Substrate
Hydrophobicity and Cell Composition Influence the Extent of Rate Limitation
and Masking of Isotope Fractionation during Microbial Reductive Dehalogenation
of Chlorinated Ethenes
posted on 2015-04-07, 00:00authored byJulian Renpenning, Insa Rapp, Ivonne Nijenhuis
This
study investigated the effect of intracellular microscale mass transfer
on microbial carbon isotope fractionation of tetrachloroethene (PCE)
and trichloroethene (TCE). Significantly stronger isotope fractionation
was observed for crude extracts vs intact cells of Sulfurospirillum
multivorans, Geobacter lovleyi, Desulfuromonas michiganensis, Desulfitobacterium
hafniense strain PCE-S, and Dehalobacter restrictus. Furthermore, carbon stable isotope fractionation was stronger for
microorganisms with a Gram-positive cell envelope compared to those
with a Gram-negative cell envelope. Significant differences were observed
between model organisms in cellular sorption capacity for PCE (S. multivorans-Kd‑PCE = 0.42–0.51
L g–1; D. hafniense-Kd‑PCE = 0.13 L g–1), as well as in envelope hydrophobicity
(S. multivorans 33.0° to 72.2°; D. hafniense 59.1° to 60.8°) when previously cultivated
with fumarate or PCE as electron acceptor, but not for TCE. Cell envelope
properties and the tetrachloroethene reductive dehalogenase (PceA-RDase)
localization did not result in significant effects on observed isotope
fractionation of TCE. For PCE, however, systematic masking of isotope
effects as a result of microscale mass transfer limitation at microbial
membranes was observed, with carbon isotope enrichment factors of
−2.2‰, −1.5 to −1.6‰, and −1.0‰
(CI95% < ± 0.2‰) for no membrane, hydrophilic
outer membrane, and outer + cytoplasmic membrane, respectively. Conclusively,
rate-limiting mass transfer barriers were (a) the outer membrane or
cell wall and (b) the cytoplasmic membrane in case of a cytoplasmic
location of the RDase enzyme. Overall, our results indicate that masking
of isotope fractionation is determined by (1) hydrophobicity of the
degraded compound, (2) properties of the cell envelope, and (3) the
localization of the reacting enzyme.