at a landscape scale about which species of B. tabaci are efficient vectors of each virus would also improve model predictions. Extending this to a detailed quantification of yield loss due to cassava diseases in the presence and absence of B. tabaci at the field and landscape level is also necessary to inform future management options.

How can we use choice of cassava cultivars in production landscapes to reduce population abundances of B. tabaci?

Besides establishing the effect of different cassava cultivars on the fitness and performance of B. tabaci, we need to provide recommendations that lead to population reductions or lower risk of outbreaks at the landscape level. An understanding of the relationship between disease dynamics across a landscape, B. tabaci movement between cultivars, and cultivar diversity and abundance is needed. From this understanding, we may be able to provide location-specific recommendations about the selection of ideal cultivars, guidance on rouging and cassava-free periods. Historically, the adoption of new and improved cassava cultivars has been variable within countries, so more effort to understand the best mechanisms for ensuring that the new cultivars that are adopted also lead to B. tabaci population reductions would be valuable.

What is the impact of natural enemies in East Africa on B. tabaci and can they reduce the risk of outbreaks?

Whilst we know there are a diversity of natural enemies present in cassava fields that can cause mortality of B. tabaci, we cannot say what role these species play in reducing the frequency or likelihood of B. tabaci outbreaks (and if this will impact disease outbreaks). Given that cassava is a crop with a relatively long growth season (compared with many vegetables), and now receives relatively little pesticide applications, it is important that we explore further the potential impact of natural enemies. Furthermore, the integration of natural enemies with other management options (e.g. host-plant resistance and habitat management) is critical.

There is very little information about the natural enemies that prey on different stages of B. tabaci in field conditions and the impact they have on B. tabaci. Therefore, there is a need to better understand their biology and behaviour (life history of individual species), their relationships and interactions with other predators and parasitoids, and quantify the impact they have on B. tabaci populations. For some groups, we lack fundamental information on whether they frequently predate on B. tabaci. For other factors, such as the effect of alternative host plants (i.e. do any provide an alternative source of natural enemies to recolonize cassava crops and attack B. tabaci), dispersal ability, response to semiochemicals, and methods to increase fitness and population growth need to be determined. It is important to quantify the scale at which natural enemies may have an impact (i.e. within a few tens of metres or within 100 m of a source field), to enable us to make specific management recommendations to farmers.

How can we sustainably manage the use of insecticides in East Africa to delay or avoid resistance in B. tabaci?

If insecticide use increases in the coming years, such as in vegetable crops in or near cassava, or in cassava itself, there is the potential for B. tabaci species attacking cassava to be exposed to strong resistance selection pressures. Experiences in cotton production landscapes elsewhere have shown that resistance can develop quickly in B. tabaci (Crowder et al., Reference Crowder, Ellers-Kirk, Yafuso, Dennehy, Degain, Harpold, Tabashnik and Carrière2008; Gnankine et al., Reference Gnankine, Ketoh and Martin2013) and studies should consider establishing baseline levels of resistant alleles in populations now. Furthermore, the testing and development of products based on newer chemistries, which have less non-target impacts, needs to be conducted in East Africa.

What research methodologies do we need to develop now to enable scientists to ask the right questions in the future?

Throughout this review, we have highlighted methodological limitations that restrict research and the questions that scientists can address. For example, we need a smarter way of estimating B. tabaci adult numbers in fields with high abundances. In cases where nymphal or egg data may provide a more informative picture of a certain ecological process, counting adults could be avoided. We can develop new and fast approaches to count, collect, record and identify nymphs if that is what is needed to address a research question. A field-based method that allows us to separate virus infection borne by B. tabaci, from that borne by cuttings (or a combination of both agents) would greatly aid in our understanding of B. tabaci as a vector (see an example in Tajebe et al., Reference Tajebe, Boni, Guastella, Cavalieri, Lund, Rugumamu, Rapisarda and Legg2015). A rapid diagnostic test for virus infection at the cutting stage would enable researchers to decide which factors they wanted to examine in their study, and be confident of their results. In addition, the advent of an infield diagnostic strip would allow scientists to detect virus at a given period and easily map patterns of disease spread. In another example, the recent development of a transcriptome technique that can provide data from one B. tabaci individual by Sseruwagi et al. (Reference Sseruwagi, Wainaina, Ndunguru, Tumuhimbise, Tairo, Guo, Vrielink, Blythe, Kinene, De Marchi, Kehoe, Tanz and Boykin2017 submitted) will reduce reliance on the use of isolines for transcriptomics studies, and could therefore help to resolve some of the urgent questions about the biological differences between B. tabaci species.

What are the economic trade-offs associated with different management options for smallholder farmers, and what networks need to be available to support adoption?

Fundamental to the deployment of new management interventions, and adoption by farmers, is strong extension networks with smallholder farmers and the wider cassava value-chain actors. Without this network, the adoption of durable solutions to B. tabaci control will be slow or unlikely to occur. Furthermore, a complete economic assessment of the trade-offs for smallholder farmers associated with adopting different practices is needed to ensure that management options are set in the current-day economic realities of these farmers. Often, researchers spend a lot of time understanding the biophysical constraints on a system but neglect the linked socio-economic system in which farmers operate. To bring about change in how this pest is managed in the future, we need to assess both systems at the same time.

Conclusions

Given the right combination of environmental factors, many species of B. tabaci within the complex have the potential to become a pest at any one point in time and exhibit outbreaks in certain locations. Furthermore, these critical factors may vary from country to country and even region to region across East Africa. Our challenge is greater than just identifying factors; we must go one step further and identify which factors are the most important for smallholder farmers to manage to minimize the risk of outbreaks. This review represents a comprehensive summary of the knowledge to date, and should be used to guide future research questions by scientists all over the world addressing this challenge.

Acknowledgements

The authorship list is made up of members of the African Cassava Whitefly Project (ACWP) team (http://cassavawhitefly.org/people) who made a significant contribution to the writing of this manuscript; however, all members of the team contributed thoughts, discussion and ideas. The authors thank them for their contribution. Hazel Parry and Paul Mwebaze helpfully reviewed an early version of this manuscript. This work was supported by the Natural Resources Institute, University of Greenwich from a grant provided by the Bill & Melinda Gates foundation (Grant Agreement OPP1058938). Mark Parnell (NRI) was very helpful in facilitating this work and the broader project goals.

References

Adriko, J., Sserubombwe, W.S., Adipala, E., Bua, A., Thresh, J.M. & Edema, R. (2011) Response of improved cassava varieties in Uganda to cassava mosaic disease (CMD) and their inherent resistance mechanisms. African Journal of Agricultural Research 6, 521531.Google Scholar
Alabi, O.J., Ogbe, F.O., Bandyopadhyay, R., Kumar, P.L., Dixon, A.G.O., Hughes, J. & Naidu, R.A. (2008) Alternate hosts of African cassava mosaic virus and East African cassava mosaic Cameroon virus in Nigeria. Archives of Virology 153, 17431747. doi: 10.1007/s00705–008–0169–8.Google Scholar
Alicai, T., Omongo, C.A., Maruthi, M.N., Hillocks, R.J., Baguma, Y., Kawuki, R., Bua, A., Otim-Nape, G.W. & Colvin, J. (2007) Re-emergence of cassava brown streak disease in Uganda. Plant Disease 91, 2429. doi: 10.1094/pd-91–0024.Google Scholar
Alicai, T., Ndunguru, J., Sseruwagi, P., Tairo, F., Okao-Okuja, G., Nanvubya, R., Kiiza, L., Kubatko, L., Kehoe, M.A. & Boykin, L.M. (2016) Cassava brown streak virus has a rapidly evolving genome: implications for virus speciation, variability, diagnosis and host resistance. Scientific Reports 6, 36164. doi: 10.1038/srep36164.Google Scholar
Antony, B., Lisha, V.S., Palaniswami, M.S., Sugunan, V.S., Makeshkumar, T. & Henneberry, T.J. (2006) Bemisia tabaci (Homoptera: Aleyrodidae) and Indian cassava mosaic virus transmission. International Journal of Tropical Insect Science 26, 176182. doi: 10.1079/ijt2006110.Google Scholar
Asiimwe, P., Ecaat, J.S., Guershon, M., Kyamanywa, S., Gerling, D. & Legg, J.P. (2007 a) Evaluation of Serangium n. sp (Col., Coccinellidae), a predator of Bemisia tabaci (Hom., Aleyrodidae) on cassava. Journal of Applied Entomology 131, 7680. doi: 10.1111/j.1439–0418.2006.01122.x.Google Scholar
Asiimwe, P., Ecaat, J.S., Otim, M., Gerling, D., Kyamanywa, S. & Legg, J.P. (2007 b) Life-table analysis of mortality factors affecting populations of Bemisia tabaci on cassava in Uganda. Entomologia Experimentalis Et Applicata 122, 3744. doi: 10.1111/j.1570–7458.2006.00487.x.Google Scholar
Barbosa, L., Yuki, V.A., Marubayashi, J.M., De Marchi, B.R., Perini, F.L., Pavan, M.A., de Barros, D.R., Ghanim, M., Moriones, E., Navas-Castillo, J. & Krasue-Sakate, R. (2015) First report of Bemisia tabaci Mediterranean (Q Biotype) species in Brazil. Pest Management Science 71(4), 501504. doi: 10.1002/ps.3909.Google Scholar
Bellotti, A., Peña, J., Arias, B., Guerrero, J.M., Trujillo, H., Holguín, C. & Ortega, A. (2005) Biological control of whiteflies by indigenous natural enemies for major food crops in the Neotropics. pp. 313323 in Anderson, P.K. & Morales, F.J. (Eds) Whitefly and Whitefly-Borne Viruses in the Tropics: Building A Knowledge Base for Global Action. Colombia, International Centre for Tropical Agriculture.Google Scholar
Berlinger, M.J., Lehmann-Sigura, N. & Taylor, R.A.J. (1996) Survival of Bemisia tabaci adults under different climatic conditions. Entomologia Experimentalis Et Applicata 80, 511519.Google Scholar
Bigirimana, S., Barumbanze, P., Ndayihanzamaso, P., Shirima, R., & Legg, J.P., (2011) First report of cassava brown streak disease and associated Ugandan cassava brown streak virus in Burundi. New Disease Reports 24, 2044–0588.Google Scholar
Blagbrough, I.S., Bayoumi, S.A.L., Rowan, M.G. & Beeching, J.R. (2010) Cassava: an appraisal of its phytochemistry and its biotechnological prospects. Phytochemistry 71, 19401951. doi: 10.1016/j.phytochem.2010.09.001.Google Scholar
Bouwmeester, H., Heuvelink, G.B.M., Legg, J.P. & Stoorvogel, J.J. (2012) Comparison of disease patterns assessed by three independent surveys of cassava mosaic virus disease in Rwanda and Burundi: comparison of crop virus disease patterns in Rwanda and Burundi. Plant Pathology 61, 399412. doi: 10.1111/j.1365–3059.2011.02500.x.Google Scholar
Boykin, L.M. & De Barro, P. (2014) A practical guide to identifying members of the Bemisia tabaci species complex: and other morphologically identical species. Frontiers in Ecology and Evolution 2, doi: 10.3389/fevo.2014.00045.Google Scholar
Boykin, L.M., Shatters, R.G. Jr., Rosell, R.C., McKenzie, C.L., Bagnall, R.A., De Barro, P.J. & Frohlich, D.R. (2007) Global relationships of Bemisia tabaci (Hemiptera: Aleyrodidae) revealed using Bayesian analysis of mitochondrial COI DNA sequence. Molecular Phylogenetics and Evolution 44, 13061319.Google Scholar
Boykin, L.M., Armstrong, K.F., Kubatko, L. & De Barro, P.J. (2012) Species delimitation and global biosecurity. Evolutionary Bioinformatics 8, 137.Google Scholar
Boykin, L.M., Bell, C.D., Evans, G., Small, I. & De Barro, P.J. (2013) Is agriculture driving the diversification of the Bemisia tabaci species complex (Hemiptera: Sternorrhyncha: Aleyrodidae)? Dating, diversification and biogeographic evidence revealed. BMC Evolutionary Biology 13, 228. doi: 10.1186/1471-2148-13-228.Google Scholar
Boykin, L.M., Kinene, T., Wainaina, J., Seal, S., Mugerwa, H., Macfadyen, S., De Barro, P., Tay, W.T., Kubatko, L., Alicai, T., Omongo, C.A., Tairo, F., Ndunguru, J. & Sseruwagi, P. (2018) Review and future guide to the naming system of African Bemisia tabaci species. Systematic Entomology. Accepted January 2018.Google Scholar
Burban, C., Fishpool, L.D.C., Fauquet, C., Fargette, D. & Thouvenel, J.C. (1992) Host-associated biotypes within West African populations of the whitefly Bemisia tabaci (Genn), (Hom, Aleyrodidae). Journal of Applied Entomology 113, 416423.Google Scholar
Caciagli, P. (2007) Survival of whiteflies during long-distance transportation of agricultural products. in Czosnek, H. (ed.) Tomato Yellow Leaf Curl Virus Disease Management, Molecular Biology, Breeding for Resistance. Dordrecht, Springer.Google Scholar
Calatayud, P.A., Rahbé, Y., Delobel, B., Khuong-Huu, F., Tertuliano, M. & Le Rü, B. (1994 a) Influence of secondary compounds in the phloem sap of cassava on expression of antibiosis towards the mealybug Phenacoccus manihoti. Entomologia Experimentalis et Applicata 72, 4757. doi: 10.1111/j.1570–7458.1994.tb01801.x.Google Scholar
Calatayud, P.A., Rahbé, Y., Tjallingii, W.F., Tertuliano, M. & Le Rü, B. (1994 b) Electrically recorded feeding behaviour of cassava mealybug on host and non-host plants. Entomologia Experimentalis et Applicata 72, 219232. doi: 10.1111/j.1570–7458.1994.tb01821.x.Google Scholar
Calatayud, P.A., Rouland, C. & Le Rü, B. (1997) Influence de la linamarine dans la relation manioc-cochenille. Acta Botanica Gallica 144, 427432. doi: 10.1080/12538078.1997.10515782.Google Scholar
Calvo, F., Bolckmans, K. & Belda, J. (2012) Release rate for a pre-plant application of Nesidiocoris tenuis for Bemisia tabaci control in tomato. Biocontrol 57, 809817.Google Scholar
Chikoti, P.C., Ndunguru, J., Melis, R., Tairo, F., Shanahan, P. & Sseruwagi, P. (2013) Cassava mosaic disease and associated viruses in Zambia: occurrence and distribution. International Journal of Pest Management 59, 6372. doi: 10.1080/09670874.2012.752887.Google Scholar
Colvin, J., Fishpool, L.D.C., Fargette, D., Sherington, J. & Fauquet, C. (1998) Bemisia tabaci (Hemiptera: Aleyrodidae) trap catches in a cassava field in cote d'Ivoire in relation to environmental factors and the distribution of African cassava mosaic disease. Bulletin of Entomological Research 88, 369378.Google Scholar
Colvin, J., Otim-Nape, G.W., Holt, J., Omongo, C., Seal, S., Stevenson, P.C., Cooter, R.J. & Thresh, J.M. (1999) Factors driving the current epidemic of severe cassava mosaic disease in East Africa. pp. 7677 in VIIth International Plant Virus Epidemiology Symposium—Plant Virus Epidemiology: Current Status and Future Prospects, Aguadulce. Almeria, Spain, International Society of Plant Pathology.Google Scholar
Colvin, J., Omongo, C.A., Maruthi, M.N., Otim-Nape, G.W. & Thresh, J.M. (2004) Dual begomovirus infections and high Bemisia tabaci populations: two factors driving the spread of a cassava mosaic disease pandemic. Plant Pathology 53, 577584. doi: 10.1111/j.1365-3059.2004.01062.x.Google Scholar
Colvin, J., Omongo, C.A., Govindappa, M.R., Stevenson, P.C., Maruthi, M.N., Gibson, G., Seal, S.E., Muniyappa, V. (2006) Host-plant viral infection effects on arthropod-vector population growth, development and behaviour: management and epidemiological implications. Advances in Virus Research 67, 419452. doi: 10.1016/s0065-3527(06)67011-5.Google Scholar
Cours, G., Fargette, D., Otim-Nape, G.W. & Thresh, J.M. (1997) The epidemic of cassava mosaic virus disease in Madagascar in the 1930s-1940s: lessons for the current situation in Uganda. Tropical Science 37, 238248.Google Scholar
Crowder, D.W., Ellers-Kirk, C., Yafuso, C.M., Dennehy, T.J., Degain, B.A., Harpold, V.S., Tabashnik, B.E. & Carrière, Y. (2008) Inheritance of resistance to Pyriproxyfen in Bemisia tabaci (Hemiptera: Aleyrodidae) males and females (B biotype). Journal of Economic Entomology 101, 927932. doi: 10.1603/0022-0493(2008)101[927:IORTPI]2.0.CO;2.Google Scholar
De Barro, P. (2012) Getting the Most out of Eretmocerus Hayati, an Effective Natural Enemy of Silverleaf Whitefly. Horticulture Australia Ltd, Final Report VG08051, Elizabeth Street Sydney NSW, Australia.Google Scholar
de Bon, H., Huat, J., Parrot, L., Sinzogan, A., Martin, T., Malézieux, E. & Vayssières, J.F. (2014) Pesticide risks from fruit and vegetable pest management by small farmers in sub-Saharan Africa. A review. Agronomy for Sustainable Development 34, 723736. doi: 10.1007/s13593-014-0216-7.Google Scholar
Delatte, H., Holota, H., Warren, B.H., Becker, N., Thierry, M. & Reynaud, B. (2011) Genetic diversity, geographical range and origin of Bemisia tabaci biotype Ms. Bulletin of Entomological Research 101, 487497.Google Scholar
Drost, Y.C., van Lenteren, J.C. & van Roermund, H.J.W. (1988) Life-history parameters of different biotypes of Bemisia tabaci (Hemiptera: Aleyrodidae) in relation to temperature and host plant: a selective review. Bulletin of Entomological Research 88(3), 219229.Google Scholar
Dubern, J. (1994) Transmission of African cassava mosaic geminivirus by the whitefly Bemisia tabaci. Tropical Science 34, 8291.Google Scholar
Elbadry, E.A. (1968) Biological studies on Amblyseius aleyrodis a predator of the cotton whitefly (Acarina, Phytoseiidae). Entomophaga 13, 323329. doi: 10.1007/BF02371914.Google Scholar
Fargette, D., Fauquet, C, & Thouvenel, J. (1985). Field studies on the spread of African Cassava Mosaic. Annals of Applied Biology 106(2), 285294. doi: 10.1111/j.1744-7348.1985.tb03118.x.Google Scholar
Fargette, D., Fauquet, C. & Thouvenel, J. (1988) Yield losses induced by African cassava mosaic virus in relation to the mode and the date of infection. Tropical Pest Management 34, 8991. doi: 10.1080/09670878809371216.Google Scholar
Fargette, D., Fauquet, C., Grenier, E. & Thresh, J.M. (1990) The spread of African cassava mosaic virus into and within cassava fields. Journal of Phytopathology-Phytopathologische Zeitschrift 130, 289302. doi: 10.1111/j.1439–0434.1990.tb01179.x.Google Scholar
Fargette, D., Jeger, M., Fauquet, C. & Fishpool, L.D.C. (1993) Analysis of temporal disease progress of African cassava mosaic-virus. Phytopathology 84, 9198. doi: 10.1094/Phyto-84–91.Google Scholar
Fauquet, C. & Fargette, D. (1990) African cassava mosaic, virus, etiology, epidemiology, and control. Plant Disease 74, 404411. doi: 10.1094/pd-74–0404.Google Scholar
Fauquet, C., Fargette, D. & Thouvenel, J.C. (1988) Some aspects of the epidemiology of African cassava mosaic virus in Ivory Coast. Tropical Pest Management 34, 9296. doi: 10.1080/09670878809371217.Google Scholar
Fishpool, L.D.C. & Burban, C. (1994) Bemisia tabaci: the whitefly vector of African cassava mosaic geminivirus. Tropical Science 34, 5572.Google Scholar
Fishpool, L.D.C., Fauquet, C., Fargette, D., Thouvenel, J.C., Burban, C. & Colvin, J. (1995) The phenology of Bemisia tabaci (Homoptera: Aleyrodidae) populations on cassava in southern Côte d'Ivoire. Bulletin of Entomological Research 85, 197207. doi: 10.1017/S0007485300034271.Google Scholar
Gerling, D., Horowitz, A.R. & Baumgaertner, J. (1986) Autoecology of Bemisia tabaci. Agriculture Ecosystems & Environment 17, 519. doi: 10.1016/0167-8809(86)90022-8.Google Scholar
Ghosh, S., Bouvaine, S. & Maruthi, M. (2015) Prevalence and genetic diversity of endosymbiotic bacteria infecting cassava whiteflies in Africa. BMC Microbiology 15 doi: 10.1186/s12866-015-0425-5.Google Scholar
Gibson, R.W. & Otim-Nape, G.W. (1997) Factors determining recovery and reversion in mosaic-affected African cassava mosaic virus resistant cassava. Annals of Applied Biology 131, 259271. doi: 10.1111/j.1744-7348.1997.tb05155.x.Google Scholar
Gibson, R.W., Legg, J.P. & Otim-Nape, G.W. (1996) Unusually severe symptoms are a characteristic of the current epidemic of mosaic virus disease of cassava in Uganda. Annals of Applied Biology 128, 479490. doi: 10.1111/j.1744–7348.1996.tb07108.x.Google Scholar
Gnankine, O., Ketoh, G. & Martin, T. (2013) Dynamics of the invasive Bemisia tabaci (Homoptera: Aleyrodidae) Mediterranean (MED) species in two West African countries. International Journal of Tropical Insect Science 33, 99106. doi: 10.1017/S1742758413000040.Google Scholar
Gold, C.S., Altieri, M.A. & Bellotti, A.C. (1989) The effects of intercropping and mixed varieties of predators and parasitoids of cassava whiteflies (Hemiptera, Aleyrodidae) in Colombia. Bulletin of Entomological Research 79, 115121.Google Scholar
Gottlieb, Y., Zchori-Fein, E., Mozes-Daube, N., Kontsedalov, S., Skaljac, M., Brumin, M., Sobol, I., Czosnek, H., Vavre, F., Fleury, F. & Ghanim, M. (2010) The transmission efficiency of tomato yellow leaf curl virus by the whitefly Bemisia tabaci Is correlated with the presence of a specific symbiotic bacterium species. Journal of Virology 84, 93109317. doi: 10.1128/JVI.00423-10.Google Scholar
Gregory, P.H. (1948) The multiple-infection transformation. Annals of Applied Biology 35, 412417.Google Scholar
Guastella, D., Lulah, H., Tajebe, L.S., Cavalieri, V., Evans, G.A., Pedata, P.A., Rapisarda, C. & Legg, J.P. (2015) Survey on whiteflies and their parasitoids in cassava mosaic pandemic areas of Tanzania using morphological and molecular techniques. Pest Management Science 71, 383394. doi: 10.1002/ps.3810.Google Scholar
Gunning, R.V., Byrne, F.J., Condé, B.D., Connelly, M.I., Hergstrom, K. & Devonshire, A.L. (1995) First report of B-biotype Bemisia tabaci (Hennadius) (Hemiptera: Aleyrodidae) in Australia. Australian Journal of Entomology 34, 116116. doi: 10.1111/j.1440–6055.1995.tb01298.x.Google Scholar
Harrison, B.D., Zhou, X., Otim-Nape, G.W., Liu, Y. & Robinson, D.J. (1997) Role of a novel type of double infection in the geminivirus-induced epidemic of severe cassava mosaic in Uganda. Annals of Applied Biology 131, 437448. doi: 10.1111/j.1744–7348.1997.tb05171.x.Google Scholar
Hillocks, R.J. & Jennings, D.L. (2003) Cassava brown streak disease: a review of present knowledge and research needs. International Journal of Pest Management 49, 225234. doi: 10.1080/0967087031000101061.Google Scholar
Himler, A.G., Adachi-Hagimori, T., Bergen, J.E., Kozuch, A., Kelly, S.E., Tabashnik, B.E., Chiel, E., Duckworth, V.E., Dennehy, T.J., Zchori-Fein, E. & Hunter, M.S. (2011) Rapid spread of a bacterial symbiont in an invasive whitefly is driven by fitness benefits and female bias. Science 332, 254256. doi: 10.1126/science.1199410.Google Scholar
Hoelmer, K., Gerling, D. & Mayer, R.T. (1995) Whitefly Parasitoids: Can They Control Field Populations of Bemisia? England, Intercept Andover.Google Scholar
Holt, J. & Colvin, J. (2001) Observation and theory of whitefly-borne virus disease epidemics. pp. 331343 in Edited for the British Society for Plant Pathology by Jeger, M.J. & Spence, N.J. (Eds) Biotic Interactions in Plant-Pathogen Associations. Wallingford, Oxon, UK, CABI publishing. ISBN no s 0 85199 512 8.Google Scholar
Horowitz, A.R. & Ishaaya, I. (2014) Dynamics of biotypes B and Q of the whitefly Bemisia tabaci and its impact on insecticide resistance. Pest Management Science 70, 15681572. doi: 10.1002/ps.3752.Google Scholar
Jameson, J.D. (1964) Cassava mosaic disease in Uganda. East African Agricultural and Forestry Journal 29, 208213. doi: 10.1080/00128325.1964.11661927.Google Scholar
Jeremiah, S.C., Ndyetabula, I.L., Mkamilo, G.S., Haji, S., Muhanna, M.M., Chuwa, C., Kasele, S., Bouwmeester, H., Ijumba, J.N. & Legg, J.P. (2015) The dynamics and environmental influence on interactions between cassava brown streak disease and the whitefly, Bemisia tabaci. Phytopathology 105, 646655. doi: 10.1094/PHYTO-05-14-0146-R.Google Scholar
Katono, K., Alicai, T., Baguma, Y., Edema, R., Bua, A. & Omongo, C. (2015) Influence of host plant resistance and disease pressure on spread of cassava brown streak disease in Uganda. American Journal of Experimental Agriculture 7, 284293. doi: 10.9734/AJEA/2015/15563.Google Scholar
Kliot, A., Cilia, M., Czosnek, H. & Ghanim, M. (2014) Implication of the bacterial endosymbiont Rickettsia spp. in interactions of the whitefly Bemisia tabaci with tomato yellow leaf curl virus. Journal of Virology 88, 56525660. doi: 10.1128/JVI.00071–14.Google Scholar
Kontsedalov, S., Zchori-Fein, E., Chiel, E., Gottlieb, Y., Inbar, M. & Ghanim, M. (2008) The presence of rickettsia is associated with increased susceptibility of Bemisia tabaci (Homoptera: Aleyrodidae) to insecticides. Pest Management Science 64, 789–782. doi: 10.1002/ps.1595.Google Scholar
Kristensen, N.P., Schellhorn, N.A., Hulthen, A.D., Howie, L.J. & De Barro, P.J. (2013) Wind-borne dispersal of a parasitoid: the process, the model, and its validation. Environmental Entomology 42, 11371148. doi: 10.1603/EN12243.Google Scholar
Laarif, A., Saleh, D., Clouet, C. & Gauthier, N. (2015) Regional co-occurrence between distinct Bemisia tabaci species in Tunisia with new insights into the role of host plants. Phytoparasitica 43, 135150. doi: 10.1007/s12600–014–0437-y.Google Scholar
Legg, J.P. (1994) Bemisia tabaci: the whitefly vector of cassava mosaic geminiviruses in Africa: an ecological perspective. African Crop Science Journal 2, 437448.Google Scholar
Legg, J.P. (1995) The ecology of Bemisia tabaci (Gennadius) (Homoptera), vector of African cassava mosaic geminivirus in Uganda. PhD, University of Reading, UK.Google Scholar
Legg, J.P. (1999) Emergence, spread and strategies for controlling the pandemic of cassava mosaic virus disease in east and Central Africa. Crop Protection 18, 627637. doi: 10.1016/S0261-2194(99)00062-9.Google Scholar
Legg, J.P. & Hillocks, R.J. (2003) Cassava brown streak virus disease; past present and future. pp. 89 in Legg, J.P. & Hillocks, R.J. (Eds) Proceedings of an International Workshop, Mombasa, Kenya, 27–30 October 2002. Aylesford, UK, Natural Resources International Limited.Google Scholar
Legg, J.P. & Ogwal, S. (1998) Changes in the incidence of African cassava mosaic virus disease and the abundance of its whitefly vector along south-north transects in Uganda. Journal of Applied Entomology-Zeitschrift Fur Angewandte Entomologie 122, 169178.Google Scholar
Legg, J.P. & Raya, M.D. (1998) Survey of cassava virus diseases in Tanzania. International Journal of Pest Management 44, 1723.Google Scholar
Legg, J.P. & Thresh, J.M. (2000) Cassava mosaic virus disease in East Africa: a dynamic disease in a changing environment. Virus Research 71, 135149. doi: 10.1016/S0168-1702(00)00194-5.Google Scholar
Legg, J.P., French, R., Rogan, D., Okao-Okuja, G. & Brown, J.K. (2002) A distinct Bemisia tabaci (Gennadius) (Hemiptera: Sternorrhyncha: Aleyrodidae) genotype cluster is associated with the epidemic of severe cassava mosaic virus disease in Uganda. Molecular Ecology 11, 12191229.Google Scholar
Legg, J., Gerling, D. & Neuenschwander, P. (2003) Biological control of whiteflies in sub-Saharan Africa. pp. 87100 in Neuenschwander, P. & Langewald, J. (Eds) Biological Control in IPM Systems in Africa. Wallingford, UK, CAB International.Google Scholar
Legg, J., Owor, B., Sseruwagi, P. & Ndunguru, J. (2006) Cassava mosaic virus disease in East and Central Africa: epidemiology and management of a regional pandemic. Advances in Virus Research 67, 355418.Google Scholar
Legg, J.P., Jeremiah, S.C., Obiero, H.M., Maruthi, M.N., Ndyetabula, I., Okao-Okuja, G., Bouwmeester, H., Bigirimana, S., Tata-Hangy, W., Gashaka, G., Mkamilo, G., Alicai, T. & Kumar, P.L. (2011) Comparing the regional epidemiology of the cassava mosaic and cassava brown streak virus pandemics in Africa. Virus Research 159, 161170. doi: 10.1016/j.virusres.2011.04.018.Google Scholar
Legg, J.P., Sseruwagi, P., Boniface, S., Okao-Okuja, G., Shirima, R., Bigirimana, S., Gashaka, G., Herrmann, H.W., Jeremiah, S., Obiero, H., Ndyetabula, I., Tata-Hangy, W., Masembe, C. & Brown, J.K. (2014 a) Spatio-temporal patterns of genetic change amongst populations of cassava Bemisia tabaci whiteflies driving virus pandemics in East and Central Africa. Virus Research 186, 6175. doi: 10.1016/j.virusres.2013.11.018.Google Scholar
Legg, J.P., Shirima, R., Tajebe, L.S., Guastella, D., Boniface, S., Jeremiah, S., Nsami, E., Chikoti, P. & Rapisarda, C. (2014b) Biology and management of Bemisia whitefly vectors of cassava virus pandemics in Africa. Pest Management Science 70, 14461453. doi: 10.1002/ps.3793.Google Scholar
Legg, J.P., Lava Kumar, P., Makeshkumar, T., Tripathi, L., Ferguson, M., Kanju, E., Ntawuruhunga, P. & Cuellar, W. (2015) Cassava virus diseases. Advances in Virus Research 91, 85–42.Google Scholar
Leuschner, K. (1977) Whiteflies: biology and transmission of African mosaic disease. pp. 5158 in Brekelbaum, T., Bellotti, A. & Lozano, C.J. (Eds) Proceedings of the Cassava Protection Workshop, CIAT, 7–12 November, 1977 Cali. Colombia, The International Center for Tropical Agriculture.Google Scholar
Liu, S.S., Colvin, J. & De Barro, P. (2012) Species concepts as applied to Bemisia tabaci systematics: how many species are there? Journal of Integrative Agriculture 11, 176186.Google Scholar
Mabasa, K.G. (2007) Epidemiology of Cassava Mosaic Disease and Molecular Characterization of Cassava Mosaic Viruses and Their Associated Whitefly (Bemisia tabaci) Vector in South Africa. Johannesburg, University of the Witwatersrand.Google Scholar
Manani, D.M., Ateka, E.M., Nyanjom, S.R.G. & Boykin, L.M. (2017) Phylogenetic relationships among whiteflies in the Bemisia tabaci (Gennadius) species complex from major cassava growing areas in Kenya. Insects 8, 114. doi: 10.3390/insects8010025.Google Scholar
Maruthi, M.N., Colvin, J., Seal, S. & Thresh, J.M. (2002a). First report of a distinct begomovirus infecting cassava from Zanzibar. Plant Disease 86, 187.Google Scholar
Maruthi, M.N., Colvin, J., Seal, S., Gibson, G. & Cooper, J. (2002b) Co-adaptation between cassava mosaic geminiviruses and their local vector populations. Virus Research 86, 7185. doi: 10.1016/s0168-1702(02)00051-5.Google Scholar
Maruthi, M.N., Hillocks, R.J., Mtunda, K., Raya, M.D., Muhanna, M., Kiozia, H., Rekha, A.R., Colvin, J. & Thresh, J.M. (2005) Transmission of cassava brown streak virus by Bemisia tabaci (Gennadius). Journal of Phytopathology 153, 307312. doi: 10.1111/j.1439–0434.2005.00974.x.Google Scholar
Mbewe, W., Kumar, P.L., Changadeya, W., Ntawuruhunga, P. & Legg, J. (2015) Diversity, distribution and effects on cassava cultivars of cassava brown streak viruses in Malawi. Journal of Phytopathology 163, 433443. doi: 10.1111/jph.12339.Google Scholar
McGrath, P.F. & Harrison, B.D. (1995) Transmission of tomato leaf curl geminiviruses by Bemisia tabaci: effects of virus isolate and vector biotype. Annals of Applied Biology 126, 307316. doi: 10.1111/j.1744–7348.1995.tb05368.x.Google Scholar
McMeniman, C.J. & O'Neill, S.L. (2010) A virulent Wolbachia infection decreases the viability of the dengue vector Aedes aegypti during periods of embryonic quiescence (C-C Chen, Ed.). PLoS Neglected Tropical Diseases 4, e748. doi: 10.1371/journal.pntd.0000748.Google Scholar
McQuaid, C.F., van den Bosch, F., Szyniszewska, A., Alicai, T., Pariyo, A., Chikoti, P.C. & Gilligan, C.A. (2017) Spatial dynamics and control of a crop pathogen with mixed-mode transmission. PLoS Computational Biology 13, e1005654.Google Scholar
Meyerdirk, D.E. & Coudriet, D.L. (1985) Predation and developmental studies of Euseius hibisci (Chant) (Acarina, Phytoseiidae) feeding on Bemisia tabaci (Gennadius) (Homoptera, Aleyrodidae). Environmental Entomology 14, 2427.Google Scholar
Mohammed, I.U., Ghosh, S. & Maruthi, M.N. (2016) Host and virus effects on reversion in cassava affected by cassava brown streak disease. Plant Pathology 65, 593600. doi: 10.1111/ppa.12458.Google Scholar
Morales, F.J. & Jones, P.G. (2004) The ecology and epidemiology of whitefly-transmitted viruses in Latin America. Virus Research 100, 5765. doi: 10.1016/j.virusres.2003.12.014.Google Scholar
Mugerwa, H., Rey, M.E., Alicai, T., Ateka, E., Atuncha, H., Ndunguru, J. & Sseruwagi, P. (2012) Genetic diversity and geographic distribution of Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) genotypes associated with cassava in East Africa. Ecol Evol 2, 27492762. doi: 10.1002/ece3.379.Google Scholar
Muimba-Kankolongo, A., Chalwe, A., Sisupo, P. & Kang, M. (1997) Distribution, prevalence and outlook for control of cassava mosaic disease in Zambia. Roots 4, 27.Google Scholar
Muli, E., Patch, H., Frazier, M., Frazier, J., Torto, B., Baumgarten, T., Kilonzo, J., Kimani, J.N., Mumoki, F., Masiga, D., Tumlinson, J. & Grozinger, C. (2014) Evaluation of the distribution and impacts of parasites, pathogens, and pesticides on honey bee (Apis mellifera) populations in East Africa. PLoS ONE 9, e94459. doi: 10.1371/journal.pone.0094459.Google Scholar
Ndunguru, J., Sseruwagi, P., Tairo, F., Stomeo, F., Maina, S., Djikeng, A., Kehoe, M. & Boykin, L.M. (2015) Analyses of twelve new whole genome sequences of cassava brown streak viruses and Ugandan cassava brown streak viruses from east Africa: diversity, supercomputing and evidence for further speciation. PLoS ONE 10, E0139321.Google Scholar
Nelson, S. (2008) Sooty Mold. Plant Disease PD-52. Mänoa, Honolulu, Hawai‘i, Cooperative extension Service, College of Tropical Agriculture and Human Resources, University of Hawaii.Google Scholar
Nichols, R.F. (1950) The brown streak disease of cassava distribution climatic effects and diagnostic symptoms. The East African Agricultural Journal 15, 154160.Google Scholar
Night, G., Asiimwe, P., Gashaka, G., Nkezabahizi, D., Legg, J.P., Okao-Okuja, G., Obonyo, R., Nyirahorana, C., Mukakanyana, C., Mukase, F., Munyabarenzi, I. & Mutumwinka, M. (2011) Occurrence and distribution of cassava pests and diseases in Rwanda. Agriculture Ecosystems & Environment 140, 492497. doi: 10.1016/j.agee.2011.01.014.Google Scholar
Ntawuruhunga, P. & Legg, J. (2007) New Spread of Cassava Brown Streak Virus Disease and its Implications for the Movement of Cassava Germplasm in the East and Central African Region. International Institute of Tropical Agriculture-Uganda & Eastern Africa Root Crops Research Network, Kampala, Uganda. Network Report.Google Scholar
Oliveira, M.R.V., Henneberry, T.J. & Anderson, P. (2001) History, current status, and collaborative research projects for Bemisia tabaci. Crop Protection 20, 709723.Google Scholar
Omongo, C.A. (2003) Cassava whitefly, Bemesia tabaci, behaviour and ecology in relation to the spread of the cassava mosaic epidemic in Uganda. PhD, University of Greenwich, UK.Google Scholar
Omongo, C.A., Kawuki, R., Bellotti, A.C., Alicai, T., Baguma, Y., Maruthi, M.N., Bua, A. & Colvin, J. (2012) African cassava whitefly, Bemisia tabaci, resistance in African and South American cassava genotypes. Journal of Integrative Agriculture 11, 327336. doi: 10.1016/s2095-3119(12)60017-3.Google Scholar
Otim, M., Legg, J., Kyamanywa, S., Polaszek, A. & Gerling, D. (2005) Occurrence and activity of Bemisia tabaci parasitoids on cassava in different agro-ecologies in Uganda. Biocontrol 50, 8795. doi: 10.1007/s10526-004-0822-4.Google Scholar
Otim, M., Legg, D.J., Kyamanywa, S., Polaszek, A. & Gerling, D. (2006) Population dynamics of Bemisia tabaci (Homoptera: Aleyrodidae) parasitoids on cassava mosaic disease–resistant and susceptible varieties. Biocontrol Science and Technology 16, 205214. doi: 10.1080/09583150500335558.Google Scholar
Otim, M., Kyalo, G., Kyamanywa, S., Asiimwe, P., Legg, J.P., Guershon, M. & Gerling, D. (2008) Parasitism of Bemisia tabaci (Homoptera: Aleyrodidae) by Eretmocerus mundus (Hymenoptera: Aphelinidae) on cassava. International Journal of Tropical Insect Science 28, 158. doi: 10.1017/s1742758408093181.Google Scholar
Otim-Nape, G.W. & Ingroot, D. (1986) Effect of cultural practices on the African cassava mosaic disease and its vector. pp. 105108 in Terry, E.R., Akoroda, M.O. & Arene, O.B. (Eds) Proceedings of the Third Triennial Symposium of the International Society for Tropical Root Crops, Owerri, Nigeria 17–23 August 1986. IDRC 258E. Owerri, Nigeria, Ottawa International Development Research Centre.Google Scholar
Otim-Nape, G.W., Thresh, J.M. & Fargette, D. (1995) Bemisia tabaci and cassava mosaic virus disease in Africa. pp. 319350 in Gerling, D. & Mayer, R.T. Bemisia 1995: Taxonomy, Biology, Damage, Control and Management. Andover, England, Intercept Ltd.Google Scholar
Otim-Nape, G.W., Thresh, J.M. & Shaw, M.W. (1998) The incidence and severity of cassava mosaic virus disease in Uganda: 1990–92. Tropical Science 38, 2537.Google Scholar
Otim-Nape, G.W., Bua, A., Thresh, J.M., Baguma, Y., Ogwal, S., Ssemakula, G.N., Acola, G., Byabakama, B., Colvin, J., Cooter, R.J. & Martin, A. (2000) The Current Pandemic of Cassava Mosaic Virus Disease in East Africa and its Control. Chatham, UK, Natural Resources Institute Catalogue Services No. PSTC28, University of Greenwich.Google Scholar
Otim-Nape, G.W., Alicai, T. & Thresh, J.M. (2001) Changes in the incidence and severity of cassava mosaic virus disease, varietal diversity and cassava production in Uganda. Annals of Applied Biology 138, 313327.Google Scholar
Patil, B.L. & Fauquet, C.M. (2010) Differential interaction between cassava mosaic geminiviruses and geminivirus satellites. Journal of General Virology 91, 18711882. doi: 10.1099/vir.0.019513-0.Google Scholar
Patil, B., Legg, J., Kanju, E. & Fauquet, C. (2015) Cassava brown streak disease: a threat to food security in Africa. Journal of General Virology 96, 956968.Google Scholar
Polston, J.E., De Barro, P. & Boykin, L.M. (2014) Transmission specificities of plant viruses with the newly identified species of the Bemisia tabaci species complex. Pest Management Science 70, 15471552. doi: 10.1002/ps.3738.Google Scholar
Riis, L., Bellotti, A.C., Bonierbale, M. & O'Brien, G.M. (2003) Cyanogenic potential in cassava and its influence on a generalist insect herbivore Cyrtomenus bergi (Hemiptera: Cydnidae). Journal of Economic Entomology 96, 19051914. doi: 10.1603/0022–0493–6.6.1905.Google Scholar
Robertson, I.A.D. (1987) The whitefly, Bemisia tabaci (Gennadius) as a vector of African cassava mosaic virus at the Kenya coast and ways in which the yield losses in cassava, Manihot esculenta Crantz caused by the virus can be reduced. Insect Science and its Application 8, 797801.Google Scholar
Sequeira, R.V., Shields, A., Moore, A. & De Barro, P. (2009) Inter-seasonal population dynamics and pest status of Bemisia tabaci (Gennadius) biotype B in an Australian cropping system. Bulletin of Entomological Research 99, 325. doi: 10.1017/S000748530800638X.Google Scholar
Sseruwagi, P. (2005) Molecular variability of cassava Bemisia tabaci and its effect on the epidemiology of cassava mosaic geminiviruses in Uganda. PhD Thesis, The University of Witwatersrand, Johannesburg, South Africa.Google Scholar
Sseruwagi, P., Otim-Nape, G.W., Osiru, D.S.O. & Thresh, J.M. (2003) Influence of NPK fertiliser on populations of the whitefly vector and incidence of cassava mosaic virus disease. African Crop Science Journal 11, 171179.Google Scholar
Sseruwagi, P., Sserubombwe, W.S., Legg, J.P., Ndunguru, J. & Thresh, J.M. (2004) Methods of surveying the incidence and severity of cassava mosaic disease and whitefly vector populations on cassava in Africa: a review. Virus Research 100, 129142. doi: 10.1016/j.virusres.2003.12.021.Google Scholar
Sseruwagi, P., Legg, J.P., Maruthi, M.N., Colvin, J., Rey, M.E.C. & Brown, J.K. (2005) Genetic diversity of Bemisia tabaci (Gennadius) (Hemiptera: Aleyrodidae) populations and presence of the B biotype and a non-B biotype that can induce silverleaf symptoms in squash, in Uganda. Annals of Applied Biology 147, 253265. doi: 10.1111/j.1744–7348.2005.00026.x.Google Scholar
Sseruwagi, P., Maruthi, M.N., Colvin, J., Rey, M.E.C., Brown, J.K. & Legg, J.P. (2006) Colonization of non-cassava plant species by cassava whiteflies (Bemisia tabaci) in Uganda. Entomologia Experimentalis et Applicata 119, 145153.Google Scholar
Sseruwagi, P., Wainaina, J., Ndunguru, J., Tumuhimbise, R., Tairo, F., Guo, J., Vrielink, A., Blythe, A., Kinene, T., De Marchi, B., Kehoe, M.A., Tanz, S. & Boykin, L.M. (2017) The first transcriptomes from field-collected individual whiteflies (Bemisia tabaci, Hemiptera: Aleyrodidae). Gates Open Research 1, 16 doi: 10.12688/gatesopenres.12783.1.Google Scholar
Storey, H.H. & Nichols, R.F.W. (1938) Studies of the mosaic of cassava. Annals of Applied Biology 25, 790806.Google Scholar
Swanson, M.M. & Harrison, B.D. (1994) Properties, relationships and distribution of cassava mosaic geminiviruses. Tropical Science 34, 1525.Google Scholar
Tajebe, L.S., Boni, S.B., Guastella, D., Cavalieri, V., Lund, O.S., Rugumamu, C.P., Rapisarda, C. & Legg, J.P. (2015) Abundance, diversity and geographic distribution of cassava mosaic disease pandemic-associated Bemisia tabaci in Tanzania. Journal of Applied Entomology 139, 627637. doi: 10.1111/jen.12197.Google Scholar
Tan, X-L., Wang, S., Ridsdill-Smith, J. & Liu, T-X. (2014) Direct and indirect impacts of infestation of tomato plant by Myzus persicae (Hemiptera: Aphididae) on Bemisia tabaci (Hemiptera: Aleyrodidae). PLoS ONE 9, e94310. doi: 10.1371/journal.pone.0094310.Google Scholar
Thompson, W.M.O. (2000) Development, morphometrics and other biological characteristics of the whitefly Bemisia tabaci (Gennadius) on cassava. Insect Science and its Application 20, 251258.Google Scholar
Thompson, W.M.O. (2011) Interaction of Bemisia tabaci with East African cassava mosaic virus-infected plants. pp. 107119 in Thompson, W.M.O. (Ed.) The Whitefly, Bemisia tabaci (Homoptera: Aleyrodidae) Interaction with Geminivirus-Infected Host Plants. Netherlands, Springer. doi:10.1007/978-94-007-1524-0_6.Google Scholar
Thresh, J.M., Otim-Nape, G.W., Legg, J.P. & Fargette, D. (1997) African cassava mosaic virus disease: the magnitude of the problem. African Journal of Root and Tuber Crops 2, 13.Google Scholar
Uzokwe, V.N.E., Mlay, D.P., Masunga, H.R., Kanju, E., Odeh, I.O.A. & Onyeka, J. (2016) Combating viral mosaic disease of cassava in the Lake Zone of Tanzania by intercropping with legumes. Crop Protection 84, 6980. doi: 10.1016/j.cropro.2016.02.013.Google Scholar
Wang, H-L., Yang, J., Boykin, L.M., Zhao, Q-Y., Wang, Y-J., Liu, S-S. & Wang, X-W. (2014) Developing conversed microsatellite markers and their implications in evolutionary analysis of the Bemisia tabaci complex. Scientific Reports 4, 6351. doi: 10.1038/srep06351.Google Scholar
Xu, J., De Barro, P.J. & Liu, S.S. (2010) Reproductive incompatibility among genetic groups of Bemisia tabaci supports the proposition that the whitefly is a cryptic species complex. Bulletin of Entomological Research 100, 359366. doi: 10.1017/S0007485310000015.Google Scholar
Zundel, C., Nagel, P., Hanna, R., Korner, F. & Scheidegger, U. (2009) Environment and host-plant genotype effects on the seasonal dynamics of a predatory mite on cassava in sub-humid tropical Africa. Agricultural and Forest Entomology 11, 321331. doi: 10.1111/j.1461-9563.2009.00429.x.Google Scholar
Figure 0

Table 1. Potential factors influencing Bemisia tabaci abundance on cassava included in this review (does not include interactions between these factors). We have suggested the likely direction of the effect in terms of an increase (↑) or decrease (↓) in B. tabaci abundance, but note there are many possible outcomes for some of these factors.

Figure 1

Table 2. Review articles with relevant information about Bemisia tabaci biology and ecology.

Figure 2

Fig. 1. Timeline of events of Bemisia tabaci and associated disease outbreaks in East Africa. CMV, cassava mosaic virus; CMD, cassava mosaic disease; CBSV, cassava brown streak virus, CBSD, cassava brown steak disease.

Figure 3

Table 3. Studies quantifying the mean number of adults (unless otherwise mentioned) Bemisia tabaci on cassava. General method used was counting the numbers of adults observed on the top five expanded leaves on 30 plants per field and on cassava aged 3–6 months after planting (Sseruwagi et al., 2004). There was some variation in methods between studies.

Figure 4

Table 4. Host plants of Bemisia tabaci in East Africa from the published literature.

Figure 5

Table 5. Records of parasitism of Bemisia tabaci from field studies in East Africa.