Modeling food web and fisheries dynamics in Lake Baringo, Kenya

IF 2 3区农林科学 Q2 FISHERIES Fisheries Management and Ecology Pub Date : 2024-07-14 DOI:10.1111/fme.12725

Jacques Riziki Walumona, Boaz Kaunda-Arara, Cyprian Ogombe Odoli, Pascal Masilya Mulungula, Raburu Philip, Benjamin Nelson Kondowe, Nyakeya Kobingi, Mugo James Murakaru, Mbalassa Mulongaibalu, Fabrice Amisi Muvundja

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Abstract

Lakes are important in supporting ecosystem services and livelihoods. However, their food webs and ecological functioning are continuously threatened by anthropogenic influences. Food web models have been widely used in studying trophodynamics, fisheries impacts, and ecological functioning of temperate lakes, but less often in Afrotropical lake systems. We used Ecopath mass-balanced trophic models annually in 1999, 2010, and 2020 to assess trends in ecosystem function, and the impact of fisheries on the Lake Baringo Ecosystem, a shallow freshwater lake in Kenya. Pre-balance (PREBAL) and Pedigree analyses supplemented Ecopath models. Model input data were from field sampling, published and gray literature. Food web trophic models indicated a bottom-up grazer and detrital food chains in all 3 years. Odum's ecosystem development indicators (total productivity to total biomass and total respiration ratios; TPP/TB and TPP/TR) showed that the lake was in a low to intermediate developmental stage, with room for bio-manipulation, and a highly reduced mean transfer efficiency (TE) (6.4%–0.49%) indicated low trophic transfer of internal production. System omnivory (SOI) and connectance (CI) indices that varied among years indicated temporal variation in food web complexity. Indices of system resilience (overhead and ascendency) indicated an increasing potential for the lake to recover from perturbations. The mean trophic level of the catch (MTLc) increased from 1999 to 2010 and decreased in 2020, by fishing down the food chain as fishing pressure increased. Oreochromis niloticus, an endemic cichlid, was the keystone species (KSi >0) controlling community structure, while the lungfish Protopterus aethiopicus, the top predator in the lake, was not a keystone species (KSi <0). We recommend an integrated approach to lake management that incorporates watershed regulations, regulates fishing effort on the keystone species (O. niloticus), and monitors water quality for sustainable management of the Lake Baringo ecosystem.

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肯尼亚巴林戈湖食物网和渔业动态建模

湖泊在支持生态系统服务和生计方面非常重要。然而，它们的食物网和生态功能不断受到人为影响的威胁。食物网模型已被广泛用于研究温带湖泊的营养动力学、渔业影响和生态功能，但较少用于非洲热带湖泊系统。我们在 1999 年、2010 年和 2020 年每年都使用 Ecopath 质量平衡营养模型来评估生态系统功能的变化趋势以及渔业对肯尼亚浅水淡水湖巴林戈湖生态系统的影响。预平衡（PREBAL）和世系分析对 Ecopath 模型进行了补充。模型输入数据来自实地采样、出版文献和灰色文献。食物网营养模型显示，3 年中都存在自下而上的食草动物和碎屑食物链。奥杜姆生态系统发展指标（总生产力与总生物量和总呼吸量之比；TPP/TB 和 TPP/TR）显示，该湖处于中低发展阶段，有生物操纵的余地，平均转移效率（TE）（6.4%-0.49%）高度降低，表明内部生产的营养转移较低。不同年份的系统杂食性（SOI）和连通性（CI）指数不同，表明食物网的复杂性随时间而变化。系统恢复力指数（开销指数和上升指数）表明，湖泊从扰动中恢复的潜力在增加。渔获量的平均营养级（MTLc）从 1999 年到 2010 年有所增加，到 2020 年则有所减少，原因是随着捕捞压力的增加，渔获量向食物链下游移动。湖中特有的慈鲷 Oreochromis niloticus 是控制群落结构的关键物种（KSi >0），而湖中的顶级捕食者肺鱼 Protopterus aethiopicus 则不是关键物种（KSi <0）。我们建议采用综合方法进行湖泊管理，其中包括流域管理条例、对基石物种（黑线鳕）的捕捞强度进行监管以及监测水质，以实现巴林戈湖生态系统的可持续管理。

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来源期刊

Fisheries Management and Ecology 农林科学-渔业

CiteScore

3.80

自引率

5.00%

发文量

审稿时长

12-24 weeks

期刊介绍： Fisheries Management and Ecology is a journal with an international perspective. It presents papers that cover all aspects of the management, ecology and conservation of inland, estuarine and coastal fisheries. The Journal aims to: foster an understanding of the maintenance, development and management of the conditions under which fish populations and communities thrive, and how they and their habitat can be conserved and enhanced; promote a thorough understanding of the dual nature of fisheries as valuable resources exploited for food, recreational and commercial purposes and as pivotal indicators of aquatic habitat quality and conservation status; help fisheries managers focus upon policy, management, operational, conservation and ecological issues; assist fisheries ecologists become more aware of the needs of managers for information, techniques, tools and concepts; integrate ecological studies with all aspects of management; ensure that the conservation of fisheries and their environments is a recurring theme in fisheries and aquatic management.