Heat-acclimatised strains of Rhodopseudomonas palustris reveal higher temperature optima with concomitantly enhanced biohydrogen production rates

Temperature is a critical parameter for bioprocess performance, requiring careful optimisation for peak efficiency. Green biohydrogen production via photofermentation by purple nonsulfur bacteria including Rhodopseudomonas palustris has been extensively researched, yet realisation is limited by comparatively low productivity. We thus assessed the growth and hydrogen productivity of two closely-related strains of R. palustris acclimated to higher temperatures, revealing markedly increased strain-dependent optima than the 30 degrees C previously accepted. Strain CGA009 grew 53% faster at 35 degrees C, with 2.4-fold higher hydrogen production rate, while at 40 degrees C strain ATH 2.1.37 displayed 86% faster growth and 4-fold higher production rate, along with improved specific production and substrate conversion efficiency. These results reaffirm the necessity of pre-acclimation when verifying temperature optima and expand the feasible temperature range for advancement of high-rate biohydrogen production. Further, the superior heat resistance and production capability of strain ATH 2.1.37 raises the potential for further efficiency gains from thermotolerant environmental isolates. (C) 2021 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

This study evaluated the growth and hydrogen productivity of two strains of R. palustris acclimated to higher temperatures, showing significantly increased optimisation effects at 35°C and 40°C. The results highlight the importance of pre-acclimation for verifying temperature optima and expand the feasible temperature range for high-rate biohydrogen production.