Management of the Nile tilapia (<i>Oreochromis niloticus</i> (L.)) fishery in the Kenyan portion of Lake Victoria, in light of changes in its life history and ecology

Njiru, M.; Getabu, Albert; Jembe, T.; Ngugi, Charles C.; Owili, Monica; Knaap, Martin Van der

doi:10.1111/j.1440-1770.2008.00363.x

Cited by 23 publications

(20 citation statements)

References 17 publications

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“…This observed change to unicuspid FR teeth and, eventually, an (almost) entirely unicuspid oral dentition is known to occur in large individuals of several other Oreochromis species, mainly in sexually mature males (Trewavas 1983). Most cichlids display dietary shifts as they grow (Njiru et al 2008), and these are often accompanied by changes in different aspects of their trophic morphology (Streelman et al 2007). This study is, to our knowledge, the first to document this ontogenetic change in cichlid oral dentition with geometric morphometrics, and it reveals that the changes occur gradually, at least in O. hunteri.…”

Section: Discussionmentioning

confidence: 97%

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Recurrent changes in cichlid dentition linked to climate‐driven lake‐level fluctuations

et al. 2019

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Climate‐induced habitat change has often been invoked as an important driver of speciation and evolutionary radiation in cichlid fishes, yet studies linking morphological change directly to long‐term environmental fluctuations are scarce. Here, we track changes through time in the oral dentition of Oreochromis hunteri, the endemic and only indigenous fish species inhabiting the East African crater Lake Chala (Kenya/Tanzania), in relation to climate‐driven lake‐level fluctuations during the last 25,000 yr. Fossil teeth were recovered from six periods representing alternating high and low lake‐level stands associated with late‐Pleistocene and Holocene trends in rainfall and drought. To construct a reference framework for morphological variation in fossil assemblages, we first analyzed the variability in oral tooth morphology within the modern‐day fish population. These analyses established that, like other cichlids, O. hunteri gradually replace their bicuspid/tricuspid oral dentition with more unicuspid teeth as they grow. In the fossil assemblages, we found systematic and recurrent changes in the relative abundance of these oral tooth types, with a higher proportion of unicuspids during low‐stands. Moreover, O. hunteri living during low‐stands systematically developed unicuspid dentition at a smaller body size, compared with conspecifics living during high‐stands. Considering that low‐stand conditions created a sizable area of oxygenated soft‐bottom habitat that is lacking during high‐stands, we propose that the associated change in oral dentition reflects the fishes’ exploitation of this new habitat either for feeding or for reproduction. The recurrent nature of the observed shifts provides evidence for the ability of O. hunteri to systematically adapt to local habitat change, and strongly suggests that morphological change in oral dentition promoted its long‐term population persistence in an aquatic ecosystem presenting the dual challenge of being both sensitive to climate change (creating constantly shifting selective pressures) and isolated from surrounding populations (limiting gene flow). In Lake Chala, ancient climate‐driven lake‐level fluctuations did not directly promote speciation in O. hunteri, but the population bottlenecks they may have caused potentially contributed to its divergence from sister species Oreochromis jipe.

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Section: Discussionmentioning

confidence: 97%

“…Most cichlids display dietary shifts as they grow (Njiru et al. ), and these are often accompanied by changes in different aspects of their trophic morphology (Streelman et al. ).…”

Section: Discussionmentioning

confidence: 99%

Recurrent changes in cichlid dentition linked to climate‐driven lake‐level fluctuations

et al. 2019

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“…This might be the case for the L. Kyoga population. For example, although O. niloticus boosted the capture fisheries in the Lake Victoria basin (Lakes Victoria and Kyoga) following introductions, the species was subsequently overexploited between the 1970s and 80s [53,54]. This was reflected in the dramatic decline of the stock sizes and increased fecundity, which are clear indicators of overfishing [54].…”

Section: Anthropogenic Activities-consequences Of Overfishingmentioning

confidence: 99%

“…For example, although O. niloticus boosted the capture fisheries in the Lake Victoria basin (Lakes Victoria and Kyoga) following introductions, the species was subsequently overexploited between the 1970s and 80s [53,54]. This was reflected in the dramatic decline of the stock sizes and increased fecundity, which are clear indicators of overfishing [54]. The low diversity in River Nile could be linked to low gene-flow connectivity with other water bodies due to hydroelectric power dams that have been constructed along the river (the upper Nile of the Ugandan side), which increases the effect of genetic drift.…”

Section: Anthropogenic Activities-consequences Of Overfishingmentioning

confidence: 99%

Molecular genetic diversity and differentiation of Nile tilapia (Oreochromis niloticus, L. 1758) in East African natural and stocked populations

et al. 2020

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Background: The need for enhancing the productivity of fisheries in Africa triggered the introduction of non-native fish, causing dramatic changes to local species. In East Africa, the extensive translocation of Nile tilapia (Oreochromis niloticus) is one of the major factors in this respect. Using 40 microsatellite loci with SSR-GBS techniques, we amplified a total of 664 individuals to investigate the genetic structure of O. niloticus from East Africa in comparison to Ethiopian and Burkina Faso populations.Results: All three African regions were characterized by independent gene-pools, however, the Ethiopian population from Lake Tana was genetically more divergent (F st = 2.1) than expected suggesting that it might be a different sub-species. In East Africa, the genetic structure was congruent with both geographical location and anthropogenic activities (Isolation By Distance for East Africa, R 2 = 0.67 and Uganda, R 2 = 0.24). O. niloticus from Lake Turkana (Kenya) was isolated, while in Uganda, despite populations being rather similar to each other, two main natural catchments were able to be defined. We show that these two groups contributed to the gene-pool of different non-native populations. Moreover, admixture and possible hybridization with other tilapiine species may have contributed to the genetic divergence found in some populations such as Lake Victoria. We detected other factors that might be affecting Nile tilapia genetic variation. For example, most of the populations have gone through a reduction in genetic diversity, which can be a consequence of bottleneck (G-W, < 0.5) caused by overfishing, genetic erosion due to fragmentation or founder effect resulting from stocking activities. Conclusions: The anthropogenic activities particularly in the East African O. niloticus translocations, promoted artificial admixture among Nile Tilapia populations. Translocations may also have triggered hybridization with the native congenerics, which needs to be further studied. These events may contribute to outbreeding depression and hence compromising the sustainability of the species in the region.

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“…; Njiru et al . , ). The result is a knowledge gap on how Nile tilapia, a commercially important species in both capture fisheries and aquaculture, responds to the conditions created by climate variability and change.…”

Section: Introductionmentioning

confidence: 99%

The responses of Nile tilapia Oreochromis niloticus (Linnaeus, 1758) in Lake Wamala (Uganda) to changing climatic conditions

et al. 2015

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Changes in the catches of Nile tilapia, Oreochromis niloticus (Linnaeus, 1758), in Lake Wamala (Uganda) have been observed since its introduction. The factors contributing to these changes, however, are not well understood. This study examined changes in species composition, size structure, size at first maturity, length-weight relationship and condition factor of Nile tilapia in Lake Wamala, in relation to changes in temperature, rainfall and lake depth, to provide a better understanding of the possible role of changing climatic conditions. There was an increase in the minimum, maximum and average temperatures since 1980, but only the minimum (0.021°C year À1) and average temperatures (0.018°C year À1 ) exhibited a significant trend (P < 0.05). Rainfall increased by 8.25 mm year À1 since 1950 and accounted for 79.5% of the water input into the lake during the period 2011-2013, while evaporation accounted for 86.2% of the water loss from the lake. The lake depth was above 4 m during the years when the rainfall exceeded the average of 1180 mm, except after 2000. The contribution of Nile tilapia to total fish catch and catch per unit effort (CPUE) increased with rainfall and lake depth up to the year 2000, after which they decreased, despite an increased rainfall level. The lake depth was positively correlated with the average total length and length at 50% maturity (r = 0.991 and 0.726, respectively), while the slopes of the length-weight relationships differed significantly between high and low lake depths [t (6) = 3.225, P < 0.05]. Nile tilapia shifted from an algal-dominated diet during the wet season to include more insects during the dry season. The results of this study indicate Nile tilapia in Lake Wamala displays a typical r-selected reproductive strategy, by growing to a small size, maturing faster and feeding on different food types, in order to survive high mortality rates under unfavourable conditions attributable to higher temperatures, low rainfall and low lake water levels.

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Management of the Nile tilapia (Oreochromis niloticus (L.)) fishery in the Kenyan portion of Lake Victoria, in light of changes in its life history and ecology

Cited by 23 publications

References 17 publications

Recurrent changes in cichlid dentition linked to climate‐driven lake‐level fluctuations

Recurrent changes in cichlid dentition linked to climate‐driven lake‐level fluctuations

Molecular genetic diversity and differentiation of Nile tilapia (Oreochromis niloticus, L. 1758) in East African natural and stocked populations

The responses of Nile tilapia Oreochromis niloticus (Linnaeus, 1758) in Lake Wamala (Uganda) to changing climatic conditions

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