Next Article in Journal
Insecticidal and Antiprotozoal Properties of Lichen Secondary Metabolites on Insect Vectors and Their Transmitted Protozoal Diseases to Humans
Previous Article in Journal
Microbial Community’s Dynamic Response to Fomesafen Usage in Chernozems of Northeast China
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Fishes of the Lower Lulua River (Kasai Basin, Central Africa): A Continental Hotspot of Ichthyofaunal Diversity under Threat

1
Département de Biologie, Faculté des Sciences, Université de Kinshasa, Kinshasa 01033, Democratic Republic of the Congo
2
Richard Gilder Graduate School, American Museum of Natural History, New York, NY 10024, USA
3
Department of Ichthyology, Division of Vertebrate Zoology, American Museum of Natural History, New York, NY 10024, USA
*
Author to whom correspondence should be addressed.
Submission received: 3 July 2021 / Revised: 18 July 2021 / Accepted: 22 July 2021 / Published: 26 July 2021
(This article belongs to the Section Animal Diversity)

Abstract

:
The ichthyofauna of the Lulua River, a large right bank tributary of the Kasai River in central Africa, is among the most poorly documented in the Kasai ecoregion. To remedy this lack of knowledge, sampling was carried out between 2007 and 2014 along the main channel and in many tributaries. A total of 201 species distributed in 81 genera, 24 families, and 12 orders are reported from the lower reaches of the Lulua. The species richness reported in this study represents a substantially improved documentation of the Lulua ichthyofauna (historically estimated at only 79 species). Here, 129 species are recorded for the first time, bringing the total number of known species to 208. Among these, five have recently been described: Raiamas brachyrhabdotos Katemo Manda, Snoeks, Choca Manda, and Vreven 2018, Distichodus kasaiensis Moelants, Snoeks, and Vreven, 2018, Distichodus polli Abwe, Snoeks, Choca Manda, and Vreven 2019, Epiplatys atractus Van Der Zee, Mbimbi, and Sonnenberg 2013, and Hypsopanchax stiassnyae Van Der Zee, Sonnenberg, and Mbimbi 2015; numerous additional taxa are currently under investigation. Recognized here as a continental hotspot of ichthyofaunal diversity, the Lulua is under extreme threat from exploitation of forest products for building materials, deforestation for shifting agriculture and charcoal exploitation, destructive fishing practices, and mining, all of which are rapidly increasing in the watershed. The present study provides baseline documentation for use in conservation planning and future developmental projects in the Kasai ecoregion in general and Lulua River basin in particular.

Graphical Abstract

1. Introduction

The Congo Basin (CB) comprises an immense hydrographic network with a wide variety of habitats hosting an extremely diverse fish community currently estimated at 1270 species, of which over 75% are considered basin endemics [1,2,3]. Second only to the Amazon in terms of volume, the CB drains an area of about 3.7 million km2 of Central Africa [4,5], and its location on both sides of the Equator results in the Congo River (CR) discharging an almost constant volume of 1308 km3 [6] of freshwater into the Atlantic Ocean (AO). From its source in the savanna highlands of the Lualaba and Haut-Katanga provinces in southeastern Democratic Republic of the Congo (DRC) to its mouth in the western Kongo Central province, the main channel of the CR flows through 4374 km [5] generating a high diversity of macro- and microhabitats including falls, rapids, swamps, pools, floodplains, flooded forests, lakes, deep rocky substrates, and a short estuarine reach. Along its journey to the AO, in the western basin, the CR is joined by large tributaries such as the Lulonga, Ruki, Ubangi, Sangha, Alima, Lefini, Kwa-Kasai, N’sele, and Inkisi that greatly increase its hydrographic and habitat complexity. The alternation of macro- and microhabitats creates perfect conditions for isolation of fish populations that may accelerate the processes of speciation even at remarkably small geographic scales [7,8]. Despite such high levels of species richness and endemism, it is recognized that several areas of the CB remain underexplored [9], and their respective ichthyofauna are poorly documented [10]. Therefore, the number of fish species currently reported from the CB is certainly underestimated and fails to capture the true ichthyofaunal diversity in the basin.
Historically, ichthyological exploration of the CB dates to the late 19th century [11] but is characterized by unequal sampling across the basin [12]. Paugy [11] reported that one of the earliest fish collecting efforts in the CB was that of N.E. Ballay between 1882 and 1885. Later numerous expeditions, such as those of P.S. de Brazza (1883–1886), M.A. Greshoff and M.P. Delhez (1899), and H. Lang and J.P. Chapin (1907–1915), have contributed to large collections of specimens housed in the Muséum National d’Histoire Naturelle (MNHN), Paris, the Africa Museum (MRAC), Tervuren, the American Museum of Natural History (AMNH), New York, and the Natural History Museum (NHMUK), London. Many of those collections formed the basis for G.A. Boulenger’s influential work on the fish fauna of the CB [13]. From 1929 through the early 1980s, several other studies (e.g., [14,15,16,17,18,19,20,21,22]) further documented the ichthyofauna of the CB. However, most collecting efforts were undertaken in the CR main channel, some associated lakes, and a few easily accessible tributaries, leaving several major tributaries and sub-tributaries virtually unexplored. This situation has made it very difficult for the scientific community to estimate with precision the true ichthyofaunal diversity of the CB. To improve this situation, the last decade has seen increasing efforts to explore and document under-sampled affluent tributaries of the CR (e.g., [23,24,25,26,27,28,29,30,31]). However, parts of the CB, particularly those of the Kasai ecoregion, in addition to being seriously impacted by ongoing deforestation and mining activities, remain poorly known [10].
The Kasai ecoregion [32], composed of the Kasai River (KR) and its main tributaries (Kwango, Kwilu, Loange, Lulua, and Sankuru), is one of the largest ecoregions of the CB and, likely due to the presence of numerous rapids and falls that restrict fish movement, is estimated to have a high level of endemism [3]. However, as already noted, this ecoregion remains underexplored, and the occurrence and distribution of many fish species remain uncertain. The lack of documentation for many tributaries and sub-tributaries of the KR constitutes a major deficit in our knowledge of fish biodiversity of CB.
An accurate accounting of species diversity is, therefore, of central importance for data-based conservation and sustainable development efforts. As such, species discovery and description remain fundamental tasks for advancing biodiversity studies in poorly documented regions such as the central CB where considerable diversity remains to be documented [33,34]. This study was carried out as part of the Congo Project initiated by the American Museum of Natural History (AMNH), in partnership with the University of Kinshasa (Democratic Republic of Congo) and the University of Marien Ngouabi (Republic of Congo), to assess ichthyofaunal diversity in the middle and lower reaches of the CRiver. Here, we provide an inventory of fish species of the lower reaches of the LR, the distributions of these species across that portion of the river and the KR, and the anthropogenic activities that constitute the main threats to that ichthyofauna and the ecological integrity of the basin.

2. Materials and Methods

2.1. Study Area

The LR catchment covers a surface area of about ca. 71,400 km2 and extends between 4.764° and 11.111° S and between 21.111° and 24.119° E. The river originates in the Lualaba Province in the southeast of the Democratic Republic of Congo near the Angolan border at an elevation of about 1200 m asl [35], and it gradually descends the Katanga plateau (a northward extension of the Kalahari plateau) crossing the Central Kasai Province to merge with the main channel of the Kasai River at about 58 km downstream of the city of Luebo in the Kasai Province. From its headwaters, near the boundaries of the Upper Zambezi and Lualaba ecoregions (Figure 1), to its confluence (at about 386 m asl) with the KR, the Lulua flows over a distance of 1256 km, characterized by high geomorphological complexity [36], resulting in extensive habitat heterogeneity along its main channel including numerous rapids, pools, small and large tributaries, large floodplains, and perennial and permanent swamps [37,38]. The numerous rapids divide the main channel of the LR into several alternating sections of low (muddy and deep) and fast current (rocky and shallow).
The LR is under a tropical savanna climate characterized by two main seasons: a longer wet season (from October to early May) and a shorter dry season from (mid-May to mid-September). The basin receives an annual rainfall that varies between 1259 and 1750 mm [39].
On the basis of its elevation profile, we divided the LR into three sections: Upper, Middle, and Lower Lulua (Figure 2). The Upper Lulua is about 260 km long, flowing from its source near the Angolan border to Kusununu, about 160 km upstream of the city of Sandoa (Sanduwa), where a significant expansion, from about 200 m to over 1000 m, of the river’s floodplain is noted. Following the classification of McManamay and Derolph [40], that section of the river has a low stream gradient with an average of 2.19 m/km (0.22%). With a length of about 660 km, the Middle Lulua is the longest section of the river and stretches from that first expansion of the floodplain to the Mbumba rapids (just upstream of Mwana Nanga at about 336 km from the Lulua outflow into the Kasai) marking the beginning of a long series of rapids. The Middle Lulua is characterized by a very low stream gradient with an average of 0.215 m/km (0.022%). From the Mbumba rapids, the river flows again in a low-gradient zone, marking the beginning of the Lower Lulua, before flowing through a very low stream gradient as it joins the Kasai. That stretch of the river is about 336 km long and can be divided into two subsections. The first subsection is about 200 km long starting from the Mbumba rapids to the vicinity of Muebela and has an average stream gradient of 1.62 m/km (0.162%), with several rapids and localized braiding of the channel. The last 136 km of the LR, which constitutes the second subsection of the Lower Lulua and its estuary, is characterized by a flattening of stream gradient with an average of 0.188 m/km (0.0188%). In this stretch, the LR is joined by its largest and longest tributary, the Kaluebo or Luebo River.

Notes on Collection Sites

A total of 43 sites were sampled along the lower reaches of the LR including 13 main channel sites, 20 tributaries, and 10 sub-tributaries, as reported in Table A1 and Figure 3. Most main channel sites are in areas of river braiding and rapids (Figure A1), except sites 1 (Luebo), 3 (Nsanga Nyembo), and 9 (Ntumba). Typically, the sampled sites are characterized by shallow habitats with a rocky substrate and fringing sandy beaches. The river flow in these sections is very rapid, generating numerous cascades, rapids, and waterfalls, and vegetal cover is predominately forest islands and woody riparian savannas. Water pH is slightly acidic with an average of 6.65 but can drop to 5.5 (at Dijiba, Site 6). However, a basic pH of 8 was recorded at Site 12 (Kabeya Nsaka) during the dry season. Collecting sites located on tributaries and sub-tributaries are more diverse, ranging from large channels of 35–63 m width (Kaluebo, Miao, and Moyo Rivers) to small creeks of less than 5 m width (Kasonga, Nkalala, and Tukomba Creeks). The pH in these tributaries is generally slightly acidic but varies from 5.5 (Luyenga River) to 7.1 (Kapelekese River). The substrate is also highly diverse, alternating among rocky, muddy, sandy, and leaf covered depending on location along channels (Figure A2).

2.2. Ichthyofauna Sampling

A total of six field expeditions, each a month long, were undertaken between 2007 and 2014: the first, during the rainy season in December 2007; the second, at the beginning of the dry season in June 2008; the third, during the rainy season in February 2010; the fourth, during the dry season in July 2010; the fifth, at the end of the dry and the beginning of rainy season in September 2011; the sixth, in September 2014. At each site, a stretch of 100 m was defined, and standard fishing techniques were employed [41]. Depending on habitat and conditions, these techniques included dip nets, cast nets, monofilament gill nets, seine nets, and some local fishing gears (Figure A3). In isolated stretches of the main channel and some tributaries, with permission, the controlled use of the isoflavone ichthyocide rotenone, was employed to sample species not readily captured using other methods [42]. Fishes were euthanized, with MS222, prior to tissue sampling and body preservation in accordance with recommended guidelines for the use of fishes in research [43,44].
Most voucher specimens are housed in the Department of Ichthyology at the American Museum of Natural History (AMNH), and associated data are accessible at https://emu-prod.amnh.org/db/emuwebamnh/index.php. Additional specimens are housed in the Department of Biology at the University of Kinshasa where they serve as teaching materials. Taxonomic nomenclature follows Fricke et al. [45]. In the absence of a comprehensive taxonomic key for the CB ichthyofauna, identification of specimens was determined on the basis of available publications on the ichthyofauna of the Congo provinces and surrounding regions. In addition to Boulenger’s catalog of fishes in the British Museum (Natural History) [46], we consulted several other documents [47,48,49,50,51,52,53,54,55,56,57,58,59,60], and the following internet resources http://www.poissons-afrique.ird.fr/drupal/faunafri, http://www.mormyrids.myspecies.info/en, and https://research.amnh.org/vz/ichthyology/congo/taxoindex.html (all accessed on 1 June 2020).

2.3. Anthropogenic Activities

Anthropogenic activities were surveyed along the LR during our sampling trips. We recorded human activities, both in and outside collecting sites, that likely had direct or indirect impacts on land cover, water quality, fish populations, and hydrology of LR and its tributaries.

3. Results

3.1. Fish Diversity

A total of 3825 individuals were collected between 2007 and 2014. Examination of these specimens resulted in the identification of 201 species, belonging to 24 families and 12 orders with their distribution among the main channel and tributaries indicated in columns 1–21 (Table A2). The distribution of species among all sites is provided in Supplementary Table S1. The order Siluriformes, with 49 species, is the most dominant and represents about 24% of all identified species (Figure 4). It is followed by Cypriniformes (20%), Characiformes (19%), Osteoglossiformes (18%), and Cichliformes (6%). These five orders together represent 87% (177 species) of the species diversity currently known from the LR basin.
At the family level, the ichthyofauna of the LR is predominated by Cyprinidae, which is the most speciose family with 41 species (20%), followed by Mormyridae with 35 species (17%), Distichodontidae with 19 species (9%), Alestidae with 18 species (8.9%), Mochokidae with 17 species (8%), and Cichlidae with 12 species (6%). The remaining families are less abundant, each with less than 5% (Figure 5). Overall, Cyprinidae, Mormyridae, Distichodontidae, Alestidae, Mochokidae, and Cichlidae account for about 70% of the ichthyofaunal diversity in the lower LR.

3.2. Anthropogenic Activities

Overall, the economic situation of people in the LR basin is cause for considerable concern. Economic activity is almost entirely based on unsustainable exploitation of natural resources and minerals, and this, along with rapid demographic growth, is placing increasing pressure on ecosystems throughout the LR valley. During our sampling trips, we identified four main categories of human activity with direct or indirect impact on fish communities in LR: (1) activities affecting land cover, (2) water quality, (3) river hydrology, and (4) fish populations (Table 1). The first three categories contribute to habitat loss and degradation, which are the greatest threats to fish communities in central Africa [10], whereas the last category affects fish population equilibrium and contributes to population fragmentation and decline.
Shifting agriculture (Figure A7A,B) is consistently observed along the LR valley (Figure A8) and is a primary source of income and food for numerous households in the area. This activity is the major cause of deforestation and land-cover alteration throughout the valley. Additionally, settlement into the region is very active and characterized by the rapid expansion of preexisting towns and villages, as well as the creation of new villages and camps. In the absence of electricity, most households rely on charcoal and firewood for cooking and lighting, further contributing to deforestation.
Artisanal alluvial diamond mining (Figure A7E,F) is widespread (Figure A8) and remains the most lucrative activity for local populations throughout the valley. Mines are mostly located along riverbanks, and sometimes whole tributaries are dammed or diverted to mine their beds. Mined materials are directly sifted or washed in the river, releasing large amounts of clay, silt, sand, and gravels. Clay mines (Figure A7C) are generally smaller and provide clay for brick fabrication (Figure A7D) destined for local construction.
Currently, the only major hydroelectric project in the LR valley is the Grand Katende hydroelectric dam, with a planned capacity of 64 MW, which is in an advanced planning stage.
Fishes play a central role in the regional food supply and are often the only source of animal protein. Fishing activities in the LR are extensive and practiced by men, women, and children primarily for subsistence. Many fishing techniques are used including netting, trapping, damming and dewatering (Figure A7G), long lines, hook and line, and a locally produced vegetal ichthyocide (Figure A7H). Fishing practices are generally unregulated and often destructive, utilizing extremely small mesh-sized nets targeting small fish, as the larger fish are becoming increasingly scarce.

4. Discussion

The dominance of Siluriformes, Cypriniformes, Characiformes, Osteoglossiformes, and Cichliformes in the LR reflects a similar composition as found in the entire CB [12,61]. At the family level, the CB ichthyofauna is dominated by Cyprinidae, Mormyridae, Cichlidae, Mochokidae, Alestidae, Distichodontidae, Amphiliidae, and Nothobranchiidae, accounting for 73% of basin-wide diversity [62]. A similar family composition is also found in the LR. We note that the apparent shift in taxonomic dominance in the lower LR is likely due to the fact that representatives of the Siluriformes are distributed among seven families, while Cypriniformes are represented by members of a single family. When compared to the family composition of the northeastern tributaries of the CR in the Cuvette Centrale ecoregion [26], we noticed the dominance of the same families in both systems. However, the most speciose family is no longer the Cyprinidae but the Mormyridae. Such a shift in dominance suggests that a difference of dominant habitats available in these river networks may be the cause. The rivers of the Cuvette Centrale ecoregion flow through dense tropical forests, with numerous blackwater swamps and small forested streams, likely offering more suitable habitats for mormyrid species than for most cyprinids. While the Mormyridae is also predominant in another river in the Kasai ecoregion, the Kwilu [27], as well as in proximate ecoregions [28,34,63], the dominance of Cyprinidae in the lower Lulua is noteworthy and likely reflects the influence of surrounding savannah and grasslands, and a riparian vegetation restricted in width along its course. Additionally, historical connections between the Upper Lulua with the headwaters of the Upper Zambezi ecoregion (see below), with its high number of cyprinid species, may contribute to the large number of cyprinids collected in the present study. These factors, combined with the presence of some characteristic and endemic species, suggest that the LR basin may represent a distinctive ecoregion within the CB; however, additional collecting within the basin is needed before definitive conclusions can be reached.
While the family composition of the LR is similar to that of the CB as a whole, species composition indicates some affinities with the Upper Zambezi ecoregion to the south of the basin (Figure 1). Indeed, species such as Pollimyrus castelnaui (Boulenger 1911) (Figure A4E), Enteromius brevidorsalis Boulenger 1915 (Figure A5D), Enteromius thamalakanensis Fowler 1935 (Figure A4B), Enteromius radiatus Peters 1853, Clypeobarbus bellcrossi (Jubb 1965), Parauchenoglanis ngamensis (Boulenger 1911), Hypsopanchax jubbi Poll and Lambert 1965 (Figure A5H), Coptodon rendalli (Boulenger 1897) (Figure A5A), Tilapia sparrmanii Smith 1840, Pseudocrenilabrus philander (Weber 1897) (Figure A5B), Pharyngochromis acuticeps (Steindachner 1866), and Ctenopoma multispine Peters 1844, present in the LR, have also been reported from the Upper Zambezi system [25,50,62]. Such affinities with the Upper Zambezi can be explained by the existence of intermittent connections between the headwaters of the two systems during their geological evolution and currently in times of extreme humidity [25,64,65,66,67].
From a taxonomic point of view, the lower LR is characterized by a remarkably rich and diversified ichthyofauna. In addition to the 201 fish species inventoried in this study, seven species reported by [14,47,68,69,70], but not observed during our study, need to be added to the list. These species are Petrocephalus simus Sauvage 1879, Brachypetersius cadwaladeri (Fowler 1930), Clarias dumerilii Steindachner 1866, Synodontis depauwi Boulenger 1899, Tetracamphilius pectinatus Roberts 2003, Trachyglanis intermedius Pellegrin 1912, and Lacustricola katangae (Boulenger 1912). It is likely that these species are rare, are very localized, or occupy specialized habitats and were able to escape capture during our campaigns. Adding these seven species, the total number of species known from the LR basin reaches 208 species. This number will very likely be exceeded in the coming years as we intensively sample more habitats in unexplored areas of the basin, particularly the Middle and the Upper LR. Indeed, of the 1256 km of the main channel, only a 200 km stretch was intensively prospected within the framework of this study. Thus, the present results suggest that the Lulua catchment harbors an extraordinarily high number of fish species in comparison to other CR tributaries, such as the Inkisi River basin where 61 fish species have been reported [31], the Lefini River basin where 140 fish species have been inventoried [30], the N’sele River with 148 fish species [28], the Kwilu River with 150 species [27], the Luilaka and Salonga Rivers, both tributaries of the Ruki River, in the Salonga National Park where 152 species have been inventoried [29], and the Lindi River where 187 fish species have been reported [26]. Overall, only the Itimbiri (232 species) and Aruwimi (246 species) Rivers, in the Cuvette Centrale ecoregion, have been reported to harbor a higher number of species [26] than that reported in the present study. These differences could, of course, be due to many factors including the size of each river catchment, the diversity of habitats, and their respective productivity, to which we can add sampling techniques, effort, and gear used in different studies. Furthermore, according to Worm and Duffy [71], there is a reciprocal influence among the productivity of an ecosystem, its stability, and its biodiversity; thus, the most productive ecosystems would have high diversities.
It should be noted that about 14.4% (29 species) of the species reported in the lower LR were exclusively collected in tributaries and have yet to be found in the main channel (species in bold type in Table A2). Tributaries share an additional 83 species with the main channel bringing the total number of species collected in tributaries to 112 (55.7% of the lower LR fish diversity). This suggests that the LR tributaries harbor a significant proportion of species in the system. It is likely that the real proportion of species finding shelter in tributaries is considerably higher as our investigation was halted due to insecurity in the Kasai provinces, and we undoubtedly did not capture the entire species richness of certain tributaries and sub-tributaries since only a single campaign was undertaken in localities outside of the main channel. Furthermore, several tributaries of the lower LR were not surveyed at all. Nonetheless, the main channel harbors the highest number of species and provides shelter to about 85% (172 species) of the basin’s ichthyofauna.
Among species reported in this study, five (Epiplatys atractus Van Der Zee, Mbimbi, and Sonnenberg 2013 (Figure A6E), Hypsopanchax stiassnyae Van Der Zee, Sonnenberg, and Mbimbi 2015 (Figure A6G), Distichodus kasaiensis Moelants, Snoeks, and Vreven, 2018, Raiamas brachyrhabdotos Katemo Manda, Snoeks, Choca Manda, and Vreven 2018, and Distichodus polli Abwe, Snoeks, Choca Manda, and Vreven 2019 (Figure A6H)) have recently been described. The first two are endemic to the Lulua basin while the remainder are more widely distributed. Furthermore, eight putatively new species have been identified, namely, Chiloglanis sp. “Lulua”, Tetracamphilus sp. “Lulua”, Epiplatys sp. “pale” Van Der Zee, Mbimbi, and Sonnenberg (in prep) (Figure A6C), Lacustriola sp., Micropanchax sp. (Figure A6H), Enteromius sp. “purple stripe” (Figure A4C), Labeo cf. lukulae “Lulua” Liyandja (in prep), and Labeo sp. nov. Liyandja (in prep). The descriptions of some of these are currently underway while others need more investigation to be confirmed as new. In addition, some taxa, such as Chelaethiops luluae, Chrysichthys cf. duttoni, Garra cf. congoensis, and Ctenochromis luluae (Figure A6B), require further taxonomic attention.
The species richness reported in this study represents a substantial improvement over the documentation of the LR ¶ichthyofauna historically estimated at 79 species [14,47,68,69,70]. In columns 22 and 23 of Table A2, distribution data culled from published IUNC assessment of the status and distribution of central African fishes [72], the Kwilu River [27,73], the freshwater fishes of Angola [25,49], and FishBase [62] were used to investigate which of the species reported in this study have previously been recorded as present in the LR basin and/or the Kasai ecoregion as a whole. We found that 129 of the species reported here have not previously been recorded in the LR (Table A2, column 22). Representatives of families such as Malapteruridae, Tetraodontidae, Bagridae, Kneriidae, Clupeidae, Pantodontidae, and Notopteridae have not previously been reported from the LR, and 32 species reported here were previously unrecorded from the Kasai ecoregion (Table A2, column 23). Adding these species to the list of 367 species compiled from existing publications and databases [25,27,60,62,72,73,74,75] brings the total number of species currently known from the Kasai ecoregion to 399. On the basis of this assessment, the Kasai ecoregion occupies the first position, in terms of species richness, in the entire CB (exclusive of Lake Tanganyika). It is followed by the Cuvette Centrale ecoregion with 360 species [26,29], the Lower Congo rapids and Lower Congo ecoregions with a combined 328 species [76], and Pool Malebo estimated at 316 species [3]. However, a total of 399 species for the Kasai ecoregion needs further investigation as some of the species in these lists, such as Labeo ansorgii, Labeo cylindricus, and Labeo annectens, may have far more restricted distributions than currently indicated, and it is highly likely that additional species will be documented in the Middle and Upper Lulua (personal observation). Additionally, it has become clear that molecular analyses are needed throughout the entire basin to ensure that species are not under-split due to rampant cryptic speciation [77,78,79] or over-split due to morphological plasticity (Liyandja, in prep.).
The highly diversified ichthyofauna of the lower LR and that of the entire basin is threatened by a combination of exploitation of forest products for building materials, deforestation for shifting agriculture and charcoal production, destructive fishing practices, and mining (particularly for diamonds), as presented in the results. According to Nguimalet [80], alluvial diamond mining is responsible for regressive and lateral erosion resulting in a complete restructuring of river geomorphology in the Central African Republic. Such changes lead to significant habitat loss and, consequently, to fish population fragmentation and/or decline. In addition to geomorphological modifications, water quality is impacted by clay, silt, and other materials released into the water, by sifting or washing operations during diamond mining, which further increase turbidity and conductivity. Soil erosion caused by deforestation and increase in runoff also contribute to the modification of water quality by carrying more materials (sediment runoff) into the water. This excess of particulate matter in suspension affects fish physiology in numerous ways, including suffocation by clogging their gills [81]. As human populations increase, each of these activities will continue to intensify, and threats are expected to worsen throughout the region. Additionally, intensification of mining and dam construction projected to support the planned Congolese Government developmental programs is underway. A prime example is the Grand Katende hydroelectric dam which is now in an advanced planning stage (https://www.afrik21.africa/en/drc-kinshasa-to-restart-work-on-the-katende-hydroelectric-dam-64-mw; accessed on 20 June 2021). If completed, the Katende dam will inundate the lower LR where the present study has been carried out, and it will undoubtedly lead to major habitat degradation and likely the extirpation of many fish species [82], numerous of which are of central importance to the fisheries of the region. Subsistence fisheries in the LR valley are not monitored, and no data on the number of fish produced from these activities are available to allow an accurate assessment of their impact on the fish communities. However, according to observations made on the field and the types of fishing gear and techniques used by fishers, we can hypothesize that fish resources in the LR valley are under very high pressure and possibly already overexploited. Some of these techniques affect movements of migratory species (Labeo spp., Labeobarbus spp.) and have an impact on their reproduction cycle. Additionally, the repetitive use of locally produced organic ichthyocides, such as Tephrosia spp., have a drastic impact on fish communities. They are already known to be responsible for the decline in species richness and abundance in tropical streams [83].
Among identified species, only one, Teleogramma monogramma, has been evaluated as vulnerable by the IUCN Red list of threatened species [84] in Central Africa. According to Stiassny et al. [10], a congener, Teleogramma brichardi, is critically endangered because of urbanization around its restricted range near Kinshasa. The populations of T. monogramma reported here have only been collected near the City of Kananga and at the Katende site, suggesting that this species may be at higher risk than assessed by the IUCN. Twenty-seven (13.4%) species reported in this study have not been evaluated, and 18 (9%) have been reported as data-deficient by the IUCN. Some of these species such as Hypsopanchax stiassnyae, Amphilius maesii, Nannocharax uniocellatus, and Clypeobarbus mediosquamatus appear to have highly localized distributions along the lower Lulua, suggesting that a reevaluation of their conservation status is urgently needed. The remaining species (77%) have been evaluated as of least concern in Central Africa. However, given the intensity of human activities in the LR valley, there is clearly a strong imperative to carry out local evaluation of the conservation status of the LR species.

5. Conclusions

The ichthyofauna of the lower Lulua River is continentally outstanding in terms of fish diversity, and the entire Lulua basin may constitute one of the most species-rich fish communities of the CB. Such an elevated level of fish diversity is likely a result of the basin’s extensive habitat diversity ranging from numerous rapids, falls, pools, small and large tributaries, large floodplains, and perennial and permanent swamps, in addition to its location at the intersection of the Kasai and Lualaba ecoregions. Additionally, its shared headwaters with the Upper Zambezi ecoregion have likely also contributed to the high diversity of its ichthyofauna. The present study, which reports more than 200 fish species in the lower LR, represents a baseline documentation that can be used in conservation and future development projects in the Kasai ecoregion in general and in the LR in particular. In the long term, the outcomes of this study are intended as a starting point for monitoring and protecting the biodiversity of the entire basin. Further investigations are necessary to capture the true fish diversity of this exceptional river catchment, and such knowledge will also contribute to a better understanding of the specific composition and biogeographical history of the ichthyofauna of the Kasai basin and that of the CB as a whole.

Supplementary Materials

The following are available online at https://0-www-mdpi-com.brum.beds.ac.uk/article/10.3390/d13080341/s1: Table S1. Species distribution among sampling sites.

Author Contributions

J.J.M.M.M., R.J.C.M.I. and M.L.J.S. contributed to the conceptualization of the study; J.J.M.M.M. and T.L.D.L. collected the data and conducted the investigation; M.L.J.S., J.J.M.M.M. and T.L.D.L. identified the species; J.J.M.M.M. and T.L.D.L. prepared the original draft; R.J.C.M.I. and M.L.J.S. edited and reviewed the draft; T.L.D.L. and J.J.M.M.M. prepared visualizations; M.L.J.S. acquired funding; J.J.M.M.M. and R.J.C.M.I. were in charge of the project administration. All authors have read and agreed to the published version of the manuscript.

Funding

Financial support for this project was provided by the AMNH Axelrod Research Curatorship (M.L.J.S.). This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Associated data are accessible at https://emu-prod.amnh.org/db/emuwebamnh/index.php.

Acknowledgments

For assistance with collection and exportation permits, as well as logistical support, we are grateful to Julien Punga Kumanenge, Jean Mukulire Malekani, and Koffi Mulumba, Ministère de l’Agriculture et du Développement Rural, Sécretariat Général de l’Agriculture, Pêche et Elevage, Direction des Pêches, and the Université de Kinshasa, Cabinet du Recteur, Democratic Republic of Congo. Our thanks also to Barbara Brown (in memoriam), Radford Arrindell, Tom Vigliotta, and Chloe Lewis (AMNH) for their help with accessioning and cataloging specimens. We are also grateful to BEBUC, through the Else Kroner-Fresenius-Stiftung foundation, for their financial and moral support to T.L.D.L.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Table A1. Sampling sites: geographic and physicochemical data (* surface temperature). Geographic coordinates are given in decimal degrees with negative latitudes indicating south and positive longitudes indicating east.
Table A1. Sampling sites: geographic and physicochemical data (* surface temperature). Geographic coordinates are given in decimal degrees with negative latitudes indicating south and positive longitudes indicating east.
Site #LocalityRiver NameLatitude (°)Longitude (°)Altitude (m)T (°C) *pHStream Order
1LueboLulua−5.3388121.40929377287Main channel
2BeyaLulua−5.932522.33472524286Main channel
3Nsanga NyemboLulua−5.9531722.34541558286.4Main channel
4Ntumba ShambuyiLulua−5.97331722.37388518307Main channel
5DipumuLulua−6.0032822.3916547276.4Main channel
6DijibaLulua−6.1727222.45215550315.5Main channel
7KasendeLulua−6.2350922.46443606306Main channel
8KatendeLulua−6.3436622.45036649286.5Main channel
9KampayaLulua−6.4272122.41587649286.9Main channel
10TshimbadiLulua−6.4732322.4185768025.37.1Main channel
11NtumbuLulua−6.4448422.4197675286.7Main channel
12Kabeya NsakaLulua−6.520122.4394968826.28Main channel
13MbumbaLulua−6.5954522.4778872530.36.9Main channel
14KakuluKaluebo−5.9023721.59208515256.5Left bank tributary
15MiaoMiao−5.9397222.22158522256.5Left bank tributary
16TshilumbaKasonga−5.9296722.3435252028.96.7Right bank tributary
17TshilumbaTukomba−5.925422.3375651230.56.6Right bank tributary
18TshilumbaNkakala−5.9327822.3474351925.76.5Right bank tributary
19MikalayiKapelekese−5.953722.3371452930.77.1Left bank tributary
20MikalayiLuankadi−5.9683622.34208534316.7Left bank tributary
21MikalayiMikalayi−5.9874622.3376554024.56.6Left bank tributary
22TshiyoyiNkombua−6.004422.3906545265.4Right bank tributary
23TshiyoyiNgalala−6.0084122.3983855031.16.3Right bank tributary
24KantumangaLubi−600,50722.52569621296Right bank tributary
25KantumangaLukumbi Kumbi−6.0041322.526661026.85.3Right bank sub-tributary
26KantumangaMusangu−6.0090322.5227862124.76Right bank sub-tributary
27BampanyaLunyenga−6.1245222.52636609295.5Right bank tributary
28KamuanduLunyenga−6.0650122.653648285,8Right bank tributary
29DijibaMoyo−6.1872522.48455562286Right bank sub-tributary
30KankunkuMinkidimbua−6.1065822.7137567325.55Right bank sub-tributary
31KamuanduTshimayi−6.1937722.7399270229.35.4Right bank sub-tributary
32KamuanduTshina−6.2018222.73446703246Right bank sub-tributary
33TshimbuluMitshikiji−650,41722.7345760285.4Right bank sub-tributary
34KazadiLubondayi−6.525922.6691875530.66Right bank sub-tributary
35KazadiMbuyi−6.5447722.6984377428.65.8Right bank sub-tributary
36KazadiKambambe−6.5487922.704575329.26.2Right bank sub-tributary
37BunkondeTshinkelu−6.2747222.490967830.56.9Right bank tributary
38BunkondeKalulua−6.2785522.4877762429.76.8Right bank tributary
39TshimbawuLuna−6.3506422.51817722276.5Right bank tributary
40KalobaTshimayi−6.4325622.43643678306.7Right bank tributary
41NtumbuKabikonyi−6.4455422.4188267424.36.3Right bank tributary
42KalobaMukundulu−6.4562822.4464869925.96.6Right bank tributary
43Kabeya NsakaMunue Mayi−6.5152722.44906906285.8Right bank tributary
Table A2. List of species collected at sites in the main channel (lower Lulua) and tributaries. Sub-tributary species are listed in their respective tributaries. Species in bold type were collected only in tributaries. Numbers in parenthesis are species numbers. In columns 22 (Kasai) and 23 (Lulua historically), distribution data culled from [25,27,60,62,72,73,74,75] were used to indicate which Lulua species are known to occur in the Kasai ecoregion and which were not reported in the catchment prior to this study.
Table A2. List of species collected at sites in the main channel (lower Lulua) and tributaries. Sub-tributary species are listed in their respective tributaries. Species in bold type were collected only in tributaries. Numbers in parenthesis are species numbers. In columns 22 (Kasai) and 23 (Lulua historically), distribution data culled from [25,27,60,62,72,73,74,75] were used to indicate which Lulua species are known to occur in the Kasai ecoregion and which were not reported in the catchment prior to this study.
Lulua Main ChannelKalueboMiaoKasongoTukombaNkakalaMikalayiLuankudiKapelekeseNkombuaNgalalaLubiLunyengaMoyoKaluluaTshikeluLunaTshimayiMukunduluKabikonyiMunue MayiLulua HistoricallyKasai Basin
TAXONAMNH (Selected Representatives)1234567891011121314151617181920212223
POLYPTERIFORMES (1)
Polytpteridae (1)
Polypterus ornatipinnis Boulenger 1902247757, 247472, 268978X--------------------XX
OSTEOGLOSSIFORMES (37)
Pantodontidae (1)
Pantodon buchholzi Peters 1876 253358, 253060X---------------------X
Notopteridae (1)
Xenomystus nigri (Günther 1868) 252627, 253052X---------------------X
Mormyridae (35)
Campylomormyrus alces (Boulenger 1920) 253224X---------------------X
Campylomormyrus curvirostris (Boulenger 1898) 268982X---------------------X
Campylomormyrus elephas (Boulenger 1898) 253131, 268985, 253131X---------------------X
Campylomormyrus mirus (Boulenger 1898)252608X---------------------X
Campylomormyrus numenius (Boulenger 1898) 252605, 253223X---------------------X
Campylomormyrus rhynchophorus (Boulenger 1898)268986, 251106, 268986X------------- -------X
Campylomormyrus tamandua (Günther 1868)247525, 252609X-------------X------XX
Campylomormyrus tshokwe (Poll 1967) 252609, 253222X---------------------X
Cyphomyrus cubangoensis (Pellegrin 1936) 268992, 268989, 268992X----------------------
Cyphomyrus discorhynchus (Peters 1952) 247444, 253514, 253390X-----X-X-------------X
Cyphomyrus psittacus (Boulenger 1897) 253157X---------------------X
Gnathonemus petersii (Günther 1862)252799, 252612, 253229X----------X---------XX
Hippopotamyrus macroterops (Boulenger 1920) 251291, 270503X----------------------
Marcusenius greshoffii (Schilthuis 1891) 247417, 247446, 243985X--X--X-X-------------X
Marcusenius intermedius Pellegrin 1924252800, 253315, 253319-----------XX---------X
Marcusenius stanleyanus (Boulenger 1897) 251125X---------------------X
Mormyrops anguilloides (Linneaus 1758)247507, 252645, 268995X-------------X---XX-XX
Mormyrops lineolatusBoulenger 1898251068--------------X--------
Mormyrops masuianus Boulenger 1898 253338, 252821X-----------------X---X
Mormyrops microstoma Boulenger 1898 247471, 251067, 268999X-------X-------------X
Mormyrops sirenoides Boulenger 1898251067, 252730----------X---X-------X
Mormyrus caballus bumbanus Boulenger 1909251133, 251243, 269000X----------------------
Mormyrus caballus caballus Boulenger 1898 247502, 247405, 253134X-------------X ----X
Mormyrus ovis Boulenger 1898 269002, 269001, 269002X---------------------X
Myomyrus macrops Boulenger 1914 247518, 247513, 251242X-X-----------X-------X
Petrocephalus christyi Boulenger 1920 247500, 252819, 253117X-X---------------X---X
Petrocephalus cf. schoutedeni Poll 1954 252727X----------------------
Petrocephalus sauvagii Boulenger 1887251065, 252729, 269016X-------------X------XX
Pollimyrus castelnaui (Boulenger 1911) 253197, 253328X------X--------------X
Pollimyrus maculipinnis (Nichols and LaMonte 1934)253350, 252822, 252614X---X---X-X---X-X-X--XX
Pollimyrus nigripinnis (Boulenger 1899) 252613X---------------------X
Pollimyrus osborni (Nichols and Griscom 1917) 247526, 253232, 253339X----------X--X-------X
Pollimyrus pulverulentus (Boulenger 1899) 253130X---------------------X
Stomatorhinus kununguensis Poll 1945 247436X----------------------
Stomatorhinus patrizii Vinciguerra 1928 252615X---------------------X
CLUPEIFORMES (3)
Clupeidae (3)
Microthrissa congica (Regan 1917) 268979, 253383X---------------------X
Microthrissa royauxi Boulenger 1902 252625X----------------------
Potamothrissa obtusirostris (Boulenger 1909) 247515, 247479X-X--------X-X--X---X-X
GONORYNCHIFORMES (2)
Kneriidae (2)
Parakneria ladigesi Poll 1967 251112, 243627X---------------------X
Parakneria vilhenae Poll 1965 253217, 253305, 253505X-X----------X--------X
CYPRINIFORMES (41)
Cyprinidae (41)
Enteromius bifrenatus (Fowler 1935)253026, 253214X--X------------------X
Enteromius brevidorsalis(Boulenger 1915)253025, 269220---X-X-XX------X-----XX
Enteromius chiumbeensis (Pellegrin 1936)247422, 269221X----X--XX---X---X- --X
Enteromius eutaenia (Boulenger 1904)252847, 269222XX-X-X--XX--XX---X-X-XX
Enteromius fasciolatus (Günther 1868)252834, 253204---X---X--X----XXX-X--X
Enteromius haasianus(David 1936)269226-----X---------------XX
Enteromius humeralis (Boulenger 1902)269095, 251320X---------------------X
Enteromius lineomaculatus (Boulenger 1903)253510, 243981X-XX-X--X---------X--XX
Enteromius cf. luluae (Fowler 1930)257172X--------------------XX
Enteromius miolepis (Boulenger 1902)247483, 253189X-X--------XXX-------XX
Enteromius paludinosus (Peters 1852)253194, 253285---X---X-------X-----XX
Enteromius radiatus (Peters 1853)253115, 252725X--X--X------X--------X
Enteromius thamalakanensis (Fowler 1935)253195, 269089-----X-X--------------X
Enteromius unitaeniatus (Günther 1866)253125X-------X---------X----
Enteromius sp “purple stripe”-X-X--X------------X----
Chelaethiops elongatus Boulenger 1899247817, 253001X---------------------X
Chelaethiops luluae (Nichols and Griscom 1917)247812, 251277X-X-----------X------XX
Clypeobarbus bellcrossi (Jubb 1965)253036---XXX----------------X
Clypeobarbus bomokandi (Myers 1924)252753X-----X-X-------------X
Clypeobarbus mediosquamatus Poll 1967269095, 251320X----------------------
Garra cf. congoensis Poll 1959253364, 251061, 269096X----------------------
Labeo cf. chariensis Pellegrin 1904247968, 253454X-X----------X------XXX
Labeo cf. cyclorhynchus Boulenger 1899247971, 247855X----------------------
Labeo cyclorhynchus Boulenger 1899252631X---------------------X
Labeo cf. dhonti Boulenger 1919251178X---------------------X
Labeo fulakariensis Tshibwabwa, Stiassny, and Schelly 2006247989, 247995X----------------------
Labeo greenii Boulenger 1902253436, 243606X-------------------XXX
Labeo lineatus Boulenger 1898247850, 269097X-----------------X---X
Labeo longipinnis Boulenger 1898247857, 269100X---------------------X
Labeo cf. lukulae Boulenger 1902253465, 269104X----------------------
Labeo lukulae Boulenger 1902253465X---------------------X
Labeo luluae Fowler, 1930269111, 247862, 269106X--------------------XX
Cyprinidae (continue)
Labeo parvus Boulenger 1902269108X-X-X----------------XX
Labeo sp. nov. (Liyandja in Prep)247858, 251173X----------------------
Labeo altivelis Boulenger 1909252632X--------------------XX
Labeobarbus caudovittatus (Boulenger 1902)247498, 269115XX--X--------X---XX---X
Labeobarbus macrolepidotus (Pellegrin 1928)247423, 269121X------------X------XXX
Leptocypris weynsii (Boulenger 1899)243660, 253039X--X-------------- ---X
Opsaridium boweni (Fowler 1930)247516, 269118X-------X-X---X---X--XX
Opsaridium ubangiense (Pellegrin 1901)253198, 247476, 253277X-X-X-X---X-XX--X-XXXXX
Raiamas branchrhabdotus Katemo, Snoeks, Chocha, and Vreven 2018252754, 251232, 253153 X-----X-------------X-X
CHARACIFORMES (38)
Citharinidae (1)
Citharinus gibbosus Boulenger 1899252624, 269038, 269037X--------------------XX
Distichodontidae (19)
Distichodus affinis Günther 1873 247827, 247828X---------------------X
Distichodus antonii Schilthuis 1891 252719, 253113X---------------------X
Distichodus atroventralis Boulenger 1898 252619X---------------------X
Distichodus fasciolatus Boulenger 1898251196, 247835X-------X-X---X---XXXXX
Distichodus lusosso Schilthuis 1891252809, 253016, 253050------------------X--XX
Distichodus kasaiensis Moelants, Snoeks, and Vreven 2018247825, 243646, 251289X-------------X-------X
Distichodus maculatus Boulenger 1899253111, 252806X-----------------X--XX
Distichodus polli Abwe, Snoeks, Chocha, and Vreven 2019247831, 269041X---------------------X
Distichodus sexfasciatus Boulenger 1897269045, 252721X-----------------X--XX
Eugnathichthys eetveldii Boulenger 1898 253161, 243649X---------------------X
Eugnathichthys macroterolepis Boulenger 1899 253152, 252805X-----------------X---X
Mesoborus crocodilus Pellegrin 1900247838, 252622X--------- XXX-------XX
Nannocharax brevis Boulenger 1902243637X---------------------X
Nannocharax elongatus Boulenger 1900 252784, 251091X---------------------X
Nannocharax macropterus Pellegrin 1926 247846, 253326X---------------------X
Nannocharax procatopus Boulenger 1920 251056, 269051X---------------------X
Nannocharax taenia Boulenger 1902253326X---------------------X
Nannocharax uniocellatus (Pellegrin 1926) 252717, 252623X---------------------X
Phago boulengeri Schilthuis 1891253048X---------------------X
Alestidae (18)
Alestes liebrechtsii Boulenger 1898247414, 243618X---------X--X----X-XXX
Alestes macrophthalmus Günther 1867253147, 252817, 252740X---------X-------X---X
Bathyaethiops breuseghemi (Poll 1945)253472X--------------------XX
Brachypetersius altus (Boulenger 1899) 247505, 247440X-X---X-X-X-----------X
Brycinus comptus (Roberts and Stewart 1976) 252749, 253151X-----X---------------X
Brycinus grandisquamis (Boulenger 1899)251080, 252644X--X----X-----X------XX
Brycinus humilis (Boulenger 1905)247527, 252649X-------------X------XX
Brycinus imberi (Peters 1852)247774, 247536X-X---X-X---------XX-XX
Brycinus kingsleyae (Günther 1896) 252787, 251301X-------X--X-X--------X
Brycinus macrolepidotus (Valenciennes 1850)247771, 252823X-----X-----------X--XX
Bryconaethiops boulengeri Pellegrin 1900247777, 247510X-X--- ---XXX-X------XX
Bryconaethiops macrops Boulenger 1920 243638, 243600X----- ---------------X
Bryconaethiops microstoma Günther 1873247775, 247506X-X---X-X------------XX
Hydrocynus goliath Boulenger 1898 252594, 253359X---------------------X
Hydrocynus vittatus Castelnau 1861269033, 253159X----- --------------XX
Micralestes acutidens (Peters 1852)252750, 252598X-----X--------------XX
Micralestes stormsi Boulenger 1902251208, 248760X-X---X-X-XX-XX-----XXX
Phenacogrammus interruptus (Boulenger 1899) 252593X---------------------X
SILURIFORMES (49)
Bagridae (1)
Bagrus ubangensis Boulenger 1902 252642, 247508X---------------------X
Clariidae (8)
Channallabes apus (Günther 1873)253186------------X--------XX
Clariallabes variabilis Pellegrin 1926253313------------X---------X
Clarias camerunensis Lönnberg 1895252801-----------X---------XX
Clarias gariepinus (Burchell 1822)252658, 253031X--X-X---------------XX
Clarias pachynema Boulenger 1903 247530, 243989X--X----------X-------X
Clarias platycephalus Boulenger 1902 247473, 253187XX----------XX---X-X--X
Clarias theodorae Weber 1897243628X----X-----X----------X
Heterobranchus longifilis Valenciennes 1840252657, 269135X--X-X-------------X-XX
Amphiliidae (7)
Amphilius maesii Boulenger 1919247495, 253183, 253314-------------X---X----X
Amphilius zairensis Skelton 1986252831-X---------------------
Belonoglanis tenuis Boulenger 1902251238, 251305X--------------------XX
Congoglanis alula (Nichols and Griscom 1917) 243604, 269124, 253215XX-----------XX-------X
Phractura scaphyrhynchura (Vaillant 1886)253185------------X---------X
Tetracamphilus sp. “Lulua” 252785X----------------------
Zaireichthys flavomaculatus (Pellegrin 1926)2474745, 253301, 253199------------XX-------XX
Malapteruridae (3)
Malapterurus monsembeensis Roberts 2000247425, 269142X---------------------X
Malapterurus microstoma Poll and Gosse 1969 247497, 253122X--X----------X-------X
Paradoxoglanis parvus Norris 2002270504X----------------------
Mochokidae (17)
Atopochilus dybowskii (Vaillant 1892) 251288, 269144X----------------------
Chiloglanis micropogon Poll 1952 243997, 251195X-X-----------X-----X-X
Chiloglanis sp.”Lulua” 253219, 251283X-------------X-----X--
Euchilichthys astatodon (Pellegrin 1928) 251245, 253220X---------------------X
Euchilichthys boulengeri Nichols and La Monte 1934251079, 251244X------------XX------XX
Synodontis acanthomias Boulenger 1899 251124X---------------------X
Synodontis alberti Schilthuis 1891 252599X---------------------X
Synodontis angelicus Schilthuis 1891247520--------------X------XX
Synodontis congicus Poll 1971 252600X---------------------X
Synodontis greshoffi Schilthuis 1891247442, 253123X-------------X------XX
Synodontis nigriventris David 1936 252602X---------------------X
Synodontis notatus Vaillant 1893252601X--------------------XX
Synodontis ornatipinnis Boulenger 1899 253345X---------------------X
Synodontis pleurops Boulenger 1897253308X--------------------XX
Synodontis smiti Boulenger 1902251062, 247521, 269154--------------X--------
Synodontis soloni Boulenger 1899 269154X----------------------
Synodontis cf. smiti Boulenger 1902247521, 269158X-------------X--------
Claroteidae (7)
Auchenoglanis occidentalis (Valenciennes 1840)269141, 247431X--------------------XX
Chrysichthys cranchii (Leach 1818) 247765, 253254X-------X-----X---X---X
Chrysichthys cf. duttoni Boulenger 1905251154X----------------------
Claroteidae (continue)
Chrysichthys duttoni Boulenger 1905252634X--------------------XX
Chrysichthys longipinnis (Boulenger 1899)252744------X----------------
Parauchenoglanis ngamensis (Boulenger 1911) 252635, 253335X---------X-------X---X
Parauchenoglanis punctatus (Boulenger 1902)247512, 247429X-------------X---XX-XX
Schilbeidae (6)
Parailia congica Boulenger 1899 252616X---------------------X
Pareutropius debauwi (Boulenger 1900) 247460, 269159X---X------X--X-------X
Schilbe congensis (Leach 1818) 251107X----------------------
Schilbe grenfelli (Boulenger 1900)251102, 253154, 253755X-----X--------------XX
Schilbe marmoratus Boulenger 1911 252617, 253042X---------------------X
Schilbe yangambianus (Poll 1954)253325X--------------------XX
SYNBRANCHIFORMES (1)
Mastacembelidae (1)
Mastacembelus congicus Boulenger 1896247514, 252647X-X-X-----X---X------XX
ANABANTIFORMES (8)
Anabantidae (6)
Ctenopoma acutirostre Pellegrin 189925263, 253307, 253045X--------------------XX
Ctenopoma gabonense Günther 1896 251312X----------------------
Ctenopoma kingsleyae Günther 1896 252591, 253046, 252591X---------------------X
Ctenopoma multispine Peters 184425321, 253342, 253040X--X-X-------------X-XX
Microctenopoma nanum (Günther 1896)253316, 269209, 253316---------X--X--------XX
Microctenopoma nigricans Norris 1995247474, 252804, 269221XX-X-X----XX-X-X-X-X-XX
Channidae (2)
Parachanna insignis (Sauvage 1884) 252590X----------------------
Parachanna obscura (Günther 1861)253306, 253041X--------------------XX
CICHLIFORMES (12)
Cichlidae (12)
Coptodon congica (Poll and Thys van den Audenaerde 1960)247794, 253420X----X-----XXX-X-----XX
Coptodon rendalli (Boulenger 1897)243980, 269195X--X---X-----X-------XX
Ctenochromis luluae (Fowler 1930)269177, 269248-----X---X-----------XX
Hemichromis elongatus (Guichenot 1861)253310X--------------------XX
Nanochromis nudiceps (Boulenger 1899) 253474, 253061X---------------------X
Oreochromis niloticus (Linneaus 1758) 247842, 253426X--X-X---- ----------XX
Pharyngochromis acuticeps (Steindachner 1866) 253118X----------------------
Pseudocrenilabrus philander(Weber 1897)243677, 247805, 253182---X---X-- -X--X------X
Steatocranus rouxi (Pellegrin 1928)247805, 251054, 251114X-X-------X---X-----XXX
Teleogramma monogramma (Pellegrin 1927)247532, 247819X--------- ---X------XX
Tilapia sparrmanii Smith 1840253416, 253432X-------X-XX---------XX
Thoracochromis stigmatogenys (Boulenger 1913)243679, 24367, 252639X--XX-----X -XX-X-X--XX
CYPRINODONTIFORMES (8)
Nothobranchiidae (3)
Epiplatys atractus Van Der Zee, Mbimbi, and Sonnenberg 2013253839, 253840-------X---XXX--------X
Nothobranchiidae (continued)
Epiplatys multifasciatus (Boulenger 1913)253038, 257173X--X-X---X-----------XX
Epiplatys sp. “pale” Van Der Zee, Mbimbi and Sonnenberg (in prep.)252449, 252459---X-X----X------------
Poeciliidae (5)
Hypsopanchax jobaerti Poll and Lambert 1965252845, 247914-------------X-X-X-----
Hypsopanchax jubbi Poll and Lambert 1965252456X--------------------XX
Hypsopanchax stiassnyaeVan Der Zee, Sonnenberg, and Mbimbi 2015253037, 252441-------------X--------X
Lacustriolasp.269241, 269169---X-X---X-------------
Micropanchaxsp.269173, 269245---------X-------------
TETRAODONTIFORMES (1)
Tetraodontidae (1)
Tetraodon miurus Boulenger 1902 252629X---------------------X

Appendix B

Figure A1. Google Earth projections and biotopes of the collection sites located along the main channel of the LR: (A,B) Luebo (Site 1); (C,D) Katende (Site 8); (E,F) Dipumu (Site 5); (G,H) Beya (Site 2).
Figure A1. Google Earth projections and biotopes of the collection sites located along the main channel of the LR: (A,B) Luebo (Site 1); (C,D) Katende (Site 8); (E,F) Dipumu (Site 5); (G,H) Beya (Site 2).
Diversity 13 00341 g0a1
Figure A2. Biotopes of collection sites located in tributaries and sub-tributaries of the LR: (A) Lubi River (Site 24); (B) Luna River (Site 39); (C) Luyenga River (Site 28); (D) Tshimayi River (Site 31); (E) Mikindimbua River (Site 30); (F) Mukundulu River (Site 42); (G) Kabikonyi River (Site 41); (H) Tukomba River (Site 17).
Figure A2. Biotopes of collection sites located in tributaries and sub-tributaries of the LR: (A) Lubi River (Site 24); (B) Luna River (Site 39); (C) Luyenga River (Site 28); (D) Tshimayi River (Site 31); (E) Mikindimbua River (Site 30); (F) Mukundulu River (Site 42); (G) Kabikonyi River (Site 41); (H) Tukomba River (Site 17).
Diversity 13 00341 g0a2
Figure A3. Fishing techniques: (A) cast net fishing; (B) passive basket fishing (traps) used in lotic habitat; (C) passive basket fishing (traps) in rapids and waterfalls; (D) active basket fishing in shallow stream; (E) active basket fishing in shallow ponds; (F) dip and seine net fishing.
Figure A3. Fishing techniques: (A) cast net fishing; (B) passive basket fishing (traps) used in lotic habitat; (C) passive basket fishing (traps) in rapids and waterfalls; (D) active basket fishing in shallow stream; (E) active basket fishing in shallow ponds; (F) dip and seine net fishing.
Diversity 13 00341 g0a3
Figure A4. Selected species reported for the first time in the Kasai ecoregion: (A) Clypeobarbus mediosquamatus; (B) Enteromius thamalakanensis; (C) Enteromius sp. “purple stripe”; (D) Garra cf. congoensis; (E) Pollimyrus castelnaui; (F) Campylomormyrus curvirostris; (G) Cyphomyrus cubangoensis; (H) Distichodus polli. Photographed immediately postmortem, scale = 1 cm.
Figure A4. Selected species reported for the first time in the Kasai ecoregion: (A) Clypeobarbus mediosquamatus; (B) Enteromius thamalakanensis; (C) Enteromius sp. “purple stripe”; (D) Garra cf. congoensis; (E) Pollimyrus castelnaui; (F) Campylomormyrus curvirostris; (G) Cyphomyrus cubangoensis; (H) Distichodus polli. Photographed immediately postmortem, scale = 1 cm.
Diversity 13 00341 g0a4
Figure A5. Selected species shared with the Zambezi headwaters: (A) Coptodon rendalli (B) Pseudocrenilabus philander (C) Enteromius brevidorsalis (D) Enteromius chiumbeensis (E) Enteromius paludinosus (F) Enteromius bifrenatus (G) Microctenopoma nigricans (H) Hypsopanchax jubbi. Photographed immediately postmortem, scale = 1 cm.
Figure A5. Selected species shared with the Zambezi headwaters: (A) Coptodon rendalli (B) Pseudocrenilabus philander (C) Enteromius brevidorsalis (D) Enteromius chiumbeensis (E) Enteromius paludinosus (F) Enteromius bifrenatus (G) Microctenopoma nigricans (H) Hypsopanchax jubbi. Photographed immediately postmortem, scale = 1 cm.
Diversity 13 00341 g0a5
Figure A6. Selected endemic species of the LR: (A) Steatocranus rouxi (B) Ctenochromis luluae (C) Opsaridium boweni (D) Labeo luluae (E) Epiplatys atractus (F) Epiplatys sp “pale”. (G) Hypsopanchanx stiassnyae (H) Micropanchax sp. Photographed immediately postmortem, scale = 1 cm.
Figure A6. Selected endemic species of the LR: (A) Steatocranus rouxi (B) Ctenochromis luluae (C) Opsaridium boweni (D) Labeo luluae (E) Epiplatys atractus (F) Epiplatys sp “pale”. (G) Hypsopanchanx stiassnyae (H) Micropanchax sp. Photographed immediately postmortem, scale = 1 cm.
Diversity 13 00341 g0a6
Figure A7. Selected images of some human activities with direct and indirect impacts on the ichthyofauna of the LR. (A,B) Shifting agriculture, (C,D) Brick fabrication and clay mining, (E,F) Artisanal diamond mining, (G) Dam prepared for fishing, (H) Vegetal ichthyocide preparation just before use in fishing.
Figure A7. Selected images of some human activities with direct and indirect impacts on the ichthyofauna of the LR. (A,B) Shifting agriculture, (C,D) Brick fabrication and clay mining, (E,F) Artisanal diamond mining, (G) Dam prepared for fishing, (H) Vegetal ichthyocide preparation just before use in fishing.
Diversity 13 00341 g0a7
Figure A8. Map of the lower Lulua River showing locations of selected anthropogenic activities in the sampling area.
Figure A8. Map of the lower Lulua River showing locations of selected anthropogenic activities in the sampling area.
Diversity 13 00341 g0a8

References

  1. Harrison, I.J.; Brummett, R.; Stiassny, M.L.J. The Congo River Basin. In The Wetland Book; Finlayson, C.M., Milton, G.R., Prentice, R.C., Davidson, N.C., Eds.; Springer: Berlin/Heidelberg, Germany, 2016; pp. 1–18. [Google Scholar] [CrossRef]
  2. Winemiller, K.O.; McIntyre, P.B.; Castello, L.; Fluet-Chounard, E.; Giarrizo, T.; Nam, S.; Baird, I.G.; Darwall, W.; Lujan, N.K.; Harrison, I.; et al. Balancing hydropower and biodiversity in the Amazon, Congo, and Mekong. Science 2016, 351, 128–129. [Google Scholar] [CrossRef] [Green Version]
  3. Snoeks, J.; Harrison, I.J.; Stiassny, M.L.J. The status and distribution of freshwater fishes. In The Diversity of Life in Africa Freshwaters: Under Water, Under Threat; Allen, D.J., Brooks, E.G.E., Darwall, W.R.T., Harrison, I.J., Holland, R.A., Smith, K.G., Eds.; IUCN: Gland, Switzerland; Cambridge, UK, 2011; pp. 42–87. Available online: https://portals.iucn.org/library/node/9409 (accessed on 2 June 2021).
  4. Campbell, D. The Congo River basin. In The World’s Largest Wetlands: Ecology and Conservation; Fraser, L.H., Keddy, P.A., Eds.; Cambridge University Press: Cambridge, UK, 2005; pp. 149–165. [Google Scholar] [CrossRef]
  5. Runge, J. The Congo River, Central Africa. In Large Rivers: Geomorphology and Management; Gupta, A., Ed.; Wiley: New York, NY, USA, 2007; pp. 293–309. [Google Scholar] [CrossRef]
  6. Dai, A.; Trenberth, K.E. Estimates of freshwater discharge from continents: Latitudinal and seasonal variations. J. Hydrometeorol. 2002, 3, 660–687. [Google Scholar] [CrossRef] [Green Version]
  7. Alter, S.E.; Munshi-South, J.; Stiassny, M.L.J. Genomewide SNP Data Reveal Cryptic Phylogeographic Structure and Microallopatric Divergence in a Rapids-Adapted Clade of Cichlids from the Congo River. Mol. Ecol. 2017, 26, 1401–1419. [Google Scholar] [CrossRef]
  8. Stiassny, M.L.J.; Alter, S.E. Life in the fast lane: Diversity, ecology and speciation of cichlids in the lower Congo River. In The Behavior, Ecology and Evolution of Cichlid Fishes: A Contenporary Modern Synthesis; Abate, M.E., Noakes, D.L.G., Eds.; Springer Academic: Berlin/Heidelberg, Germany, in press.
  9. Thieme, M.L.; Abell, R.; Stiassny, M.L.J.; Skelton, P.; Lehner, B.; Teugels, G.G.; Dinerstein, E.; Kamdem-Toham, A.; Burgess, N.; Olson, D. Freshwater Ecoregions of Africa and Madagascar: A Conservation Assessment; Island Press: Washington, DC, USA, 2005; p. 483. [Google Scholar]
  10. Stiassny, M.L.J.; Brummett, R.E.; Harrison, I.J.; Monsembula, R.; Mamonekene, V. The Status and Distribution of Freshwater Fishes in Central Africa. In The Status and Distribution of Freshwater Biodiversity in Central Africa; Brooks, E.G.E., Allen, D.J., Darwall, W.R.T., Eds.; IUCN: Gland, Switzerland; Cambridge, UK, 2011; pp. 27–47. [Google Scholar]
  11. Paugy, D. An Historical Review of African Freshwater Ichthyology. Freshw. Rev. 2010, 3, 1–32. [Google Scholar] [CrossRef]
  12. Teugels, G.G.; Guégan, J.-F. Diversité Biologique Des Poissons d’eaux Douces de La Basse-Guinée et de l’Afrique Centrale. Ann. Musée R. D’afrique Centrale. Sci. Zool. 1994, 275, 67–85. Available online: https://www.documentation.ird.fr/hor/fdi:010021353 (accessed on 2 June 2021).
  13. Boulenger, G.A. Les Poissons du Basin du Congo; Etat Independant du Congo: Bruxelles, Belgium, 1901; p. 420.
  14. Fowler, H.W. The Fresh-Water Fishes Obtained by the Gray African Expedition: 1929. With Notes on Other Species in the Academy Collection. Proc. Acad. Nat. Sci. Phila. 1930, 82, 27–83. Available online: http://www.jstor.com/stable/4064060 (accessed on 2 June 2021).
  15. Poll, M. Recherche sur la faune ichtyologique de la région du Stanley Pool. Ann. Mus. Congo Séries Sci. Zool. 1959, 71, 75–174. [Google Scholar]
  16. Poll, M.; Gosse, J.P. Contribution à l’étude systématique de la faune ichthyologique du Congo central. Ann. Mus. R. Afr. Centr. Série Sci. Zool. 1963, 116, 43–110. [Google Scholar]
  17. Matthes, H. Les poissons du lac Tumba et de la région d’Ikela: Étude systématique et écologique. Ann. Mus. R. Afr. Centr. Série Sci. Zool. 1964, 126, 1–204. [Google Scholar]
  18. Gosse, J.-P. Les poissons du bassin de l’Ubangi. Mus. R. Afr. Centr. Doc. Zool. 1968, 13, 1–56. [Google Scholar]
  19. Stewart, D.J.; Roberts, T.R. An Ecological and Systematic Survey of Fishes in the Rapids of the Lower Zaire or Congo River. Bull. Mus. Comp. Zool. 1976, 147, 239–317. [Google Scholar]
  20. Poll, M. Exploration du Parc National de l’Upemba—Mission G.F.; Fondation pour favoriser les Recherches Scientifiques en Afrique: Bruxelles, Belgium, 1976; Volume 73, p. 127. [Google Scholar]
  21. Banister, K.E.; Bailey, R.G. Fishes collected by the Zaire River Expedition 1974–75. Zool. J. Linn. Soc. 1979, 66, 205–249. [Google Scholar] [CrossRef]
  22. Balon, E.K.; Stewart, D.J. Fish assemblages in a river with unusual gradient (Luongo, Africa-Zaire system), reflections on river zonation, and description of another new species. Environ. Biol. Fishes 1983, 9, 225–252. [Google Scholar] [CrossRef]
  23. Kisekelwa, T.; Isumbisho, M.; Ntakimazi, G.; Micha, J.-C. Preliminary assessment of fish diversity in Lowa River. Bull. Sci. Inst. Natl. Environ. Conserv. Nat. 2013, 12, 17–24. [Google Scholar]
  24. Kisekelwa, T.; Snoeks, J.; Vreven, E. An annotated checklist of the fish fauna of the river systems draining the Kahuzi-Biega National Park (Upper Congo: Eastern DR Congo). J. Fish Biol. 2020, 96, 700–721. [Google Scholar] [CrossRef] [PubMed]
  25. Skelton, P.H. The Freshwater Fishes of Angola. In Biodiversity of Angola, Science & Conservation: A Mordern Synthesis; Huntley, B.J., Russo, V., Lages, F., Ferrand, N., Eds.; Springer: Cham, Switzerland, 2019; p. 604. [Google Scholar] [CrossRef] [Green Version]
  26. Decru, E.; Vreven, E.; Danadu, C.; Walanga, A.; Mambo, T.; Snoeks, J. Ichthyofauna of the itimbiri, aruwimi, and lindi/tshopo rivers (Congo basin): Diversity and distribution patterns. Acta Ichthyol. Piscat. 2017, 47, 225–247. [Google Scholar] [CrossRef] [Green Version]
  27. Mbimbi, J.J.M.M.; Stiassny, M.L.J. Fishes of the Kwilu River (Kasai basin, Central Africa): A list of species collected in the vicinity of Kikwit, Bandundu Province, Democratic Republic of Congo. Check List 2011, 7, 691–699. [Google Scholar] [CrossRef] [Green Version]
  28. Monsembula Iyaba, R.J.C.; Liyandja, T.; Stiassny, M.L.J. Fishes of the N’sele River (Pool Malebo, Congo basin, Central Africa): A list of species collected in the main channel and affluent tributaries, Kinshasa Province, Democratic Republic of Congo. Check List 2013, 9, 941–956. [Google Scholar] [CrossRef] [Green Version]
  29. Monsembula Iyaba, R.J.C.; Stiassny, M.L.J. Fishes of the Salonga National Park (Congo basin, central Africa): A list of species collected in the Luilaka, Salonga, and Yenge Rivers (Equateur Province, Democratic Republic of Congo). Check List 2013, 9, 246–256. [Google Scholar] [CrossRef] [Green Version]
  30. Ibala, A.Z. Faune des Poisons des Rivières Luki et Lefini (Bassin du Congo): Diversité et Ecologie. Ph.D. Thesis, Catholic University of Leuven, Leuven, Belgium, 2010. [Google Scholar]
  31. Wamuini, S.L.; Vreven, E.; Vandewalle, P.; Mutambue, S.; Snoeks, J. Contribution à la connaissance de l’ichtyofaune de l’Inkisi au Bas-Congo (RD du Congo). Cybium 2010, 34, 83–91. Available online: http://hdl.handle.net/2268/67762 (accessed on 2 June 2021).
  32. Abell, R.; Thieme, M.L.; Revenga, C.; Bryer, M.; Kottelat, M.; Bogutskaya, N.; Petry, P. Freshwater Ecoregions of the World: A New Map of Biogeographic Units for Freshwater Biodiversity Conservation. BioScience 2008, 58, 403–414. [Google Scholar] [CrossRef] [Green Version]
  33. Stiassny, M.L.J.; Mamonekene, V. Micralestes (Characiformes, Alestidae) of the lower Congo River, with a description of a new species endemic to the lower Congo River rapids in the Democratic Republic of Congo. Zootaxa 2007, 1614, 17–29. [Google Scholar] [CrossRef] [Green Version]
  34. Stiassny, M.L.J.; Alter, S.E.; Liyandja, T.L.D.; Modimo, M.Y.; Monsembula Iyaba, R.J.C. Fishes of the Mfimi River in the central Congo basin of the Democratic Republic of Congo. Kasai ecoregion or part of the Cuvette Centrale? Check List. in press.
  35. Tshitenge, J.-M.M.; Mbata, A.M.; Lukanda, V.M.; Phuku, E.P.; Kazadi, A.M.B.; Tondozi, F.K. Time-scale characteristics of Kasai river hydrological regime variability for 1940–1999. Int. J. Innov. Appl. Stud. 2016, 17, 531–547. Available online: http://arxiv.org/abs/1611.07317 (accessed on 2 June 2021).
  36. Roberts, E.; Jelsma, H.A.; Hegna, T. Mesozoic Sedimentary Cover Sequences of the Congo Basin in the Kasai Region, Democratic Republic of Congo. In Geology and Resource Potential of the Congo Basin; De Wit, J.M., Guillocheau, F., De Wit, C.J.M., Eds.; Springer: Berlin, Germany/Heidelberg, 2015; pp. 1–417. [Google Scholar] [CrossRef]
  37. Bernacsek, G.M.; Hughes, R.H.; Hughes, J.S. A Directory of AFRICAN WETLANDS; IUCN: Gland, Switzerland; UNEP: Nairobi, Kenya; WCMC: Cambridge, UK, 1992; p. 820. Available online: https://portals.iucn.org/library/node/6001 (accessed on 2 June 2021).
  38. Laghmouch, M.; Hardy, B. Carte Géologique de la République Démocrqtiaue du Congo; Musée Royal de l’Afrique Centrale: Tervuren, Belgium, 2005; Available online: https://vdocuments.mx/carte-geologique-republique-democratique-du-congo.html (accessed on 2 June 2021).
  39. Devroey, E. Le Kasai et Son Bassin Hydrographique; Boletim Meridia no 47: Bruxelles, Beligum, 1939; p. 314. [Google Scholar] [CrossRef]
  40. McManamay, R.A.; Derolph, C.R. Data descriptor: A stream classification system for the conterminous United States. Sci. Data 2019, 6, 1–18. [Google Scholar] [CrossRef] [Green Version]
  41. Lang, M.A.; Baldwin, C.C. Methods and Techniques of Underwater Research. In Proceedings of the American Academy of Underwater Sciences Scientific Diving Symposium, Washington, DC, USA, 12–13 October 1996; p. 236. [Google Scholar]
  42. Robertson, D.R.; Smith-Vaniz, W.F. Rotenone: An essential but demonized tool for assessing marine fish diversity. BioScience 2008, 58, 165–170. [Google Scholar] [CrossRef] [Green Version]
  43. Bennett, R.H.; Ellender, B.R.; Mäkinen, T.; Miya, T.; Pattrick, P.; Wasserman, R.J.; Woodford, D.J.; Weyl, O.L.F. Ethical considerations for field research on fishes. Koedoe 2016, 58, 1–15. [Google Scholar] [CrossRef] [Green Version]
  44. Jenkins, J.A.; Bart, H.L.; Bowker, J.D.; Bowser, P.R.; MacMillan, J.R.; Nickum, J.G.; Rose, J.D.; Sorensen, P.W.; Whitledge, G.W. Guidelines for Use of Fishes in Research—Revised and Expanded, 2014. Fisheries 2014, 39, 415–416. [Google Scholar] [CrossRef]
  45. Fricke, R.; Eschmeyer, W.N.; Van der Laan, R. Eschmeyer’s Catalog of Fishes: Genera, Species, References. Available online: http://researcharchive.calacademy.org/research/ichthyology/catalog/fishcatmain.asp (accessed on 10 June 2021).
  46. Boulenger, G.A. Catalogue of the Fresh-Water Fishes of Africa in the British Museum; Trustees: London, UK, 1909; Volume I, p. 373. [Google Scholar]
  47. Roberts, T.R. Systematics and osteology of Leptoglaninae a new subfamily of the African catfish family Amphiliidae, with descriptions of three new genera and six new species. Proc. Calif. Acad. Sci. 2003, 54, 81–132. Available online: https://www.biodiversitylibrary.org/part/118630 (accessed on 10 June 2021).
  48. Tshibwabwa, S.M. Systématique des Espèces Africaines du Genre Labeo (Teleostei; Cyprinide) dans les Régions Ichtyogéographiques de Basse-Guinée et du Congo; Presses Universitaires de Namur: Namur, Belgique, 1997; Volumes 1 and 2, p. 529. [Google Scholar]
  49. Poll, M. Contribution à la Faune Ichthyologique de l’Angola; Companhia de Diamantes de Angola: Lisbon, Portugal, 1967; pp. 1–381. Available online: http://mormyrids.myspecies.info/sites/mormyrids.myspecies.info/files/Poll_1967_optimized.pdf (accessed on 10 June 2021).
  50. Poll, M. Revision des Synodontis Afiricains (Famille Mochocidae). Ann. Mus. R. Afr. Centr. Sci. Zool. 1971, 191, 1–497. [Google Scholar]
  51. Skelton, P.H. A Complete Guide to the Freshwater Fishes of Southern Africa, 2nd ed.; Struik Publishers: Cape Town, South Africa, 2001; pp. 1–397. [Google Scholar]
  52. Teugels, G.G. A systematic revision of the African species of the genus Clarias (Pisces; Clariidae). Ann. Mus. R. Afr. Centr. 1986, 247, 1–199. [Google Scholar]
  53. De Vos, L. A systematic revision of the African Schilbeidae (Teleostei, Siluriformes): With an annotated bibliography. Ann. Mus. R. Afr. Centr. 1995, 271, 1–450. [Google Scholar]
  54. Norris, S.M. A revision of the African electric catfishes, Family Malapteruridae (Teleostei, Siluriformes), with erection of a new genus and descriptions of fourteen new species, and an annotated bibliography. K. Mus. Midden Afr. Tervuren 2002, 289, 1–155. [Google Scholar]
  55. Stiassny, M.L.J. A taxonomic revision of the African genus Tylochromis (Labroidei, Cichlidae), with notes on the anatomy and relationships of the group. Ann. Mus. R. Afr. Centr. Zool. 1989, 8, 1–161. [Google Scholar]
  56. Boden, G.; Teugels, G.G.; Hopkins, C.D. A systematic revision of the large-scaled Marcusenius with description of a new species from Cameroon (Teleostei; Osteoglossomorpha; Mormyridae). J. Nat. Hist. 1997, 31, 1645–1682. [Google Scholar] [CrossRef]
  57. Lavoué, S.; Sullivan, J.P. Petrocephalus boboto and Petrocephalus arnegardi, two new species of African electric fish (Osteoglossomorpha, Mormyridae) from the Congo River basin. ZooKeys 2014, 400, 43–60. [Google Scholar] [CrossRef] [Green Version]
  58. Gourène, G.; Teugels, G.G. Synopsis de la classification et phylogénie des Pellonulinae de l’Afrique Occidentale et Centrale (Teleostei; Clupeidae). J. Afr. Zool. 1994, 108, 77–91. [Google Scholar]
  59. Moelants, T.; Mbadu, V.Z.; Snoeks, J.; Vreven, E. A review of the Distichodus antonii assemblage (Characiformes: Distichodontidae) from the Congo basin. J. Nat. Hist. 2014, 48, 1707–1735. [Google Scholar] [CrossRef]
  60. Moelants, T.; Snoeks, J.; Vreven, E. Distichodus kasaiensis and D. ingae, two new distichodontid species (Characiformes: Distichodontidae) from the Congo basin. Icthyol. Explor. Freshwater 2018, 28, 177–192. [Google Scholar] [CrossRef]
  61. Lévêque, C.; Paugy, D. Caractéristiques générales de la faune ichtyologique. In Les Poissons des Eaux Continentales Africaines: Diversité, Ecologie, Utilisation par L’homme, 2nd ed.; Lévêque, C., Paugy, D., Eds.; IRD: Paris, France, 2006; pp. 45–57. [Google Scholar]
  62. Froese, R.; Pauly, D. Fishbase. Available online: http://www.fishbase.org (accessed on 10 June 2021).
  63. Stiassny, M.L.J.; Teugels, G.G.; Hopkins, C.D. The Fresh and Brackish Water Fishes of Lower Guinea, West-Central Africa; IRD Éditions: Paris, France, 2007; Volumes I and II, p. 1403.
  64. Bell-Cross, G. Movemnet of fish across the Congo-Zambezi watershed in the Mwinilunga district of Northern Rhodesia. Proc. Cent. Afr. Sci. Med Congr. Lusaka North. Rhod. 1965, 1965, 415–424. [Google Scholar]
  65. Moore, A.E.; Larkin, P.A. Drainage evolution in south-central Africa since the breakup of Gondwana. S. Afr. J. Geol. 2001, 104, 47–68. [Google Scholar] [CrossRef]
  66. Stankiewicz, J.; de Wit, M.J. A proposed drainage evolution model for Central Africa -Did the Congo flow east? J. Afr. Earth Sci. 2006, 44, 75–84. [Google Scholar] [CrossRef]
  67. Tweddle, D. Overview of the Zambezi River system: Its history, fish fauna, fisheries, and conservation. Aquat. Ecosyst. Health Manag. 2010, 13, 224–240. [Google Scholar] [CrossRef]
  68. Boulenger, G.A. Description d’un poisson nouveau receuilli à Luluabourg (Congo Belge). Rev. Zool. Afr. 1913, 2, 394–395. [Google Scholar]
  69. Nichols, J.T.; LaMonte, F.R. New fishes from the Kasai district of the Belgian Congo. Am. Mus. Novit. 1933, 7, 1–6. Available online: http://hdl.handle.net/2246/2068 (accessed on 10 June 2021).
  70. Nichols, J.T.; LaMonte, F.R. More new fishes from the Kasai District of the Belgian Congo. Am. Mus. Novit. 1934, 7, 1–6. Available online: http://hdl.handle.net/2246/4609 (accessed on 10 June 2021).
  71. Worm, B.; Duffy, J.E. Biodiversity, productivity and stability in real food webs. Trends Ecol. Evol. 2003, 18, 628–632. [Google Scholar] [CrossRef]
  72. Brooks, E.G.E.; Allen, D.J.; Darwall, W.R.T. The Status and Distribution of Freshwater Biodiversity in Central Africa; IUCN: Gland, Switzerland; Cambridge, UK, 2011; p. 126. [Google Scholar]
  73. Stiassny, M.L.J.; Sakharova, H. Review of the smiliogastrin cyprinids of the Kwilu River (Kasai Basin, central Africa), revised diagnosis for Clypeobarbus (Cyprinidae: Cyprininae: Smiliogastrini) and description of a new species. J. Fish Biol. 2016, 88, 1394–1412. [Google Scholar] [CrossRef]
  74. Katemo Manda, B.; Snoeks, J.; Chocha Manda, A.; Vreven, E. Hidden species diversity in Raiamas salmoducius (Teleostei: Cyprinidae) from the Congo basin: Two new species based on morphometric evidence. Icthyol. Explor. Freshw. 2018, 28, 345–363. [Google Scholar] [CrossRef]
  75. Abwe, E.; Snoeks, J.; Chocha Manda, A.; Vreven, E. Distichodus polli, a new distichodontid species (Teleostei: Characiformes) from the southern Congo basin. Icthyol. Explor. Freshw. 2019, 29, 79–96. [Google Scholar] [CrossRef]
  76. Lowenstein, J.H.; Osmundson, T.W.; Becker, S.; Hanner, R.; Stiassny, M.L.J. Incorporating DNA barcodes into a multi-year inventory of the fishes of the hyperdiverse Lower Congo River, with a multi-gene performance assessment of the genus Labeo as a case study. Mitochondrial DNA 2011, 22 (Suppl. 1), 52–70. [Google Scholar] [CrossRef] [PubMed]
  77. Decru, E.; Moelants, T.; De Gelas, K.; Vreven, E.; Verheyen, E.; Snoeks, J. Taxonomic challenges in freshwater fishes: A mismatch between morphology and DNA barcoding in fish of the north-eastern part of the Congo basin. Mol. Ecol. Resour. 2016, 16, 342–352. [Google Scholar] [CrossRef] [PubMed]
  78. Arroyave, J.; Martinez, C.M.; Stiassny, M.L.J. DNA barcoding uncovers extensive cryptic diversity in the African long-fin tetra Bryconalestes longipinnis (Alestidae: Characiformes). J. Fish Biol. 2019, 95, 1–14. [Google Scholar] [CrossRef] [PubMed]
  79. Bragança, P.H.N.; Van der Zee, J.; Chakona, A.; Schmidt, R.C.; Stiassny, M.L.J. Following the Mangroves: Diversification in the banded lampeye Aplocheilichthys spilauchen (Duméril, 1861) (Cyprinodontiformes: Procatopodidae) along the Atlantic coast of Africa. Hydrobiologia 2021, 848, 1433–1453. [Google Scholar] [CrossRef]
  80. Nguimalet, C.R. Diamond mining impacts and dynamics in river beds: The Boungou and Pipi rivers in Central African Republic. Revue Geo. Eco. Trop. 2004, 28, 39–52. Available online: http://www.geoecotrop.be/uploads/publications/pub_281_04.pdf (accessed on 20 June 2021).
  81. Lévêque, C.; Paugy, D. Impacts des activités humaines. In Les Poissons des Eaux Continentales Africaines: Diversité, Ecologie, Utilisation par L’homme, 2nd ed.; Lévêque, C., Paugy, D., Eds.; IRD: Paris, France, 2006; pp. 403–424. [Google Scholar]
  82. Epa, U.P.K.; Mohotti, C.R.W.C. Impact of fishing with Tephrosia candida (Fabaceae) on diversity and abundance of fish in the streams at the boundary of Sinharaja Man and Biosphere Forest Reserve, Sri Lanka. Rev. Biol. Trop. 2016, 64, 1129–1141. Available online: https://www.scielo.sa.cr/pdf/rbt/v64n3/0034-7744-rbt-64-03-01129.pdf (accessed on 20 June 2021).
  83. Arantes, C.C.; Fitzgerald, D.B.; Hoeinghaus, D.J.; Winemiller, K.O. Impacts of hydroelectric dams on fishes and fisheries in the tropical rivers through the lens of functional traits. Curr. Opin. Environ. Sustain. 2019, 37, 28–40. [Google Scholar] [CrossRef]
  84. The IUCN Red List of Threatened Species. Available online: https://www.iucnredlist.org (accessed on 20 June 2021).
Figure 1. Map of the Lulua River showing the location of the Lulua catchment in the Kasai ecoregion of the Congo Basin and neighboring ecoregions. The red rectangle indicates the part of the lower LR where this study was conducted.
Figure 1. Map of the Lulua River showing the location of the Lulua catchment in the Kasai ecoregion of the Congo Basin and neighboring ecoregions. The red rectangle indicates the part of the lower LR where this study was conducted.
Diversity 13 00341 g001
Figure 2. Longitudinal profile of the Lulua River and its subdivision into three sections based on the channel slope gradient.
Figure 2. Longitudinal profile of the Lulua River and its subdivision into three sections based on the channel slope gradient.
Diversity 13 00341 g002
Figure 3. Map of the LR sampling sites: (A) green circles, main channel sites; (B) red circles, tributary and sub-tributary sites.
Figure 3. Map of the LR sampling sites: (A) green circles, main channel sites; (B) red circles, tributary and sub-tributary sites.
Diversity 13 00341 g003
Figure 4. Relative representation of each order in the lower Lulua River.
Figure 4. Relative representation of each order in the lower Lulua River.
Diversity 13 00341 g004
Figure 5. Relative representation of each family in the lower Lulua River.
Figure 5. Relative representation of each family in the lower Lulua River.
Diversity 13 00341 g005
Table 1. Human activities identified in the LR valley grouped in categories following their impact on the system.
Table 1. Human activities identified in the LR valley grouped in categories following their impact on the system.
Category(1) Land Cover(2) Water Quality(3) Hydrology(4) Fish Populations
Activities
  • Shifting agriculture
  • Settlement
  • Forest exploitation

for building materials and charcoal
  • Diamond mining
  • Diamond mining
  • Clay mining
  • Large- and small-scale damming
  • Diamond mining
  • Fisheries
  • Dams
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Mbimbi Mayi Munene, J.J.; Stiassny, M.L.J.; Monsembula Iyaba, R.J.C.; Liyandja, T.L.D. Fishes of the Lower Lulua River (Kasai Basin, Central Africa): A Continental Hotspot of Ichthyofaunal Diversity under Threat. Diversity 2021, 13, 341. https://0-doi-org.brum.beds.ac.uk/10.3390/d13080341

AMA Style

Mbimbi Mayi Munene JJ, Stiassny MLJ, Monsembula Iyaba RJC, Liyandja TLD. Fishes of the Lower Lulua River (Kasai Basin, Central Africa): A Continental Hotspot of Ichthyofaunal Diversity under Threat. Diversity. 2021; 13(8):341. https://0-doi-org.brum.beds.ac.uk/10.3390/d13080341

Chicago/Turabian Style

Mbimbi Mayi Munene, José J., Melanie L. J. Stiassny, Raoul J. C. Monsembula Iyaba, and Tobit L. D. Liyandja. 2021. "Fishes of the Lower Lulua River (Kasai Basin, Central Africa): A Continental Hotspot of Ichthyofaunal Diversity under Threat" Diversity 13, no. 8: 341. https://0-doi-org.brum.beds.ac.uk/10.3390/d13080341

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop