A novel type of denitrifying bacterium (strain HxN1) with the capacity to oxidize n-alkanes anaerobically with nitrate as the electron acceptor to CO 2 formed (1-methylpentyl)succinate (MPS) during growth on n-hexane as the only organic substrate under strict exclusion of air. Identification of MPS by gas chromatography-mass spectrometry was based on comparison with a synthetic standard. MPS was not formed during anaerobic growth on n-hexanoate. Anaerobic growth with [1-13 C]n-hexane or d 14 -n-hexane led to a 1-methylpentyl side chain in MPS with one 13 C atom or 13 deuterium atoms, respectively. This indicates that the 1-methylpentyl side chain originates directly from n-hexane. Electron paramagnetic resonance spectroscopy revealed the presence of an organic radical in n-hexane-grown cells but not in n-hexanoate-grown cells. Results point at a mechanistic similarity between the anaerobic initial reaction of n-hexane and that of toluene, even though n-hexane is much less reactive; the described initial reaction of toluene in anaerobic bacteria is an addition to fumarate via a radical mechanism yielding benzylsuccinate. We conclude that n-hexane is activated at its second carbon atom by a radical reaction and presumably added to fumarate as a cosubstrate, yielding MPS as the first stable product. When 2,3-d 2 -fumarate was added to cultures growing on unlabeled n-hexane, 3-d 1 -MPS rather than 2,3-d 2 -MPS was detected, indicating loss of one deuterium atom by an as yet unknown mechanism.
The anaerobic degradation pathway of the saturated hydrocarbon n-hexane in a denitrifying strain (HxN1) was examined by gas chromatography-mass spectrometry of derivatized extracts from cultures grown with unlabeled and deuterated substrate; several authentic standard compounds were included for comparison. The study was focused on possible reaction steps that follow the initial formation of (1-methylpentyl)succinate from n-hexane and fumarate. 4-Methyloctanoic, 4-methyloct-2-enoic, 2-methylhexanoic, 2-methylhex-2-enoic and 3-hydroxy-2-methylhexanoic acids (in addition to a few other methyl-branched acids) were detected in n-hexane-grown but not in n-hexanoate-grown cultures. Labeling indicated preservation of the original carbon chain of n-hexane in these acids. Tracing of the deuterium label of 3- d1-(1-methylpentyl)succinate in tentative subsequent products indicated a deuterium/carboxyl carbon exchange in the succinate moiety. This suggests that the metabolism of (1-methylpentyl)succinate employs reactions analogous to those in the established conversion of succinyl-CoA via methylmalonyl-CoA to propionyl-CoA. Accordingly, a pathway is proposed in which (1-methylpentyl)succinate is converted to the CoA-thioester, rearranged to (2-methylhexyl)malonyl-CoA and decarboxylated (perhaps by a transcarboxylase) to 4-methyloctanoyl-CoA. The other identified fatty acids match with a further degradation of 4-methyloctanoyl-CoA via rounds of conventional beta-oxidation. Such a pathway would also allow regeneration of fumarate (for n-hexane activation) from propionyl-CoA formed as intermediate and hence present a cyclic process.
Two types of C-terminal sequences apparently represent substrate-binding sites; the PHB type is present in the PHB depolymerases of A. faecalis and P. pickettii and in PhaZ2, PhaZ3, and PhaZ5, and the PHV type is present in the PHV-hydrolyzing depolymerases (PhaZ4 and PhaZ1). phaZ1 was transferred to A. eutrophus H16 and JMP222. All transconjugants of both strains were able to grow with extracellular PHB as a carbon source and produced translucent halos on PHB-containing solid media. PhaZ1, PhaZ2, PhaZ4, and PhaZ5 were purified from P. lemoignei and from recombinant E. coli; the processing sites of the precursors in E. coli were the same as in P. lemoignei, and similar substrate specificities were determined for the wild-type and the recombinant proteins. All PHA depolymerases hydrolyzed PHB at high specific activities. PhaZ1 and PhaZ4 additionally cleaved PHV, and PhaZ4 hydrolyzed poly(4-hydroxybutyrate). None of the depolymerases was able to hydrolyze polylactide or PHA consisting of monomers with more than five carbon atoms. While the wild-type depolymerase proteins were glycosylated and found to contain glucose and N-acetylglucosamine, none of the recombinant proteins was glycosylated. PHB hydrolysis was dependent on divalent cations such as Ca 2؉ and was inhibited by the presence of EDTA.
Strain HxN1, a member of the Betaproteobacteria, can grow anaerobically by denitrification with n-alkanes. n-Alkanes are apparently activated by subterminal carbon addition to fumarate yielding (1-methylalkyl)succinates, the postulated enzyme being (1-methylalkyl)succinate synthase (Mas). Genes encoding this enzyme (mas) were searched for via proteins that were specifically formed in n-hexane-grown cells (in comparison with caproate-grown cells), as revealed by two-dimensional gel electrophoresis. Partial amino acid sequencing and subsequent probe development for hybridization of restricted DNA led to the identification of a gene cluster. Deduced proteins are similar to the subunits of benzylsuccinate synthase (Bss), the toluene-activating enzyme in other anaerobic bacteria and its activase. The tentative (1-methylalkyl)succinate synthase is presumably a heterotrimer (MasDEC) which, like benzylsuccinate synthase, contains a motif (in MasD, the large subunit) characteristic of glycyl radical-bearing sites. Based on amino acid sequence comparison, the tentative (1-methylalkyl)succinate synthase branches outside of the phylogenetic cluster of benzylsuccinate synthases from different organisms and represents a separate line of descent within glycyl radical enzymes. n-Hexane-induced co-transcription of the mas genes and additional genes of an apparent operon was demonstrated by Northern hybridization experiments.
The capacity of denitrifying bacteria for anaerobic utilization of saturated hydrocarbons (alkanes) was investigated with n-alkanes of various chain lengths and with crude oil in enrichment cultures containing nitrate as electron acceptor. Three distinct types of denitrifying bacteria were isolated in pure culture. A strain (HxN1) with oval-shaped, nonmotile cells originated from a denitrifying enrichment culture with crude oil and was isolated with n-hexane (C6H14). Another strain (OcN1) with slender, rod-shaped, motile cells was isolated from an enrichment culture with n-octane (C8H18). A third strain (HdN1) with oval, somewhat pleomorphic, partly motile cells originated from an enrichment culture with aliphatic mineral oil and was isolated with n-hexadecane (C16H34). Cells of hexane-utilizing strain HxN1 grew homogeneously in the growth medium and did not adhere to the alkane phase, in contrast to the two other strains. Quantification of substrate consumption and cell growth revealed the capacity for complete oxidation of alkanes under strictly anoxic conditions, with nitrate being reduced to dinitrogen.
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