TY - JOUR
T1 - Chlorinated Ethene Reactivity with Vitamin B12 Is Governed by Cobalamin Chloroethylcarbanions as Crossroads of Competing Pathways
AU - Heckel, Benjamin
AU - McNeill, Kristopher
AU - Elsner, Martin
N1 - Publisher Copyright:
© 2018 American Chemical Society.
PY - 2018/4/6
Y1 - 2018/4/6
N2 - Chlorinated ethenes are toxic groundwater contaminants. Although they can be dechlorinated by microorganisms, reductive dehalogenases, and their corrinoid cofactor, biochemical reaction mechanisms remain unsolved. This study uncovers a mechanistic shift revealed by contrasting compound-specific carbon (ϵ13C) and chlorine (ϵ37Cl) isotope effects between perchloroethene, PCE (ϵ37Cl = -4.0‰) and cis-dichloroethene, cis-DCE (ϵ37Cl = -1.5‰), and a pH-dependent shift for trichloroethene, TCE (from ϵ37Cl = -5.2‰ at pH 12 to ϵ37Cl = -1.2‰ at pH 5). Different pathways are supported also by pH-dependent reaction rates, TCE product distribution, and hydrogen isotope effects. Mass balance deficits revealed reversible and irreversible cobalamin-substrate association, whereas high-resolution mass spectrometry narrowed down possible structures to chloroalkyl and chlorovinyl cobalamin complexes. Combined experimental evidence is inconsistent with initial electron transfer or alkyl or vinyl complexes as shared intermediates of both pathways. In contrast, it supports cobalamin chlorocarbanions as key intermediates from which Cl- elimination produces vinyl complexes (explaining rates and products of TCE at high pH), whereas protonation generates less reactive alkyl complexes (explaining rates and products of TCE at low pH). Multielement isotope effect analysis holds promise to identify these competing mechanisms also in real dehalogenases, microorganisms, and even contaminated aquifers.
AB - Chlorinated ethenes are toxic groundwater contaminants. Although they can be dechlorinated by microorganisms, reductive dehalogenases, and their corrinoid cofactor, biochemical reaction mechanisms remain unsolved. This study uncovers a mechanistic shift revealed by contrasting compound-specific carbon (ϵ13C) and chlorine (ϵ37Cl) isotope effects between perchloroethene, PCE (ϵ37Cl = -4.0‰) and cis-dichloroethene, cis-DCE (ϵ37Cl = -1.5‰), and a pH-dependent shift for trichloroethene, TCE (from ϵ37Cl = -5.2‰ at pH 12 to ϵ37Cl = -1.2‰ at pH 5). Different pathways are supported also by pH-dependent reaction rates, TCE product distribution, and hydrogen isotope effects. Mass balance deficits revealed reversible and irreversible cobalamin-substrate association, whereas high-resolution mass spectrometry narrowed down possible structures to chloroalkyl and chlorovinyl cobalamin complexes. Combined experimental evidence is inconsistent with initial electron transfer or alkyl or vinyl complexes as shared intermediates of both pathways. In contrast, it supports cobalamin chlorocarbanions as key intermediates from which Cl- elimination produces vinyl complexes (explaining rates and products of TCE at high pH), whereas protonation generates less reactive alkyl complexes (explaining rates and products of TCE at low pH). Multielement isotope effect analysis holds promise to identify these competing mechanisms also in real dehalogenases, microorganisms, and even contaminated aquifers.
KW - chlorinated ethenes
KW - cobalamin
KW - groundwater contamination
KW - kinetic isotope effect
KW - mechanistic study
KW - outer-sphere single-electron transfer
KW - reductive dehalogenation
KW - trichloroethene
UR - http://www.scopus.com/inward/record.url?scp=85045097954&partnerID=8YFLogxK
U2 - 10.1021/acscatal.7b02945
DO - 10.1021/acscatal.7b02945
M3 - Article
AN - SCOPUS:85045097954
SN - 2155-5435
VL - 8
SP - 3054
EP - 3066
JO - ACS Catalysis
JF - ACS Catalysis
IS - 4
ER -