Fanglei Shi

Whole-genome sequencing of the snub-nosed monkey provides insights into folivory and evolutionary history

Colobines are a unique group of Old World monkeys that principally eat leaves and seeds rather than fruits and insects. We report the sequencing at 146× coverage, de novo assembly and analyses of the genome of a male golden snub-nosed monkey (Rhinopithecus roxellana) and resequencing at 30× coverage of three related species (Rhinopithecus bieti, Rhinopithecus brelichi and Rhinopithecus strykeri). Comparative analyses showed that Asian colobines have an enhanced ability to derive energy from fatty acids and to degrade xenobiotics. We found evidence for functional evolution in the colobine RNASE1 gene, encoding a key secretory RNase that digests the high concentrations of bacterial RNA derived from symbiotic microflora. Demographic reconstructions indicated that the profile of ancient effective population sizes for R. roxellana more closely resembles that of giant panda rather than its congeners. These findings offer new insights into the dietary adaptations and evolutionary history of colobine primates.

Population genomics reveals low genetic diversity and adaptation to hypoxia in snub-nosed monkeys

Snub-nosed monkeys (genus Rhinopithecus) are a group of endangered colobines endemic to South Asia. Here, we re-sequenced the whole genomes of 38 snub-nosed monkeys representing four species within this genus. By conducting population genomic analyses, we observed a similar load of deleterious variation in snub-nosed monkeys living in both smaller and larger populations and found that genomic diversity was lower than that reported in other primates. Reconstruction of Rhinopithecus evolutionary history suggested that episodes of climatic variation over the past 2 million years, associated with glacial advances and retreats and population isolation, have shaped snub-nosed monkey demography and evolution. We further identified several hypoxia-related genes under selection in R. bieti (black snub-nosed monkey), a species that exploits habitats higher than any other nonhuman primate. These results provide the first detailed and comprehensive genomic insights into genetic diversity, demography, genetic burden, and adaptation in this radiation of endangered primates.

Mitochondrial genome of Plateau zokor Myospalax baileyi

Plateau zokors Myospalax baileyi are subterranean rodents and endemic to the cold and hypoxic (2800–4300 m above sea level) climate of the farm, prairie, alpine prairie, and meadow habitats across the Tibetan plateau. The complete mitochondrial (mt) genome of M. baileyi has been determined. Our results showed that the total length of the mitogenome was 16,351 bp, and had a gene content of 13 protein coding, 22 tRNAs and 2 rRNAs. Except for the seven tRNA and Nd6 genes, all other mt genes are encoded on the heavy strand. The overall base composition of the heavy strand is 33.65% A, 29.65% T, 24.42% C, and 12.28% G, with an AT content of 63.3%.

Full‐length Numt analysis provides evidence for hybridization between the Asian colobine genera Trachypithecus and Semnopithecus

The phylogenetic position of the genus Semnopithecusis unresolved because of topological incongruence when inferred using different molecular markers. Although some studies proposed hybridization between the genera Semnopithecus and Trachypithecus to explain the discordance, no conclusive evidence for hybridization has been identified. To address this issue, we used DNA walking and long‐range PCR to describe a nuclear mitochondrial DNA (Numt) segment present in Trachypithecus pileatus which extends over more than 15 kb, and represents approximately 92% of the entire mitochondrial genome. We assessed the presence of this Numt in 16 other colobine species, including four species of the genus Trachypithecus, six species of the genus Semnopithecus, and representative species of six other genera belonging to the subfamily Colobinae. We failed to detect a Numt sequence in any of the other colobine species except for T. shortridgei, which is closely related to T. pileatus. The sister relationship of this Numt within the genus Semnopithecus suggests that it was derived from the mt genome of the genus Semnopithecus and invaded the nuclear genome of T. pileatus by unidirectional introgression hybridization. These results offer the most conclusive evidence for the existence of hybridization between Semnopithecus and Trachypithecus. Am. J. Primatol. 77:901–910, 2015.

Implications of genetics and current protected areas for conservation of 5 endangered primates in China.

Most of Chinas 24-28 primate species are threatened with extinction. Habitat reduction and fragmentation are perhaps the greatest threats. We used published data from a conservation genetics study of 5 endangered primates in China (Rhinopithecus roxellana, R. bieti, R. brelichi, Trachypithecus francoisi, and T. leucocephalus); distribution data on these species; and the distribution, area, and location of protected areas to inform conservation strategies for these primates. All 5 species were separated into subpopulations with unique genetic components. Gene flow appeared to be strongly impeded by agricultural land, meadows used for grazing, highways, and humans dwellings. Most species declined severely or diverged concurrently as human population and crop land cover increased. Nature reserves were not evenly distributed across subpopulations with unique genetic backgrounds. Certain small subpopulations were severely fragmented and had higher extinction risk than others. Primate mobility is limited and their genetic structure is strong and susceptible to substantial loss of diversity due to local extinction. Thus, to maximize preservation of genetic diversity in all these primate species, our results suggest protection is required for all sub-populations. Key priorities for their conservation include maintaining R. roxellana in Shennongjia national reserve, subpopulations S4 and S5 of R. bieti and of R. brelichi in Fanjingshan national reserve, subpopulation CGX of T. francoisi in central Guangxi Province, and all 3 T. leucocephalus sub-populations in central Guangxi Province.

Differentiated adaptive evolution, episodic relaxation of selective constraints, and pseudogenization of umami and sweet taste genes TAS1Rs in catarrhine primates

BackgroundUmami and sweet tastes are two important basic taste perceptions that allow animals to recognize diets with nutritious carbohydrates and proteins, respectively. Until recently, analyses of umami and sweet taste were performed on various domestic and wild animals. While most of these studies focused on the pseudogenization of taste genes, which occur mostly in carnivores and species with absolute feeding specialization, omnivores and herbivores were more or less neglected. Catarrhine primates are a group of herbivorous animals (feeding mostly on plants) with significant divergence in dietary preference, especially the specialized folivorous Colobinae. Here, we conducted the most comprehensive investigation to date of selection pressure on sweet and umami taste genes (TAS1Rs) in catarrhine primates to test whether specific adaptive evolution occurred during their diversification, in association with particular plant diets.ResultsWe documented significant relaxation of selective constraints on sweet taste gene TAS1R2 in the ancestral branch of Colobinae, which might correlate with their unique ingestion and digestion of leaves. Additionally, we identified positive selection acting on Cercopithecidae lineages for the umami taste gene TAS1R1, on the Cercopithecinae and extant Colobinae and Hylobatidae lineages for TAS1R2, and on Macaca lineages for TAS1R3. Our research further identified several site mutations in Cercopithecidae, Colobinae and Pygathrix, which were detected by previous studies altering the sensitivity of receptors. The positively selected sites were located mostly on the extra-cellular region of TAS1Rs. Among these positively selected sites, two vital sites for TAS1R1 and four vital sites for TAS1R2 in extra-cellular region were identified as being responsible for the binding of certain sweet and umami taste molecules through molecular modelling and docking.ConclusionsOur results suggest that episodic and differentiated adaptive evolution of TAS1Rs pervasively occurred in catarrhine primates, most concentrated upon the extra-cellular region of TAS1Rs.

Complete mitochondrial genome of the crested black macaque (Macaca nigra).

Abstract The complete mitochondrial sequence of the crested black macaque (Macaca nigra) has been determined by mapping the raw data to previously published mitochondrial assemblies of the corresponding species. The total sequence length is 16,564 bp and includes 13 protein-coding genes, 2 ribosomal RNA genes, 22 transfer RNA genes and 1 D-loop control region. The base composition of mtDNA genome is 31.76% A, 25.27% T, 30.17% C, and 12.80% G, with an AT content of 57.03%. The arrangement of genes in M. nigra is identical to that of M. mulatta. All genes are encoded on the heavy strand with the exception of ND6 and eight tRNA genes. The mitochondrial genome of M. nigra presented here will contribute to a better understanding of the population genetics, help to protect its genetic diversity and resolve phylogenetic relationships within the family.

Complete mitochondrial genome of the capped langur (Trachypithecus pileatus)

Abstract The complete mitochondrial sequence of the capped langur (Trachypithecus pileatus) has been determined using long amplification polymerase chain reaction (LA-PCR). The total sequence length is 16,526 bp and includes 13 protein-coding genes, 2 ribosomal RNA genes, 22 transfer RNA genes and 1 D-loop locus. The base composition of H-strand is 31.9% A, 29.1% T, 26.2% C and 12.8% G, with an AT content of 55.3%. The arrangement of genes in T. pileatus is identical to that of other primate species. All genes are encoded on the heavy strand with the exception of ND6 and eight tRNA genes. The mitochondrial genome of T. pileatus presented here will contribute to a better understanding of the species’ population genetics, helping to protect its genetic diversity and resolve phylogenetic relationships within the family.

Complete mitochondrial genome of the Macaca mulatta brevicaudus

Abstract The complete mitochondrial sequence of the Macaca mulatta brevicaudus has been determined by mapping the raw data to previously published mitochondrial assemblies of the corresponding species. The total sequence length is 16,561 bp, consisting of 13 protein-coding genes, 22 transfer RNA genes, two ribosomal RNA genes, and one D-loop control region. The base composition of the mtDNA genome is 31.77% A, 25.14% T, 30.33% C, and 12.76% G, with an AT content of 56.90%. The arrangement of genes in M. m. brevicaudus is identical to that of M. mulatta. All genes are encoded on the heavy strand with the exception of ND6 and eight tRNA genes. The mitochondrial genome of M. m. brevicaudus presented here will contribute to a better understanding of the population genetics, help to protect its genetic diversity and resolve phylogenetic relationships within the family.

Mitochondrial genome of the Guizhou snub-nosed monkey (Rhinopithecus brelichi).

The Guizhou snub-nosed monkey (Rhinopithecus brelichi) is an endangered species which is endemic to a small region in the fanjing mountain national nature reserve in Guizhou province, China. In this study, we determined the complete mitochondrial genome of R. brelichi. The results showed that the total length of the mitogenome was 16,548 bp and contained 13 protein-coding genes, 22 transfer RNA genes, two ribosomal RNA genes and one control region. Overall base composition of the complete mitochondrial DNA was 32.35% A, 29.28% T, 25.54% C and 12.83% G. All the genes in R. brelichi were distributed on the H-strand, except for the ND6 subunit gene and eight tRNA genes which were encoded on the L-strand.