Colin A ChapmanRelated papers
The bounty of minor lakes: the role of small satellite water bodies in evolution and conservation of fishes in the Lake Victoria Region, East Africa
Hydrobiologia, 2001
The Lake Victoria Region (LVR) encompasses the large lakes Victoria, Kyoga, Edward, George and Kivu, as well as scores of small satellite lakes within the parent catchments. Taken as a whole, the LVR originally harbored a unique fish fauna that included in excess of 600 endemic species of cichlid fishes. As a result of human influence, including a commercial fishery and the introduction of several exotic species, nearly 200 cichlid species and several endemic genera have become extinct from lakes Victoria and Kyoga. Recently, we have discovered that some of the apparently extinct taxa survive as extant representatives in the satellite lakes. Here, we summarize the findings of our ecological survey of the fish species of the satellite lakes. We also discuss the results of some preliminary genetic analyses, and highlight major genetic and ecological changes in the fish fauna that have taken place in the regional fishery. Minor lakes now play a crucial role in conserving the endangered species of the entire region, and also as living museums of East African ecological history. Our findings allude to the historical importance of minor satellite lakes as natural refugia for the fishes of the Lake Victoria Region, a region characterized by a history of geological and climatic instability.
Chapter 3. The status and distribution of freshwater fishes
Thieme et al. (2005) listed the ecoregions of Africa, the reasons for their consideration as distinct entities, and described each ecoregion. The southern African region covered in this report contains 22 of the defined ecoregions (see Chapter 1: Figure 1.1 and Table 1.2). In terms of the fish fauna, however, there is considerable overlap between the ecoregions, and Skelton (2001) provided a more general classification in which he recognised the following six major aquatic ecoregions: tropical east coast region, tropical interior region, highveld (temperate) region, montane-escarpment region, Cape Fold Mountains region and Kalahari-Karoo-Namib region (Figure 3.1). Skelton (2001) further divided the fauna broadly into two groups, the tropical “Zambezian” fauna and a temperate southern fauna, which is further subdivided into the Karoo group and the Cape group. The distribution of fishes is a result of the geomorphological history of the region and a brief description of this history helps to explain the current distributions and our adoption of a simplified selection of ecoregions based on actual river systems.
Biodiversity of Estuarine Fish Faunas in West Africa
In West Africa (between Ivory Coast and Sénégal), estuarine environments vary from lagoons to high discharge rivers to inverse hypersaline estuaries. This results in a high diversity of estuarine fish species, with an important turnover and a core of ubiquitous species. The species richness of a given estuary depends on the combination of hydrological factors (marine or freshwater dominance) and biogeography (continental biogeographic regions). The catch rate is higher in lagoons and inverse estuaries than in normal estuaries, which can be explained by the predominance of small juveniles in the latter. Clupeids are the most abundant fishes all over the region, but different systems have different dominant species. Assessing the functioning of West-African estuaries provides useful comparisons to Asian estuarine systems.
The status and distribution of freshwater biodiversity in Eastern Africa
Occasional Paper of …
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How many species of cichlid fishes are there in African lakes?
Molecular Ecology, 2008
Aim Current estimates of species richness within rapidly evolving species flocks are often highly dependent on the species status of allopatric populations that differ in phenotypic traits. These traits may be unreliable indicators of biological species status and systematists may have inconsistently assigned species among lineages or locations on the basis of these traits, thus hampering comparative studies of regional species richness and speciation rates. Our aim was to develop a method of generating standardized estimates of regional species richness suitable for comparative analysis, and to use these estimates to examine the extent and consistency of species assignment of allopatric populations within rapidly evolving cichlid fish flocks present in three east African lakes.
On the Size of African Riverine Fish Faunas
Integrative and Comparative Biology, 1982
SYNOPSIS. An apparent anomaly exists in the size of riverine fish faunas of the Nile and Zaire; the Nile while considerably longer, appears depauperate when compared with the Zaire. This paradox is explained when discharge, not length, is used as a measure of river size. Indeed, the number of freshwater fish species in African rivers is more closely related to discharge than to length or catchment area. Discharge is directly proportional to terrestrial productivity of a river basin, which in turn affects total biomass of fish and number of species. Changes in the size of rivers during the geologic past affected their capacity to sustain diverse fish faunas. Rivers flowing through especially arid lands during the late-Pleistocene were reduced in discharge, and concomitantly, fish faunas. Immigration of fish from refuge rivers during the Holocene partially restored these diminished faunas. We propose that fish are more mobile than they seem, and that the distinctiveness of riverine fish faunas may be maintained by competitive pressure from established residents, rather than by limited dispersal abilities of fish. Theories of the distribution of fish in Africa are considered, and we suggest that discharge as affected by climatic stability is largely responsible for the size of African riverine fish faunas.
The status and distribution of freshwater fish
IUCN, Gland, Switzerland, Cambridge, UK, and Malaga, Spain, 2010
Northern African fishes have a history marked by regional extinction, which has reduced the recorded/former species richness by 19%. However, despite this, the geographical location, and specific climate (relatively high summer temperatures, and low rainfall), the number of endemic species in the northern African fish community remains high.
In the rivers: Multiple adaptive radiations of cyprinid fishes (Labeobarbus) in Ethiopian Highlands
Scientific Reports
Multiple repeated patterns of adaptive radiation were revealed in cyprinid fish inhabiting the compact geographic region of the ethiopian Highlands. We found four independently evolved radiations in the evolutionary hexaploid (2n = 150) Labeobarbus lineage based on matrilineal relationships of >800 individuals. Each radiation displayed similar patterns of mouth phenotype diversification, and included ecomorphs/species of the generalized, lipped, scraping (one or two), and large-mouthed (one to three) types. All radiations were detected in geographically isolated rivers, and originated from different ancestral populations. This is the first documented case in which numerous parallel radiations of fishes occurred-via different ways-in a riverine environment. Some radiations are very recent and monophyletic, while others are older and include ecomorphs that originated in separate mini flocks and later combined into one. The diversification bursts among Ethiopian Labeobarbus were detected in the mid-upper reaches of rivers (1050-1550 m above sea level), which likely offer ecological opportunities that include diverse habitats yet poor fauna (i.e. lower competition and relaxed selection). this promising example of parallel evolution of adaptive radiation warrants further investigation.
The Influence of Celebrity Endorsements on Purchase Intention (A Study on VIVO V7
Celebrity endorsements in advertising is one the most effective tools to promote and inform a new product or service. Several previous research has been proven that celebrity endorsers as a marketing platform brings many positive impact on consumer purchase intention, especially for new brand entering new market.Those researches have proved empirically the effectiveness and the positive impact of celebrity endorsements in advertising, particularly on purchase intention and also revealed that several dimensions that built celebrity endorsement. By using structural equation modeling (SEM) through Smart-PLS, this research investigates the impact ofcelebrity endorsements variables on purchase intention.The data used in this study is the primary data. The data itself collected directly by the researcher to answer the problem or research objectives. To test the independent variable on the dependent variable, a survey was conducted in Indonesia by using a structured questionnaire. The questionnaire was self-administered, meaning respondents were given statement items and filled in responses themselves through the online survey platform, namely Survey Monkey. Total samples are 100 respondents.The findings reveal that celebrity endorsement has a positive and significant impact on purchase intention, and the three dimensions (attractiveness, expertise, and trustworthiness) play an important role on forming celebrity endorsement variable. The correlation values and loading factor of the three constructs; attractiveness, trustworthiness, and expertise, represent the contribution on celebrity endorsement. Moreover, trustworthiness of the celebrity is the biggest contributor on celebrity endorsement variable. This is followed by attractiveness and expertise dimensions.
Verh. Internat. Verein. Limnol.
2008, vol. 30, Part 1, p. 16–34, Stuttgart, January 2008
© by E. Schweizerbart’sche Verlagsbuchhandlung 2008
Plenary lecture
Biodiversity conservation in African inland waters: Lessons
of the Lake Victoria region
Lauren J. Chapman, Colin A. Chapman, Les Kaufman, Frans Witte, and John Balirwa
The biodiversity crisis in inland waters
Fresh waters are among the most seriously threatened ecosystems on the planet, having suffered intense human impacts
over the past century (SALA et al. 2000, COWX & COLLARESPEREIRA 2002, DUDGEON et al. 2005). In their direct comparison
of rates of species loss in freshwater vs. terrestrial ecosystems,
R ICCIARDI & R ASMUSSEN (1999) projected a future extinction
rate of 4% per decade for North American freshwater faunas.
This is 5 times greater than that for terrestrial faunas and
matches estimates for tropical rainforest communities. Although rates of species loss from tropical freshwaters are less
known (DUDGEON et al. 2005), the limited data on North America is a serious alarm call for tropical faunas. These distressing
trends reflect salient characteristics of both freshwater ecosystems and humans. People have settled disproportionately near
waterways for millennia, and their impacts on inland waters
have followed development and population growth throughout
history. Fresh water is a resource that may be extracted, diverted, contained, eutrophied, or contaminated by humans; the
effects are intensified by the landscape position of many inland
waters as “receivers” of effluents (SALA et al. 2000). The result
of these multiple stressors on inland waters has been a massive
reshaping of aquatic communities, with the pace of change
quickening in the tropics.
With respect to vertebrate faunas, there is little doubt that
freshwater fishes represent the most threatened set of vertebrates in the world due to both extensive and intensive human
impacts, but also because of the disproportionate richness of
inland waters (DUDGEON et al. 2005). Over 10 000 fish species
live in freshwater, representing approximately 41% of global
fish diversity (LUNDBERG et al. 2000). Despite this extraordinary richness of species, surface freshwater habitats contain a
relatively small proportion of the earth’s water supply. The
combination of species-rich faunas, high endemism, and the
disproportionate richness of the inland waters as habitat has
led to a global biodiversity crisis for fresh waters. Of the native
eschweizerbartxxx
freshwater species of North America, 21.3% (217 species) are
imperiled (WILLIAMS et al. 1989).
A significant challenge to conservation of freshwater fishes
results from their patchy nature, imposed by catchment divides
and saltwater barriers (LUNDBERG et al. 2000, STIASSNY 2002a,
DUDGEON et al. 2005). This same heterogeneity that has fostered wild allopatric speciation – hundreds of species are
known only from one drainage or lake system – severely limits
possibilities for faunal rescue. Fish like to be in water, and most
cannot easily move from one aquatic system to another without
it; they therefore have to adapt to changes in situ or disappear.
An additional challenge to freshwater conservation is our limited knowledge of fish diversity (STIASSNY 2002a, 2002b). This
problem is particularly serious in tropical waters where less
intensive exploration and accelerating environmental change
in these species-dense systems rob us of potential future discoveries. Some of the most poignant cases are found in equatorial Africa where several fish species have suffered anonymous
extinction, the most notable example being Lake Victoria, the
largest tropical lake in the world.
Key words: African fish, East Africa, eutrophication, invasive
species, physiological ecology
African fresh waters: Threats
Africa is a continent with many unique and remarkable
inland waters. From Victoria Falls to the floodplain of the
Niger delta, from the equatorial swamp forest of the
Congo to wetlands of the Okavango, from the rift lakes
(some of the largest in the world), to the small crater lakes
of western Uganda and Ethiopia – the inland waters of
Africa, particularly tropical Africa are incredibly diverse
(LÉVÊQUE 1997). Matching this richness of systems is a
spectacular diversity of aquatic life and strategies for
0368-0770/08/0016 $ 4.75
© 2008 E. Schweizerbartsche Verlagsbuchhandlung, D-70176 Stuttgart
L. J. Chapman et al., Biodiversity conservation in African inland waters
survival in some of the most extreme environments in the
world, from the dense interior of papyrus swamps where
low-oxygen stress is the norm of daily life, to the alkaline
lakes of the Great Rift Valley and piping hot springs in
Uganda and Kenya. In fact, even when water is not there,
some fishes persist, like the infamous lungfishes Protopterus spp. and the less well-known (except to aquarium
hobbyists) Nothobranchius, a killifish that survives the
dry season as desiccation-resistant cysts, awaiting rehydration at a later time (GENADE et al. 2005).
The extraordinary diversity of terrestrial taxa in African rainforests and savannas is mirrored by the richness
of its fish fauna. Africa has over 2,850 known species (a
conservative estimate) of indigenous freshwater fishes
within 40–50 families (LUNDBERG et al. 2000). However,
Africa’s evolutionary phenomena – its “living fossils” and
species flocks – add a particular distinctiveness to the
fauna. Africa has an unparalleled assemblage of more archaic fish families, mostly endemic (LÉVÊQUE 1997, LUNDBERG et al. 2000). Examples include the bichers (polypterids) and African lungfishes (some of the oldest fishes
on earth), and a stunning array of osteoglossomorphs,
including the African arowana and the extraordinary
mormryids or elephant-nose fishes, the weakly electric
fishes of Africa. The larger species among these phylogenetic treasures are important food fishes and have been
locally depleted by overexploitation in many regions
(GOUDSWAARD et al. 2002a, KAUFMAN 2003). Outstanding
species radiations are the hallmark of the Great Lakes of
East Africa, but radiations also have taken place in some
of the smallest (crater lakes) and shallowest (soda lakes)
water bodies as well (KAUFMAN 2003). More than 15% of
the worlds’ freshwater fish species live in the Great Lakes
of East Africa (THIEME et al. 2005). The Congo River basin is also host to an extremely diverse fish fauna, with the
highest richness of any river on the African continent, and
second only to the Amazon on a global scale (CHAPMAN
2001, CHAPMAN & CHAPMAN 2003).
For hundreds of millions of African people, the health
of their inland waters is inextricably linked to their own
well being. These systems provide drinking water, hydroelectric power, water for irrigation, foods with critically
needed protein, and much more. However, increasing
demands for services of inland waters is placing great
strain on these environments. Africa is facing not only a
continent-wide shortage of potable water, but overall water quality has declined markedly due to multiple perturbations, including progressive deforestation, exponentially increasing human populations, industrialization,
and urbanization. And while Africa makes a relatively
small contribution to global climate change, African
lakes seem very sensitive to such change (LIVINGSTONE
eschweizerbartxxx
17
2003). The current emphasis on sustainable management
of natural resources contained in the Convention for Biological Diversity (CBD 1994) and of fisheries as formulated in the Food and Agricultural Organization of the
United Nations (FAO) Code of Conduct for Responsible
Fisheries, imposes a need to explore, understand, and
predict the influence of human pressures on African inland waters, from the challenges of freshwater supply to
wetland degradation to the introduction of non-indigenous species.
We review the major threats to African inland waters
and discuss key lessons learned from the Lake Victoria
region that highlight both the vulnerability and lability of
fishes in the face of environmental change. We focus on
mechanisms that have fostered persistence of native species, in particular the use of structural and physiological
refugia to sidestep invader impacts. We explore cascading effects of Nile perch on the trophic structure of invaded systems. Finally, we consider the consequences of
faunal collapse and recovery on resurging species.
Supply of fresh water
Among the challenges currently facing Africa, none is
more trenchant than threats to the ability of the continent’s supply of fresh water to sustain human life in the
future. Several basins in Africa, including Lake Chad,
the Nile, the Niger, and the Volta, are projected to support
>10 million people by 2025 and will suffer water stress
(WRI 1994, REVENGA & CASSAR 2002). In the more arid
regions of southern Africa where population pressures
are as high as the land is dry, provision for storage of
more than an annual supply of water must be engineered
to withstand droughts that can persist for years. In principal, West Africa currently has adequate water resources.
However, many of the region’s rivers have been impounded to form reservoirs ranging from small farm dams to
large multi-million-dollar dams such as the Akosombo
on the Volta. The vast shifts in hydrology and ecology
brought about by water containment and diversion can
massively influence natural systems and services (WELCOMME 2003). Water deficits in Africa are exacerbated by
water quality issues including industrial and mine effluents, sewage, runoff of nutrients and pesticides, siltation,
and salinization. Pollution of surface and groundwater is
becoming a serious threat from countries with burgeoning human and livestock populations and the rapid development of a continent-wide industrial base, but also from
deforestation, mining, and agriculture (REVENGA & CASSAR 2002, T HIEME et al. 2005). An estimated 86% of Africa’s total water withdrawals are directed toward agricul-
18
Verh. Internat. Verein. Limnol. 30
ture (FAO 2005a). Given that the population of Africa is
projected to more than double between 2005 and 2050
(UNITED NATIONS POPULATION DIVISION 2006), and given
that most of the next generation is predicted to continue
to live subsistence lifestyles, Africa is expected to undergo tremendous agricultural expansion (THIEME et al.
2005), which will place brutal demands on water supply.
Deforestation
In sub-Saharan Africa, tropical forests are increasingly
threatened by forest conversion and degradation, with
recent estimates suggesting a conversion rate of 0.4–0.5%
per year (LANLY et al. 1991, FAO 1993, MAYAUX et al.
2005). Rain forests once covered an estimated 3 620
000 km2 of the African continent before anthropogenically-induced habitat alterations (MARTIN 1991); now Africa ranks second only to South America in net rate of
forest loss (FAO 2005b). Deforestation has reduced rain
forest in Central Africa to 55% of its original area, but it
has been much more severe in West Africa (72% loss).
An estimated 28% of the rain forests that once covered
East Africa remain (MARTIN 1991), with the majority of
land clearing associated with subsistence farming and
fuelwood harvest.
Deforestation threatens aquatic faunas on several dimensions: indirectly through the effects of forest removal
on water quality and flow regimes, and directly through
loss of allochthonous input generated by the forest. There
is critical need to understand the functional links between large-scale land use and aquatic ecosystem change,
and the implications of protected areas on watershed integrity. A growing number of studies in Africa indicate
significant effects of deforestation on a diverse suite of
aquatic communities, including inshore habitats in Lake
Tanganyika (COHEN et al. 1993); high-altitude rainforest
rivers (KASANGAKI et al. 2006); crater lakes of western
Uganda (EFITRE 2007); and small Malagasy streams
(BENSTEAD et al. 2003). Interest within Africa in the use
of aquatic invertebrates as indicators of water quality and
ecosystem change (DALLAS 1997, THORNE et al. 2000,
NDARUGA et al. 2004, KASANGAKI et al. 2006) is growing
along with the recognition that these indicators are not
easily translated from temperate to tropical systems and
must be developed in situ.
eschweizerbartxxx
Wetland degradation
Africa has some of the largest wetland systems in the
world, including approximately 85 000 km2 of permanent
swamp and 400 000 km2 of seasonally inundated swamps
(THOMPSON & HAMILTON 1983, DENNY 1985). The emergent sedge papyrus (Cyperus papyrus) dominates much
of the permanent swamp on the African continent. Papyrus is the fastest growing sedge in the world, normally
attaining heights of 3–4 m, and typically comprising
>95% of the plant biomass of the swamp (THOMPSON
1976, THOMPSON et al. 1979, ELLERY et al. 1995). The
dense canopy and root mats of papyrus limit both mixing
of the water column and light (THOMPSON et al. 1979,
JONES & MUTHURI 1985). In combination with high rates
of organic decomposition, these conditions result in extremely low oxygen levels in the water beneath the
swamp canopy and create a very unique habitat for aquatic organisms (CARTER 1955, BEADLE & LIND 1960, CHAPMAN & LIEM 1995, CHAPMAN et al. 1998), including a
highly specialized fish fauna adapted for life in deoxygenated waters (ROBERTS 1975, CHAPMAN et al. 2002).
Many African wetlands are not permanent swamps but
seasonal floodplains associated with major rivers, and
they often host rich fish faunas that depend on these
habitats for breeding, nurseries, feeding, and refuge
(CHAPMAN et al. 2001, WELCOMME 2005). Fish populations
in these wetlands tend to reach high density and undergo
predictable seasonal migrations, factors that favour the
development of fisheries (WELCOMME 2005). Wetlands
also attract humans because of their rich soils, their water
supply, and opportunities for grazing of domestic stock,
which is particularly important in the dry season. Africans have lived with and within wetlands throughout history, and many human exploitation activities in wetlands
can be sustainable; however, an expanding and accelerating trend is large-scale drainage and conversion to large
tracts of agricultural land (CHAPMAN et al. 2001). Wetlands are also threatened by irrigation schemes, development of waterways to improve transport, industrial pollution, and mining extracts (CHAPMAN et al. 2001). Estimates of wetland loss range from 40% in Cameroon to
70% in Liberia (WRI 1994), a scale comparable to forest
degradation on the continent.
Over-exploitation of fisheries
In Africa, many fisheries have been exploited to levels
that have produced substantial degradation (WELCOMME
2005), dramatically restricting one of the most important
protein sources for Africa’s expanding human population. Often this degradation involves a “fishing-down”
process, the successive loss of the largest individuals and
species in favor of smaller, faster, and shorter-lived fishes
(REGIER & HENDERSON 1973, WELCOMME 1995). These
L. J. Chapman et al., Biodiversity conservation in African inland waters
shifts have been carefully documented for the Oueme
River fishery in West Africa (Benin; WELCOMME 1999)
and the Central Delta of the Niger in Mali (LAE 1994).
Reductions in size are accompanied by changes to many
of the fundamental parameters of the fish community.
The number of species in the fishery tends to increase;
large species are eliminated from the fishery, and survival of many species occurs through use of connected
refugia (WELCOMME 2003, 2005). Clearly this situation is
undesirable for conservation and probably unsustainable
for fisheries, and reports on many African fisheries suggest they are or have been fished at levels that incur damage to the assemblage (THIEME et al. 2005, WELCOMME
2005). On a positive note, WELCOMME (2005) argues that
African waters, particularly floodplain systems where
ups and downs are part of life, may be quite resilient if the
stress is removed; an excellent example is the reestablishment of normal fish catch in rivers of the Niger Basin after the Sahelian drought (WELCOMME & HALLS 2004).
Non-indigenous species
The transfer or introduction of non-native fish species
has been widespread in Africa and continues (FAO/CIFA
1985). The primary purpose of such transfers has been to
maintain or increase fish yield, although some introductions have been undertaken to expand sport fisheries or
for biological control (OGUTU-OHWAYO & HECKY 1991,
PRINGLE 2005). About 50 fish species have been introduced into or translocated within the inland waters of
Africa, 23 of which are from outside Africa (WELCOMME
1988). In the Congo basin, for example, WELCOMME (1981)
reported 7 international transfers of fishes including:
Astatoreochromis alluaudi (cichlid, for the control of
snail vectors of bilharzia); Clarias gariepinis (catfish, for
experimental fish culture and predation on stunted tilapia); Heterotis niloticus (African arowana (an osteoglossomorph), escaped from aquaculture installations); Lepomis gibbosus (North American sunfish, for forage for
M. salmoides); Micropterus salmoides (North American
bass, control of stunted tilapia); Sarotherodon macrochir
(South African tilapia, aquaculture); and Tilapia rendalli.
Perhaps the most widespread continental travelers have
been the tilapias, introduced into many African waters to
stock natural lakes where tilapias did not occur to fill apparently vacant trophic niches, to compensate for depleting commercial fisheries of native tilapias, to develop
new fisheries in man-made waterbodies, and for biological control of aquatic vegetation (LÉVÊQUE 1997, BALIRWA
et al. 2003). Even though Africa has seen an increase in
non-native fish production through such introductions
eschweizerbartxxx
19
and aquaculture, local communities that had depended on
the native fish did not necessarily benefit, but further
transfers are inevitable given the accelerating interest and
donor support for aquaculture activities in regions of Africa.
Dynamics of the Lake Victoria Region
– biodiversity lost & (partly) found
Major threats to the aquatic systems of Africa, which are
numerous and complex, are also (not surprisingly) interrelated. Rarely do threats occur singly, and most imperilled species are subjected to multiple interacting stressors (REVENGA et al. 2005). For example, high human
population density leads to accelerating deforestation,
conversion to agricultural land, high nutrient input, and
eutrophication of water bodies. The increase in primary
production may increase fish yield, at least for awhile. At
the same time, high population density can spark increased fishing pressure and create a decline in stocks
that can lead to an increase in alternative livelihoods such
as charcoal production. Species introductions are also
often used to compensate for depleting commercial fisheries, but they can have devastating effects on native fish
communities (Fig. 1). These complex interactions are
particularly well exemplified in the Lake Victoria basin
of East Africa, a region that has experienced massive,
fundamental changes in its ecology over the past century.
The dynamic eco-history of the basin highlights both the
vulnerability and lability of native and introduced species
in the face of environmental change and supports a reconciliation of biodiversity maintenance and fisheries
sustainability in the region. To explore the response of the
fish fauna to multiple environmental stressors we (a)
summarize the history of biodiversity loss in the Lake
Victoria Region, and (b) examine characteristics of the
fishes that persisted, those that prospered, and those that
are recovering coincident with heavy fishing on Nile
perch.
Biodiversity loss
Lake Victoria is the largest tropical lake in the world,
with its waters shared by 3 countries: Tanzania, 51%;
Kenya, 6%; Uganda, 43%. The lake harbors Africa’s
largest inland fishery, yielding 500 000 MT since the
1990s (BALIRWA 2007), but it is best known to scientists
for its 500+ endemic species of haplochromine cichlids,
representing one of the most rapid, extensive, and recent
radiations of vertebrates known (GREENWOOD 1974, SEE-
20
Verh. Internat. Verein. Limnol. 30
Fig. 1. Figurative representation of
the interaction of multiple stressors
on fisheries sustainability and biodiversity in inland waters.
HAUSEN 1996, KAUFMAN et al. 1997, SEEHAUSEN et al.
2003b, VERHEYEN et al. 2003). In addition, a diverse assemblage of non-cichlids inhabits the basin (CORBET
1961, GREENWOOD 1966, 1974, van OIJEN 1995).
Throughout the 20th Century, Lake Victoria underwent
massive and fundamental changes in its ecology, and the
fish stock of the lake was subjected to 3 major series of
interacting events: overfishing, species introductions,
and habitat degradation. Fishing intensified over the century with the introduction of new technologies, and by
the 1950s and 1960s, there was alarming evidence that
eschweizerbartxxx
many important food fishes were overexploited (OGUTUOHWAYO 1990, BALIRWA et al. 2003). Changes in the Lake
Victoria fish stocks conform in a general way to the
“fishing-down” model as indicated in the catch per unit
effort of some economically important fishes in Tanzania
between 1958 and 1970 (Fig. 2). By the late 1950s, the
catch of key migratory species in the fishery had fallen
(CADWALLADR 1965), and the fishery focused on tilapia
and bagrid catfish. By the late 1960s, these and other species, including the lungfish, had fallen dramatically. The
fishery was characterized by a drift to the smallest spe-
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L. J. Chapman et al., Biodiversity conservation in African inland waters
cies, the haplochromine cichlids (BALIRWA et al. 2003),
and even here intensive trawl fishing rapidly eliminated
local stocks (WITTE et al. 1992b).
New fish species were introduced to compensate for
depleted commercial fisheries. The large Nile perch
(Lates niloticus) was first introduced into lakes of the
Lake Victoria basin in the mid-1950s to convert low value
haplochromines into higher value and more easily captured fish and to foster a sport-fishing industry (JACKSON
2000, PRINGLE 2005). Nile perch, which reaches >2 m in
length and >200 kg in weight (OGUTU-OHWAYO 2004),
feeds on invertebrates at a small size and then switches to
piscivorous feeding (OGUTU-OHWAYO 1994, SCHOFIELD &
CHAPMAN 1999). Nile perch numbers were low in the lake
until the 1980s when trawl surveys (GOUDSWAARD et al.
2006) and catch landings in the 3 riparian countries
(BALIRWA et al. 2003, MATSUISHI et al. 2006) showed a
dramatic population increase. The upsurge of Nile perch
did not exhibit lake-wide synchrony, but was first observed in the Nyanza Gulf of Kenya in 1979, in Ugandan
waters 2–3 years later, and in the Mwanza Gulf of Tanzania 4–5 years later (GOUDSWAARD et al. 2006). Mechanisms underlying the Nile perch boom are not fully understood; however, GOUDSWAARD et al. (2006) hypothesize
that the decline of haplochromines associated with exploitation decreased predatory and competitive effects on
juvenile Nile perch, facilitating juvenile survival. The
upsurge of Nile perch created a new industry and a huge
export market for Uganda, Kenya, and Tanzania, causing
a rapid expansion of the fish-freezing industry to more
than 30 factories in the 1990s (BALIRWA 2007). In 2003,
fish exports were valued at $243 million US (LVFO 2005,
BALIRWA 2007), but a catastrophic change occurred in this
species-rich system. Although many fish stocks in Lake
Victoria had declined before the upsurge of the Nile
perch, including the haplochromines in some areas, the
increase in the Nile perch coincided with the further decline or disappearance of many native species. For example, the final disappearance of haplochromine cichlids
in Mwanza Gulf was reported after the upsurge of Nile
perch, (GOUDSWAARD et al. 2006), most notably the disappearance of >40% of the endemic haplochromine cichlids
(KAUFMAN 1992, WITTE et al. 1992a, 1992b, KAUFMAN &
OCHUMBA 1993, SEEHAUSEN & BOUTON 1997). Certainly
other changes in the Lake Victoria system, including increasing eutrophication (see below), contributed to the
faunal collapse, but the Nile perch seems to have been an
important player (BALIRWA et al. 2003, GOUDSWAARD et al.
2006). The situation in Lake Victoria has been followed
closely by the international community because of its
economic importance and catastrophic biodiversity loss.
But similar changes have occurred with the introduction
eschweizerbartxxx
21
of Nile perch into other lakes in the basin, including lakes
Kyoga and Nabugabo, providing replication of this ecologically devastating, but economically lucrative situation.
Coincident with severe anthropogenic changes in the
watershed (e.g., increased population density, industrialization, deforestation), Lake Victoria changed from a
mesotrophic system in the 1930s to a eutrophic system
(HECKY 1993, HECKY et al. 1994). Primary productivity
doubled, and algal biomass increased 8–10-fold (MUGIDDE
1993), accompanied by a shift in algal species composition from large chain-forming diatoms to blue-green algae (HECKY 1993). High-resolution palaeolimnological
data show that the increase in phytoplankton production
evident from the 1930s parallels human-population
growth and associated agricultural expansion in the basin
(MUGIDDE 1993, VERSCHUREN et al. 2002). The switch in
phytoplankton communities may have facilitated a decline in the native tilapiine Oreochromis esculentus, an
apparent specialist on the large chain diatom Aulacoseira
(formerly Melosira) spp. both in plankton and detrital
deposits. The switch perhaps also triggered an upsurge in
the introduced Oreochromis niloticus, which can eat almost anything from minute cyanobacteria up through
large animal prey (BATJAKAS et al. 1997). The change in
trophic status of the lake was also accompanied by a decrease in water transparency. Loss of water clarity caused
loss of genetic and ecological differentiation among haplochromine species, and is likely to be partially responsible for loss of species diversity among littoral cichlids
(SEEHAUSEN et al. 1997a).
Another dramatic change to the Lake Victoria system
has been the development of hypolimnetic anoxia induced by euthropication in the lake basin. The deeper
part of the lake became stratified throughout much of the
year (HECKY 1993, HECKY et al. 1994), and the duration
and severity of hypoxia has also increased in shallower
areas (WANINK et al. 2001). The eutrophication-induced
loss of hypolimnetic oxygen seems to have started in the
early 1960s after at least 140 years of adequate yearround dissolved oxygen in the bottom waters (VERSCHUREN et al. 2002). TALLING (1966) reported anoxia only in
the deepest parts of the lake in 1960–1961, while HECKY
(1993) reported widespread, long-lasting (Oct-Mar) anoxia in deeper waters in 1990–1991. Fish kills associated
with upwellings of anoxic water, in addition to the possible effects of phytotoxins, provide evidence of high risk
for some species (OCHUMBA 1990, KAUFMAN & OCHUMBA
1993).
Ecological changes in the lake, including declining
oxygen availability, also reflect invasion of the nonindigenous water hyacinth, Eichhornia crassipes. Water hya-
22
Verh. Internat. Verein. Limnol. 30
cinth (native to South America) appeared in Lake Kyoga
in Uganda in 1988 and in Lake Victoria in 1989 (TWONGO
et al. 1995) and spread rapidly. In the Ugandan waters,
stationary fringes were estimated to cover 2 200 ha along
80% of the shoreline by 1995 (NARO 2002). The invasion had significant socio-economic and environmental
impacts, including disruption of transport, fishing activities, reduction of water supply, negative impacts on water
quality for humans and livestock, and spread of waterborne diseases (TWONGO 1996, NARO 2002, NJIRU et al.
2002). Surprisingly, water hyacinth rapidly disappeared
almost completely over most of its previous range in the
late 1990s. A number of interactive factors apparently account for its remission, including mechanical and manual
removal and the introduction of weevils Neochetina eichhorniae and N. bruchi for biological control. However,
recently WILLIAMS et al. (2007) argued that while weevils
almost certainly played a part, the synchronous lakewide reduction of water hyacinth during the second quarter of 1998 was the result of the 1997/1998 El Niño that
caused stable shoreline water hyacinth stands to become
dislodged and then destroyed by wave action. Despite the
rapid remission of the invasive plant, scientists remain
concerned. A recent outbreak of water hyacinth observed
in Mwanza Gulf (Mary Kishe-Machumu, pers. comm.
Feb 2007) confirms the expectation of periodic outbreaks
of water hyacinth that will demand continuous vigilance
and control efforts (NARO 2002).
These various events influenced the structure of the
fish stock in Lake Victoria and resulted in the fishery being converted from a multi-species system exploiting
native fishes to one in which 3 species comprise almost
the whole of the catch, 2 of which are introduced. Entire
functional groups disappeared in the 1980s, as did the
wealth of ecological services that they provided. The
Lake Kyoga system that lies downstream of Lake Victoria and forms from a dendritic expansion of the Nile has
been extremely useful in understanding effects of Nile
perch on functional and specific fish diversity. The Kyoga
satellite system is comprised of species-rich lakes where
Nile perch are absent or rare and low diversity lakes
where Nile perch are abundant (MBABAZI et al. 2004,
SCHWARTZ et al. 2006). Food web studies in 6 of these
lakes revealed shorter food chains in perch lakes, suggesting a reduction in the number of pathways from primary production to apex consumers in the presence of the
predator and modified food web (SCHWARTZ et al. 2006).
It has been recently argued that eutrophication poses
the most serious threat to the Lake Victoria fish fauna;
however, the relative importance of different environmental stressors is still not fully understood. The lake
was initially heavily influenced by overfishing, and this
eschweizerbartxxx
soon led to fish introductions that further complicated the
web of species interactions and system dynamics. Anthropogenic changes in the watershed (increased population density, industrialization, change in fish composition, deforestation) and the introduction of water hyacinth
contributed to the formation of an enduring anoxic hypolimnion and changes in water quality. Greatly increased
primary productivity, one outcome of the interplay of
stressors, can initially foster a rise in fish productivity.
However, coincident decreases in water transparency
threaten any such gains while also threatening a diverse,
haplochromine-rich food base that can enhance Nile
perch production (Fig. 1). Note that the faunal composition of lakes Nabugabo and Kyoga changed dramatically
even though they experienced less intense watershed
transformation than Lake Victoria.
The residual fauna and physiological exclusion
Despite a radically altered food web structure, some indigenous species have both persisted with Nile perch and
been resilient to increasing eutrophication and other human-induced stressors. Understanding conditions that
allow some species to endure these multiple stressors
while others succumb is critical to conservation of freshwater faunas and the management of human impacts.
Over the years, interest in conservation of the residual
fauna has sparked several studies directed toward identification of faunal refugia; habitats where native fishes are
protected from Nile perch predation and that could form
the basis of biodiversity restoration. Currently, we recognize 4 major types of biodiversity banks: satellite lakes,
rivers, rocky habitats, and wetlands.
A small portion of the fauna considered extirpated
from lakes Kyoga, Victoria, and Nabugabo can still be
found in satellite water bodies around the main lakes
(OGUTU-OHWAYO 1993, KAUFMAN et al. 1997, MWANJA
2004). For example, the Lake Kyoga complex (the main
lake and satellite lakes) harbours a rich assemblage of an
estimated 40 haplochromine cichlids, with the satellite
lakes contributing 37 species comprising 11 trophic
groups and the main lake harbouring 15 species comprising only 2 trophic groups (M BABAZI et al. 2004). In many
cases, dense hypoxic swamps separate these satellite
lakes from the main Lake Kyoga and seem to act as a biological filter preventing Nile perch colonization, which
are unable to survive in hypoxic waters (SCHOFIELD &
CHAPMAN 2000), and probably also nutrient influx (BALIRWA et al. 2003, SCHWARTZ et al. 2006).
Rivers are also an important refugium for indigenous
species in the Lake Victoria region. The Victoria Nile
L. J. Chapman et al., Biodiversity conservation in African inland waters
harbors an interesting and partially endemic haplochromine assemblage. Upstream, before and after the Owens
Falls Dam are species typical of Lake Victoria. Where the
Victoria Nile joins Lake Kyoga are taxa such as Pyxichromis orthostoma and undescribed taxa characteristic
of the Kyoga satellite lake refugia (L. Kaufman, pers.
observ.). The Victoria Nile is also home to remnants of
the Nile’s once formidable population of migratory fishes, including Barbus altianalis and Labeo victorianus, as
well as several regionally endemic mormyrids.
Rocky shores and offshore rocky islands are major refugia within Lake Victoria, harboring a large number of
rock-dwelling specialists (SEEHAUSEN 1996, SEEHAUSEN &
BOUTON 1997, SEEHAUSEN et al. 1999, WITTE et al. 2007).
They also serve as refugia for a number of species that
were not specialized rock-dwellers in the pre-Nile perch
era, but either shifted to these habitats or had a broader
pre-Nile perch distribution that included these habitats
(WITTE et al. 1992a, SEEHAUSEN 1996, 1997). In their longterm survey of haplochromine communities in the littoral, sub-littoral and rocky shores of Mwanza Gulf, Tanzania, WITTE et al. (2007) found that haplochromines from
rocky shores were the least affected of these habitat-associated assemblages.
Wetlands in the Lake Victoria basin serve as both
structural and low-oxygen refugia for fishes that can tolerate wetland conditions and function as barriers to dispersal of Nile perch (CHAPMAN et al. 1996a, 1996b,
BALIRWA 1998, SCHOFIELD & CHAPMAN 1999, CHAPMAN et
al. 2002, MNAYA et al. 2006). Unlike Nile perch, some
haplochromine cichlids and some native noncichlids are
relatively tolerant of hypoxia (CHAPMAN et al. 1995,
ROSENBERGER & CHAPMAN 2000, SCHOFIELD & CHAPMAN
2000, CHAPMAN et al. 2002, RUTJES 2006), thus permitting
some fishes to persist in wetlands under reduced predator
pressure from both Nile perch and other large piscivores
(CHAPMAN et al. 2002). The ecotone of the wetland/open
water is a particularly important refugium because interaction with the main lake waters elevates dissolved oxygen. Nile perch are rare in these ecotonal wetlands, and
species richness is higher than in the interior swamp
(CHAPMAN et al. 1996a, 1996b, BALIRWA 1998, SCHOFIELD
& CHAPMAN 1999, CHAPMAN et al. 2002). However, even
areas deep within the fringing swamp are important in
the maintenance of a subset of the basin fauna (CHAPMAN
et al. 1996b, CHAPMAN et al. 2002).
The physiological exclusion of Nile perch from the
dense interior of hypoxic wetlands has been critical in
minimizing predator-prey overlap and in limiting Nile
perch invasion of the Kyoga satellites. This highlights the
importance of environmental stressors in modulating
predator-prey interactions. A growing body of empirical
23
support (beyond the Victoria basin) demonstrates sizesensitive tolerance to hypoxia in fishes: in particular, field
studies supporting physiological exclusion of large piscine
predators from hypoxic habitats. ROBB & ABRAHAMS
(2003) evaluated hypoxic tolerance of small yellow perch
(Perca flavescens) and fathead minnows (Pimephales
promelas), both potential prey of large yellow perch. They
found that both within and between the 2 species, smaller
individuals were the most tolerant of hypoxic environments, and suggest that low-oxygen habitats have the potential to act as a refuge for these smaller fish. MCNEIL &
CLOSS (2007) found a generally high level of tolerance to
periodic hypoxia in the fishes of the Ovens River floodplain in south-east Australia with the exception of 3 species, one of which was the predacious introduced redfin
perch (Perca fluviatilis), again supporting the role of hypoxic habitats as refuge for tolerant prey. Small Amazonian oscars seek out hypoxic habitats as refuge; evidence
suggests that they are not more tolerant than larger conspecifics, but rather accept a greater physiological compromise to access hypoxic shelter (SLOMAN et al. 2006).
All these examples point toward the important of hypoxic
stress as a predator-prey modulator.
Two success stories: fishes that flourished with
Nile perch
eschweizerbartxxx
Many fish species vanished coincident with the upsurge
of Nile perch; others persisted through use of structural,
physiological, and behavioural refugia; and others have
prospered. In addition to the Nile perch, 4 nonindigenous
tilapiines (Tilapia zillii, O. niloticus, O. leucostictus, and
Tilapia rendalli) were also introduced at various points
around Lake Victoria from 1953 onward in response to
reduced catch per unit effort (CPUE) of the 2 regionally
endemic tilapiines (Oreochromis esculentus and Oreochromis variabilis) that had been the main target of the
local fisheries. By 1960, these 4 exotic tilapiines had also
been introduced in lakes Kyoga, Nabugabo, and later into
other lakes within the region (BEAUCHAMP 1958, WELCOMME 1967, WELCOMME 1988). However, of all the native
and introduced tilapiines in the Lake Victoria region,
only O. niloticus, the Nile tilapia, has become abundant
and commercially important in the presence of Nile perch
(GOUDSWAARD et al. 2002b).
This successful establishment of O. niloticus has been
attributed to several factors, including their dietary plasticity, their flexibility in life history traits, and their ability to withstand a broad range of environmental variation
(LOWE-MCCONNELL 1958, BALIRWA 1998, LÉVÊQUE 2002,
GOUDSWAARD et al. 2002b). Oreochromis niloticus juve-
24
Verh. Internat. Verein. Limnol. 30
niles are very tolerant of hypoxic stress and penetrate
deep swamp refugia with the lake basin (CHAPMAN et al.
1996a, 1996b, CHAPMAN et al. 2002). In Lake Nabugabo,
juvenile Nile tilapia are the most abundant tilapiine in
hypoxic wetlands, where Nile perch tend to be rare
(BWANIKA et al. 2006, Chapman and colleagues, unpubl.
data). When they reach about 8 cm they tend to move into
more open water, where they exceed the gape size of at
least smaller Nile perch. In the Mwanza Gulf of Lake
Victoria, GOUDSWAARD et al. (2002b) reported the largest
(>20 cm) Nile tilapia from the most offshore sites, whereas the smallest size classes were caught between the
fringing vegetation where the density of piscivorous Nile
perch was much lower. Nile tilapia also shows a high degree of dietary flexibility both within and among lakes.
Studies on the diet of O. niloticus in both its indigenous
and new habitats in East Africa date back to the early
1950s. Earlier studies described the diet of O. niloticus as
predominantly herbivorous, comprised mainly of algae,
epiphytic diatoms, and bottom debris (FISH 1955, LOWEMCCONNELL 1958, MORIARITY & MORIARITY 1973). Studies undertaken shortly after the establishment of O. niloticus in the Victoria region still recorded a predominantly herbivorous diet (WELCOMME 1967). Indeed, O. niloticus is remarkable in its ability to efficiently collect
and assimilate even the smallest (and sometimes toxic)
cyanobacterial cells using a specialized feeding mechanism that Lake Victoria’s native tilapiines lack (SANDERSON et al. 1996, BATJAKAS et al. 1997). Recent studies,
however, indicate a shift in the dietary composition of O.
niloticus to include a broad spectrum of items with high
proportions of macroinvertebrates and detritus (GOPHEN
et al. 1993, BALIRWA 1998). The haplochromines of Lake
Victoria consisted of a wide range of trophic groups including detritivore/phytoplanktivores, zooplanktivores,
durophages, snail winklers, epiphytic and epilithic algal
grazers, macrophyte browsers, cleaners, piscivores including paedophages, and both generalized and morphologically specialized insectivores (GOLDSCHMIDT et al.
1993, WITTE et al. 2007). Their disappearance from various water bodies where Nile perch have been introduced
may have produced feeding opportunities for other taxa.
BWANIKA et al. (2006) explored the hypothesis that Nile
tilapia exhibit increased omnivory coincident with the
Nile perch invasion and the radical reorganization of the
food web. They recorded an omnivorous diet dominated
by detritus and invertebrates for O. niloticus in lakes
Nabugabo and Victoria (2 lakes with Nile perch), while a
predominantly herbivorous diet was characteristic of O.
niloticus in 4 lakes without Nile perch (BWANIKA et al.
2006). They also demonstrated that Nile tilapia from a
lake without Nile perch (Wamala) grew slower and exeschweizerbartxxx
hibited a lower energy density than Nile tilapia from
Lake Nabugabo (BWANIKA 2005, BWANIKA et al. in press).
In Lake Victoria, comparisons of recent growth rates for
Nile tilapia (MUHOOZI 2003) indicate that growth is higher
than that reported in earlier studies (GETABU 1992,
MOREAU et al. 1995). Possibly the higher growth rate of
Nile tilapia was driven by the predatory effects of Nile
perch on haplochromine cichlids through release of a new
and highly preferable prey base to the tilapia (BWANIKA et
al. 2006). Another possibility could be, at least to some
degree, intensive fishing of tilapia (MUHOOZI 2003) or
indirect effects that do not require the invocation of direct
trophic competition between haplochromines and tilapiines.
A second striking example of a fish that has flourished
in the presence of perch is the small pelagic minnow Rastrineobola argentea. By the late 1980s, R. argentea was
the only indigenous zooplanktivore still abundant and
had shown a surprising 6-fold increase in biomass
(WANINK 1999) coupled with an explosion in landings
(BALIRWA et al. 2003). This native cyprinid has flourished
in the open waters of lakes Victoria, Kyoga, and Nabugabo, despite the fact that it is comprised a major part of the
prey of the introduced Nile perch (OGUTU-OHWAYO 1994,
SCHOFIELD & CHAPMAN 1999). The dramatic increase in R.
argentea has been attributed to the relaxation of competitive pressure by haplochromines subsequent to the Nile
perch boom, and a shift from juvenile to adult mortality
has probably increased the number of fish recruiting
(WANINK & WITTE 2000a).
A biased recovery
By the 1990s the fisheries of lakes Victoria, Kyoga, and
Nabugabo were dominated by the Nile perch, the co-invading Nile tilapia, and native cyprinid R. argentea. But
remnant populations of species remained within refugia,
and these have provided seeds of resurgence over the past
decade. In some lakes of the Victoria basin (Nabugabo,
Kyoga, Basina) and some sections of Lake Victoria, intense fishing pressure has coincided with a resurgence of
some fishes, most notably, an increase in the biomass of
haplochromine cichlids (WITTE et al. 2000, CHAPMAN et
al. 2003, MATSUISHI et al. 2006, SCHWARTZ et al. 2006,
WITTE et al. 2007).
Levels of fishing effort in Lake Victoria grew exponentially between the early 1980s and 2000, from around
12 000 boats in 1983, to 22 700 in 1990, and more than 42
500 in 2000; the number of gillnets has grown more than
8-fold over the same time, with 20% of the nets below the
legal mesh size of 5 inches (UNECIA 2001, MUHOOZI
L. J. Chapman et al., Biodiversity conservation in African inland waters
2003, MATSUISHI et al. 2006). Recent frame surveys carried out since 2000 revealed a 36% increase in the fishers
on Lake Victoria between 2000 and 2002, and 24% increase in the number of fishing crafts (LVFO 2005).
Acoustic surveys indicated that the Nile perch biomass
index decreased from 1.59 to 0.89 million tones over the
2 years prior to September 2001 (UNECIA 2001). Over
the same period the biomass of small pelagic fishes (Rastrineobola argentea and pelagic haplochromine cichlids,
mostly Yssichromis spp.) increased (UNECIA 2001, GETABU et al. 2003). Trawl surveys conducted at this time
indicated that Nile perch comprised the largest component of the catch; however, approximately 70% of their
catch by mass was immature (UNECIA 2001), and fishery independent surveys (reviewed in MATSUISHI et al.
2006) indicate that large numbers of juvenile Nile perch
are still present in Lake Victoria, suggesting no recruitment bottleneck. A similar pattern is evident in Lake
Nabugabo (Chapman and colleagues, unpubl. data). MATSUISHI et al. (2006) suggest that because Nile perch is a
highly fecund pelagic spawner, a lesser number of larger
individuals might find refuge from the fishery in the
deeper offshore waters and facilitate recruitment.
The size at maturity (Lm50) for Nile perch has undergone dramatic changes over the course of its invasion.
Soon after its introduction, Nile perch in lakes Victoria
and Kyoga matured at a much smaller size than in their
native habitat (30–34 cm total length (TL) in males and
50–54 cm in females (OGUTU-OHWAYO 2004)). It increased
dramatically over the next few decades, reaching 60–
70 cm TL in males and 95–100 cm TL in females in 1988,
but then declined to 54–64 cm and 73–78 cm TL in males
and females, respectively, in 1999/2000 (UNECIA 2001).
In Uganda, the size at maturity seems to have stabilized
at 56–60 cm TL for males and 66–70 cm for females
(FIRRI 2005).
The community- and ecosystem-level effects of intense pressure on the Nile perch fishery are still not well
understood, and there is current debate on lakewide and
regional patterns of Nile perch population dynamics.
Some native fish species are clearly resurging; however,
these comprise a biologically filtered fauna, representing
species that persisted in the face of eutrophication, deoxygenation of deepwater, and Nile perch. The resurgence
of haplochromine cichlids in the sublittoral zone of the
Mwanza Gulf (which has been well documented) and
elsewhere (less well documented) involves only a few
species that occur in large quantities and only a few trophic groups, mainly zooplanktivores and detritivores
(SEEHAUSEN et al. 1997b, WITTE et al. 2000, 2007). In
Mwanza Gulf, the detritivores and phytoplanktivores
originally formed the most important guild of haplochroeschweizerbartxxx
25
mine cichlids, with more than 13 species making up 31%
of the cichlid biomass, followed by the zooplanktivores
with 12 species comprising 27% of the biomass (WITTE et
al. 2000). In their recent 2005 survey WITTE et al. (2007)
found that 5 detritivorous species were regularly caught
again, but at low abundance. Eight zooplanktivores were
caught with overall densities higher in 2005 as before the
upsurge of Nile perch, whereas densities of detritivores
are about 10 times lower (WITTE et al. 2007).
Resurgence is also evident in other lakes in the region.
Intense fishing of Nile perch in Lake Nabugabo has coincided with a reappearance of some indigenous species in
the open waters, particularly haplochromines, and a shift
in the distribution of Nile perch (CHAPMAN et al. 2003). In
a 1995 survey of nearshore areas of Lake Nabugabo,
SCHOFIELD & CHAPMAN (1999) compared the catch per
unit effort (CPUE) of Nile perch in habitats 5 m and 20 m
from the shore in 2 ecotones: wetlands and forest (exposed) edge. At that time Nile perch were most abundant
in the 20-m offshore transects at forest edge sites. By
2005, there was no detectable difference in the catch per
unit effort of Nile perch between inshore and 20-m offshore waters of exposed and wetland ecotones (Fig. 3).
Over the same time frame, the average size of Nile perch
in experimental gill nets declined, and Nile perch are now
significantly larger in wetland areas than exposed areas
(Chapman and Paterson, unpubl. data). These patterns
may reflect, at least in part, intense harvest of Nile perch
in their preferred habitat. Haplochromine cichlids were
extremely rare in Lake Nabugabo the early-mid 1990s,
mostly found in inshore areas, and the small juveniles
were found almost exclusively in wetlands (OGUTUOHWAYO 1993, SCHOFIELD & CHAPMAN 1999). By 2000,
they had increased substantially in abundance and started
to move offshore. By 2005, they were more abundant
20 m offshore than near the shore (Fig. 3), although small
juveniles were still most abundant in wetland ecotones.
Their overall abundance on the nearshore transects had
declined from 2000, but was still higher than in 1995.
Part of this trend reflects continued movement offshore;
in 2005, haplochromines were captured in nets set 600 m
offshore, a habitat virtually unoccupied by haplochromines in 1995. This increases the potential for interaction
of Nile perch and haplochromines in offshore waters.
However, the decrease in Nile perch density and size in
this habitat may sufficiently reduce risk on haplochromines to foster both resurgence and movement away
from inshore refugia.
The dramatic change in the faunal assemblage over the
phases of the Nile perch invasion in Lake Nabugabo and
Lake Victoria has been reflected in prey selection by Nile
perch (OGUTU-OHWAYO 1994, CHAPMAN et al. 2003, BALIR-
26
Verh. Internat. Verein. Limnol. 30
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Fig. 3. Mean catch per unit effort of Nile perch (+SE) in transects with either exposed shoreline (forest edge, rocky cliff) or wetland ecotone. In each transect, experimental gill nets were placed inshore (just off the deadfall of the forest edge or just off the
wetland ecotone) and away from the shoreline (~20 m offshore). Note that we do not present data here for areas of open water
further offshore. CPUE represents the number of fish per experimental gill net. Source: 1995 data are adapted from SCHOFIELD &
CHAPMAN (1999); 2005 data are unpublished (L. Chapman and J. Paterson).
WA 2007). In Lake Nabugabo in 1995, Nile perch fed
largely on insects until reaching ~30 cm, when fish became the dominant prey by mass (SCHOFIELD & CHAPMAN
1999). By 2000, Nile perch >10 cm were feeding primarily on fish and by 15 cm were strongly piscivorous (CHAPMAN et al. 2003). The major prey taxa in 1995 were Rastrineobola argentea and juvenile Nile perch. By 2000, the
major prey taxon was haplochromine cichlids. Between
1968 and 1977, Nile perch 20–60 cm in Lake Victoria fed
heavily on the abundant haplochromine cichlids. However, by 1988, the major prey eaten by Nile perch in Lake
Victoria had changed to Caridina nilotica, Anisoptera
nymphs, juvenile Nile perch, and tilapiines, with very
few haplochromines (BALIRWA 2007). This remained the
main type of prey eaten by Nile perch until 2000, after
which the proportion of haplochromines in the diet started to increase (KATUNZI et al. 2006, BALIRWA 2007). In
Lake Victoria the shift to piscivory occurred at a larger
body size after the collapse of the haplochromine cichlid
fauna (OGUTU-OHWAYO 1994, SCHOFIELD & CHAPMAN
1999). Thus, the ontogenetic dietary shift in Nile perch
clearly changes with the period of the invasion process.
When haplochromines are rare, the size at the ontogenetic shift is substantially larger. Some current models
for fisheries management assume that Nile perch begin
feeding on fishes at 40 cm (e.g., MATSUISHI et al. 2006),
characteristic of this species in its native range. However,
eschweizerbartxxx
the size of the ontogenetic shift is highly labile in this
species, and such information should be considered in
predicting the cascading effects that fishing regimes will
ultimately have on the species and the native fauna.
Phenotypic change in a filtered fauna
The situation in Lake Victoria is highly dynamic, and the
Nile perch population structure is a moving target that
will demand adaptive management if sustainability is
elected as a priority. The future is difficult to predict, but
what is clear is that fish that have endured the invasion
have experienced a dynamic set of selection pressures
and now find themselves inhabiting a system much
changed from 40 years ago. Only a subset of the basin
fauna now exists, and limnological conditions are still
being strongly influenced by a basin heavily impacted by
intense human land use; thus, those species that have
persisted, recovered, or prospered during the invasion
process may differ in phenotype from the pre-Nile perch
fauna.
Some fish species have experienced generations of intense predation pressure by Nile perch. For such species,
we anticipate differences between pre- and post-Nile
perch populations with respect to predator-associated
morphology. If fishes have survived many generations of
L. J. Chapman et al., Biodiversity conservation in African inland waters
predation pressure by Nile perch, then they may have altered their body morphology to become faster or more
difficult to swallow. Other species have survived generations of strong selection pressure for refugial characteristics, such as low oxygen, and thus we might expect phenotypic change over time that reflects these selective
agents (e.g., hypoxic stress).
Scientists in the lake basin are now exploring the effects of predator pressure dynamics on haplochromines
and Nile perch, and a growing body of information is
demonstrating rapid phenotypic change. These studies
have been done by comparing populations in lakes with
and without Nile perch and by comparing archived museum specimens to contemporary conspecifics (Table 1).
There is evidence for an increase in gill size in several
species that have either persisted in deep swamp refugia
under extreme hypoxia, or have resurged in the main lake
in the 1990s under conditions of decreased oxygen concentration (Table 1). Comparisons of the haplochromine
cichlid Pseudocrenilabrus multicolor and the mormyrids
Gnathonemus victoriae, and Petrocephalus catostoma
from dense hypoxic swamp refugia near Lake Nabugabo
to populations from well-oxygenated waters of nearby
lakes without Nile perch showed larger gills (either gill
surface area or total gill filament length) in the swampdwelling populations for all 3 species (Table 1). This suggests that increase in gill surface area may be an adaptive
response to hypoxic stress that has facilitated use of deep
swamp refugia and permitted persistence with Nile perch
in the Nabugabo system.
WITTE et al. (in 2008) provided more direct evidence
for rapid morphological change in the Lake Victoria region by comparing archived specimens of an endemic
haplochromine (Haplochromis (Yssichromis) pyrrhocephalus) to contemporary conspecifics (Table 1). The
zooplanktivorous H. pyrrhocephalus nearly vanished
coincident with the upsurge of Nile perch in the 1980s,
but recovered in the 1990s. WITTE et al. (in press) reported
a total gill surface area 64% greater in recently collected
specimens (1993–2001) than in conspecifics collected
prior to the Nile perch explosion (1977–1981). WANINK &
WITTE (2000b) found evidence for morphological shifts
in R. argentea. After the decline of the demersal haplochromine cichlids, R. argentea exhibited a habitat shift to
exploit the bottom area and its macroinvertebrate prey.
The habitat shift was accompanied by a significant increase in the number of gill filaments, perhaps in response to reduced oxygen concentrations in the new
feeding areas, and a decrease in gill raker number related
to larger prey items (WANINK & WITTE 2000a, b, WANINK
et al. 2001).
Evidence for rapid morphological shifts in whole-body
eschweizerbartxxx
27
morphology is also evident in the lake basin and represent a variety of selection pressures, including predation
in open waters by Nile perch or selection pressures in
structurally complex refugia. Using geometric morphometric tools Chapman and colleagues have found strong
morphological differentiation between P. multicolor from
swamp refugia in Lake Nabugabo and conspecifics from
a nearby lake population, where they persist in well-oxygenated waters in the absence of Nile perch. Preliminary
analysis suggests a strong axis of diversification characterized by a deepened midbody of the population in the
Nile perch system, which may help to exceed the gape
size of small Nile perch or assist with maneuverability in
structurally complex refugia (Dewitt, Chapman & Langerhans unpubl. data). We also compared the whole-body
morphology of R. argentea collected from Lake Nabugabo in 1995 when Nile perch were extremely abundant and
feeding on R. argentea (SCHOFIELD & CHAPMAN 1999) to
specimens collected in 2003 (after Nile perch had shifted
back to the resurging haplochromine prey base) and to
specimens from a nearby perch-less lake into which R.
argentea was recently introduced (most probably from
Lake Nabugabo). Preliminary analyses indicate that collections with higher predation intensity from Nile perch
were characterized by a smaller head and larger caudal
region, which match biomechanical predictions for increasing swimming speed, and show a remarkable resemblance to differences observed between predator regimes in Gambusia species (LANGERHANS et al. 2004);
however, additional collections will be required to cover
a broader size range and validate patterns (Langerhans,
Chapman & Low-Decarie unpubl. data). Similar changes
were observed for H. pyrrhocephalus (WITTE et al. in
press).
Trophic shifts have been reported in several species in
response to changes coincident with the Nile perch invasion. For example, the predatory catfish Bagrus docmak,
for which Nile perch is both a predator and competitor
(GOUDSWAARD & WITTE 1997), exhibited a shift from a
primarily piscivorous diet dominated by haplochromines
prior to the Nile perch upsurge to a broader diet that included a significant proportion of invertebrates and R.
argentea (OLOWO & CHAPMAN 1999). The endemic cichlid
H. pyrrhocephalus reappeared in the 1990s; the former
zooplanktivore exhibited a new diet that included more
large prey such as fish, shrimps, and mollusks, items
never encountered in this species in the past (KATUNZI et
al. 2003). A post-Nile perch habitat shift in R. argentea
was accompanied by a switch in diet from zooplankton to
energetically rich macroinvertebrates (including chironomid larvae and the prawn Caridina nilotica (WANINK
1998).
28
Verh. Internat. Verein. Limnol. 30
Table 1. Summary of studies providing evidence for phenotypic change in response to changes coincident with the Nile perch
introduction. Comparisons are made between (a) populations in lakes with Nile perch and populations in lakes without NP or
populations within deep swamp refugia (absence of NP), and (b) specimens collected before and after the Nile perch upsurge. We
have also included comparisons of Nile perch at different phases of its invasion.
Trait
Gill size
Species
Pseudocrenilabrus multicolor
Gnathonemus victoriae
Petrocephalus catostoma
Rastrineobola argentea
Haplochromis pyrrhocephalus
Shape traits
Comparison
Presence vs. absence of Nile
perch
Presence vs. absence of Nile
perch
Presence vs. absence of Nile
perch
Before vs. after Nile perch
Before vs. after Nile perch
Data Source
Rosenberger & Chapman 2000,
Chapman et al. 2000
Chapman et al. 2002
Chapman et al. 2002
Wanink & Witte 2000a, b
Witte et al. In press
Rastrineobola argentea
Presence vs. absence of Nile
perch
Before vs. after Nile perch
Retina
Haplochromis pyrrhocephalus
Haplochromis tanaos
Before vs. after Nile perch
Before vs. after Nile perch
Size at maturity or
Lates niloticus
early-mid-late in the invasion
Ogutu-Ohwayo 2004,
Balirwa 2007
size of ripe females
Rastrineobola argentea
Zooplanktivorous haps
Before vs. after Nile perch
Before vs. after Nile perch
Wanink & Witte 2000a
Wanink & Witte 2000a
Absolute fecundity
Rastrineobola argentea
Zooplanktivorous haps
Before vs. after Nile perch
Before vs. after Nile perch
Wanink & Witte 2000a
Wanink & Witte 2000a
Before vs. after Nile perch
Before vs. after Nile perch
Presence vs. absence of Nile
perch
Early-mid-late in the invasion
Wanink & Witte 2000a, b
Witte et al. In press
Olowo 1998
Feeding apparatus
Gill rakers
Muscles
Diet
Pseudocrenilabrus multicolor
DeWitt, Chapman, Langerhans,
unpubl.
Chapman, Langerhans, L-DeCarie unpubl.
Witte et al. In press
Witte et al. 2005
eschweizerbartxxx
Rastrineobola argentea
Haplochromis pyrrhocephalus
Brycinus sadleri
Lates niloticus
Rastrineobola argentea
Haplochromis tanaos
Haplochromis pyrrhocephalus
Bagrus docmak
Schilbe intermedius
Oreochromis niloticus
Before vs. after Nile perch
Before vs. after Nile perch
Before vs. after Nile perch
Before vs. after Nile perch
Before vs. after Nile perch
Presence vs. absence of Nile
perch
Recent work in Mwanza Gulf has indicated broader
dietary spectra in several other haplochromine species
(e.g., in the zooplanktivore H. tanaos, (van OIJEN &
WITTE 1996); and several detritivores, M. Kishe-Machumu unpubl.). Broader diets in the haplochromines may
reflect decreased competition for benthic prey following
the dramatic decline in congeners and other macroinvertebrate feeders. Broader diets may also reflect the influence of reduced transparency associated with eutrophication. Fish may not be able to visually detect small prey as
easily as larger prey under reduced light, and/or as their
Ogutu-Ohwayo 1994, Schofield
& Chapman 1999
Wanink 1998
van Oijen & Witte 1996
Katunzi et al. 2003
Olowo & Chapman 1999
Olowo & Chapman 1999
Bwanika et al. 2006
visual encounter rate goes down, they become less
choosy (SEEHAUSEN et al. 2003a).
It is unknown whether these phenotypic changes in
gill size, body shape, and other traits are due to heritable
response to selection, environmentally induced phenotypic plasticity, and/or hybridization; but they certainly
open the door for studies of contemporary evolution. We
have used common-garden rearing experiments to explore the degree to which developmental plasticity explains variation in the morpho-physiology of Pseudocrenilabrus multicolor, a widespread cichlid that persists in
L. J. Chapman et al., Biodiversity conservation in African inland waters
water bodies with Nile perch (where they are confined to
hypoxic refugia) and waters without Nile perch (where
they persist in well-oxygenated habitats). Fish from both
high- and low-predation habitats show a high degree of
morphological plasticity in gill traits in response to
growth under high and low-oxygen conditions, suggesting that phenotypic plasticity may contribute to persistence with Nile perch (CHAPMAN et al. 2000, CHAPMAN &
GALIS, unpubl. data). RUTJES (2006) also reported high
levels of plasticity in rearing experiments under low- and
high-oxygen conditions in 3 haplochromine species from
Lake Victoria. Studies are ongoing in the Witte and
Chapman labs to explore the source of phenotypic divergence in species that have persisted or prospered with the
invasion of Nile perch.
The Lake Victoria region is a hot spot for studies of
phenotypic alterations in natural populations and the role
of human activities in precipitating adaptive phenotypic
change. In a recent review, HENDRY et al. (in press) conducted a meta-analysis based on >3000 rates of phenotypic change in 68 systems that demonstrated higher
rates of phenotypic change in anthropogenic context than
in natural contexts. They also point out a particularly
important contribution of phenotypic plasticity, also evident in our studies of cichlids in the Lake Victoria basin.
Fisheries, faunal dynamics, and
phenotypic change: a summary
eschweizerbartxxx
Lake Victoria is a highly dynamic system, and the Nile
perch population structure is a moving target that will
demand adaptive management if sustainability is elected
as a priority. Management strategies that facilitate a
heavy, but sustainable, Nile perch fishery, may allow the
coexistence of many indigenous species, but attempts to
protect and restore biodiversity will only succeed if the
general environmental quality permits, particularly in
Lake Victoria where euthrophication seems to have
played an important role in patterns of faunal collapse
and recovery. A major challenge facing conservation in
the lake basin is the spatial and temporal heterogeneity in
patterns of faunal collapse and resurgence, and our information on this heterogeneity. Our knowledge of faunal
trends and environmental change, both within and among
water bodies that harbor introduced Nile perch (Kyoga,
Victoria, Nabugabo, and others), should be fully exploited to detect general patterns and processes that might not
occur synchronously. The future holds many challenges
for the Lake Victoria region, but the basin offers a
glimpse of what the future may hold for the world’s fresh
waters and highlights the importance of human predators
29
as integral forces in aquatic food web dynamics. The lake
basin also contains a wealth of information on human
influences on phenotypic variation and confirms a growing awareness that humans are important drivers of phenotypic change in populations.
Acknowledgements
The authors have a long history of research in the Lake Victoria
region, and thus, we would like to thank the many scientists
who have participated in documenting the patterns of change
in the waters of the Lake Victoria region, the fishermen who
have worked with all of us over the years, our graduate students
who have worked in the lake basin, and the 3 fisheries research
institutes of the riparian countries (National Fisheries Resources Research Institute of Uganda, Tanzania Fisheries Research Institute, and the Kenyan Marine and Freshwater Fisheries Research Institute). We also acknowledge funding from a
variety of sources including: the Wildlife Conservation Society, National Science Foundation, National Science and Engineering Research Council of Canada, the US National Undersea Research Program, Netherlands Organization for the Advancement of Tropical Research (WOTRO), Dutch Science
Foundation (ALW), Leids Universiteits-Fonds (LUF), the Wageningen Agricultural University, the Section for Research and
Technology of the Netherlands Minister of Development Cooperation, the Schure-Beijerinck-Popping Fonds, the Stichting
Leids Universiteits-Fonds, the National Geographic Society,
the Pew Charitable Trusts, the American Association of Zoological Parks and Aquaria, USAID, the World Bank (LVEMP)
and many smaller but critical sources.
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[WRI ] WORLD R ESOURCES INSTITUTE 1994. World Resources
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Authors’ addresses: Lauren J. Chapman, Department of Biology, 1245 Dr. Penfield, McGill University, Montreal, Quebec, H3A
1B1, Canada and Wildlife Conservation Society, 2300 Southern Boulevard, Bronx, NY 10460, USA. Corresp. author: Lauren.
[email protected]
Colin Chapman, Department of Anthropology and McGill School of Environment, McGill University, 855 Sherbrooke St. West,
Montreal, Quebec, H3A 2T7, Canada and Wildlife Conservation Society, 2300 Southern Boulevard, Bronx, NY 10460, USA.
Les Kaufman, Department of Biology, Boston University, 5 Cummington Street, Boston MA 02215.
Frans Witte, Institute of Biology, University of Leiden, P. O. Box 9516, 2300, RA Leiden, The Netherlands.
John Balirwa, National Fisheries Resources Research Institute of Uganda, Box 343, Jinja Uganda.
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