Teresa Kearney

Diversity of Bartonella and Rickettsia spp. in Bats and Their Blood-Feeding Ectoparasites from South Africa and Swaziland

In addition to several emerging viruses, bats have been reported to host multiple bacteria but their zoonotic threats remain poorly understood, especially in Africa where the diversity of bats is important. Here, we investigated the presence and diversity of Bartonella and Rickettsia spp. in bats and their ectoparasites (Diptera and Siphonaptera) collected across South Africa and Swaziland. We collected 384 blood samples and 14 ectoparasites across 29 different bat species and found positive samples in four insectivorous and two frugivorous bat species, as well as their Nycteribiidae flies. Phylogenetic analyses revealed diverse Bartonella genotypes and one main group of Rickettsia, distinct from those previously reported in bats and their ectoparasites, and for some closely related to human pathogens. Our results suggest a differential pattern of host specificity depending on bat species. Bartonella spp. identified in bat flies and blood were identical supporting that bat flies may serve as vectors. Our results represent the first report of bat-borne Bartonella and Rickettsia spp. in these countries and highlight the potential role of bats as reservoirs of human bacterial pathogens.

The excreted microbiota of bats: evidence of niche specialisation based on multiple body habitats

&NA; Animal‐associated microbiotas form complex communities, which play crucial functions for their host, including susceptibility to infections. Despite increasing attention to bats as reservoirs of zoonotic pathogens, their microbiota is poorly documented, especially for samples potentially implicated in pathogen transmission such as urine and saliva. Here, using low‐biomass individual samples, we examined the composition and structure of bacterial communities excreted by insectivorous bats, focusing on three body habitats (saliva, urine and faeces). We show that niche specialisation occurs as bacterial community composition was distinct across body habitats with the majority of phylotypes being body habitat specific. Our results suggest that urine harbours more diverse bacterial communities than saliva and faeces and reveal potentially zoonotic bacteria such as Leptospira, Rickettsia, Bartonella and Coxiella in all body habitats. Our study emphasised that, in addition to the traditional use of gut‐associated samples such as faeces, both urine and saliva are also of interest because of their diverse microbiota and the potential transmission of pathogenic bacteria. Our results represent a critical baseline for future studies investigating the interactions between microbiota and infection dynamics in bats.

Novel Paramyxoviruses in Bats from Sub-Saharan Africa, 2007–2012

As part of a larger survey for detection of pathogens among wildlife in sub-Saharan Africa conducted during 2007–2012, multiple diverse paramyxovirus sequences were detected in renal tissues of bats. Phylogenetic analysis supports the presence of at least 2 major viral lineages and suggests that paramyxoviruses are strongly associated with several bat genera.

Synchronized shift of oral, faecal and urinary microbiotas in bats and natural infection dynamics during seasonal reproduction

Seasonal reproduction is a period of extreme physiological and behavioural changes, yet we know little about how it may affect host microbial communities (i.e. microbiota) and pathogen transmission. Here, we investigated shifts of the bacterial microbiota in saliva, urine and faeces during the seasonal reproduction of bats in South Africa, and test for an interaction in shedding patterns of both bacterial (Leptospira) and viral (adeno- and herpesviruses) agents. Based on a comparative approach in two cave-dwelling bat species and high-throughput sequencing of the 16S rRNA gene, we demonstrated a clear signature in microbiota changes over the reproduction season, consistent across the multiple body habitats investigated, and associated with the sex, age and reproductive condition of bats. We observed in parallel highly dynamic shedding patterns for both bacteria and viruses, but did not find a significant association between viral shedding and bacterial microbiota composition. Indeed, only Leptospira shedding was associated with alterations in both the diversity and composition of the urinary microbiota. These results illustrate how seasonal reproduction in bats substantially affects microbiota composition and infection dynamics, and have broad implications for the understanding of disease ecology in important reservoir hosts, such as bats.

Evolution's Chimera: Bats and the Marvel of Evolutionary Adaptation

Professor David Jacobs, of the University of Cape Town, has written a fascinating book introducing evolutionary theory primarily with examples involving bats. This combination of subjects is not surprising as Prof. Jacobs holds a South African Research Chairs Initiative Chair in Animal Evolution and Systematics, and bats have for many years been the focus of his research groups work. In this new book, evolutionary and biological concepts are clearly explained, and important terms are indicated by bold-face text making them easy to find. There is also a useful glossary at the beginning of the book, and the text is fully indexed. The text is complemented by figures that support the various explanations, and useful analogies are given throughout the book to assist in understanding the different concepts.

DNA barcoding for identification of cryptic species in the field and existing museum collections: a case study of Aethomys and Micaelamys (Rodentia: Muridae)

DNA barcoding has been proposed as a method for species identification. However, this method has been criticised for its over-reliance on a single mitochondrial gene. In this study, four mitochondrial gene regions and one nuclear gene region were used to investigate their different abilities to identify tissue associated with museum specimens of Aethomys chrysophilus, Aethomys ineptus and Micaelamys namaquensis. Aethomys chrysophilus and the more recently elevated A. ineptus are indistinguishable on morphological grounds; however, their ranges are largely parapatric with only one syntopic locality currently known. All of the mitochondrial gene regions were able to separate M. namaquensis from A. chrysophilus and A. ineptus, but they varied in their abilities to resolve differences between A. chrysophilus and A. ineptus. The sequence results identified a specimen from KwaZulu-Natal that was misclassified and should have been identified as A. ineptus. Seven specimens that had not been reclassified following the elevation of A. ineptus to species level were identified as A. ineptus. Individuals of A. chrysophilus from Malawi could not be classified as either A. chrysophilus or A. ineptus, and may be a hybrid or a new, distinct species. This study indicates that DNA barcoding may be used to separate M. namaquensis from A. chrysophilus and A. ineptus, and although it was not able to separate A. chrysophilus and A. ineptus, it did indicate specimens from Malawi may be a new cryptic species.

New records of bat species using Gatkop Cave in the maternal season

Abstract Eight bat species were recorded at Gatkop Cave, in the northern part of South Africa in December 2011 (Cloeotis percivali, Hipposideros caffer, Myotis tricolor, Miniopterus natalensis, Nycteris thebaica, Rhinolophus blasii, Rhinolophus smithersi, and Rhinolophus simulator). With the exception of M. natalensis, R. simulator and Myo. tricolor, the other five species were recorded for the first time at Gatkop Cave during this time of the year, when thousands of M. natalensis use the cave as a maternity and nursery roost. Previously it was suggested the large numbers of M. natalensis using Gatkop Cave during the maternal period excluded other bat species. The reason for this recorded change in species roost composition at Gatkop Cave during the maternal period in relation to previous records made from the late 1960s and the mid 1980s is not clear, two possible reasons are the loss of other roosts, or these species were previously present but were not captured as a result of the particular methods used.

Hidden Identities: Cryptic Species in the Otomys Genus (Cuvier 1824) (Rodentia: Muridae: Otomyinae) Revealed by Mitochondrial and Nuclear DNA in South Africa

The recent taxonomy and phylogeny of Otomyinae has been in a state of flux as new systematic revisions combining molecular, karyotypic and morphometric information have identified changes at various taxonomic levels. Currently two genera of Otomyinae and eight species of Otomys are recognized in South Africa. However, the position of Otomys sloggetti on the phylogeny of Otomyinae has not been resolved, and since this species was not well represented in recent revisions it may also reveal multiple cryptic evolutionary species. In this study four mitochondrial and one nuclear gene regions and external morphological characters were analysed to elucidate relationships within O. sloggetti, as well as between O. sloggetti and other Otomys species occurring in South Africa. The data from this study suggested O. sloggetti belongs to neither the Otomys, nor the Parotomys genera. Instead, we propose returning to the classification of Otomyinae and recognize Myotomys as the valid genus for O. sloggetti. Within O. sloggetti, our data does not support the traditional view of the distribution and intraspecific variation of the species, and invites a new hypothesis. Specimens identified in the field as O. sloggetti were found to represent two different clades. One of the clades was genetically and morphologically consistent with the description for O. sloggetti, while the other was distinct from O. sloggetti and other Otomys species known to occur in South Africa. Our data suggests that this is a novel species within the Otomys genus.