Abstract
Heterotrophic bacteria and archaea (‘heteroprokaryotes’) drive global carbon cycling, but how to quantitatively organize their functional complexity remains unclear. We generated a global-scale understanding of marine heteroprokaryotic functional biogeography by synthesizing genetic sequencing data with a mechanistic marine ecosystem model. We incorporated heteroprokaryotic diversity into the trait-based model along two axes: substrate lability and growth strategy. Using genetic sequences along three ocean transects, we compiled 21 heteroprokaryotic guilds and estimated their degree of optimization for rapid growth (copiotrophy). Data and model consistency indicated that gradients in grazing and substrate lability predominantly set biogeographical patterns, and identified deep-ocean ‘slow copiotrophs’ whose ecological interactions control the surface accumulation of dissolved organic carbon.
Competing Interest Statement
The authors have declared no competing interest.
Footnotes
Updated to the revised version (Jan 2025).