Growth Kinetics, Carbon Isotope Fractionation, and Gene Expression in the Hyperthermophile Methanocaldococcus jannaschii during Hydrogen-Limited Growth and Interspecies Hydrogen Transfer

Abstract

Hyperthermophilic methanogens are often H₂ limited in hot subseafloor environments, and their survival may be due in part to physiological adaptations to low H₂ conditions and interspecies H₂ transfer. The hyperthermophilic methanogen Methanocaldococcus jannaschii was grown in monoculture at high (80 to 83 μM) and low (15 to 27 μM) aqueous H₂ concentrations and in coculture with the hyperthermophilic H₂ producer Thermococcus paralvinellae The purpose was to measure changes in growth and CH₄ production kinetics, CH₄ fractionation, and gene expression in M. jannaschii with changes in H₂ flux. Growth and cell-specific CH₄ production rates of M. jannaschii decreased with decreasing H₂ availability and decreased further in coculture. However, cell yield (cells produced per mole of CH₄ produced) increased 6-fold when M. jannaschii was grown in coculture rather than monoculture. Relative to high H₂ concentrations, isotopic fractionation of CO₂ to CH₄ (ε_CO2-CH4) was 16‰ larger for cultures grown at low H₂ concentrations and 45‰ and 56‰ larger for M. jannaschii growth in coculture on maltose and formate, respectively. Gene expression analyses showed H₂-dependent methylene-tetrahydromethanopterin (H₄MPT) dehydrogenase expression decreased and coenzyme F₄₂₀-dependent methylene-H₄MPT dehydrogenase expression increased with decreasing H₂ availability and in coculture growth. In coculture, gene expression decreased for membrane-bound ATP synthase and hydrogenase. The results suggest that H₂ availability significantly affects the CH₄ and biomass production and CH₄ fractionation by hyperthermophilic methanogens in their native habitats.IMPORTANCE Hyperthermophilic methanogens and H₂-producing heterotrophs are collocated in high-temperature subseafloor environments, such as petroleum reservoirs, mid-ocean ridge flanks, and hydrothermal vents. Abiotic flux of H₂ can be very low in these environments, and there is a gap in our knowledge about the origin of CH₄ in these habitats. In the hyperthermophile Methanocaldococcus jannaschii, growth yields increased as H₂ flux, growth rates, and CH₄ production rates decreased. The same trend was observed increasingly with interspecies H₂ transfer between M. jannaschii and the hyperthermophilic H₂ producer Thermococcus paralvinellae With decreasing H₂ availability, isotopic fractionation of carbon during methanogenesis increased, resulting in isotopically more negative CH₄ with a concomitant decrease in H₂-dependent methylene-tetrahydromethanopterin dehydrogenase gene expression and increase in F₄₂₀-dependent methylene-tetrahydromethanopterin dehydrogenase gene expression. The significance of our research is in understanding the nature of hyperthermophilic interspecies H₂ transfer and identifying biogeochemical and molecular markers for assessing the physiological state of methanogens and possible source of CH₄ in natural environments.

Keywords: Methanocaldococcus; RNA-Seq; Thermococcus; carbon isotope fractionation; hydrogen; hyperthermophiles; methanogenesis; syntrophs.