English

Insular microbiogeography

Genomics 2017-03-23 v1 Populations and Evolution

Abstract

The diversity revealed by large scale genomics in microbiology is calling into question long held beliefs about genome stability, evolutionary rate, even the definition of a species. MacArthur and Wilson's theory of insular biogeography provides an explanation for the diversity of macroscopic animal and plant species as a consequence of the associated hierarchical web of species interdependence. We report a large scale study of microbial diversity that reveals that the cumulative number of genes discovered increases with the number of genomes studied as a simple power law. This result is demonstrated for three different genera comparing over 15,000 isolates. We show that this power law is formally related to the MacArthur-Wilson exponent, suggesting the emerging diversity of microbial genotypes arises because the scale independent behavior first reported by MacArthur and Wilson extends down to the scale of microbes and their genes. Assessing the depth of available whole genome sequences implies a dynamically changing core genome, suggesting that traditional taxonomic classifications should be replaced with a quasispecies model that captures the diversity and dynamic exchange of genes. We report Species population "clouds" in a defined microbiome, with scale invariance extending down to the level of single-nucleotide polymorphisms (SNPs).

Keywords

Cite

@article{arxiv.1703.07454,
  title  = {Insular microbiogeography},
  author = {James H. Kaufman and Christopher A. Elkins and Matthew Davis and Allison M Weis and Bihua C. Huang and Mark K Mammel and Isha R. Patel and Kristen L. Beck and Stefan Edlund and David Chambliss and Simone Bianco and Mark Kunitomi and Bart C. Weimer},
  journal= {arXiv preprint arXiv:1703.07454},
  year   = {2017}
}

Comments

23 pages, 7 figures, including Appendices

R2 v1 2026-06-22T18:53:13.476Z