Department of Botany and Zoology

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Browsing Department of Botany and Zoology by browse.metadata.advisor "Bates, John M."

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    Habitat fragmentation, patterns of diversity and phylogeography of small mammal species in the Albertine rift
    (Stellenbosch : Stellenbosch University, 2011-12) Kaleme, Prince K.; Jansen van Vuuren, Bettine; Bowie, Rauri C. K.; Bates, John M.; Stelenbosch University. Faculty of Science. Dept. of Botany and Zoology.
    ENGLISH ABSTRACT: The Albertine Rift is characterized by a heterogeneous landscape which may, at least in part, drive the exceptional biodiversity found across all taxonomic levels. Notwithstanding the biodiversity and beauty of the region, large areas are poorly understood because of political instability with the inaccessibility of most of the region as a contributing factor. The majority of studies in the Albertine Rift have focussed on charismatic mega fauna, with other taxa receiving less attention. One of the taxonomically and numerically more abundant small mammal genera is the genus Praomys, an African endemic with a wide distribution range spanning most of west, central and east Africa. Four species are typically recognized from the Albertine Rift namely P. degraaffi, P. jacksoni, P. misonnei and P. verschureni. In this study I used a combination of DNA sequence data (mitochondrial control region, mitochondrial cytochrome b and 7th intron of the nuclear ß-fibrinogen gene) as well as morphometric data (traditional and geometric) to investigate the systematics of the Praomys taxa occurring in the Albertine Rift. To allow meaningful DNA assessments and in an attempt to identify potential drivers of diversifications, other Praomys species were also included from public sequence data bases for comparisons. The main focus was on P. jacksoni (the numerically most abundant taxon; also, up to 2005, all Praomys in the Albertine Rift were mostly collected as “jacksoni”) and P. degraaffi (an Albertine Rift endemic). A surprising finding was the presence of P. mutoni; this represents a range extension for this species into the Albertine Rift. Distinct evolutionary lineages were found in both P. jacksoni (confirmed by sequence data as well as morphometrics) as well as P. degraaffi (based only on sequence data; insufficient samples precluded a full morphometric investigation). These lineages (in both P. jacksoni as well as P. degraaffi) appear to be separated along a north – south gradient; however, further investigations should confirm this. To further investigate the genetic patterns at local scales across the Albertine Rift, as well as introgression between species as revealed by sequence data, a species-specific microsatellite library was developed for P. jacksoni. Twelve polymorphic markers were identified of which nine also amplified in P. degraaffi. Introgression was confirmed between the two focal species with almost 20% of the individuals analysed being jacksoni-degraaffi hybrids. This is perhaps not so surprising given that there is considerable overlap in their ranges (between ~ 1500 m a.s.l. to 2450 m a.s.l.) as well as the relative ages of the species (the divergence time between these two species were estimated at 3.8 Mya). The presence of distinct lineages within each of these species was confirmed by microsatellite analyses (these lineages diverged approcimately at same time at ca. 3.4 Mya). As suggested by sequence and morphometric data, these lineages had a largely north – south distribution but with considerable overlap in the central Albertine Rift in the vicinity of Lake Kivu. The phylogeographic patterns obtained for both focal species were not consistent with the physical barriers such as the rivers, lakes or mountains, nor were they exclusively associated with Pleistocene phenomena such as the change of the course of the rivers or uplift; rather, the lineages predate the Pleistocene and fall firmly in the Pliocene (>3 Mya). Biogeographically, the north - south location of lineages with a centrally - located contact zone could be a result of parapatric speciation due to habitat fragmentation or past climate change, followed by secondary contact. Barcoding using genetic information provides a useful tool to identify unknown taxa, cryptic diversity or where different life stages are difficult to identify. From an invasion biology perspective, it allows for the rapid identification of problem taxa against a known data base. By adopting such a barcoding approach (senso lato), the presence of three invasive rodents was confirmed in the Democratic Republic of the Congo (DRC); these are Rattus rattus (black rat), R. norvegicus (Norway rat) and Mus musculus domesticus (house mouse). A comparison with global data available for these species revealed two possible introduction pathways namely via the shipping port at Kinshasa/Matadi (with strong links to Europe) and via the slave trade routes in the east (strong links to the Arab world and the east). Of these three taxa, only R. rattus is currently documented from the DRC although the others have received mention in the gray literature. These findings draw attention to the lack of any official policy regarding biosecurity in the DRC, and argue for the development of strict control measures to prevent further introductions.