The fundamental role of pH in CH4 bioconversion into polyhydroxybutyrate in mixed methanotrophic cultures

V Pérez; R Lebrero; R Muñoz; R Pérez

doi:10.1016/j.chemosphere.2024.141832

The fundamental role of pH in CH4 bioconversion into polyhydroxybutyrate in mixed methanotrophic cultures

Chemosphere. 2024 May:355:141832. doi: 10.1016/j.chemosphere.2024.141832. Epub 2024 Apr 1.

Authors

V Pérez¹, R Lebrero¹, R Muñoz¹, R Pérez²

Affiliations

¹ Institute of Sustainable Processes, Valladolid University, Dr. Mergelina s/n, Spain; Department of Chemical Engineering and Environmental Technology, Valladolid University, Prado de la Magdalena 5, Valladolid, Spain.
² Institute of Sustainable Processes, Valladolid University, Dr. Mergelina s/n, Spain; Department of Chemical Engineering and Environmental Technology, Valladolid University, Prado de la Magdalena 5, Valladolid, Spain. Electronic address: rebeca.perez@uva.es.

PMID: 38570044
DOI: 10.1016/j.chemosphere.2024.141832

Abstract

Climate change and plastic pollution are likely the most relevant challenges for the environment in the 21st century. Developing cost-effective technologies for the bioconversion of methane (CH₄) into polyhydroxyalkanoates (PHAs) could simultaneously mitigate CH₄ emissions and boost the commercialization of biodegradable polymers. Despite the fact that the role of temperature, nitrogen deprivation, CH₄:O₂ ratio or micronutrients availability on the PHA accumulation capacity of methanotrophs has been carefully explored, there is still a need for optimization of the CH₄-to-PHA bioconversion process prior to becoming a feasible platform in future biorefineries. In this study, the influence of different cultivation broth pH values (5.5, 7, 8.5 and 10) on bacterial biomass growth, CH₄ bioconversion rate, PHA accumulation capacity and bacterial community structure was investigated in a stirred tank bioreactor under nitrogen deprivation conditions. Higher CH₄ elimination rates were obtained at increasing pH, with a maximum value of 50.4 ± 2.7 g CH₄·m^-3·h^-1 observed at pH 8.5. This was likely mediated by an increased ionic strength in the mineral medium, which enhanced the gas-liquid mass transfer. Interestingly, higher PHB accumulations were observed at decreasing pH, with the highest PHB contents recorded at a pH 5.5 (43.7 ± 3.4 %w·w^-1). The strong selective pressure of low pH towards the growth of Type II methanotrophic bacteria could explain this finding. The genus Methylocystis increased its abundance from 34 % up to 85 and 90 % at pH 5.5 and 7, respectively. On the contrary, Methylocystis was less abundant in the community enriched at pH 8.5 (14 %). The accumulation of intracellular PHB as energy and carbon storage material allowed the maintenance of high CH₄ biodegradation rates during 48 h after complete nitrogen deprivation. The results here obtained demonstrated for the first time a crucial and multifactorial role of pH on the bioconversion performance of CH₄ into PHA.

Keywords: Bioplastics; Greenhouse gas abatement; Methane; Methanotrophic bacteria; PHA; pH.

MeSH terms

Carbon / metabolism
Hydrogen-Ion Concentration
Methane / metabolism
Methylocystaceae* / metabolism
Nitrogen / metabolism
Polyhydroxyalkanoates*
Polyhydroxybutyrates

Substances

Polyhydroxybutyrates
Polyhydroxyalkanoates
Carbon
Methane
Nitrogen