Hostname: page-component-586b7cd67f-dlnhk Total loading time: 0 Render date: 2024-11-22T18:03:36.669Z Has data issue: false hasContentIssue false
  • English
  • Français

Conservation value of vanilla agroecosystems for vertebrate diversity in north-east Madagascar

Published online by Cambridge University Press:  17 June 2022

Daniel Hending Open the ORCID record for Daniel Hending [Opens in a new window] ,
Angelo Andrianiaina ,
Zafimahery Rakotomalala  and
Sam Cotton Open the ORCID record for Sam Cotton [Opens in a new window]
Daniel Hending
Affiliation:
Department of Field Conservation & Science, Bristol Zoological Society, Bristol Zoo Gardens, Clifton, Bristol, BS8 3HA, UK
Angelo Andrianiaina
Affiliation:
Mention Zoologie et Biodiversité Animale, Université d'Antananarivo, Antananarivo, Madagascar
Zafimahery Rakotomalala
Affiliation:
Mention Zoologie et Biodiversité Animale, Université d'Antananarivo, Antananarivo, Madagascar
Sam Cotton*
Affiliation:
Department of Field Conservation & Science, Bristol Zoological Society, Bristol Zoo Gardens, Clifton, Bristol, BS8 3HA, UK
*
(Corresponding author, [email protected])
Rights & Permissions [Opens in a new window]

Abstract

As a result of increasing global demand for food, large areas of natural habitat are being converted to agroecosystems to accommodate crop cultivation. This agricultural expansion is most prominent in the tropics, where many rural communities are dependent solely on farming income for their livelihoods. Such agricultural land conversion can have severe implications for local fauna. In this study, we compared vertebrate species diversity between natural forest habitat and three types of vanilla plantations maintained under varying management regimes in north-east Madagascar. We used diurnal and nocturnal transects to survey vertebrate diversity. Natural forest habitat contained the greatest vertebrate species diversity, and had proportionally more threatened and endemic species than all vanilla plantation types. However, we observed a greater number of species and a higher inverse Simpson index in minimally managed vanilla plantations located within or near natural forest compared to intensively managed vanilla plantations. These findings are important and encouraging for animal conservation and sustainable crop cultivation in Madagascar, and suggest that newly created vanilla plantations, and already existing plantations, should endeavour to follow the more traditional, minimalistic management approach to improve sustainability and promote higher faunal diversity.

Keywords

Agroforestryanimal conservationbiodiversityhabitat managementMadagascarspecies richnessvanilla plantationvertebrate surveys
Type
Article
Information
Oryx , Volume 57 , Issue 1 , January 2023 , pp. 118 - 128
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 © The Author(s), 2022. Published by Cambridge University Press on behalf of Fauna & Flora International

Introduction

As a result of global human population expansion, almost half of the Earth's land cover has been modified to accommodate agricultural areas (Vitousek et al., Reference Vitousek, Mooney, Lubchenco and Melillo1997; Foley et al., Reference Foley, DeFries, Asner, Barford, Bonan and Carpenter2005; Pongratz et al., Reference Pongratz, Reick, Raddatz and Claussen2008; Flohre et al., Reference Flohre, Fischer, Aavik, Bengtsson, Berendse and Bommarco2011; Hanke et al., Reference Hanke, Böhner, Dreber, Jürgens, Schmeidel and Wesuls2014). This global demand for arable land is predicted to increase further as human populations continue to rise and encroach on remaining areas of natural habitat (Dunn, Reference Dunn2004; Godfray et al., Reference Godfray, Beddington, Crute, Haddad, Lawrence and Muir2010; Phalan et al., Reference Phalan, Balmford, Green and Scharlemann2011; Tscharntke et al., Reference Tscharntke, Clough, Wanger, Jackson, Motzke and Perfecto2012). Land conversion can have a profoundly detrimental effect on the diversity of native fauna and flora (Tilman et al., Reference Tilman, Cassman, Matson, Naylor and Polasky2002; Pongratz et al., Reference Pongratz, Reick, Raddatz and Claussen2008; Medan et al., Reference Medan, Torretta, Hodara, de la Fuente and Montaldo2011), and data on the effects of specific agricultural practices on biodiversity are urgently needed to curb loss of species, especially in the tropics (Dunn, Reference Dunn2004; Harvey et al., Reference Harvey, Medina, Sanchez, Vilchez, Hernandez and Saenz2006; Newbold et al., Reference Newbold, Oppenheimer, Etard and Williams2020).

Cash-crop plantations are one example of anthropogenic, agricultural environments that have replaced areas once dominated by natural forest (Vallan et al., Reference Vallan, Andreone, Raherisoa and Dolch2004; Razakamanarivo et al., Reference Razakamanarivo, Razakavololona, Razafindrakoto, Vieilledent and Albrecht2012). These plantations are agroecosystems, functional areas of agricultural activity that harbour an ecosystem of living organisms, and they are often associated with reduced biodiversity (Perfecto & Vandermeer, Reference Perfecto and Vandermeer2008). For instance, amphibian diversity was lower in exotic tree plantations converted from intact forest (Vallan, Reference Vallan2002; Vallan et al., Reference Vallan, Andreone, Raherisoa and Dolch2004). However, some species are known to make use of these agricultural environments. Crop species such as coffee, tea, cacao and rubber are sometimes cultivated in diversified agroforestry systems in which native trees are integrated with the crop plants (Leakey, Reference Leakey1996), and these systems are beneficial to native vertebrates as they provide potential travel routes, refuges and feeding opportunities (Donald, Reference Donald2004; Faria et al., Reference Faria, Paciencia, Dixo, Laps and Baumgarten2007; Ranganathan et al., Reference Ranganathan, Daniels, Chandran, Ehrlich and Daily2008; Clough et al., Reference Clough, Putra, Pitopang and Tscharntke2009; Anand et al., Reference Anand, Krishnaswamy, Kumar and Bali2010; Venugopal, Reference Venugopal2010; Eppley et al., Reference Eppley, Donati, Ramanamanjato, Randriatafika, Andriamandimbiarisoa and Rabehevitra2015; Webber et al., Reference Webber, Solofondranohatra, Razafindramoana, Fernández, Parker and Steer2020). The method of cultivation in such diversified systems appears to have consequences for biodiversity, with systems managed under less intensive regimes suffering the lowest biodiversity loss (Faria et al., Reference Faria, Paciencia, Dixo, Laps and Baumgarten2007; Perfecto & Vandermeer, Reference Perfecto and Vandermeer2008).

Madagascar is known for its exceptional biodiversity and endemism (Myers et al., Reference Myers, Mittermeier, Mittermeier, da Fonseca and Kent2000; Goodman & Benstead, Reference Goodman and Benstead2005; Wilme et al., Reference Wilme, Goodman and Ganzhorn2006). Driven by a rapid increase in human population, prices of and international demand for cash crops, and a consequent increase in demand for crop cultivation areas (Irwin et al., Reference Irwin, Wright, Birkinshaw, Fisher, Gardner and Glos2010; Rogers et al., Reference Rogers, Glew, Honzak and Hudson2010; Schwitzer et al., Reference Schwitzer, Glatt, Nekaris and Ganzhorn2011; Llopis et al., Reference Llopis, Harimalala, Bär, Heinimann, Rabemananjara and Zaehringer2019), Malagasy habitats are suffering large-scale fragmentation and loss of primary vegetation (Ganzhorn et al., Reference Ganzhorn, Lowry, Schatz and Sommer2001; Harper et al., Reference Harper, Steininger, Tucker and Juhn2007; Vieilledent et al., Reference Vieilledent, Grinand, Rakotomalala, Ranaivosoa, Rakotoarijaona and Allnutt2018). It remains unclear how animal species respond to these agricultural environments, whether they are a suitable habitat for Madagascar's already fragile biota and if agroforestry brings oppurtunities for biodiversity conservation (Ganzhorn, Reference Ganzhorn1987; Ramanamanjato & Ganzhorn, Reference Ramanamanjato and Ganzhorn2001).

Cash-crop plantations such as vanilla, cacao, coffee, sugarcane and timber (e.g. Eucalyptus sp.) are common in north-east Madagascar (Ramanamanjato & Ganzhorn, Reference Ramanamanjato and Ganzhorn2001; Razakamanarivo et al., Reference Razakamanarivo, Razakavololona, Razafindrakoto, Vieilledent and Albrecht2012; Bomgardner, Reference Bomgardner2016) and have replaced pre-existing natural forests (Irwin et al., Reference Irwin, Wright, Birkinshaw, Fisher, Gardner and Glos2010; Schwitzer et al., Reference Schwitzer, Glatt, Nekaris and Ganzhorn2011). These highly modified, agricultural environments may retain some species but others may be lost during the land conversion process (Gibbs et al., Reference Gibbs, Mackey and Currie2009). Furthermore, the availability of suitable habitat in agricultural environments (such as agroforests) depends on many factors, including management techniques, landscape composition and distance to forest (Ocampo-Ariza et al., Reference Ocampo-Ariza, Denis, Motombi, Bobo, Kreft and Waltert2019; Warren-Thomas et al., Reference Warren-Thomas, Nelson, Juthong, Bumrungsri, Brattström and Stroesser2020). Although these modified environments are degraded compared to natural forest habitat, they may be crucial for species conservation (Perfecto & Vandermeer, Reference Perfecto and Vandermeer2008). For instance, Madagascar's eucalyptus plantations harbour a variety of animals, including seven species of threatened lemurs (Ganzhorn, Reference Ganzhorn1987; Ramanamanjato & Ganzhorn, Reference Ramanamanjato and Ganzhorn2001). Despite this conservation potential, the biodiversity value of Madagascar's cash-crop plantations remains poorly known.

In this study, we used rapid visual surveys to assess species richness and calculate the inverse Simpson index for vertebrates in vanilla plantations of the Sava region of north-east Madagascar, the country's principal vanilla-growing region, with c. 24,500 ha of vanilla plantations (ILO, 2011). As recent studies have demonstrated the value of Madagascar's vanilla plantations for biodiversity (Hending et al., Reference Hending, Andrianiaina, Rakotomalala and Cotton2018, Reference Hending, Sgarlata, Le Pors, Rasolondraibe, Jan and Rakotonanahary2020a; Martin et al., Reference Martin, Andriafanomezantsoa, Dröge, Osen, Rakotomalala, Wurz, Andrianarimisa and Kreft2021; Osen et al., Reference Osen, Soazafy, Martin, Wurz, März, Ranarijaona and Hölscher2021; Raveloaritiana et al., Reference Raveloaritiana, Wurz, Grass, Osen, Soazafy and Martin2021), we compared species diversity and richness in vanilla plantations with that in natural forests. We hypothesized that vanilla plantations would contain lower vertebrate diversity than natural forests, as was also observed in studies on other groups of organisms (e.g. Hending et al., Reference Hending, Andrianiaina, Rakotomalala and Cotton2018, Reference Hending, Sgarlata, Le Pors, Rasolondraibe, Jan and Rakotonanahary2020a), and we also predicted that vertebrate diversity would vary significantly between vanilla plantations maintained under different management regimes.

Study area

The Sava region of north-east Madagascar covers an area of > 25,000 km2 (Bomgardner, Reference Bomgardner2016). We conducted our investigation within the Vohemar District, in the 2,500 km2 Loky-Manambato Protected Area, and the Bemarivo area of the Sambava District. The remaining forest habitat in the Sava region is under threat from slash-and-burn agriculture as a result of rapid human population growth, wood exploitation and, in the case of the Loky-Manambato Protected Area, gold mining (Meyler et al., Reference Meyler, Salmona, Ibouroi, Besolo, Rasolondraibe and Radespiel2012; Quemere et al., Reference Quemere, Amelot, Pierson, Crouau-Roy and Chikhi2012; Schwitzer et al., Reference Schwitzer, Mittermeier, Davies, Johnson, Ratsimbazafy and Razafindramanana2013).

Methods

Habitat definition and survey area selection

Following Hending et al. (Reference Hending, Andrianiaina, Rakotomalala and Cotton2018), we defined four habitat types for rapid biodiversity assessment, using geographical and observational data to facilitate consistent and meaningful comparisons.

Natural forest Primary, secondary or degraded forest, comprising ≥ 75% native tree species, which has generated at the site, within or outside a protected area.

Forest vanilla eco-plantation Plantations that are directly derived from the forest. Vanilla vines are grown upon pre-existing, naturally growing tutor trees that are not managed. Sites are connected to or in close proximity of (< 100 m) the nearest natural forest.

Non-forest vanilla eco-plantation Plantations that are directly derived from a natural habitat that is not forest (e.g. grassland, savannah). Vanilla vines are grown upon pre-existing, naturally growing tutor trees that are not managed. Other crop species are often grown alongside the vanilla. Sites are > 0.5 km from the nearest natural forest.

Intensive vanilla plantation Plantations derived from the clearing of pre-exiting habitat outside the forest. Vanilla is grown upon tutor tree species that are planted (i.e. not naturally growing), heavily managed and densely planted to make maximum use of available space. Other crop species are often grown alongside the vanilla and natural fertilizers may be used at these sites to enhance soil quality.

The eco-plantation classification reflects the pre-existing ecosystem within which the vanilla is grown, rather than a judgement of the plantation's ecological merits or shortcomings.

We surveyed sites in each habitat during 10 January–25 April 2017, the wet season in the Sava region, with nine sites in natural forest, six in forest eco-plantation, six in non-forest eco-plantation and five in intensive plantation (Fig. 1, Table 1). This was the total number of sites available to us within the surveyed area. We recorded waypoints for the perimeter of each survey site using a GPS, and from these we calculated areas and measured the distance from the perimeter of each site to the nearest natural forest, with ArcGIS 10.6 (Esri, Redlands, USA).

Fig. 1 Localities of natural forest, forest eco-plantation, non-forest eco-plantation and intensive plantation sites surveyed in the Sava region of northern Madagascar near Vohemar-Daraina (a) and Sambava (b). Forested areas are shaded.

Table 1 Centroid location, distance to the nearest forest fragment, and area of each vanilla plantation surveyed in the Sava region, north east Madagascar (Fig. 1), during 10 January–25 April 2017, by habitat type (see text for definitions).

1 The three Ampondra sites were adjacent or close to each other, and therefore survey data were combined to avoid potential pseudo-replication.

Vertebrate surveys

We assessed vertebrate biodiversity (mammals, birds, reptiles and amphibians) at each site using 1–3 parallel transects, depending on the shape and size of each site. All transects were based on trails, established by either villagers (in forests) or farmers (in plantations), which passed through the middle of the forest or plantation. Visibility was limited to c. 10 m either side of the transects because of the density of surrounding vegetation. Two investigators (DH and AA) walked along each transect, recording all vertebrate species observed. We surveyed each transect on one day only, at 05.00, 12.00 and 21.00, to maximize the chances of observing both diurnal and nocturnal fauna, walking at a pace of 1 km/h to ensure a consistent survey rate across transects. We used binoculars and hand-held high-lumen torches to assist with animal identification during diurnal and nocturnal transects, respectively. We only recorded birds that were perched or terrestrially active (bird flyovers were not counted). We searched under stones and under vegetation to survey for amphibians and small reptiles. We captured and handled reptiles and frogs, the only amphibians in Madagascar, so that we could accurately identify them. All species were identified using field keys (Garbutt, Reference Garbutt2007; Glaw & Vences, Reference Glaw and Vences2007; Mittermeier et al., Reference Mittermeier, Louis, Richardson, Schwitzer, Langrand and Rylands2010; Sinclair & Langrand, Reference Sinclair and Langrand2013).

Data Analysis

We performed all statistical analyses in R 4.02 (R Core Team, 2017). Varitions between surveyed sites in area (forests 104–5,424 ha; plantations 0.42–27 ha) and transect length (forests 700–1,050 m; plantations 200–1,000 m), may have led to differences in survey effort and thus detection bias acros sites, and therefore we tested for differences in survey effort (transect length) using a t test (between forests and plantations) and a one-way ANOVA (between plantation types). We also examined whether plantation areas varied between plantation types using a Kruskal–Wallis test (residual distribution was non-normal and could not be appropriately transformed).

We noted the IUCN Red List status of all species recorded, and whether each species was endemic to Madagascar, regionally native, migratory or invasive to Madagascar using the field keys and the IUCN Red List (IUCN, 2020). We compared mean total observed number of species between habitat types using a generalized linear mixed model (GLMM), as a proxy of total biodiversity. We then repeated this analysis separately for major taxonomic groups. We controlled for survey effort, vegetation type (as a proxy of visibility, obtained from Hending et al., Reference Hending, Andrianiaina, Maxfield, Rakotomalala and Cotton2020b), transect length, elevation, mean temperature, annual precipitation and site location as random factors in the GLMMs. Mean temperature and precipitation were obtained for each site from Worldclim (Hijmans et al., Reference Hijmans, Cameron, Parra, Jones and Jarvis2005, 1 km2 resolution) and mean elevation from the Shuttle Radar Topography Mission raster layers (Jarvis et al., Reference Jarvis, Reuter, Nelson and Guevara2008; 90 × 90 m resolution) using the R packages raster (Hijmans, Reference Hijmans2017) and sp (Bivand et al., Reference Bivand, Pebesma and Gomez-Rubio2013). Similarly, GLMMs were used to compare the per cent of species that were native, endemic or invasive to the study sites, or categorized as threatened, between habitat types. Habitat type was coded as a fixed factor in all GLMMs. We performed post-hoc sequential Holm–Bonferroni multiple comparisons between habitat types for all GLMMs.

To control for differences between sites, we used EstimateS 9 (Colwell, Reference Colwell2013) to calculate the expected number of species (S) per N individuals in each habitat type using rarefaction (Colwell & Coddington, Reference Colwell and Coddington1994; Lande et al., Reference Lande, DeVries and Walla2000; Colwell et al., Reference Colwell, Mao and Chang2004). Transect data from all sites of each habitat type were pooled to form one dataset for each habitat, and the number of knots was the total number of individual animals (N) observed in each habitat type (Colwell & Coddington, Reference Colwell and Coddington1994; Colwell et al., Reference Colwell, Mao and Chang2004). As the number of individuals observed was different between habitats, we extrapolated the observed number of individuals from the three vanilla plantations up to the maximum number of individual animals (knots) observed in the natural forest habitat (the habitat with the greatest number of individuals; N = 834). We used rarefied and extrapolated S values (and associated 95% confidence intervals, derived from 100 randomization runs) to construct comparable species diversity–individual accumulation curves for each habitat type.

In addition, we also used EstimateS to calculate the inverse Simpson index (λ = 1/D; Simpson, Reference Simpson1949), which accounts for the number of individuals of each species observed and therefore controls for differences in species abundance between sites. We used the index values to construct diversity index–individual accumulation curves, with associated 95% confidence intervals (derived from 100 randomizations), for each of the four habitat types. We created diversity index–individual accumulation curves for three taxonomic groups (birds, reptiles and frogs) to investigate the distributions of these groups among the habitat types. We did not repeat this process for mammals as sample sizes were too small for rarefaction, but we present these data as box plots.

Results

Mean transect lengths in forests were significantly longer than those in plantations (forest 916 ± SE 40.8 m, plantation 521 ± SE 58.8 m; t = 4.57, df = 24, P < 0.001). In vanilla plantations, transect lengths were longer in larger plantations (r s = 0.556, N = 17, P = 0.021). However, neither transect length nor plantation area differed significantly between the three plantation types (transect length, one-way ANOVA: F 2,14 = 0.193, P = 0.827; plantation area, Kruskal–Wallis: χ 2 = 0.518, df = 2, P = 0.772), suggesting that any differences between plantations were not the result of biased survey effort.

We recorded a total of 190 vertebrate species: 74 birds, 62 reptiles, 38 frogs and 16 mammals, including nine lemur species (see Supplementary Table 1 for a list of all species). Of these species 136 are endemic to Madagascar, and 27 are categorized as threatened on IUCN Red List (as of 2018: 17 Vulnerable, eight Endangered and two Critically Endangered). Observed species counts and analysis of species diversity between habitat types are summarized in Table 2.

Table 2 Summary of the observed total number and mean number of species, mean number of species of birds, reptiles, frogs and mammals, per cent of species that are native, migratory or invasive, and per cent of species in each of four groups of IUCN Red List categories in each of the four habitat types (see text for definitions) in the Sava region, north-east Madagascar. Values with the same superscript letter within a row are not significantly different from each other in a GLMM of habitat type (corrected for multiple comparisons, following sequential Holm–Bonferroni correction).

1 CR, Critically Endangered; DD, Data Deficient; EN, Endangered; NE, Not Evaluated; VU, Vulnerable.

When data were pooled for all sites of each habitat, the number of animal species observed differed significantly between habitat types, with forests having the highest observed mean species diversity (Table 2). When controlling for differences between habitats in the number of individuals, natural forests also had significantly higher mean species diversity than all three types of vanilla plantation (Fig. 2a). This conclusion held whether the comparisons of species diversity were performed at the extrapolated values of the habitat with the highest number of observed individuals (N = 834 for natural forest) or the rarefied values of the habitat with the lowest number of individuals (N = 251 for intensive plantation). Within vanilla plantations, we observed significantly fewer species in intensive plantations compared to forest eco-plantations (Table 2; see Supplementary Table 2 for full GLMM results).

Fig. 2 (a) Expected number of animal species computed by rarefaction (S, solid lines), and (b) the inverse Simpson diversity index, with upper and lower 95% confidence intervals (dotted lines), among individuals in the four habitat types in the Sava region, north-east Madagascar (Fig. 1); extrapolations up to 834 knots (individuals) are depicted by the dashed extensions in (a). The vertical line indicates the point of comparison (the point of the maximum runs for the habitat with the fewest observed species). Rarefaction, extrapolation, diversity indices and associated confidence intervals were computed in EstimateS (Colwell, Reference Colwell2013).

Comparisons of the inverse Simpson's diversity index at the largest common number of individuals across all four habitats (N = 251; Fig. 2b) suggest that natural forest had a significantly higher diversity index than forest eco-plantations. Furthermore, forest eco-plantations had a significantly higher index than non-forest eco-plantations and intensive plantations; non-forest eco-plantations and intensive plantations had similar values of the index (Fig. 2b).

The observed species diversity of all taxon-specific groups was highest in natural forest, and there were no observed differences in species diversity between the three types of vanilla plantation (Table 2). After accounting for species abundance, we observed some consistent taxon-specific differences between vanilla plantations in the inverse Simpson index, with forest eco-plantations having higher values than other plantation types (Figs 3 & 4). There were few differences between non-forest eco-plantations and intensive plantations for any taxon, except for frogs, where diversity was significantly lower in intensive plantations (Fig. 3c).

Fig. 3 Inverse Simpson index–individual curves (with associated 95% confidence intervals) of (a) birds, (b) reptiles and (c) frogs observed in the four habitat types in the Sava region, north-east Madagascar. The vertical line indicates the point of comparison (the point of the maximum runs for the habitat with the fewest observed species). Diversity indices and associated confidence intervals were computed in EstimateS (Colwell, Reference Colwell2013). Note the differing x- and y-axis scales.

Fig. 4 Box plots (median, upper and lower quartiles, and maximum and minimum values) of the inverse Simpson diversity index for mammals observed in the four habitat types in the Sava region, north-east Madagascar (numbers in parentheses indicate sample size from which diversity indices were computed).

When all taxa were pooled for each habitat type, the highest number of native species (both endemic and non-endemic) was observed in natural forest, and the lowest in intensive plantations (Table 2). There were slight differences of only marginal significance in the number of migratory species (Table 2). A significantly lower per cent of species categorized as Least Concern were observed in natural forest compared to vanilla plantations, and conversely there was a higher per cent of threatened or Near Threatened species in natural forest (Table 2). There were few significant differences between the different vanilla plantation habitats based on threat status, although forest eco-plantations had a significantly lower per cent of Least Concern species and a higher per cent of threatened species compared to non-forest eco-plantations and intensive plantations (Table 2).

Discussion

Forests vs plantations

Vertebrate diversity was the greatest in natural forest habitat. Although vanilla plantations are capable of supporting biodiversity, our results indicate that increased management and modification of these plantations result in degradation of this species diversity. This is unsurprising, considering that biodiversity has been previously observed to be lower in plantations than natural forests (Vallan, Reference Vallan2002; Perfecto & Vandermeer, Reference Perfecto and Vandermeer2008). When focusing on specific taxa, we found that bird and reptile diversity were significantly higher in natural forest than in all vanilla plantation types. For reptiles this finding was surprising; although some reptile species prefer habitats with prominent leaf-litter, and are known to show negative responses to habitat degradation (Perfecto et al., Reference Perfecto, Rice, Greenberg and van der Voort1996; Faria et al., Reference Faria, Paciencia, Dixo, Laps and Baumgarten2007), other reptile species prefer open habitats (e.g. Vallan et al., Reference Vallan, Andreone, Raherisoa and Dolch2004). Avian diversity can be high in plantation ecosystems (Greenberg et al., Reference Greenberg, Bichier and Sterling1997; Clough et al., Reference Clough, Putra, Pitopang and Tscharntke2009), but some terrestrial and forest-specialized species are disturbed by agricultural activity, making our finding unsurprising. Frog diversity also varied significantly, and was highest in natural forest, an expected finding considering that many Malagasy frog species prefer undisturbed habitats, as they require food resources from forest tree species and dead wood or tree holes for breeding (Vallan, Reference Vallan2002; Vallan et al., Reference Vallan, Andreone, Raherisoa and Dolch2004). However, many of Madagascar's frog species are highly cryptic (e.g. Lehtinen et al., Reference Lehtinen, Nussbaum, Richards, Cannatella and Vences2007), and the total amphibian diversity would have been difficult to detect in our rapid survey. There was a significantly higher mammal diversity in natural forest than in vanilla plantations, perhaps because forests contain the high canopies required by some mammal species, such as lemurs (Vargas et al., Reference Vargas, Jiminez, Palomares and Palacios2002), and the prey required by carnivores (Karpanty & Wright, Reference Karpanty, Wright, Gursky and Nekaris2007). Natural forests also had more endemic species, fewer invasive species and a higher per cent of threatened species compared to vanilla plantations. This reinforces the view that natural forests are refuges for Madagascar's most threatened fauna, over 85% of which is endemic (Goodman & Benstead, Reference Goodman and Benstead2005).

Although we found significant differences in vertebrate diversity and abundance between forest and plantation habitats, we expect that other factors may also contribute to animal diversity at each site, in addition to anthropogenic influences. For example, floral diversity also varies greatly between natural and agricultural habitats (Hending et al., Reference Hending, Sgarlata, Le Pors, Rasolondraibe, Jan and Rakotonanahary2020a) and, in many cases, animal diversity correlates directly with plant diversity (Huston, Reference Huston1979; Faria et al., Reference Faria, Paciencia, Dixo, Laps and Baumgarten2007); this correlation may occur within Madagascar's vanilla agroecosystems. The area of each site is also likely to have an influence, as some of the vanilla plantation sites surveyed were very small (e.g. < 1 ha) and fragmented. These small sites may be unable to support animals that require large ranges, such as some lemurs (Mittermeier et al., Reference Mittermeier, Louis, Richardson, Schwitzer, Langrand and Rylands2010), carnivores (Gerber et al., Reference Gerber, Karpanty and Randriantenaina2012) and insectivorous mammals (Levesque et al., Reference Levesque, Rakotondravony and Lovegrove2012). Additionally, the presence and abundance of some animals may be related to particular abiotic conditions (unrelated to habitat types) that are not uniform among our study sites; e.g. frogs require nearby water sources to survive (Glaw & Vences, Reference Glaw and Vences2007), the presence of which was variable between study sites (D. Hending & A. Andrianiaina, pers. obs., 2018).

Effect of plantation management regime

The diversity indices suggest that forest eco-plantations support significantly higher vertebrate diversity than non-forest vanilla plantations. These findings mostly also hold true when individual groups of taxa are compared (Figs 3 & 4). In most cases, intensively managed vanilla plantations had the lowest vertebrate species diversity, which suggests that vertebrate diversity correlates negatively with habitat degradation and anthropogenic disturbance in Madagascar's vanilla cultivation areas, and possibly in agroecosystems more generally. Thus we accept our hypothesis that animal diversity is affected by vanilla plantation management regime.

The variation in animal diversities among vanilla plantation types is most likely because of species-specific habitat requirements and tolerance levels to human disturbance and habitat alteration (Tews et al., Reference Tews, Brose, Grimm, Tielbörger, Wichmann and Schwager2003). Although some species may tolerate or even prefer disturbed, open habitat, (e.g. reptiles: Pike et al., Reference Pike, Webb and Shine2011; mouse lemurs: Hending, Reference Hending2021), many species in Madagascar's vanilla cultivation region may only be able to survive in intact, natural forest (e.g. the Critically Endangered golden-crowned sifaka Propithecus tattersalli; Quemere et al., Reference Quemere, Amelot, Pierson, Crouau-Roy and Chikhi2012). Furthermore, intensively managed habitat types are unlikely to have the opportunities for feeding and movement that eco-plantations provide for native fauna (e.g. lemurs; Hending et al., Reference Hending, Andrianiaina, Rakotomalala and Cotton2018).

Limitations

The results of this study provide evidence that natural forest habitat, and forested vanilla plantations, contain higher vertebrate richness and diversity than agricultural habitats, particularly in agroecosystems located outside forest matrices. However, as this investigation was a rapid biodiversity assessment, we had limited survey time at each study site and therefore not all species would have been detected. Our surveys of reptiles, birds and small mammals was based solely on visual observations, and we therefore only recorded species close to ground level; some small, arboreal species such as some snakes (e.g. Stenophis spp.; Glaw & Vences, Reference Glaw and Vences2007), and mammals (e.g. Eliurus spp.; Goodman & Carleton, Reference Goodman, Carleton and Goodman1998), may therefore have been overlooked. Additional species such as the fanaloka Fossa fossana and the fossa Cryptoprocta ferox may have also been missed (we only saw one fossa individual, at one study site) as they tend to avoid areas of human activity (i.e. transect lines; Albignac, Reference Albignac, Jolly, Oberle and Albignac1984).

Implications for animal conservation and sustainable agroforestry

Little natural forest remains in the Sava region, and in Madagascar generally, and that which remains is highly degraded and fragmented (Schwitzer et al., Reference Schwitzer, Mittermeier, Davies, Johnson, Ratsimbazafy and Razafindramanana2013). The continued conversion of existing forest to vanilla plantations will severely threaten Madagascar's faunal diversity, particularly species only capable of surviving within natural forest. However, vanilla plantations that have already been derived from forest may serve as a suitable alternative to more slash-and-burn agriculture, which would avoid further forest conversion. The results of our study suggest that minimally managed and modified plantations, especially those located in or near natural forest habitat, can support relatively high vertebrate diversity, although this may only persist within a multifunctional landscape. Although it remains to be seen whether animals can use them long-term, forest eco-plantations may be a suitable habitat and a valuable haven for a subset of forest specialist animals, and vanilla cultivation in Madagascar should be encouraged to replicate these habitat types (whilst not compromising the little forest that remains). These viable habitats lie between isolated fragments of natural forest, and open areas and gallery forest or other degraded patches of vegetation could therefore be repurposed as vanilla plantations to improve habitat availability and increase their economic value. Threatened mammals, birds, reptiles and frogs, which we observed in vanilla plantations, would be able to use these matrices to travel between natural forests, and important seed dispersing species would contribute to the further regeneration of the forest (Bollen et al., Reference Bollen, van Elacker and Ganzhorn2004; Hending et al., Reference Hending, Andrianiaina, Rakotomalala and Cotton2017; Hending et al., Reference Hending, Andrianiaina, Rakotomalala and Cotton2018). Our findings are both encouraging and important for agroforestry in Madagascar, and locally for the coordination of responsible and sustainable cultivation of the vanilla crop within the Sava region. Any further conversion of forest for vanilla cultivation should, however, be discouraged.

Madagascar's vanilla industry is worth an estimated USD 200 million per annum (AFB, 2016). Over 200,000 of Madagascar's farmers, most of whom reside in the Sava region, depend on this industry for their livelihoods (AFB, 2016), and the financial value of the vanilla industry, along with sustainability certification schemes, should provide sufficient incentives for farming communities to establish and maintain sustainable plantations. The high level of animal diversity in forest eco-plantations suggests a potentially high conservation value for the vanilla industry. Overall, forest eco-plantations appear to be the most sustainable method of vanilla cultivation in terms of both animal conservation and agriculture.

In summary, eco-plantations in or within close proximity to natural forests should be promoted for the responsible and sustainable cultivation of vanilla, as they have high value for both species conservation and sustainable agroforestry. In addition to vanilla, Madagascar's farmers depend on a variety of crops for food and export income (e.g. coconut, cacao; Dorosh & Haggblade, Reference Dorosh and Haggblade1993). To further our knowledge of faunal diversity in these agroecosystems, rapid biodiversity assessments should be conducted, to facilitate a better understanding of the effects of agricultural land conversion on animal diversity and to provide insight into the relationship between animal diversity and agricultural intensity in the tropics.

Acknowledgements

This work was funded by Conservation International through its Verde Ventures programme. We thank all plantation owners and farmers who allowed us to survey their plantations; the many individuals who helped us by offering hospitality, and acting as guides and/or cooks during our time in the Sava region; everyone at Fanamby's offices in Daraina and Vohemar for their support, assistance and advice; Madagascar’ Institute for the Conservation of Tropical Environments, Madagascar's Ministry of Forest, Ecology and Environment, and the Mention Zoology et Biodiversité Animale, University of Antananarivo for organizing research permits (Permit number 295/16/MEEF/SG/DGF/DSAP/SCB.Re); and colleagues for helpful discussions.

Author contributions

Experimental design: SC; fieldwork: DH, AA; fieldwork ideas and advice, logistics: ZR; analyses, figures: DH, SC; writing: all authors.

Conflict of interest

None.

Ethical standards

This research abided by the Oryx guidelines on ethical standards, and was conducted according to the laws of both the UK and Madagascar.

Data availability

The datasets generated and/or analysed are available from the authors on request.

Footnotes

*

Also at: School of Biological Sciences, Life Sciences Building, University of Bristol, Bristol, UK

Supplementary material for this article is available at doi.org/10.1017/S0030605321001265

References

AFB (2016) VANILLA: Madagascar. Speculative traders are blamed for the price hike – which fails to benefit producers. Africa Research Bulletin, 53, 21295B–21295C.Google Scholar
Albignac, R. (1984) The carnivores. In Key Environments—Madagascar (eds Jolly, A., Oberle, P. & Albignac, R.), pp. 167181. Pergamon Press, Oxford, UK.CrossRefGoogle Scholar
Anand, M.O., Krishnaswamy, J., Kumar, A. & Bali, A. (2010) Sustaining biodiversity conservation in human-modified landscapes in the western Ghats: remnant forests matter. Biological Conservation, 143, 23632374.CrossRefGoogle Scholar
Bivand, R.S., Pebesma, E. & Gomez-Rubio, V. (2013) Applied Spatial Data Analysis with R. 2nd edition. Springer, New York, USA.CrossRefGoogle Scholar
Bollen, A., van Elacker, L. & Ganzhorn, J.U. (2004) Tree dispersal strategies in the littoral forest of Saint Luce (SE-Madagascar). Oecologia, 139, 604616.CrossRefGoogle ScholarPubMed
Bomgardner, M.M. (2016) The problem with vanilla. Chemical and Engineering News, 94, 3842.Google Scholar
Clough, Y., Putra, D.D., Pitopang, R. & Tscharntke, T. (2009) Local and landscape factors determine functional bird diversity in Indonesian cacao agroforestry. Biological Conservation, 142, 10321041.CrossRefGoogle Scholar
Colwell, RK. (2013) EstimateS: Statistical Estimation of Species Richness and Shared Species from Samples. Version 9. purl.oclc.org/estimates [accessed 20 April 2018].Google Scholar
Colwell, R.K. & Coddington, J.A. (1994) Estimating terrestrial biodiversity through extrapolation. Philosophical Transactions of the Royal Society B, 345, 101118.Google ScholarPubMed
Colwell, R.K., Mao, C.X. & Chang, J. (2004) Interpolating, extrapolating, and comparing incidence-based species accumulation curves. Ecology, 85, 27172727.CrossRefGoogle Scholar
Donald, P.F. (2004) Biodiversity impacts of some agricultural commodity production systems. Conservation Biology, 18, 1737.CrossRefGoogle Scholar
Dorosh, P. & Haggblade, S. (1993) Agriculture-led growth: foodgrains versus export crops in Madagascar. Agricultural Economics, 9, 165180.Google Scholar
Dunn, R.R. (2004) Managing the tropical landscape: a comparison of the effects of logging and forest conversion to agriculture on ants, birds, and lepidoptera. Forest Ecology and Management, 191, 215224.CrossRefGoogle Scholar
Eppley, T.M., Donati, G., Ramanamanjato, J.B., Randriatafika, F., Andriamandimbiarisoa, L.N., Rabehevitra, D. et al. (2015) The use of an invasive species habitat by a small folivorous primate: implications for lemur conservation in Madagascar. PLOS ONE, 10, e0140981.CrossRefGoogle ScholarPubMed
Faria, D., Paciencia, M.L.B., Dixo, M., Laps, R.R. & Baumgarten, J. (2007) Ferns, frogs, lizards, birds and bats in forest fragments and shade cacao plantations in two contrasting landscapes in the Atlantic Forest, Brazil. Biodiversity Conservation, 16, 23352357.CrossRefGoogle Scholar
Flohre, A., Fischer, C., Aavik, T., Bengtsson, J., Berendse, F., Bommarco, R. et al. (2011) Agricultural intensification and biodiversity partitioning in European landscapes comparing plants, carabids and birds. Ecological Applications, 21, 17721781.CrossRefGoogle ScholarPubMed
Foley, J.A., DeFries, R., Asner, G.P., Barford, C., Bonan, G., Carpenter, S.R. et al. (2005) Global consequences of land use. Science, 309, 570574.CrossRefGoogle ScholarPubMed
Ganzhorn, J.U. (1987) A possible role of plantations for primate conservation in Madagascar. American Journal of Primatology, 12, 205215.CrossRefGoogle ScholarPubMed
Ganzhorn, J.U., Lowry, P.P. II, Schatz, G.E. & Sommer, S. (2001) The biodiversity of Madagascar: one of the world's hottest hot spots on its way out. Oryx, 35, 346348.CrossRefGoogle Scholar
Garbutt, N. (2007) Mammals of Madagascar: A Complete Guide. University Press, Yale, USA.Google Scholar
Gardner, C.J., Nicoll, M.E., Mbohoahy, T., Oleson, K.L.L., Ratsifandrihamanana, A.N., Ratsirarson, J. et al. (2013) Protected areas for conservation and poverty alleviation: experiences from Madagascar. Journal of Applied Ecology, 50, 12891294.CrossRefGoogle Scholar
Gerber, B.D., Karpanty, S.M. & Randriantenaina, J. (2012) The impact of forest logging and fragmentation on carnivore species composition, density and occupancy in Madagascar's rainforests. Oryx, 46, 414422.CrossRefGoogle Scholar
Gibbs, K.E., Mackey, R.L. & Currie, D.J. (2009) Human land use, agriculture, pesticides and losses of imperiled species. Diversity and Distributions, 15, 242253.CrossRefGoogle Scholar
Glaw, F. & Vences, M. (2007) Field Guide to the Amphibians and Reptiles of Madagascar. 3rd edition. Frosch Verlag, Cologne, Germany.Google Scholar
Godfray, H.C.J., Beddington, J.R., Crute, I.R., Haddad, L., Lawrence, D., Muir, J.F. et al. (2010) Food security: the challenge of feeding 9 billion people. Science, 327, 812818.CrossRefGoogle ScholarPubMed
Goodman, S.M. & Benstead, J.P. (2005) Updated estimates of biotic diversity and endemism for Madagascar. Oryx, 39, 7377.CrossRefGoogle Scholar
Goodman, S.M. & Carleton, M.D. (1998) The rodents of the Réserve Spéciale d'Anjanaharibe-Sud, Madagascar. In A Floral and Faunal Inventory of the Réserve Spéciale D'Anjanaharibe-Sud, Madagascar: with Reference to Elevational Variation (ed. Goodman, S. M.), pp. 201221. Fieldiana Zoologica, Chicago, USA.CrossRefGoogle Scholar
Greenberg, R., Bichier, P. & Sterling, J. (1997) Bird populations in rustic and planted shade coffee plantations of eastern Chiapas, Mexico. Biotropica, 29, 501514.CrossRefGoogle Scholar
Hanke, W., Böhner, J., Dreber, N., Jürgens, N., Schmeidel, U., Wesuls, D. et al. (2014) The impact of livestock grazing on plant diversity: an analysis across dryland ecosystems and scales in southern Africa. Ecological Applications, 24, 11881203.CrossRefGoogle ScholarPubMed
Harper, G.J., Steininger, M.K., Tucker, C.J. & Juhn, D. (2007) Fifty years of deforestation and forest fragmentation in Madagascar. Environmental Conservation, 34, 325333.CrossRefGoogle Scholar
Harvey, C.A., Medina, A., Sanchez, D.M., Vilchez, S., Hernandez, B., Saenz, J.C. et al. (2006) Patterns of animal diversity in different forms of tree cover in agricultural landscapes. Ecological Applications, 16, 19861999.CrossRefGoogle ScholarPubMed
Hending, D. (2021) Environmental drivers of Cheirogaleidae population density: remarkable resilience of Madagascar's smallest lemurs to habitat degradation. Ecology and Evolution, 11, 58745891.CrossRefGoogle ScholarPubMed
Hending, D., Andrianiaina, A., Maxfield, P., Rakotomalala, Z. & Cotton, S. (2020b) Floral species richness, structural diversity and conservation value of vanilla agroecosystems in Madagascar. African Journal of Ecology, 58, 100111.CrossRefGoogle Scholar
Hending, D., Andrianiaina, A., Rakotomalala, Z. & Cotton, S. (2017) Range extension and behavioural observations of the recently described Sheth's dwarf lemur (Cheirogaleus shethi). Folia Primatologica, 88, 401408.CrossRefGoogle ScholarPubMed
Hending, D., Andrianiaina, A., Rakotomalala, Z. & Cotton, S. (2018) The use of vanilla plantations by lemurs: encouraging findings for both lemur conservation and sustainable agroforestry in the Sava region, northeast Madagascar. International Journal of Primatology, 39, 141153.CrossRefGoogle Scholar
Hending, D., Sgarlata, G.M., Le Pors, B., Rasolondraibe, E., Jan, F., Rakotonanahary, A.N. et al. (2020a) Distribution and conservation status of the endangered Montagne d'Ambre fork-marked lemur (Phaner electromontis). Journal of Mammalogy, 101, 10491060.CrossRefGoogle Scholar
Hijmans, R.J. (2017) Raster: Geographic Data Analysis and Modeling. R package version 2.6-7. CRAN.R-project.org/package=raster [accessed 10 September 2020].Google Scholar
Hijmans, R.J., Cameron, S.E., Parra, J.L., Jones, P.G. & Jarvis, A. (2005) Very high resolution interpolated climate surfaces for global land areas. International Journal of Climatology, 25, 19651978.CrossRefGoogle Scholar
Huston, M. (1979) A general hypothesis of species diversity. The American Naturalist, 113, 81101.CrossRefGoogle Scholar
ILO (International Labour Organisation) (2011) Etat des Lieux du Travail des Enfants dans la Fillière Vanille dans la Région de la SAVA. International Labour Organisation of the United Nations, Antananarivo, Madagascar.Google Scholar
Irwin, M.T., Wright, P.C., Birkinshaw, C., Fisher, B.L., Gardner, C.J., Glos, J. et al. (2010) Patterns of species change in anthropogenically disturbed forests of Madagascar. Biological Conservation, 143, 23512362.CrossRefGoogle Scholar
IUCN (2020) The IUCN RedList of Threatened Species. iucnredlist.org [accessed 27 April 2020].Google Scholar
Jarvis, A., Reuter, H.I., Nelson, A. & Guevara, E. (2008) Hole-Filled Seamless SRTM Data V4. International Centre for Tropical Agriculture (CIAT). srtm.csi.cgiar.org [accessed 5 June 2019].Google Scholar
Karpanty, S.M. & Wright, P.C. (2007) Predation on lemurs in the rainforest of Madagascar by multiple predator species: observations and experiments. In Primate Anti-Predator Strategies (eds. Gursky, S. & Nekaris, K.A.I.), pp. 7799. Springer, Boston, USA.CrossRefGoogle Scholar
Lande, R., DeVries, P.J. & Walla, T.R. (2000) When species accumulation curves intersect: implications for ranking diversity using small samples. Oikos, 89, 601605.CrossRefGoogle Scholar
Leakey, R. (1996) Definition of agroforestry revisited. Agroforestry Today, 8, 57.Google Scholar
Lehtinen, R.M., Nussbaum, R.A., Richards, C.M., Cannatella, D.C. & Vences, M. (2007) Mitochondrial genes reveal cryptic diversity in plant-breeding frogs from Madagascar (Anura, Mantellidae, Guibemantis). Molecular Phylogenetics and Evolution, 44, 11211129.CrossRefGoogle ScholarPubMed
Levesque, D.L., Rakotondravony, D. & Lovegrove, B.G. (2012) Home range and shelter site selection in the greater hedgehog tenrec in the dry deciduous forest of western Madagascar. Journal of Zoology, 287, 161168.CrossRefGoogle Scholar
Llopis, J.C., Harimalala, P.C., Bär, R., Heinimann, A., Rabemananjara, Z.H. & Zaehringer, J.G. (2019) Effects of protected area establishment and cash crop price dynamics on land use transitions 1990–2017 in north-eastern Madagascar. Journal of Land Use Science, 14, 5280.CrossRefGoogle Scholar
Martin, D.A., Andriafanomezantsoa, R., Dröge, S., Osen, K., Rakotomalala, E., Wurz, A., Andrianarimisa, A. & Kreft, H. (2021) Bird diversity and endemism along a land-use gradient in Madagascar: the conservation value of vanilla agroforests. Biotropica, 53, 179190.CrossRefGoogle Scholar
Medan, D., Torretta, J.P., Hodara, K., de la Fuente, E.B. & Montaldo, N.H. (2011) Effects of agriculture expansion and intensification on the vertebrate and invertebrate diversity in the Pampas of Argentina. Biodiversity Conservation, 20, 30773100.CrossRefGoogle Scholar
Meyler, S.V., Salmona, J., Ibouroi, M.T., Besolo, A., Rasolondraibe, E., Radespiel, U. et al. (2012) Density estimates of two endangered nocturnal lemur species from northern Madagascar: new results and a comparison of commonly new methods. American Journal of Primatology, 74, 414422.CrossRefGoogle Scholar
Mittermeier, R.A., Louis, E.E., Richardson, M., Schwitzer, C., Langrand, O., Rylands, A.B. et al. (2010) Lemurs of Madagascar. 3rd edition. Conservation International, Arlington, USA.Google Scholar
Myers, N., Mittermeier, R.A., Mittermeier, C.G., da Fonseca, G.A.B. & Kent, J. (2000) Biodiversity hotspots for conservation priorities. Nature, 403, 853858.CrossRefGoogle ScholarPubMed
Newbold, T., Oppenheimer, P., Etard, A. & Williams, J.J. (2020) Tropical and Mediterranean biodiversity is disproportionately sensitive to land-use and climate change. Nature Ecology & Evolution, 4, 16301638.CrossRefGoogle ScholarPubMed
Ocampo-Ariza, C., Denis, K., Motombi, F.N., Bobo, K.S., Kreft, H. & Waltert, M. (2019) Extinction thresholds and negative responses of Afrotropical ant-following birds to forest cover loss in oil palm and agroforestry landscapes. Basic and Applied Ecology, 39, 2637.CrossRefGoogle Scholar
Osen, K., Soazafy, M.R., Martin, D.A., Wurz, A., März, A., Ranarijaona, H.L.T. & Hölscher, D. (2021) Land-use history determines stand structure and tree diversity in vanilla agroforests of northeastern Madagascar. Applied Vegetation Science, 24, e12563.CrossRefGoogle Scholar
Perfecto, I., Rice, R., Greenberg, R. & van der Voort, M.E. (1996) Shade coffe: a disappearing refuge for biodiversity. Bioscience, 46, 598608.CrossRefGoogle Scholar
Perfecto, I. & Vandermeer, J. (2008) Biodiversity conservation in tropical agroecosystems: a new conservation paradigm. Annals of the New York Academy of Sciences, 1134, 173200.CrossRefGoogle ScholarPubMed
Phalan, B., Balmford, A., Green, R.E. & Scharlemann, J.P.W. (2011) Minimising the harm to biodiversity of producing more food globally. Food Policy, 36, 6271.CrossRefGoogle Scholar
Pike, D.A., Webb, J.K. & Shine, R. (2011) Removing forest canopy cover restores a reptile assemblage. Ecological Applications, 21, 274280.CrossRefGoogle ScholarPubMed
Pongratz, J., Reick, C., Raddatz, T. & Claussen, M. (2008) A reconstruction of global agricultural areas and land cover for the last millennium. Global Biogeochemical Cycles, 22, GB3018.CrossRefGoogle Scholar
Quemere, E., Amelot, X., Pierson, J., Crouau-Roy, B. & Chikhi, L. (2012) Genetic data suggests a natural prehuman origin of open habitats in northern Madagascar and question the deforestation narrative in this region. Proceedings of the National Academy of Sciences USA, 109, 1302813033.CrossRefGoogle ScholarPubMed
R Core Team (2017) R: A Language and Environment for Statistical Computing. R Foundation for Statistical Computing, Vienna, Austria.Google Scholar
Ramanamanjato, J.B. & Ganzhorn, J.U. (2001) Effects of forest fragmentation, introduced Rattus rattus and the role of exotic tree plantations and secondary vegetation for the conservation of an endemic rodent and a small lemur in littoral forests of southeastern Madagascar. Animal Conservation, 4, 175183.CrossRefGoogle Scholar
Ranganathan, J., Daniels, R.J.R., Chandran, M.D.S., Ehrlich, P.R. & Daily, G.C. (2008) Sustaining biodiversity in ancient tropical countryside. Proceedings of the National Academy of Sciences USA, 105, 1785217854.CrossRefGoogle ScholarPubMed
Raveloaritiana, E., Wurz, A., Grass, I., Osen, K., Soazafy, M.R., Martin, D.A. et al. (2021) Land-use intensification increases richness of native and exotic herbaceous plants, but not endemics, in Malagasy vanilla landscapes. Diversity and Distributions, 27, 784798.CrossRefGoogle Scholar
Razakamanarivo, R.H., Razakavololona, A., Razafindrakoto, M.A., Vieilledent, G. & Albrecht, A. (2012) Below-ground biomass production and allometric relationships of eucalyptus coppice plantation in the central highlands of Madagascar. Biomass and Bioenergy, 45, 110.CrossRefGoogle Scholar
Rogers, H.M., Glew, L., Honzak, M. & Hudson, M.D. (2010) Prioritizing key biodiversity areas in Madagascar by including data on human pressure and ecosystem services. Landscape Urban Planning, 96, 4856.CrossRefGoogle Scholar
Schwitzer, C., Glatt, L., Nekaris, K.A.I. & Ganzhorn, J.U. (2011) Responses of animals to habitat alteration: an overview focussing on primates. Endangered Species Research, 14, 3138.CrossRefGoogle Scholar
Schwitzer, C., Mittermeier, R.A., Davies, N., Johnson, S., Ratsimbazafy, J., Razafindramanana, J. et al. (2013) Lemurs of Madagascar: A Strategy for Their Conservation 2013–2016. IUCN SSC Primate Specialist Group, Bristol Conservation and Science Foundation, and Conservation International, Bristol, UK.Google Scholar
Simpson, E.H. (1949) Measurement of Diversity. Nature, 163, 688.CrossRefGoogle Scholar
Sinclair, I. & Langrand, O. (2013) Birds of the Indian Ocean Islands. 3rd edition. Struik Nature, New Holland Publishers, Cape Town, South Africa.Google Scholar
Tews, J., Brose, U., Grimm, V., Tielbörger, K., Wichmann, M.C., Schwager, M. et al. (2003) Animal species diversity driven by habitat heterogeneity/diversity: the importance of keystone structures. Journal of Biogeography, 31, 7992.CrossRefGoogle Scholar
Tilman, D., Cassman, K.G., Matson, P.A., Naylor, R. & Polasky, S. (2002) Agricultural sustainability and intensive production practices. Nature, 418, 671677.CrossRefGoogle ScholarPubMed
Tscharntke, T., Clough, Y., Wanger, T.C., Jackson, L., Motzke, I., Perfecto, I. et al. (2012) Global food security, biodiversity conservation and the future of agricultural intensification. Biological Conservation, 151, 5359.CrossRefGoogle Scholar
Vallan, D. (2002) Effects of anthropogenic environmental changes on amphibian diversity in the rainforests of eastern Madagascar. Journal of Tropical Ecology, 18, 725742.CrossRefGoogle Scholar
Vallan, D., Andreone, F., Raherisoa, V.H. & Dolch, R. (2004) Does selective wood exploitation affect amphibian diversity? The case of An'Ala, a tropical rainforest in eastern Madagascar. Oryx, 38, 410417.CrossRefGoogle Scholar
Vargas, A., Jiminez, I., Palomares, F. & Palacios, M.J. (2002) Distribution, status, and conservation needs of the golden-crowned sifaka (Propithecus tattersalli). Biological Conservation, 108, 325334.CrossRefGoogle Scholar
Venugopal, P.D. (2010) Population density estimates of agamid lizards in human-modified habitats of the Western Ghats, India. Herpetological Journal, 20, 6976.Google Scholar
Vieilledent, G., Grinand, C., Rakotomalala, F.A., Ranaivosoa, R., Rakotoarijaona, J.R., Allnutt, T.F. et al. (2018) Combining global tree cover loss data with historical national forest cover maps to look at six decades of deforestation and forest fragmentation in Madagascar. Biological Conservation, 222, 189197.CrossRefGoogle Scholar
Vitousek, P.M., Mooney, H.M., Lubchenco, J. & Melillo, J.M. (1997) Human domination of Earth's ecosystems. Science, 277, 494499.CrossRefGoogle Scholar
Warren-Thomas, E., Nelson, L., Juthong, W., Bumrungsri, S., Brattström, O., Stroesser, L. et al. (2020) Rubber agroforestry in Thailand provides some biodiversity benefits without reducing yields. Journal of Applied Ecology, 57, 1730.CrossRefGoogle Scholar
Webber, A.D., Solofondranohatra, J.S., Razafindramoana, S., Fernández, D., Parker, C.A., Steer, M. et al. (2020) Lemurs in cacao: presence and abundance within the shade plantations of northern Madagascar. Folia Primatologica, 91, 96107.CrossRefGoogle ScholarPubMed
Wilme, L., Goodman, S.M. & Ganzhorn, J.U. (2006) Biogeographic evolution of Madagascar's’ microendemic biota. Science, 312, 10631065.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1 Localities of natural forest, forest eco-plantation, non-forest eco-plantation and intensive plantation sites surveyed in the Sava region of northern Madagascar near Vohemar-Daraina (a) and Sambava (b). Forested areas are shaded.

Figure 1

Table 1 Centroid location, distance to the nearest forest fragment, and area of each vanilla plantation surveyed in the Sava region, north east Madagascar (Fig. 1), during 10 January–25 April 2017, by habitat type (see text for definitions).

Figure 2

Table 2 Summary of the observed total number and mean number of species, mean number of species of birds, reptiles, frogs and mammals, per cent of species that are native, migratory or invasive, and per cent of species in each of four groups of IUCN Red List categories in each of the four habitat types (see text for definitions) in the Sava region, north-east Madagascar. Values with the same superscript letter within a row are not significantly different from each other in a GLMM of habitat type (corrected for multiple comparisons, following sequential Holm–Bonferroni correction).

Figure 3

Fig. 2 (a) Expected number of animal species computed by rarefaction (S, solid lines), and (b) the inverse Simpson diversity index, with upper and lower 95% confidence intervals (dotted lines), among individuals in the four habitat types in the Sava region, north-east Madagascar (Fig. 1); extrapolations up to 834 knots (individuals) are depicted by the dashed extensions in (a). The vertical line indicates the point of comparison (the point of the maximum runs for the habitat with the fewest observed species). Rarefaction, extrapolation, diversity indices and associated confidence intervals were computed in EstimateS (Colwell, 2013).

Figure 4

Fig. 3 Inverse Simpson index–individual curves (with associated 95% confidence intervals) of (a) birds, (b) reptiles and (c) frogs observed in the four habitat types in the Sava region, north-east Madagascar. The vertical line indicates the point of comparison (the point of the maximum runs for the habitat with the fewest observed species). Diversity indices and associated confidence intervals were computed in EstimateS (Colwell, 2013). Note the differing x- and y-axis scales.

Figure 5

Fig. 4 Box plots (median, upper and lower quartiles, and maximum and minimum values) of the inverse Simpson diversity index for mammals observed in the four habitat types in the Sava region, north-east Madagascar (numbers in parentheses indicate sample size from which diversity indices were computed).

Supplementary material: PDF

Hending et al. supplementary material

Hending et al. supplementary material 1
Download Hending et al. supplementary material(PDF)
PDF 229 KB
Supplementary material: File

Hending et al. supplementary material

Hending et al. supplementary material 2

Download Hending et al. supplementary material(File)
File 17.6 KB