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Ecología en Bolivia

versão impressa ISSN 1605-2528versão On-line ISSN 2075-5023

Ecología en Bolivia vol.51 no.1 La Paz abr. 2016

 

Reseña

 

Floodplain fish communities in river systems in Bolivia: Current knowledge and addressing future research challenges

 

Comunidades de peces de las llanuras de inundación en ríos de Bolivia: El conocimiento actual y direccionamiento de retos en investigación futura

 

 

Laura Muñoz Puelles1, Andrew B. Gill1,*, Karina Osinaga2 & Humberto L. Perotto-Baldivieso1,3

1Cranfield University, School of Energy, Environment and Agrifood, Cranfield, Bedfordshire, England. *Corresponding author: a.b.gill@cranfield.ac.uk
2Museo de Historia Natural Noel Kempff Mercado, Facultad de Ciencias Agrícolas, Universidad Autónoma Gabriel Rene Moreno, Santa Cruz, Bolivia. Current address: Laura Muñoz Puelles
University of Valencia, School of Pharmacy, Department of Botany, Burjassot, Valencia, Spain.
3Caesar Kleberg Wildlife Research Institute, Texas A & M University-Kingsville, Kingsville, Texas, U.S.A.

 

 


Resumen

Las comunidades de peces tropicales de agua dulce están amenazadas debido a las presiones antropogénicas, especialmente la alteración del régimen hidrológico que determina el alcance y las características de los canales y los hábitats inundables para peces. Las consecuencias ecológicas de estas modificaciones pueden conllevar cambios importantes en la abundancia y diversidad de peces, limitaciones en la conectividad de las redes tróficas, disminución en la disponibilidad de microhábitats para reproducción y refugio, y modificaciones en los patrones de migración con consecuencias negativas para los servicios ambientales y los recursos pesqueros. La evidencia documentada de estos cambios es escasa y los enfoques actuales sobre inventariado de especies para recolectar datos relacionados con la pesca no consideran los gradientes espaciales y temporales que influyen en las comunidades piscícolas presentes en las llanuras de inundación. En este contexto es necesario proponer enfoques metodológicos adecuados que combinen la información disponible con un análisis de los cambios potenciales antes de que las acciones antrópicas sean irreversibles. En comparación con otros ríos tropicales, los ríos bolivianos están todavía relativamente bien conservados. Sin embargo, los planes de energía hidroeléctrica, la deforestación y la contaminación minera podrían tener efectos devastadores en los patrones hidrológicos y su biodiversidad. Esta revisión resume el conocimiento actual sobre los peces en llanuras de inundación de Bolivia, identifica carencias científicas y propone enfoques de ecología del paisaje para integrar patrones y procesos de los ríos tropicales inundables para contribuir al conocimiento actual y a la conservación de los recursos acuáticos de la región.

Palabras clave: Alteraciones hidrológicas, Amenazas antrópicas, Conectividad en ecosistemas fluviales, Tiempos de inundación.


Abstract

Tropical freshwater fish communities are increasingly under threat from anthropogenic pressures, particularly alteration to the hydrological regime (e.g. via deforestation and mining within the watershed and in-stream impoundments) which defines the extent and characteristics of in-channel and floodplain habitats for fishes. The ecological consequences of altered hydrology for tropical floodplain ecosystems are likely to be major declines in fish abundance and diversity, lower food web connectivity, reduced microhabitat availability for reproduction and refuge, modified migration patterns and consequently reduced ecosystem services, e.g. fishery resource. Evidence of change is lacking and the current species inventory approaches of collecting fish-related data do not consider spatial (i.e. river-floodplain distances) and temporal (i.e. flood water levels) gradients that are known to largely influence fish communities present in floodplain waterbodies. In the context of increasing threats, fish diversity and community declines are real and require suitable methodological approaches to combine available information and an informed analysis of likely change before actions are irreversible. Bolivian rivers are relatively undisturbed compared to other tropical rivers, however, plans for hydropower and increased deforestation and mining in the region could have devastating effects on the hydrological patterns and the dependent biodiversity. This review aims to summarize the current knowledge of floodplain freshwater fishes using Bolivian rivers as the example, identify the gaps that exist in the science and to propose a landscape ecology approach to integrate pattern and process understanding of the river-floodplain mosaic to fill knowledge gaps in an appropriate way towards the conservation of fish resources.

Key words: Anthropogenic threats, Connectivity in river systems, Flood timing, Hydrological changes.


 

 

Introduction

Of the estimated 15,000 known species of freshwater fish in the world approximately 50% are found in the tropical regions of South America (Froese & Pauly 2014). When combined with fish diversity in Central America current estimates can reach up to 80% of global freshwater diversity (Helfman 2007, Reis 2013). By far this is the highest freshwater fish diversity of any region globally and new species continue to be described (Junk et al. 2007). Available information about the current status of their biodiversity and habitats is critical as there is growing concern that current anthropogenic activities of deforestation, mining, impoundment and overfishing may be causing major declines in the freshwater fish communities and diversity (Barletta et al. 2010).

Tropical freshwater fishes are vital for the sustenance and maintenance of ecological integrity and thus the provision of multiple ecosystem services at local, national and regional scales (Lowe-McConnell 1989, Ayala et al. 2003, Winemiller & Jepsen 2005, Taylor et al. 2006, Anderson et al. 2009, 2011). Freshwater fish in the tropics occupy a great diversity of ecological niches, and play an essential role in ecosystem functions, such as stream nutrient recycling and productivity (Taylor et al. 2006), that are fundamental to the maintenance of aquatic and terrestrial food webs (Ayala et al. 2000). Trophic niche characteristics of each species are dependent on their individual morphological variations, reproduction and foraging abilities, and prey-predator dynamics (Sampaio et al. 2013). For instance, small for age fishes, through their movement strategies, affect their overall population distribution and biomass concentration, determining energy fluxes between primary producers and top predators and influencing trophic events and adaptation of predators (Yurek et al. 2013). The predators in turn regulate the population dynamics of prey species (Ayala et al. 2003). Fruit-eating fishes exert strong influences on local plant-recruitment dynamics and regional biodiversity by assisting in their seed dispersal and germination, both critical in the life history of plants (Anderson et al. 2009, 2011; Horn et al. 2011). These plants form part of the flooded forests, which are central in global ecosystem services such as carbon storage and climate regulation. The excrement of frugivorous and other fishes also contain organic matter that becomes available to detritivorous fishes, which play a significant role in sustaining production through increasing availability of resources in tropical freshwater ecosystems (Ayala et al. 2003, Taylor et al. 2006).

Tropical freshwater fishes are also indispensable as a source of animal protein for local human consumption hence loss in their diversity and abundance will bring both ecological and economic losses (Mounic-Silva 2012). For appropriate conservation and management of tropical river floodplain systems, it is essential that there is a significant improvement in understanding many aspects about the ecology of associated floodplain fishes. Declining freshwater fish diversity imposes an urgent need to study the links between fish communities, ecological niches, ecosystem functioning and human activities. Improving current understanding through the application of contemporary methodological research will be indispensable to designing and implementing effective measures of protection for tropical floodplains and other critical fish habitats that benefit ecological functions and the provision of ecosystem services to local communities that depend directly on these resources.

Bolivia is one of the most diverse countries in terms of freshwater fish species (>700) and fish-related cultures (Andolina et al. 2005; Sarmiento et al. 2014). Indigenous people make up 36 linguistic groups and 59% of the Bolivian population. Local communities are strongly dependent on the provisioning ecosystem service of fish to sustain their livelihoods (Lauzanne et al. 1990, Reinert & Winter 2002, FAO 2011).

Importantly, indigenous groups have an invaluable ecological understanding of these systems, including the fish communities present, and historically have used their knowledge to obtain fish resources in ways that can be considered as sustainable as they do not disrupt the natural dynamics of the river floodplain system (Pérez-Llorente et al. 2013). However new economic activities in the headwaters of the rivers feeding into the Amazon, increased land use changes and potential new developments in energy infrastructure may have a long-term negative impact on tropical freshwater communities in the region. Therefore, it is important to determine the state of the knowledge on freshwater fish in Bolivia to then propose strategic research to inform policy that can effectively contribute to the conservation of such important resources. The aim of this review was to assess the current knowledge of floodplain freshwater fishes, identify the gaps that exist both in science and management and to propose a methodological approach to address the knowledge gaps in a way appropriate to conservation of fish resources.

We focused our review in the Amazon region of Bolivia due to its current importance as a reference system that has not significantly been affected by human activities and because of the potential negative impact of new economic activities being developed across the watershed in the country and beyond its boundaries. This review is divided into five sections: The first section describes the ecological characteristics of the Amazon region of Bolivia, the second reviews the state of freshwater fish science in Bolivia, the third section refers to major threats to fish of floodplain rivers in the Amazon basin, the fourth provides insights on how landscape ecology can be the next research frontier to provide evidence-based information for effective conservation planning and the fifth section provides some final thoughts and conclusions emerging from this review.

 

Ecological characteristics of the Amazon region of Bolivia

The Bolivian Amazon basin extends over 67% (~716.021,19 km2) of the territory in the country and comprises approximately 10% of the total area of the Amazon basin (Farias et al. 2010). The climate is tropical with mean annual temperatures from 10 to 25°C (± 5-6°C) and the mean annual precipitation from 1,200 to 2,000 mm across the region (Pouilly et al. 2004a, Ronchail et al. 2005). The highest temperatures occur in the rainy or wet season (October - March), mostly concentrated from December to March. Overall, the basin contains some 145 main rivers, 37 lakes and 202 permanent lagoons, with a significant proportion of the area being prone to flooding in the wet season (FAO 2005). This basin is characterized by three main floodplain rivers (i.e. Mamoré, Beni and Madre de Dios rivers) that drain from the Andean watersheds and the central plain of the Bolivian Amazon. These rivers are rich in sediments and nutrients from weathering of sedimentary deposits, which leads to waters that are white-coloured, highly turbid with, low transparency, and neutral pH. Additionally, The Itenez river, another important river of the Bolivian Amazon drains from the Brazilian shields carrying clear-waters alongside the northwest of the Mamoré floodplain until both rivers conflux at Guayaramerín (Bourrel et al. 2009).

The central plain of the Bolivian Amazon encompasses the fringing floodplain of the Mamoré River or Llanos de Moxos (Hamilton et al. 2004, Duponchelle et al. 2007). This is one of the largest floodplain systems of the Amazon and is characterized by gallery forests, abundant floodplain lakes and outlying savannahs that appear to be subject to backwater effects of the Mamoré. The most important floodplain lakes within this area are permanent formed by migrating river channels and several large basins with rectangular shapes that reflect the underlying alignment of the basement rock (Ogawa et al. 2012). In the Mamoré the hydrological dynamics are strongly seasonal and promote spatial and temporal changes that are vital for aquatic organisms. The hydrological processes are well known and described in numerous studies (e.g. Hamilton et al. 2004, Pouilly et al. 2004a, Bourrel et al. 2009). Floodplain waterbodies are closely associated with the hydrological dynamics; some of which dry out as the flood ebbs and others form large floodplain lakes for most of the year. These are permanent lentic waters and can be classified into "lagunas de meandro" (oxbow lakes), "lagunas de depresión" (depression lakes) and "lagos de sabana" (savannah lakes) (Pouilly et al. 2004a).

Oxbow lakes are formed by migrating river channels of the Mamoré river system and are associated with the gallery forest. During the dry season these lakes act as nutrient sinks with inputs from rainfall, runoff and litterfall from the gallery forests. In the wet season fishes are able to move into the oxbow lakes to exploit nutrient resources and then leave to spawn, using the connecting channels between the river and the oxbow lakes that become inundated in the floods (Osorio et al. 2011). Depression lakes are formed in floodplains adjacent to the main streams by different rates of sedimentation and receive rainfall and overflow from the Mamoré and its tributaries, favouring connectivity and allowing movement of fish. These lakes are strongly patterned along an environmental gradient and provide extensive shallow water habitats that support diverse fish communities (Pouilly et al. 2006). The savannah lakes are characterized by extended surfaces and isolation periods during floods. Instead these lakes are directly connected to the phreatic soil level that maintains water levels and general physical-chemical conditions along the year (Pouilly et al. 2004b).

 

State of freshwater fish science in Bolivia

Fish taxonomy

Fish are the most unknown of vertebrate groups in Bolivia and reflect the poor overall state of knowledge of aquatic diversity in the country (Carvajal-Vallejos et al. 2014). In the Amazon region of Bolivia, 802 fishes are known to science and new fishes are described annually (Habützel et al. 2013, Carvajal-Vallejos et al. 2014, Sarmiento et al. 2014). Possibly the most documented river of the Bolivian Amazon is the Mamoré (394 spp.), although the ichthyofauna of the river Iténez (430 spp.) is referred as the most diverse (Carvajal-Vallejos et al. 2014). Over 97% of the species fall within five major orders, Characiformes, Siluriformes, Perciformes, Gymnotiformes and Cyprinodontiformes (Table 1).

The remaining 3% is formed by orders with five or less species each (Habützel et al. 2013, Carvajal-Vallejos et al. 2014). Almost all existing knowledge about the fishes of the Bolivian Amazon comes from inventories and taxonomic studies. Despite all taxonomic efforts, the scientific basis for a complete fish classification and understanding of the fish diversity for the Bolivian Amazon basin remains poor. This is mainly attributed to the remoteness of some areas with difficult access, as well as to the complexity of other regions that require specific methods and techniques to be surveyed. Current checklists and associated publications have been criticized for not considering spatial (i.e. river-floodplain distances) and temporal (i.e. change in water level at different phases of flooding) gradients (Hablützel 2012) that have been seen to largely influence fish communities present in floodplain waterbodies. In addition, some studies are carried out independently and apply their own criteria to inventory fish (Pouilly et al. 2004a), favouring discrepancies between naturalists about how to classify the ichthyofauna of Bolivia. An example is the fish genus called Microgeophagus, Papiliochromis or Mikrogeophagus (Morgenstern 2011), which appears in checklists under different names. Lack of consensus hinders the description of newly found specimens that are either duplicated or omitted in taxonomic reviews and other studies. Up to date, existing literature on fishes of Bolivia is perhaps too reliant on publications about the ichthyofauna of other South American countries, mainly Brazil, Venezuela and Peru. Owing to few habitats being sampling correctly (Junk et al. 2013), methods for data collection and monitoring of fish populations and communities that combine multiple techniques for sampling and data analysis are increasingly being used to improve accuracy of their results. New methods and tools have been proposed owing to the lack of a standardized protocol for fish sampling in the region (Anjos & Zuanon 2007). However, a perpetual problem is that a number of areas remain difficult to access resulting in insufficient information being available.

The scientific basis for a complete classification of fish fauna in Bolivia remains ill-defined and the lack of identification keys for the country complicates the verification of surveyed fish to the level of species (Pouilly et al. 2004a). It is generally assumed that new collection efforts and taxonomic reviews will likely increase the number of known Bolivian fish species considerably in the near future. However, some fishes may still have to be discarded from current checklists due to misidentifications. Future checklists should be more critical regarding false reports and every new report should be accompanied by at least a brief list of identification criteria (Hablützel et al. 2013).

Fish communities and habitats

The floodplain landscape of the Bolivian Amazon is characterized by meandering rivers that promote great diversity of habitats for fish (Pouilly et al. 2004a). Along the river channel there is a large heterogeneity of hydromorphological and riparian features that create diversity of flow types and a range of habitat opportunities for fish and other aquatic animals. Areas prone to flooding are expansive and productive zones, which are particularly vital as nursery grounds and refuge for fishes on a temporal basis, with this diversity supporting supply of economically valuable species to nearby human settlements throughout the Bolivian Amazon. Existing literature on the floodplain fish of the Mamoré accounts for more than 200 studies mainly focused on the composition of fish communities in this area. Such studies constitute valuable information sources about the relationships between their morphology, distribution, habitats and diets.

Floodplain fishes are known for displaying ontogenetic shifts in diet and habitat use, specific ecological traits for movement and growth and large-scale migrations in relation to environmental changes (Aldea-Guevara et al. 2013). For instance, storage of fats and lipids observed in floodplain migratory fishes allows for the sexual development of gonads and enables large scale reproductive migrations in response to hydrological cues for movement (Yurek et al. 2013). It has been suggested that ecological traits of migratory species may be constrained by geographical barriers, such as river rapids (Hubert et al. 2006). These potential barriers to fish movement may disrupt genetic connectivity between aquatic species of the Bolivian Amazon and other basins. Although river rapids apparently pose no barrier to reproductive migrations for species belonging to the genus Brachyplatystoma, Pseudoplatystoma and Prochilodus, other species like black pacú (Colossoma macropomum) undertake smaller scale, more localized seasonal movements for feeding and reproduction in within the limits of a geographical region (Farias et al. 2010).

Life histories of fishes in the Bolivian floodplains are complex because environmental conditions are highly variable inducing changes in trophic and reproduction behaviour (Espírito-Santo et al. 2013). Some fishes show restricted distributions, which makes them very vulnerable to local changes in habitat conditions, more commonly fish require multiple habitats through their life. Some fish belonging to the Rivulidae family are known for their seasonal life history (Hablützel 2012). They have an annual life history living in temporary habitats and resisting desiccation by laying their eggs on the substratum (Nielsen 2013). Furthermore, some species, such as the economically important, Colossoma macropomum require a suite of habitat types for different life stages making them potentially susceptible to the impacts of habitat fragmentation and alteration (Pouilly et al. 2004b, Junk et al. 2007, Aldea-Guevara et al. 2013). Many life-history strategies of fish are not fully understood. In a number of cases, it is currently unknown how life-history strategies of fishes vary according to environmental variables (e.g. water transparency), floodplain morphology and/ or flood pulse which may play an important role in the structure of fish communities in the Amazon (Duponchelle et al. 2007).

The hydrology across the Mamoré floodplain causes predictable varying environmental conditions over time and space to which fish communities respond. In general, it has been accepted that spatial habitat diversity promotes species diversity in fish communities. However, the seasonal habitat changes are less understood (Ayala et al. 2000, 2003, Freitas et al. 2010). There is evidence that important structural variations in fish communities occur among hydrological phases (Espírito-Santo et al. 2013). During the wet season fishes are dispersed across the flooded forest and become concentrated in freshwater bodies in the dry period, thus fish density and biomass per unit volume are increased as the water levels drop (Pouilly et al. 2004b, Rejas & Maldonado 2000).

Because most ichthyologic surveys are conducted in the dry season many species are not recorded (Hablützel 2012). This is reflected in the difficulties documented in several studies on trophic behaviour and diet of fishes, which refer to diet shifts according to different stages in the development of each species (Barros & Higuchi 2007). In these studies, body size has been shown to be a key parameter in trophic behaviour (Pouilly et al. 2004b). Current knowledge on the spatial and temporal changes in floodplain fish communities and habitats can be complemented with studies on individual species with different morphological characters and life history-strategies (Freitas et al. 2010, Castello et al. 2011, Carvajal-Vallejos et al. 2014).

 

Major threats to fish in Bolivian floodplain rivers

Deforestation

There are over 40 studies concerning deforestation in Bolivia, where the focus has been on socioeconomic and cultural aspects and their effects on terrestrial environments. Scientific evidence exists on the adverse effects of deforestation on terrestrial and aquatic environments (e.g. Killeen et al. 2007, Arancibia Arce et al. 2013, Müller et al. 2014). Increasing deforestation is driven by several factors, mainly construction of road infrastructure, urban development and the intensification of commercial agriculture (Bottazzi & Dao 2013). Despite its low population density, current deforestation rates in Bolivia are 200,000 ha per year. Current estimates indicate that deforestation rates will increase due to mechanized agriculture, cattle ranching, small-scale agriculture supported by strong international investment, increased demand nationally as a result of population growth, road expansion and institutional weaknesses (Steininger et al. 2001, Salonen et al. 2011, Müller et al. 2014). However the impacts of on-going deforestation on the aquatic environments of Bolivia have received little attention. Some of the most important consequences of deforestation for floodplain fish in the country are habitat loss and increasing loads of sediments into the rivers (Fearnside 2013). In particular, fine sediments in excess are known to cause irreversible damage to fish gills and create problems that reduce their reproductive fitness (Swinkels et al. 2012), with consequences for species population demographics and community interactions.

Mining and water pollution

Bolivia has traditionally been a mining country (Stassen et al. 2012). Over the years large and medium scale mining activities have been intensively developed across the country mostly for gold and zinc extractions. The boom in the mining industry over the past 30 years has raised mercury concentrations in soil and watercourses, with negative consequences on aquatic ecosystems and indigenous communities (Muñoz et al. 2013). Of particular concern is mercury bioaccumulation in aquatic food webs affecting people who have a regular fish diet (Maurice-Bourgoin et al. 1999, Maurice-Bourgoin et al. 2000 Pouilly et al. 2013). Laffont et al. (2009) and Stassen et al. (2012) have reported reproductive and developmental disorders in native groups in Bolivia due to overexposure of mercury present in fish. The lack of specific regulation for mining activities, has led to increased aurifer production mainly through small scale mining that is currently increasing in extent within the Amazon river basin. Unfortunately, to date there are no published quantitative data on the amount of current mining production and associated impacts on fish and the wider aquatic food web.

Indiscriminate overfishing

Bolivia harbours a great diversity of fish species and fish dependent local communities. However, current fisheries in Bolivia are relatively unmanaged and consequently fish populations are overexploited due to indiscriminate overfishing (Castello et al. 2011). Traditionally fishing has been an activity for subsistence, recently converted into a commercial practice that uses advanced fishing equipment and techniques. These improvements allow capturing fish all year around, especially when fish concentrate in floodplain waterbodies (FAO 2005). Indiscriminate fishing practices continue to decrease the abundance of commercially important fishes and have changed the age structure of natural populations. Also overfishing is disrupting a co-evolutionary equilibrium between frugivorous fishes (Anderson 2009, 2011). Limited knowledge of reproductive biology, stock levels and sustainable fishery management render it difficult to adequately manage fish resources (FAO 2005). In addition, economic development is increasing human dependence on fish resources and the consequences of overfishing will be aggravated in the absence of adequate conservation and management of fishery resources (Mounic-Silva 2012).

Impoundment

Construction of dams and reservoirs on rivers can potentially affect ecological and hydrological processes at multiple scales with direct impacts on aquatic and adjacent terrestrial ecosystems (Liu et al. 2013). Changes in the water regime modify the flow and alter seasonal and inter-annual variability with impacts on the timing, magnitude and frequency of the floods. It also changes river dynamics from lotic to lentic waters that significantly affect the composition and structure of fish communities (Agostinho et al. 2008). Most affected species are those that require distinct habitats to fulfil their life cycles, thus impoundment barriers that interrupt their migration or alter habitat extent and linkage also bring losses to f isheries production (Baigún et al. 2012, Fearnside 2013). Hence, conservation of spawning areas is essential for sustainable management of fish resources. Currently, 60% of all dams in Bolivia are in the Amazon region (FAO 2014). Two new river dams will be constructed in Bolivia as part of the Madeira-Complex, a massive programme of hydroelectric dam construction in their Amazonian territories. The rivers will be widened to be navigable, high-voltage electricity transmission lines will be installed, and extensive tracts of land will be flooded, hydrology will be significantly altered with resultant large-scale loss of fish stocks and valuable chestnut forests. The energy produced by the two dams will supply the Brazilian market with Bolivia assuming the role of energy exporter (Antentas 2009). The ecological and socio-economic impacts of impoundments in Bolivia have been little studied, especially in the Amazon basin. Over the past decades some variability in the precipitation trends have affected the hydrological balance in the South American countries like Bolivia on which hydropower production is highly dependent so that environmental impact studies are also required to ensure their management (Switkes 2008, Palomino-Cuya et al. 2013).

Landscape ecology for conserving tropical floodplain ecosystems

Landscape ecology theories can improve the understanding of patterns and processes in rivers (Wiens 2002, Carbonneau et al. 2012). The foundation principles of river and floodplain patchiness, connectivity, landscape of species relevance to organisms, and the scale over which these aspects influence organisms can be applied to rivers and floodplains in Bolivia, as much as elsewhere. This requires a shift in the paradigm from the river linear system framework to floodplain shifting mosaics of aquatic and terrestrial habitats in a network-based context (Erös et al. 2012). The use of new technologies is already challenging some of the traditional paradigms of river systems (Carbonneau et al. 2012). Their spatial composition and heterogeneity combined with hydrological connectivity is providing information about their biodiversity and processes that shape these ecosystems (Erös et al. 2012, Tonolla et al. 2012). Similar to terrestrial patches, riverscapes and floodplain patches should be defined as areas with similar physical and biological attributes from the perspective of individual species or species communities to assess spatial structure and connectivity (Carbonneau et al. 2012). With this concept, microhabitat availability for reproduction and movement can be mapped and their spatial patterns can be linked to taxonomy and functional traits, such as reproduction and trophic habits (Pouilly et al. 2004b). The resulting information at the patch level can then be complemented with icthyofauna biomass and coupled with life cycle information (Carvajal-Vallejos et al. 2014). A good example of the application of this concept is the analysis and quantification of thermal patches to assess spatial heterogeneity and link it to fish communities done by Tonolla et al. (2012). The spatial heterogeneity of the resulting patches can then be used to quantify connectivity and link to species movement and dispersal. Maintaining connectivity has become a standard goal of conservation biology and a primary goal in freshwater conservation planning (Thieme et al. 2007). The spatial relationship between habitat patches in riverscapes and floodplains is an important factor for the integration of species populations within a community (Carbonneau et al. 2012).

The importance of longitudinal connectivity in rivers has grown in the last decade, since landscape principles have included the dendritic nature of river networks within models of metapopulation dynamics. (Segurado et al. 2013). It is now recognized that longitudinal connectivity affects ecological processes that have an impact at individual and population levels. In recent years, the use of patch-based analysis with graphs has become a very useful tool for modelling stream networks and modelling habitat connectivity (Erös et al. 2012). These are also suitable for developing alternative scenarios for landscape design and conservation (Bodin & Saura 2009, Erös et al. 2012). Using graph-based approaches, Segurado et al. (2013) developed a general framework to assess the role of river barriers to prioritize connectivity rehabilitation based on quantitative measurements. Connectivity sampling designs are fundamental to achieve ecologically and statistically valid results (Perotto-Baldivieso et al. 2009). The value and importance of stream connectivity and directionality within a dendritic river system can also be assessed (Liu et al. 2013). The integration of hydrological information, geomorphology data, and vegetation mapping could improve our understanding of connectivity in river systems (Stevaux et al. 2013). Also, the integration of data at multiple scales is of fundamental importance to understanding connectivity in river networks at large scales (Arancibia-Arce et al. 2013, Van Looy et al. 2014). This is often determined by the species being studied and the availability of the biological and ecological data (e.g. reproductive season, home ranges and dispersal) to make sound biological inferences within the spatial models. The use of habitat patches across a hierarchy of spatial scales can further be used to understand connectivity and the related ecological processes in river systems (Erös et al. 2012).

Also, the use of geospatial mapping and analysis has seen significant advances in the last decades (Carbonneau et al. 2012). Advances in remote sensing (RS) and geographic information systems (GIS) have provided a unique opportunity to map and quantify the spatial heterogeneity of rivers and floodplains. For example, Tonolla et al. (2012) have used very high resolution thermal infrared imagery to quantity thermal heterogeneity at relevant scales to species in floodplain ecosystems. Others have used Laser Illuminated Detection And Ranging (LIDAR) to assess river topography (Carbonneau et al. 2012). The development of technologies to capture data at very high spatial and temporal resolutions is making it possible to move from the conceptual theories of patterns and processes in riverscapes to the testing and practice of such theories (Carbonneau et al. 2012). GIS and RS now provide the possibility of assessing river systems at broader spatial scales and hence incorporate condition assessment into conservation planning (Linke et al. 2012). These advances, however, are highly dependent on data availability.

Unfortunately there is a paucity of appropriate methodologies for sampling and capturing information at the relevant spatial and temporal scales for the processes that drive stream and river ecology (Fausch et al. 2002, Van Looy et al. 2013). Better knowledge about the occurrence and distribution of fish taxa is crucial for effective conservation and further ecological research (Hablützel et al. 2013). One of the keys to success in the application of landscape ecology principles and approaches is the availability of data at different scales. Currently one of the major hurdles to achieving freshwater conservation efforts is publicly available and suitable data to understand species dispersal processes, metapopulation structures and population demographics and how these may be affected by anthropogenic activities in floodplain systems (Thieme et al. 2007, Carbonneau et al. 2012).

Merging species modeling with systematic conservation planning in river landscapes has provided a successful end user model conservation planning package (Linke et al. 2012). However to achieve this level of information data at multiple scales is essential for floodplain river systems in the Bolivian Amazon. There is a desperate need to accurately map river systems, taxonomic data has to be organized and shared amongst scientific communities as well as the public in order to move forward a research agenda that can inform conservation planning that can grow public awareness in the use of natural resources (Perotto-Baldivieso et al. 2012). This information combined with biotic and behavioural knowledge of fish species can provide an enhanced chance of successfully developing evidence-based and effective conservation planning for the floodplain river systems in Bolivia as well as other regions in the world. The Geospatial Center for Biodiversity (http://www.museonoelkempff.org/cgb/ is an important resource as it provides an integrated platform to disseminate both spatial and taxonomic data to provide researchers with information and develop further collaboration (Perotto-Baldivieso et al. 2012).

It is also crucial to incorporate the human dimension to successfully achieve an effective conservation strategy of fish biodiversity. Fish constitute an important part in the diet of indigenous groups, especially during the rainy season, when large areas are flooded and human populations are isolated (Pouilly et al. 2004b). Rivers are also important corridors for the exchange and sale of agricultural and non-timber products and a key source for financial income (Salonen et al. 2011). Fish diversity loss will undoubtedly have an adverse effect on the survival of local communities; therefore any conservation approach must rely on local knowledge and the participation of local communities to be effective (Reinert & Winter 2002).

 

Conclusions

Tropical floodplain systems are fundamental for physical and ecological processes that shape many important ecosystem services at multiple scales. Understanding the impact of human activities on aquatic ecosystems (including their adjacent and linked terrestrial systems) is crucial given the significance and value of the Amazon basin and its biological diversity. Freshwater fish are a core component required for ecosystem functioning of tropical floodplain rivers and wetlands. Therefore ensuring their protection is indispensable to maintain and improve local and regional aquatic biodiversity. The current challenges that tropical floodplain ecosystems face are habitat loss and degradation due to multiple human activities and a lack of publicly available information. Landscape ecology principles and approaches can provide a fundamental step change to integrate information, help in addressing many of the questions posed in this article, and ultimately aid the conservation of fish diversity and livelihoods in the Amazon floodplains of Bolivia. Many opportunities for protecting freshwater species and their habitat exist, particularly in the western portion of the Bolivian Amazon basin, where entire river systems are still intact. The use of new technologies to map habitats, track species and monitor ecosystems are available and provide the opportunity to improve the chances of conserving such unique and valuable ecosystems. Coupled with obtaining new data there is also an urgent need for accessing suitable existing datasets and applying appropriate analytical methods, such as the landscape ecology approach, that specifically deals with scales relevant to the fish and the human communities, to advance the research agenda for freshwater fish and their ecosystems in the region.

 

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Reseña recibida en: 3 de febrero de 2016.

Manejado por: Melina Campero.

Aceptado en: 12 de marzo de 2016.

 

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