Microbiomes, metagenomics, and primate conservation

New strategies, tools, and applications

R. M. Stumpf, A. Gomez, K. R. Amato, C. J. Yeoman, J. D. Polk, B. A. Wilson, K. E. Nelson, B. A. White, S. R. Leigh

Research output: Contribution to journalComment/debate

Abstract

Conservation strategies require multifaceted approaches to monitor and protect primate populations, many of which are rapidly declining around the world. We propose that microbial ecology and next-generation microbiome analyses offer valuable perspectives and tools for investigating and monitoring primate health and improving conservation efforts. The microbial communities inhabiting primates and other taxa profoundly affect host health, nutrition, physiology, and immune systems, through relationships that range from commensal and mutualistic to pathogenic. Recent advances in DNA sequencing now make it feasible and economically viable to identify microbiomes among and within hosts. Herein, we highlight several examples in which microbial analyses of primates can aid conservation approaches that are broadly applicable across other taxa. First, we highlight evidence for clear spatial variation (e.g. biogeographic niche specificity, both within the anatomical regions of the host body, as well as in the geographic location of the host) and temporal (e.g. seasonal, ontogenetic) patterns in microbial distribution. We emphasize that microbial communities are sensitive to alterations in the external environment and that microbial diversity correlates with habitat quality, imposing direct health consequences. Incorporating microbial host and biogeographic variation holds great potential for forest corridor assessments and for reintroduction efforts. Finally, microbial pathogens transmitted between humans and wild primate populations carry both direct and indirect conservation implications. Principally, we argue that phylogenetic analyses of infectious pathogens (e.g., Ebola, dengue, Borellia, and Treponema) can aid our understanding of modes of disease transmission and aid conservation disease abatement efforts. The application of microbial analyses to conservation is currently in its infancy but holds enormous potential. To date, no conservation policy or legislation includes microbiome assessments. Integrating new understanding of the patterns of microbial diversity and early signs of impending microbial disruption offer valuable tools for informing conservation strategies and monitoring and promoting primate (including human) health.

Original languageEnglish (US)
Pages (from-to)56-66
Number of pages11
JournalBiological Conservation
Volume199
DOIs
StatePublished - Jul 1 2016

Fingerprint

primate
Primates
microbial communities
monitoring
nutrition physiology
Treponema
microbial community
pathogen
dengue
pathogens
microbial ecology
infancy
disease transmission
commensal
reintroduction
laws and regulations
immune system
habitat quality
human health
spatial variation

Keywords

  • Captive management
  • Conservation
  • Disease
  • Metagenomics
  • Microbiomes
  • Monitoring
  • Primates
  • Reintroductions

ASJC Scopus subject areas

  • Ecology, Evolution, Behavior and Systematics
  • Nature and Landscape Conservation

Cite this

Microbiomes, metagenomics, and primate conservation : New strategies, tools, and applications. / Stumpf, R. M.; Gomez, A.; Amato, K. R.; Yeoman, C. J.; Polk, J. D.; Wilson, B. A.; Nelson, K. E.; White, B. A.; Leigh, S. R.

In: Biological Conservation, Vol. 199, 01.07.2016, p. 56-66.

Research output: Contribution to journalComment/debate

Stumpf, R. M. ; Gomez, A. ; Amato, K. R. ; Yeoman, C. J. ; Polk, J. D. ; Wilson, B. A. ; Nelson, K. E. ; White, B. A. ; Leigh, S. R. / Microbiomes, metagenomics, and primate conservation : New strategies, tools, and applications. In: Biological Conservation. 2016 ; Vol. 199. pp. 56-66.
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