Metabolic reconstruction of aromatic compounds degradation from the genome of the amazing pollutant-degrading bacterium Cupriavidus necator JMP134

Keyphrases

• Pollutants 100%
• Aromatic Compounds 100%
• Degrading Bacteria 100%
• Cupriavidus Necator JMP134 100%
• Aromatic Compound Degradation 100%
• Ring Cleavage 100%
• Metabolic Reconstruction 100%
• Cleavage Pathway 75%
• Necator 50%
• Catabolic 50%
• Biodegradation 50%
• Genomic Data 50%
• Catechol 50%
• 2,4-Dichlorophenoxyacetic Acid 25%
• Chloroaromatics 25%
• Substituted Aromatics 25%
• Chlorophenols 25%
• Chlorocatechol 25%
• Chloro 25%
• Energy Sources 25%
• Aromatic Degradation 25%
• Carbon Source 25%
• Complete Genome Sequence 25%
• Catabolic Genes 25%
• Peripheral Response 25%
• Environmentally Relevant 25%
• Benzoyl-CoA Pathway 25%
• Protocatechuate 25%
• Nitrophenol 25%
• Amino 25%
• Hydroquinone 25%
• Gene Redundancy 25%
• In Silico 25%
• Homogentisate 25%
• Hydroxyquinol Pathway 25%
• Ortho 25%
• Methyl 25%
• Gentisate 25%
• Reaction Channel 25%
• Methylcatechol 25%
• Catabolic Potential 25%

INIS

• bacteria 100%
• pollutants 100%
• aromatic compounds 100%
• cleavage 66%
• rings 66%
• data 33%
• genes 33%
• aromatics 33%
• biodegradation 33%
• catechol 33%
• range 16%
• strains 16%
• growth 16%
• genetics 16%
• spectra 16%
• energy sources 16%
• carbon sources 16%
• redundancy 16%
• nitrophenol 16%
• biochemistry 16%

Pharmacology, Toxicology and Pharmaceutical Science

• Cupriavidus Necator 100%
• Aromatic Compound 100%
• Necator 33%
• Guaiacol 33%
• Catechol 16%
• Hydroquinone 16%
• Homogentisic Acid 16%
• Benzoyl-CoA 16%
• Protocatechuic Acid 16%
• 1,2,4 Benzenetriol 16%
• Nitrophenol 16%
• Gentisic Acid 16%
• Chlorophenol 16%