Determinants of the Adult Microbiome: Kinship, Dispersal, and Social Relationships

Diakiw, Laura Oksana, Diakiw, Laura Oksana

January 2017

Primates who disperse from their natal group may shape their adult stable gut microbiome through physical contact and shared environments with their new group members. However, it is possible that individuals retain the dominant microbiome composition that they developed as an infant in their natal group even after joining their new group, due to a combination of genetic inheritance and exposure to their natal group environment. Microbial exposure during early life, before an immune system has been developed, can exert strong selection on a developing individual, in effect creating a selection bottleneck. Therefore, the environmental signals transmitted from mother to infant are critical in developing an infant’s immunocompetence. Determining what adaptations take place in an individual’s gut microbiota during their life could help determine the maternal importance of gut microbe transmissions which may be essential to the evolutionary success of a species. We studied Eulemur rubriventer (red-bellied lemurs) who live in family groups. We tested whether individuals now living in different social groups as adults overlap in microbe composition, and if areas of overlap are distinct compared with unrelated individuals. We also tested whether the gut microbiomes of co-residents (dispersed adult group-mates) would be more similar than that of individuals living in different groups. Using census and genetic data, we determined the social group membership and relatedness of 15 individuals in Ranomafana National Park, Madagascar. Quantitative real-time PCR and Microbial 16S ribosomal RNA gene sequencing indicated that E. rubriventer kinship accounted for just 2.4% of variability in gut microbiome diversity. Our findings indicate that host adult social group explained 25% of the variation in composition of E. rubriventer microbiomes. Additional research incorporating an increased sample size to include additional kin dyads is necessary to fully understand the influence of genetic kinship and early life colonization on the GI microbiome. If initial microbial colonizing species are retained in adults, this demonstrates that early life colonization can persist through adulthood and perhaps preserve important microbial species across larger evolutionary time scales.

Development

Genetic Kinship

Gut microbiome

Primates

Red-bellied lemur

Social relationships

Secrets of the deep : the molecular genetics of cryptic beaked whales

Thompson, Kirsten Freja

January 2017

Beaked whales are comparatively unknown social mammals due to their deep-ocean distribution and elusive habits. The deep-ocean is the largest biome on Earth and the final frontier for human expansion. Since their first discovery, beaked whales have remained largely hidden from science. In this era of rapid technological advancement, genetic and genomic methods are key tools for population biologists and are particularly useful in describing rarely seen species. Using DNA-barcoding and nuclear markers, the publications in this thesis provide data on the distribution and external appearance of two species of beaked whale: the spade-toothed (Mesoplodon traversii) and Derinayagala’s whale (Mesoplodon hotaula). These whales were previously known from only a handful of tissue and bone specimens. Long-term efforts have facilitated the collection of samples of Gray’s beaked whale (Mesoplodon grayi) and we have used shot-gun sequencing to characterise the mitochondrial genome and isolate species-specific nuclear microsatellite loci. Using genetic species and sex identification, together with museum specimens and multivariate analyses, we provide clear evidence of sexual dimorphism in cranial dimensions and geographic variation in external morphology. No genetic differentiation was evident in Gray’s beaked whales across a large study area (~ 6,000 km). With a large female effective population size (Ne) and genetic homogeneity, we hypothesise that gene flow is facilitated by large-scale oceanographic features, such as the sub-tropical convergence. Genetic kinship analyses within Gray’s beaked whale groups suggest that the whales that strand together are not related. Both sexes disperse from their parents and these groups are not formed through the retention of kin. These results are consistent with a ‘fission-fusion’ social system that has been observed in some oceanic dolphin species. Taken together, these data provide the first insights into the population dynamics, dispersal and social organisation in Gray’s beaked whales. These publications highlight the value of using genetics alongside other techniques to describe inter- and intraspecific diversity. For beaked whales, the dead can tell us much about the living.

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