Adaptation of phenol-degrading Pseudomonas putida KB3 to suboptimal growth condition: A focus on degradative rate, membrane properties and expression of xylE and cfaB genes

Autor: Joanna Żur-Pińska, Agnieszka Mrozik, Artur Pinski, Gabriela Pacek, Agnieszka Nowak
Jazyk: angličtina
Rok vydání: 2021
Předmět:
Salinity
Membrane permeability
Health
Toxicology and Mutagenesis

0211 other engineering and technologies
02 engineering and technology
Membrane properties
010501 environmental sciences
01 natural sciences
Environmental pollution
Catechol 2
3-Dioxygenase

sanility
chemistry.chemical_compound
Suboptimal temperatures
Phenol degradation
GE1-350
Cyclopropane fatty acid
Fatty acid methyl ester
0105 earth and related environmental sciences
chemistry.chemical_classification
021110 strategic
defence & security studies

biology
Phenol
Pseudomonas putida
pH
Pseudomonas
Cell Membrane
Public Health
Environmental and Occupational Health

Suboptimal temperatures
pH
salinity

Temperature
Fatty acid
General Medicine
Gene Expression Regulation
Bacterial

Methyltransferases
Hydrogen-Ion Concentration
biology.organism_classification
Pollution
Adaptation
Physiological

Environmental sciences
Biodegradation
Environmental

chemistry
Biochemistry
TD172-193.5
Gene expression
Bacteria
Zdroj: Ecotoxicology and Environmental Safety, Vol 221, Iss, Pp 112431-(2021)
National Information Processing Institute
Popis: Detailed characterization of new Pseudomonas strains that degrade toxic pollutants is required and utterly necessary before their potential use in environmental microbiology and biotechnology applications. Therefore, phenol degradation by Pseudomonas putida KB3 under suboptimal temperatures, pH, and salinity was examined in this study. Parallelly, adaptive mechanisms of bacteria to stressful growth conditions concerning changes in cell membrane properties during phenol exposure as well as the expression level of genes encoding catechol 2,3-dioxygenase (xylE) and cyclopropane fatty acid synthase (cfaB) were determined. It was found that high salinity and the low temperature had the most significant effect on the growth of bacteria and the rate of phenol utilization. Degradation of phenol (300 mg L−1) proceeded 12-fold and seven-fold longer at 10 °C and 5% NaCl compared to the optimal conditions. The ability of bacteria to degrade phenol was coupled with a relatively high activity of catechol 2,3-dioxygenase. The only factor that inhibited enzyme activity by approximately 80% compared to the control sample was salinity. Fatty acid methyl ester (FAMEs) profiling, membrane permeability measurements, and hydrophobicity tests indicated severe alterations in bacteria membrane properties during phenol degradation in suboptimal growth conditions. The highest values of pH, salinity, and temperature led to a decrease in membrane permeability. FAME analysis showed fatty acid saturation indices and cyclopropane fatty acid participation at high temperature and salinity. Genetic data showed that suboptimal growth conditions primarily resulted in down-regulation of xylE and cfaB gene expression.
Databáze: OpenAIRE