Hostname: page-component-586b7cd67f-tf8b9 Total loading time: 0 Render date: 2024-11-22T22:29:57.191Z Has data issue: false hasContentIssue false

Prioritizing threats to improve conservation strategy for the tiger Panthera tigris in the Sundarbans Reserve Forest of Bangladesh

Published online by Cambridge University Press:  24 July 2013

Abdul Aziz*
Affiliation:
69/1 New Circular Road, Malibagh, Dhaka 1217, Bangladesh.
Adam C. D. Barlow
Affiliation:
69/1 New Circular Road, Malibagh, Dhaka 1217, Bangladesh.
Christina C. Greenwood
Affiliation:
69/1 New Circular Road, Malibagh, Dhaka 1217, Bangladesh.
Anwarul Islam
Affiliation:
69/1 New Circular Road, Malibagh, Dhaka 1217, Bangladesh.
*
(Corresponding author) E-mail [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Tigers Panthera tigris face a wide and complex array of threats. Given limited time and resources it is essential to direct conservation actions based on the relative importance of each threat. The Sundarbans Reserve Forest is the last stronghold of tigers in Bangladesh and supports one of the largest populations of tigers in the world. As in other tiger landscapes, the threats faced by the tigers have yet to be assessed. This study follows an approach developed by The Nature Conservancy to identify and prioritize threats and set a time-frame for their reduction. We identified a total of 23 threats; four were linked to tigers, two to prey and 17 to habitat. Of the identified threats, the highest ranked included poaching of tigers, poaching of prey, sea-level rise, upstream water extraction/divergence, wood collection, fishing, and harvesting of other aquatic resources. All threats were then scheduled for reduction, based on the rank and current information base for each threat and the likely time-frame for implementing potential solutions. This study demonstrates how the application of a prioritization framework can greatly improve the focus and likelihood of success of any species- or ecosystem-based conservation programme.

Type
Carnivore Conservation
Copyright
Copyright © Fauna & Flora International 2013 

This paper contains supplementary material that can be found online at http://journals.cambridge.org

Introduction

Wild tiger Panthera tigris populations have declined by at least half over the last decade alone, with the current number estimated to be 3,200–3,600, excluding cubs (Seidensticker, Reference Seidensticker2010). To reverse the current downward trend of tiger populations, protecting source sites (Walston et al., Reference Walston, Robinson, Bennett, Breitenmoser, da Fonseca and Goodrich2010) and maintaining metapopulations (Wikramanayake et al., Reference Wikramanayake, Dinerstein, Seidensticker, Lumpkin, Pandav and Shrestha2011) have been proposed as conservation goals. To achieve such goals and to design, prioritize and implement conservation actions that will save tigers from extinction, threats to tigers need to be identified and ranked in terms of their potential impact (TNC, 2007). If all threats are not considered and explicitly assessed there is a risk that conservation efforts are wasted on low-priority threats while the biological target is degraded or lost as a result of higher priority threats. In addition, given limited time and resources, we need to identify the optimum allocation of the available resources for conservation actions (Sinclair et al., Reference Sinclair, Hik, Schmitz, Scudder, Turpin and Larter1995).

Guidelines for threat assessment have been created by The Nature Conservancy (TNC, 2007). The first step in this assessment is to set the scope and biological targets upon which the threats are acting and to assess the viability of those targets (TNC, 2007). The scope provides the overall goal and the scale of the conservation issue, and the specified targets establish a clear focus upon which planning and monitoring steps are concentrated (TNC, 2007). To achieve conservation goals, a threat reduction time-line can then be developed to deal with each threat, based on its priority.

Despite decades of conservation efforts, however, there has been little assessment or identification of the multitude of threats facing tigers and the landscapes they inhabit. A study in Russia documented tiger mortality from poaching (Kretchmar, Reference Kretchmar2006), and theoretical models have been developed to investigate the potential impact of poaching (Kenney et al., Reference Kenney, Smith, Starfield and McDougal1995) and depletion of prey (Karanth & Stith, Reference Karanth, Stith, Seidensticker, Christie and Jackson1999). Furthermore, habitat destruction is the only threat that has been examined across all of the remaining 76 Tiger Conservation Landscapes (Sanderson et al., Reference Sanderson, Forrest, Loucks, Ginsberg, Dinerstein and Seidensticker2006; Nagendra et al., Reference Nagendra, Rocchini and Ghate2010). Assessing threats to tigers and the effects of conservation actions involves monitoring the status of the tiger population in question and the status of the resources, such as prey and habitat, on which the population depends (TNC, 2007).

One of the most important remaining Tiger Conservation Landscapes is the Sundarbans Reserve Forest of Bangladesh and India. The Bangladesh Tiger Action Plan was developed to provide guidelines for tiger conservation efforts from 2009 to 2017 (Ahmad et al., Reference Ahmad, Greenwood, Barlow, Islam, Hossain, Khan and Smith2009). The vision of the Action Plan is ‘protected tiger landscapes in Bangladesh, where wild tigers thrive at optimum carrying capacities and which continue to provide essential ecological services to mankind’ (Ahmad et al., Reference Ahmad, Greenwood, Barlow, Islam, Hossain, Khan and Smith2009). The Sundarbans Reserve Forest constitutes almost half of the remaining forest in Bangladesh and is the last stronghold of tigers, with an estimated population of 300–500 (Ahmad et al., Reference Ahmad, Greenwood, Barlow, Islam, Hossain, Khan and Smith2009; Barlow, Reference Barlow2009). The prey of tigers in this forest comprises mainly spotted deer Axis axis and wild boar Sus scrofa (Reza et al., Reference Reza, Feeroz and Islam2001). Both the tiger and its prey rely on a healthy ecosystem for food and shelter (Seidensticker, Reference Seidensticker, Miller and Everett1986; Sunquist, Reference Sunquist, Tilson and Nyhus2010). The Action Plan highlights many of the threats to tigers and their prey and habitat in the Sundarbans Reserve Forest but does not identify all threats or rank those threats.

The overall aim of this study was to demonstrate how application of existing conservation planning tools can improve understanding of a conservation setting and increase the focus of conservation strategy. The specific objectives, in the context of tigers in the Sundarbans Reserve Forest, were to (1) set the scope for biological targets and actions, (2) assess the viability of the biological targets, (3) identify and rank threats to the biological targets, and (4) set a time-line for reduction of threats. We followed TNC's conservation planning approach, supported by MIRADI v. 3.0 (CMP, 2010), specialized project management software developed by the Conservation Measures Partnership. Using tigers in the Sundarbans as a case study we demonstrate how using a structured approach to threat prioritization could improve planning for species conservation in other landscapes.

Methods

Defining project scope and biological targets

The TNC approach requires a definition of the project scope (‘the place where the biodiversity of interest to the project is located’; TNC, 2007). For this case study the scope was defined as the 6,017 km2 Sundarbans Reserve Forest of Bangladesh (Fig. 2); a UNESCO world heritage site, a RAMSAR site, and a Tiger Conservation Landscape of global importance (Sanderson et al., Reference Sanderson, Forrest, Loucks, Ginsberg, Dinerstein and Seidensticker2006). The Bangladesh Forest Department is the custodian of the Forest, which is delineated into four ranges and 55 compartments, contains three Wildlife Sanctuaries (Sundarbans West, 715 km2; Sundarbans South, 370 km2; Sundarbans East, 312 km2), and is protected by > 90 guard posts (Ahmad et al., Reference Ahmad, Greenwood, Barlow, Islam, Hossain, Khan and Smith2009).

Biological targets, which can be components of the ecosystem or focal species, are then selected as the basis for setting conservation objectives, carrying out conservation actions and evaluating progress (Salafsky et al., Reference Salafsky, Margolis, Redford and Robinson2002; TNC, 2007). For the Sundarbans Reserve Forest, the tiger was selected as the focal species, tiger prey because its status is directly linked to the status of the tiger population (Karanth et al., Reference Karanth, Kumar, Nichols, Link and Hines2004), and habitat because it is essential for the survival of tiger and prey (Seidensticker, Reference Seidensticker, Miller and Everett1986; Sunquist, Reference Sunquist, Tilson and Nyhus2010).

Assessing viability of biological targets

The biological targets were assessed in terms of their current and desired viability. The viability of a target is the state or health of that target, defined in terms of key ecological attributes (TNC, 2007). Such an attribute is ‘an aspect of a target's biology or ecology that if present defines a healthy target, and if missing or altered would lead to the outright loss or extreme degradation of that target over time’ (TNC, 2007). Each attribute has one or more indicators that allow measurement of the attribute's state; their value can be set as very good, good, fair, or poor (TNC, 2007). A value is set for the current state of each indicator based on existing knowledge, and a second value is set for the desired future state of each indicator based on what the conservation project would like to achieve given the current state and potential for improvement (TNC, 2007). These key ecological attributes therefore provide a way of evaluating changes in the state of each target over time and act as a basis for measurement of success of the conservation project (Fig. 1). The attributes and their indicators were selected for each target, considering the information available and the approaches available to monitor their change over time. A literature review was carried out to collect information to assess the current viability of the targets in terms of the current state of their key ecological attributes. The desired states of the biological targets were set, considering their current state and their potential for improvement over the time-frame of the Bangladesh Tiger Action Plan.

Fig. 1 Relationship between threats, key ecological attributes, and biological targets (adapted from TNC, 2007).

Fig. 2 Location of wildlife sanctuaries in the Sundarbans Reserve Forest.

Identifying and prioritizing threats

Threats were identified for each of the selected targets. Threats are ‘the proximate activities or processes that have directly caused, are causing, or may cause stresses and thus the destruction, degradation and/or impairment of focal biological targets’ (TNC, 2007; Fig. 1). To ensure consistency of threat type we used only direct threats (also known as ‘sources of stress’ in the TNC framework; e.g. wood cutting) rather than indirect threats (e.g. lack of alternative firewood; TNC, 2007). A list of threats was created based on the Bangladesh Tiger Action Plan, the literature review, and discussions amongst the authors about threats that may emerge in the future, following TNC (2007). The generic TNC threat category list in MIRADI was also referenced to ensure that a thorough threat list was developed.

The approach chosen to rank threats depends on how the identified threats act on the selected targets. Threats can act on targets in two different ways: a simple system where the effect of threats is aggregated on all stresses, and a complex system where the threats act on each individual stress (TNC, 2007). We selected the simple system because we felt this better reflected the relationship between the threats and targets in the case of the Bangladesh Tiger Action Plan. In this simple threat-rating system each threat is scored based on three components: scope, severity and irreversibility. Each of these components was ranked as very high, high, medium, or low, depending on the available information for that threat and its effect on the biological target (Table 1). The overall rank for a threat was then calculated by MIRADI, using a rule-based approach that accounts for the accumulative ranks of the threat's scope, severity and irreversibility.

Table 1 Definitions of components and associated ratings used to prioritize each threat (adapted from TNC, 2007).

A literature review was carried out to gather information on aspects of each threat. The scope, severity and irreversibility ratings of each threat component were then assigned by the authors, based on the available information. There was a lack of information for many of the threats, so assumptions (based on the authors' experience of conservation in the Sundarbans Reserve Forest and advice from senior Bangladesh Forest Department staff with experience working in this Forest) were made regarding some ratings, pending further research.

Creating a time-line for threat reduction

A time-line for reduction of each threat was created, considering (1) the threat's rank, (2) the current information base for the threat, and (3) the likely time-frame for implementing potential solutions for the threat. Threats were scheduled for reduction in the short term (2009–2017), medium term (2018–2025), or long term (2026+), or unscheduled pending further research. The outlined time-frame does not cover when activities need to be started to ensure the required reduction of the threat; for example, activities may need to be started in the short term to achieve reduction of a threat in the medium or long term.

Results

Based on the available information the indicators for the viability of the three biological targets (tigers, their prey, and habitat) were judged to be fair to very good, with most indicators in need of improvement to reach desired target states (Tables 2–4). A total of 23 threats were identified; four were linked to tigers, two to prey, and 17 to habitat (Table 5, Supplementary Tables S1–S3). In terms of ranking, six threats were prioritized as high, 10 as medium and seven as low (Table 5). Poaching of tigers and their prey, sea-level rise, upstream water extraction/divergence, wood collection, and fishing and harvesting of aquatic resources were the highest ranked threats (Table 5).

Table 2 Key ecological attributes, indicators and measurements to assess the current viability of the tiger Panthera tigris in the Sundarbans Reserve Forest (Fig. 2; Barlow et al., Reference Barlow, Ahmad, Rahman, Howlader, Smith and Smith2008, Reference Barlow, Chakma, Hossain, Mizan, Howlader and Greenwood2009).

Table 3 Key ecological attributes, indicators and measurements to assess current viability of prey in the Sundarbans Reserve Forest (I.U. Ahmad, unpubl. data).

Table 4 Key ecological attributes, and measurements to assess current viability of habitat in the Sundarbans Reserve Forest (Siddiqi, Reference Siddiqi2001; Smith et al., Reference Smith, Braulik, Strindberg, Ahmed and Mansur2006; Wahid et al., Reference Wahid, Babel and Bhuiyan2007; Iftekhar & Saenger, Reference Iftekhar and Saenger2008; Islam & Peterson, Reference Islam and Peterson2008).

* DBH, Diameter at breast height

Table 5 Ranking score, overall priority, and schedule of reduction for threats to tiger, prey, and habitat for the Sundarbans Reserve Forest.

The threats scheduled for reduction in the short term (2009–2017) were poaching of tigers, killing of stray tigers, diseases of tigers and their prey, poaching of prey, and livestock grazing. There were a further three threats scheduled for medium-term reduction (2018–2025), five threats were scheduled for long-term reduction (2026+), and nine were unscheduled pending further research (Table 5).

Discussion

The main strength of the TNC framework is that it focuses on and measures success with respect to biological targets, and thus the process is not constrained by the perceived capabilities or interests of the individuals or groups involved in the threat prioritization process. The three targets selected for the Sundarbans Reserve Forest are useful for directing conservation activities at the present time but new targets can be added in the future if that improves planning and management. Additional species that represent large taxonomic groups or act as flagship or umbrella species for other aspects of the Sundarbans Reserve Forest landscape (e.g. birds) could be added either as targets or key ecological attributes, depending on the conservation need.

The viability assessment and threat-ranking parts of the framework allow the use of information from other projects on related taxa, communities or ecological systems in similar settings. However, with respect to the current Sundarbans targets, there is considerable scope to improve the key ecological attributes for habitat in particular; so far we have had difficulty identifying attributes related to the terrestrial and aquatic components of the Sundarbans Reserve Forest ecosystem that would reflect the system's viability and could be tracked through time by associated indicators. Improving the choice of key ecological attributes and indicators will be a priority activity, as they are fundamental to evaluating the response of the targets to the conservation actions that are implemented.

The framework helped to identify a large number of threats not normally associated with tiger conservation (e.g. plant disease may not be directly linked to the tiger population but is a direct threat to tiger habitat). Some of the threats identified in this case study may be unique to the Sundarbans Reserve Forest (e.g. sea acidification) but others may affect all Tiger Conservation Landscapes to some degree (e.g. tiger poaching and prey poaching).

Current threat rankings are best judgements based on the available information, so threat rankings will undoubtedly change in the future following improvement of the information base through additional research, and implementation of conservation actions that affect those threats (e.g. improved law enforcement and development of alternative livelihoods). Another option would be to not rank threats with a poor information base. However, we feel that sometimes the risk of wasting money on unnecessary management actions because of a poor information base for a particular threat assessment would be greatly outweighed by the risk of biodiversity loss from inaction during the often lengthy time taken to assess the threat more comprehensively. Research to improve understanding of threats should of course be carried out but in parallel to (rather than instead of) the management activities to mitigate that threat.

High levels of livestock grazing are associated with high levels of livestock depredation by tigers and may also be one of the factors that encourage tigers to stray into villages (Rahman et al., Reference Rahman, Barlow, Greenwood, Islam and Ahmed2010). Therefore, although livestock grazing was only ranked as a low-priority threat, it was scheduled for reduction in the short term because it is closely linked to the medium-ranked threat of the killing of stray tigers.

Although sea level rise and upstream water extraction/diversion were prioritized as high-ranked threats, these two threats were scheduled for reduction in the long term because of the extrinsic nature of these threats and considering the time-frame required to mitigate them. Similarly, wood collection and fishing and harvesting of other aquatic resources were placed in the medium term despite being ranked as high-category threats, because mitigating these threats would entail reducing the considerable direct economic dependency of millions of local people on the Sundarbans Reserve Forest (Canonizado & Hossain, Reference Canonizado and Hossain1998). In addition, many threats were categorized as unscheduled, pending further research to understand the scope, severity and irreversibility of these threats to the biological targets.

Despite lacking some information on target viability and threats, however, the framework helped the Forest Department and the WildTeam start conservation actions to tackle the high-priority threats. The Forest Department are now implementing a 5-year programme to improve protection of the Sundarbans Reserve Forest, and WildTeam are preparing social marketing campaigns to address killing of stray tigers and poaching of deer, and carrying out research to fill in the information gaps identified through the assessment of threats.

The findings of this case study may also be applicable to the Sundarbans in India because of the similarity of the ecological settings. The conservation framework could also be useful to improve strategies for tiger conservation in all Tiger Conservation Landscapes and could be adapted and applied to improve conservation of other species and ecosystems.

Acknowledgements

The formulation of this article would not have been possible without the support of the Bangladesh Forest Department, who lead tiger conservation efforts in the country and provided extensive review through Ishtiaq U. Ahmad, Md. Akbar Hossain, Tapan Kumar Dey, Md. Mozaharul Islam, Zahir Uddin Ahmed, Mihir Kumar Doe and Abu Naser Hossain. We are also grateful for the reviews of Matthew Linkie (Fauna & Flora International), Elizabeth Fahrni Mansur (Bangladesh Cetacean Biodiversity Project), Sarah Christie, Jonathan Baillie, Paul De Ornellas (Zoological Society of London), Travis Child (WTB), Md. Sayed Iftekhar (University of Tasmania) and Gertrude Denzau.

Biographical sketches

Md Abdul Aziz is a researcher for WildTeam and has a particular interest in the population ecology of large mammals in Bangladesh. Adam Barlow is a director of WildTeam, has been researching tigers in Nepal, Thailand and Bangladesh for the last 12 years, and has a particular interest in carnivore and prey population monitoring. Christina Greenwood is director of WildTeam and has a strong focus on strengthening delivery of conservation projects through improving strategy and processes using approaches developed in the business world. Md Anwarul Islam is chief executive officer of WildTeam, has worked in wildlife conservation in Bangladesh for the last 15 years, and his work is focused on building up a new generation of conservationists.

References

Agrawala, S., Ota, T., Ahmed, A.U., Smith, J. & van Aalst, M. (2003) Development and Climate Change in Bangladesh: Focus on Coastal Flooding and the Sundarbans. OECD, Paris, France.Google Scholar
Ahmad, I.U., Greenwood, C.G., Barlow, A.C.D., Islam, M.A., Hossain, A.N.M., Khan, M.M.H. & Smith, J.L.D. (2009) Bangladesh Tiger Action Plan 2009–2017. Bangladesh Forest Department, Ministry of Environment and Forests, Government of the People's Republic of Bangladesh, Dhaka, Bangladesh.Google Scholar
Alam, M.J.B. & Ahmed, F. (2010) Modeling climate change: perspective and applications in the context of Bangladesh. In Indian Ocean Tropical Cyclones and Climate Change (ed. Charabi, Y.), pp. 1523. Springer, Dordrecht, Netherlands.Google Scholar
Appel, M.J.G. & Summers, B.A. (1995) Pathogenicity of morbilliviruses for terrestrial carnivores. Veterinary Microbiology, 44, 187191.Google Scholar
Bangladesh Forest Department (2007) Cyclone Sidr Damage in the Sundarbans Reserve Forest, Bangladesh. A Report on the Preliminary Assessment and Mitigations Measures. Ministry of Environment and Forest, Government of Bangladesh, Dhaka, Bangladesh.Google Scholar
Barlow, A.C.D. (2009) The Sundarbans tiger: Adaptation, population status, and conflict management. PhD thesis. University of Minnesota, St Paul, USA.Google Scholar
Barlow, A.C.D., Ahmad, M.I.U., Rahman, M.M., Howlader, A., Smith, A.C. & Smith, J.L.D. (2008) Linking monitoring and intervention for improved management of tigers in the Sundarbans of Bangladesh. Biological Conservation, 141, 20312040.CrossRefGoogle Scholar
Barlow, A.C.D., Chakma, S., Hossain, A.N.M., Mizan, R., Howlader, A., Greenwood, C.J. et al. (2009) Bangladesh Sundarbans Relative Tiger Abundance Survey. Technical Report. Wildlife Trust of Bangladesh, Dhaka, Bangladesh.Google Scholar
Barlow, A.C.D., Greenwood, C.J., Ahmad, M.I.U. & Smith, J.L.D. (2010) Use of an action-selection framework for human–wildlife conflict in the Bangladesh Sundarbans. Conservation Biology, 24, 13381347.CrossRefGoogle ScholarPubMed
Barlow, A.C.D., Smith, J.L.D., Ahmad, I.U., Hossain, A.N.M., Rahman, M. & Howlader, A. (2011) Female tiger Panthera tigris home range size in the Bangladesh Sundarbans: the value of this mangrove ecosystem for the species' conservation. Oryx, 45, 125128.CrossRefGoogle Scholar
Biswas, S.R., Choudhury, J.K., Nishat, A. & Rahman, M.M. (2007) Do invasive plants threaten the Sundarbans mangrove forest of Bangladesh? Forest Ecology and Management, 245, 19.CrossRefGoogle Scholar
Blasco, F. & Aizpura, M. (2002) Mangroves along the coastal stretch of the Bay of Bengal: present status. Indian Journal of Marine Sciences, 3, 920.Google Scholar
Blower, J. (1985) Sundarbans Forest Inventory Project, Bangladesh: Wildlife Conservation in the Sundarbans. Overseas Development Administration, Land Resources Development Centre, Surbiton, UK.Google Scholar
Canonizado, J.A. & Hossain, M.A. (1998) Integrated Forest Management Plan for The Sundarbans Reserved Forest. Bangladesh Forest Department, Dhaka, Bangladesh.Google Scholar
Chaffey, D.R., Miller, F.R. & Sandom, J.H. (1985) A Forest Inventory of The Sundarbans, Bangladesh. Main Report. Overseas Development Administration, London, UK.Google Scholar
Chapron, G., Miquelle, D.G., Lambert, A., Goodrich, J.M., Legendre, S. & Clobert, J. (2008) The impact on tigers of poaching versus prey depletion. Journal of Applied Ecology, 45, 16671674.Google Scholar
CMP (Conservation Measures Partnership) (2010) Adaptive Management Software for Conservation Projects. Http://www.conservationmeasures.org/Miradi/ [accessed 29 October 2010].Google Scholar
Emanuel, K.A. (1987) The dependence of hurricane intensity on climate. Nature, 326, 483485.Google Scholar
Gani, M.O. (2002) A study on the loss of Bengal tiger (Panthera tigris) in five years (1996–2000) from Bangladesh Sundarbans. Tigerpaper, 29, 611.Google Scholar
Goodrich, J.M., Kerley, L.L., Smirnov, E.N., Miquelle, D.G., McDonald, L., Quigley, H.B. et al. (2008) Survival rates and causes of mortality of Amur tigers on and near the Sikhote-Alin Biosphere Zapovednik. Journal of Zoology, 276, 323329.Google Scholar
Hansen, J.E. (2007) Scientific reticence and sea level rise. Environmental Research Letters, 2, 16.Google Scholar
Harun-or-Rashid, S., Biswas, S.R., Bocker, R. & Kruse, M. (2009) Mangrove community recovery potential after catastrophic disturbances in Bangladesh. Forest Ecology and Management, 257, 923930.CrossRefGoogle Scholar
Hossain, A.N.M., Chakma, S., Barlow, A.C.D., Greenwood, C.J. & Islam, M.A. (2009) Sundarbans Reserved Forest Protection Assessment: Current State. Technical Report. Wildlife Trust of Bangladesh, Dhaka, Bangladesh.Google Scholar
Huda, M.S. & Hauqe, M.E. (2001) Current Status of Winter Fishery in Dublar Char and Options for Improvement, Sundarbans Biodiversity Conservation Project. Project Report No. 37. Ministry of Environment and Forests, Government of the People's Republic of Bangladesh, Dhaka, Bangladesh.Google Scholar
Iftekhar, M.S. & Islam, M.R. (2004) Degeneration of Bangladesh's Sundarbans mangroves: a management issue. The International Forestry Review, 6, 123135.Google Scholar
Iftekhar, M.S. & Saenger, P. (2008) Vegetation dynamics in the Bangladesh Sundarbans mangroves: a review of forest inventories. Wetlands Ecological Management, 16, 291312.Google Scholar
Islam, M.S. & Haque, M. (2004) The mangrove-based coastal and nearshore fisheries of Bangladesh: ecology, exploitation and management. Reviews in Fish Biology and Fisheries, 14, 153180.Google Scholar
Islam, T. & Peterson, R.E. (2008) Climatology of landfalling tropical cyclones in Bangladesh 1877–2003. Natural Hazards, 48, 115135.Google Scholar
IUCN Bangladesh (2003) Conservation Monitoring of Sundarbans Biodiversity, Biodiversity Health Status Workshop Proceedings. IUCN Bangladesh Country Office, Dhaka, Bangladesh.Google Scholar
Jagrata Juba Shangha (2003) Human–Wildlife Interactions in Relation to the Sundarbans Reserved Forest of Bangladesh. Report No. 78. Sundarbans Biodiversity Conservation Project, Department of Environment and Forests, Dhaka, Bangladesh.Google Scholar
Karanth, K.U., Kumar, N.S., Nichols, J.D., Link, W.A. & Hines, J.E. (2004) Tigers and their prey: predicting carnivore densities from prey abundance. Proceedings of the National Academy of Sciences of the United States of America, 101, 48544858.Google Scholar
Karanth, K.U. & Stith, B.M. (1999) Prey depletion as a critical determinant of tiger population viability. In Riding the Tiger: Tiger Conservation in Human-Dominated Landscapes (eds Seidensticker, J., Christie, S. & Jackson, P.), pp. 100113. Cambridge University Press, Cambridge, UK.Google Scholar
Karim, A. (1994) The physical environment. In Mangroves of the Sundarbans, Volume II: Bangladesh (eds Hussain, Z. & Acharya, G.), pp. 1142. IUCN, Bangkok, Thailand.Google Scholar
Keawcharoen, J., Oraveerakul, K., Kuiken, T., Fouchier, R.A.M., Amonsin, A., Payungporn, S. et al. (2004) Avian influenza H5N1 in tigers and leopards. Emerging Infectious Disease, 10, 21892191.CrossRefGoogle ScholarPubMed
Kenney, J.S., Smith, J.L., Starfield, A.M. & McDougal, C.W. (1995) The long-term effects of tiger poaching on population viability. Conservation Biology, 9, 11271133.CrossRefGoogle ScholarPubMed
Kretchmar, M. (2006) The Amur tiger. The most expensive trophy in the world. Hunting and Fishing, 1, 96107. [in Russian]Google Scholar
Lacerda, L.D., Martinell, L.A., Rezende, C.E., Mozeto, A.A., Ovalle, A.R.C., Victoria, R.L. et al. (1988) The fate of trace metals in suspended matter in a mangrove creek during a tidal cycle. The Science of Total Environment, 75, 169180.Google Scholar
Loucks, C., Barber-Meyer, S., Hossain, M.A.A., Barlow, A. & Chowdhury, M.R. (2010) Sea level rise and tigers: predicted impacts to Bangladesh's Sundarbans mangroves. Climate Change, 98, 291298.Google Scholar
McLeod, E. & Salm, R.V. (2006) Managing Mangroves for Resilience to Climate Change. IUCN, Gland, Switzerland.Google Scholar
Miah, M.G. & Bari, M.N. (2001) Agricultural Practices and Their Impact on The Ecology and Biodiversity of the Sundarban Area of Bangladesh. Technical Project Report of UNESCO, BSMRAU, Gazipur, Bangladesh.Google Scholar
Miah, M.G., Bari, M.N. & Rahman, M.A. (2003) Agricultural activities and their impacts on the ecology and biodiversity of the Sundarbans area of Bangladesh. Journal of the National Science Foundation Sri Lanka, 31, 175199.Google Scholar
MOEF (Ministry of Environment and Forest) (2008) Bangladesh Climate Change Strategy and Action Plan 2008. Ministry of Environment and Forest, Government of the People's Republic of Bangladesh, Dhaka, Bangladesh.Google Scholar
Mukhopadhyay, K. (2004) An assessment of a biomass gasification based power plant in the Sundarbans. Biomass and Bioenergy, 27, 253264.Google Scholar
Myers, D.L., Zurbriggen, A., Lutz, H. & Pospischil, A. (1997) Distemper: not a new disease in lions and tigers. Clinical and Vaccine Immunology, 4, 180.Google Scholar
Nagendra, H., Rocchini, D. & Ghate, R. (2010) Beyond parks and monoliths: spatially differentiating park–people relationships in the Tadoba Andhari Tiger Reserve in India. Biological Conservation, 143, 29002908.Google Scholar
Newman, J. (2004) The Tiger Skin Trail. Environmental Investigation Agency, Bangkok, Thailand.Google Scholar
Nowell, K. (2000) Far from a Cure: The Tiger Trade Revisited. Species in Danger Series, Traffic International, Cambridge, UK.Google Scholar
Nowell, K. & Ling, X. (2007) Taming the Tiger Trade. TRAFFIC, East Asia, Hong Kong.Google Scholar
Rahman, M.A. (1994) Disease and Disorders of the Trees with Special Reference to Top Dying of Sundri in the Mangrove Forests of Sundarbans in Bangladesh. FAO/UNDP Project No. BGD/84/056. Integrated Resource Development of the Sundarbans Reserve Forest, Dhaka, Bangladesh.Google Scholar
Rahman, H.A., Barlow, A.C.D., Greenwood, C.J., Islam, M.A. & Ahmed, I.U. (2010) Livestock Depredation by Tiger on the Edge of the Bangladesh Sundarbans. Technical Report. Wildlife Trust of Bangladesh, Dhaka, Bangladesh.Google Scholar
Rahmstorf, S. (2007) A semi-empirical approach to projecting future sea-level rise. Science, 315, 368370.Google Scholar
Rees, H.G. & Collins, D.N. (2006) Regional differences in response of flow in glacier-fed Himalayan rivers to climatic warming. Hydrological Processes, 20, 21572169.Google Scholar
Reza, A.H.M.A., Feeroz, M.M. & Islam, M.A. (2001) Food habits of the Bengal tiger (Panthera tigris tigris) in the Sundarbans. Bangladesh Journal of Zoology, 29, 173180.Google Scholar
Reza, A.H.M.A., Feeroz, M.M. & Islam, M.A. (2002) Man–tiger interaction in the Bangladesh Sundarbans. Bangladesh Journal of Life Sciences, 14, 7582.Google Scholar
Roy, S., Hens, D., Biswas, D. & Kumar, R. (2002) Survey of petroleum-degrading bacteria in coastal waters of Sunderban Biosphere Reserve. World Journal of Microbiology and Biotechnology, 18, 575581.Google Scholar
Salafsky, N., Margolis, R., Redford, K.H. & Robinson, J.G. (2002) A conceptual framework and research agenda for conservation science. Conservation Biology, 16, 14691479.Google Scholar
Salam, M.A. & Noguchi, T. (1998) Factors influencing the loss of forest cover in Bangladesh: an analysis from socioeconomic and demographic perspectives. Journal of Forestry Research, 3, 145150.Google Scholar
Sanderson, E., Forrest, J., Loucks, C., Ginsberg, J., Dinerstein, E., Seidensticker, J. et al. (2006) Setting Priorities for the Conservation and Recovery of Wild Tigers: 2005–2015. Technical Assessment. WCS, WWF, Smithsonian, and NFWF-STF, New York, Washington, DC, USA.Google Scholar
Sarkar, S.K. & Bhattacharya, A.K. (2003) Conservation of biodiversity of the coastal resources of Sundarbans, northeast India: an integrated approach through environmental education. Marine Pollution Bulletin, 47, 260264.Google Scholar
Seidensticker, J. (1986) Large carnivores and the consequences of habitat insularization: ecology and conservation of tigers in Indonesia and Bangladesh. In Cats of the World: Biology, Conservation, and Management (eds Miller, S.D. & Everett, D.D.), pp. 141. National Wildlife Federation, Washington, DC, USA.Google Scholar
Seidensticker, J. (2010) Saving wild tigers: a case study in biodiversity loss and challenges to be met for recovery beyond 2010. Integrative Zoology, 5, 285299.Google Scholar
Shapiro, L.J. (1988) Impact of Climate Change on Hurricanes. UN Environment Programme, Mexico City, Mexico.Google Scholar
Shepherd, C.R. & Nolan, N. (2004) Nowhere to Hide: The Trade in Sumatran Tiger. TRAFFIC Southeast Asia, Selangor, Malaysia.Google Scholar
Siddiqi, N.A. (2001) Mangrove Forestry in Bangladesh. Institute of Forestry and Environmental Sciences, University of Chittagong, Chittagong, Bangladesh.Google Scholar
Sinclair, A.R.E., Hik, D.S., Schmitz, O.J., Scudder, G.G.E., Turpin, D.H. & Larter, N.C. (1995) Biodiversity and the need for habitat renewal. Ecological Applications, 5, 579587.Google Scholar
Smith, B.D., Braulik, G., Strindberg, S., Ahmed, B. & Mansur, R. (2006) Abundance of Irrawaddy dolphins (Orcaella brevirostris) and Ganges river dolphins (Platanista gangetica gangetica) estimated using concurrent counts made by independent teams in the waterways of the Sundarbans mangrove forest in Bangladesh. Marine Mammal Science, 22, 527547.Google Scholar
Smith, B.D., Braulik, G., Strindberg, S., Mansur, R., Diyan, M.A.A. & Ahmed, B. (2008) Habitat selection of freshwater-dependent cetaceans and the potential effects of declining freshwater flows and sea-level rise in waterways of the Sundarbans mangrove forest, Bangladesh. Aquatic Conservation: Marine and Freshwater Ecosystems, 19, 209225.Google Scholar
Smith, J.L.D. (1993) The role of dispersal in structuring the Chitwan tiger population. Behaviour, 124, 165195.Google Scholar
Smith, J.L.D. & McDougal, C. (1991) The contribution of variance in lifetime reproduction to effective population size in tigers. Conservation Biology, 5, 484490.Google Scholar
Sunquist, M. (2010) What is a tiger? Ecology and behavior. In Tigers of the World—The Science, Politics and Conservation of Panthera tigris (eds Tilson, R. & Nyhus, P.J.), pp. 1931. Academic Press, London, UK.Google Scholar
TNC (The Nature Conservancy) (2007) Conservation Action Planning Handbook: Developing Strategies, Taking Actions and Measuring Success at any Scale. The Nature Conservancy, Arlington, USA.Google Scholar
Wahid, S.M. (1995) Final Report on Hydrological Study of the Sundarbans. FAO/UNDP Project No. BGD/84/056. Integrated Resource Development of the Sundarbans Reserved Forest, Dhaka, Bangladesh.Google Scholar
Wahid, S.M., Babel, M.S. & Bhuiyan, A.R. (2007) Hydrologic monitoring and analysis in the Sundarbans mangrove ecosystem, Bangladesh. Journal of Hydrology, 332, 381395.Google Scholar
Walston, J., Robinson, J.G., Bennett, E.L., Breitenmoser, U., da Fonseca, G.A.B., Goodrich, J. et al. (2010) Bringing the tiger back from the brink—the six percent solution. PLoS Biology, 8(9), e1000485.Google Scholar
Wikramanayake, E., Dinerstein, E., Seidensticker, J., Lumpkin, S., Pandav, B., Shrestha, M. et al. (2011) A landscape-based conservation strategy to double the wild tiger population. Conservation Letters, 4, 219227.Google Scholar
Figure 0

Fig. 1 Relationship between threats, key ecological attributes, and biological targets (adapted from TNC, 2007).

Figure 1

Fig. 2 Location of wildlife sanctuaries in the Sundarbans Reserve Forest.

Figure 2

Table 1 Definitions of components and associated ratings used to prioritize each threat (adapted from TNC, 2007).

Figure 3

Table 2 Key ecological attributes, indicators and measurements to assess the current viability of the tiger Panthera tigris in the Sundarbans Reserve Forest (Fig. 2; Barlow et al., 2008, 2009).

Figure 4

Table 3 Key ecological attributes, indicators and measurements to assess current viability of prey in the Sundarbans Reserve Forest (I.U. Ahmad, unpubl. data).

Figure 5

Table 4 Key ecological attributes, and measurements to assess current viability of habitat in the Sundarbans Reserve Forest (Siddiqi, 2001; Smith et al., 2006; Wahid et al., 2007; Iftekhar & Saenger, 2008; Islam & Peterson, 2008).

Figure 6

Table 5 Ranking score, overall priority, and schedule of reduction for threats to tiger, prey, and habitat for the Sundarbans Reserve Forest.

Supplementary material: PDF

Aziz supplementary material

Aziz supplementary material

Download Aziz supplementary material(PDF)
PDF 116.3 KB