Position-Specific Metabolic Probing and Metagenomics of Microbial Communities Reveal Conserved Central Carbon Metabolic Network Activities at High Temperatures

Authors

Scott C. Thomas, University of Nevada, Las Vegas
Kevin O. Tamadonfar, University of Nevada, Las Vegas
Cale O. Seymour, University of Nevada, Las Vegas
Dengxun Lai, University of Nevada, Las Vegas
Jeremy A. Dodsworth, California State University
Senthil K. Murugapiran, University of Nevada, Las Vegas
Emiley A. Eloe-Fadrosh, Joint Genome Institute
Paul Dijkstra, Northern Arizona University
Brian P. Hedlund, University of Nevada, Las VegasFollow

Document Type

Article

Publication Date

7-5-2019

Publication Title

Frontiers in Microbiology

Publisher

Frontiers Media

Volume

10

First page number:

1

Last page number:

19

Abstract

Temperature is a primary driver of microbial community composition and taxonomic diversity; however, it is unclear to what extent temperature affects characteristics of central carbon metabolic pathways (CCMPs) at the community level. In this study, 16S rRNA gene amplicon and metagenome sequencing were combined with 13C-labeled metabolite probing of the CCMPs to assess community carbon metabolism along a temperature gradient (60–95°C) in Great Boiling Spring, NV. 16S rRNA gene amplicon diversity was inversely proportional to temperature, and Archaea were dominant at higher temperatures. KO richness and diversity were also inversely proportional to temperature, yet CCMP genes were similarly represented across the temperature gradient and many individual metagenome-assembled genomes had complete pathways. In contrast, genes encoding cellulosomes and many genes involved in plant matter degradation and photosynthesis were absent at higher temperatures. In situ 13C-CO2 production from labeled isotopomer pairs of glucose, pyruvate, and acetate suggested lower relative oxidative pentose phosphate pathway activity and/or fermentation at 60°C, and a stable or decreased maintenance energy demand at higher temperatures. Catabolism of 13C-labeled citrate, succinate, L-alanine, L-serine, and L-cysteine was observed at 85°C, demonstrating broad heterotrophic activity and confirming functioning of the TCA cycle. Together, these results suggest that temperature-driven losses in biodiversity and gene content in geothermal systems may not alter CCMP function or maintenance energy demands at a community level.

Keywords

13C stable isotope; Isotopomers; Heterotrophy; Catabolic; Anabolic; Thermophile; Hyperthermophile; Diversity

Disciplines

Biodiversity | Genomics | Microbiology

File Format

pdf

File Size

1.838 KB

Language

English

Repository Citation

Thomas, S. C., Tamadonfar, K. O., Seymour, C. O., Lai, D., Dodsworth, J. A., Murugapiran, S. K., Eloe-Fadrosh, E. A., Dijkstra, P., Hedlund, B. P. (2019). Position-Specific Metabolic Probing and Metagenomics of Microbial Communities Reveal Conserved Central Carbon Metabolic Network Activities at High Temperatures. Frontiers in Microbiology, 10 1-19. Frontiers Media.
http://dx.doi.org/10.3389/fmicb.2019.01427