Many heterotrophic bacteria have the ability to make polyhedral structures containing metabolic enzymes that are bounded by a unilamellar protein shell (metabolosomes or enterosomes). These bacterial organelles contain enzymes associated with a specific metabolic process (e.g. 1,2-propanediol or ethanolamine utilization). We show that the 21 gene regulon specifying the pdu organelle and propanediol utilization enzymes from Citrobacter freundii is fully functional when cloned in Escherichia coli, both producing metabolosomes and allowing propanediol utilization. Genetic manipulation of the level of specific shell proteins resulted in the formation of aberrantly shaped metabolosomes, providing evidence for their involvement as delimiting entities in the organelle. This is the first demonstration of complete recombinant metabolosome activity transferred in a single step and supports phylogenetic evidence that the pdu genes are readily horizontally transmissible. One of the predicted shell proteins (PduT) was found to have a novel Fe-S center formed between four protein subunits. The recombinant model will facilitate future experiments establishing the structure and assembly of these multiprotein assemblages and their fate when the specific metabolic function is no longer required.It has been recognized for more than 30 years that all cyanobacteria (1) and some other chemoautotrophic bacteria (2) contain carboxysomes. These polyhedral cellular inclusions consist of a proteinaceous shell enclosing an active enzyme, ribulose bisphosphate carboxylase/oxygenase (RuBisCO). 4Their function is to enhance the fixation of carbon dioxide (3), a reaction of planetary significance in that marine cyanobacteria are responsible for the majority of global carbon fixation (4, 5). More recently, sequence similarity was noticed between carboxysome shell genes and metabolic operon genes associated with propanediol utilization (pdu) and ethanolamine utilization (eut) in a variety of heterotrophic bacteria found in the mammalian gut (3) and the environment. In growth conditions that induce these metabolic operons, polyhedral organelles resembling carboxysomes were observed on electron microscopy of Salmonella enterica serovar Typhimurium (6), Klebsiella oxytoca, Citrobacter freundii, and Escherichia coli (7). Bioinformatics analysis also locates genes resembling carboxysome shell genes in metabolic operons in Clostridium perfringens (8), Clostridium tetani (9), Listeria monocytogenes and Listeria innocua (10), Enterococcus faecalis (11), Lactobacillus collinoides (12), Citrobacter rodentium, 5 and Yersinia enterocolitica (13) among other organisms. The non-carboxysome polyhedral structures have been referred to as enterosomes (3) or metabolosomes (14), emphasizing their role in cellular metabolism.There is some considerable interest in how these proteinaceous organelles form and the arrangement of protein subunits that give rise to these remarkable macromolecular assemblies. In carboxysomes, there are thought to be a number of shell prot...
Sulfur metabolism depends on the iron-containing porphinoid siroheme. In Salmonella enterica, the S-adenosyl-L-methionine (SAM)-dependent bismethyltransferase, dehydrogenase and ferrochelatase, CysG, synthesizes siroheme from uroporphyrinogen III (uro'gen III). The reactions mediated by CysG encompass two branchpoint intermediates in tetrapyrrole biosynthesis, diverting flux first from protoporphyrin IX biosynthesis and then from cobalamin (vitamin B(12)) biosynthesis. We determined the first structure of this multifunctional siroheme synthase by X-ray crystallography. CysG is a homodimeric gene fusion product containing two structurally independent modules: a bismethyltransferase and a dual-function dehydrogenase-chelatase. The methyltransferase active site is a deep groove with a hydrophobic patch surrounded by hydrogen bond donors. This asymmetric arrangement of amino acids may be important in directing substrate binding. Notably, our structure shows that CysG is a phosphoprotein. From mutational analysis of the post-translationally modified serine, we suggest a conserved role for phosphorylation in inhibiting dehydrogenase activity and modulating metabolic flux between siroheme and cobalamin pathways.
During porphyrin biosynthesis the oxygen-independent coproporphyrinogen III oxidase (HemN) catalyzes the oxidative decarboxylation of the propionate side chains of rings A and B of coproporphyrinogen III to form protoporphyrinogen IX. The enzyme utilizes a 5-deoxyadenosyl radical to initiate the decarboxylation reaction, and it has been proposed that this occurs by stereo-specific abstraction of the pro-S-hydrogen atom at the -position of the propionate side chains leading to a substrate radical. Here we provide EPR-spectroscopic evidence for intermediacy of the latter radical by observation of an organic radical EPR signal in reduced HemN upon addition of S-adenosyl-L-methionine and the substrate coproporphyrinogen III. This signal (g av ؍ 2.0029) shows a complex pattern of well resolved hyperfine splittings from at least five different hydrogen atoms. The radical was characterized using regiospecifically labeled (deuterium or 15 N) coproporphyrinogen III molecules. They had been generated from a multienzyme mixture and served as efficient substrates. Reaction of HemN with coproporphyrinogen III, perdeuterated except for the methyl groups, led to the complete loss of resolved proton hyperfine splittings. Substrates in which the hydrogens at both ␣-and -positions, or only at the -positions of the propionate side chains, or those of the methylene bridges, were deuterated showed that there is coupling with hydrogens at the ␣-, -, and methylene bridge positions. Deuterium or 15 N labeling of the pyrrole nitrogens without labeling the side chains only led to a slight sharpening of the radical signal. Together, these observations clearly identified the radical signal as substrate-derived and indicated that, upon abstraction of the pro-Shydrogen atom at the -position of the propionate side chain by the 5-deoxyadenosyl radical, a comparatively stable delocalized substrate radical intermediate is formed in the absence of electron acceptors. The observed hyperfine constants and g values show that this coproporphyrinogenyl radical is allylic and encompasses carbon atoms 3, 3, and 4.Modified tetrapyrroles such as hemes and chlorophylls play important roles in a range of essential life processes from respiration to photosynthesis. Their underlying molecular architecture is reflected in a shared biosynthetic pathway that requires the coordinated activity of a large number of highly diverse enzymes (1-3). During porphyrin formation two structurally unrelated coproporphyrinogen III oxidases catalyze the oxidative decarboxylation of the propionate side chains on pyrrole rings A and B of the macrocycle to the corresponding vinyl groups (Scheme 1a) (4). The oxygen-dependent enzyme, HemF, found in eukaryotes and some bacteria, uses molecular oxygen as an electron acceptor during this process (5). For oxygen-independent coproporphyrinogen formation most bacteria carry the oxygen-independent enzyme HemN. In Escherichia coli, HemN is a monomeric protein that contains an oxygen-sensitive [4Fe-4S] cluster (6, 7). The enzyme belo...
In Bacillus megaterium, the hemAXBCDL genes were isolated and were found to be highly similar to the genes from Bacillus subtilis that are required for the conversion of glutamyl-tRNA into uroporphyrinogen III. Overproduction and purification of HemC (porphobilinogen deaminase) and -D (uroporphyrinogen III synthase) allowed these enzymes to be used for the in vitro synthesis of uroporphyrinogen III from porphobilinogen. A second smaller cluster of three genes (termed sirABC) was also isolated and found to encode the enzymes that catalyse the transformation of uroporphyrinogen III into sirohaem on the basis of their ability to complement a defined Escherichia coli (cysG) mutant. The functions of SirC and -B were investigated by direct enzyme assay, where SirC was found to act as a precorrin-2 dehydrogenase, generating sirohydrochlorin, and SirB was found to act as a ferrochelatase responsible for the final step in sirohaem synthesis. CbiX, a protein found encoded within the main B. megaterium cobalamin biosynthetic operon, shares a high degree of similarity with SirB and acts as the cobaltochelatase associated with cobalamin biosynthesis by inserting cobalt into sirohydrochlorin. CbiX contains an unusual histidine-rich region in the C-terminal portion of the protein, which was not found to be essential in the chelation process. Sequence alignments suggest that SirB and CbiX share a similar active site to the cobaltochelatase, CbiK, from Salmonella enterica.
SummaryCobalamin (vitamin B12) production in Bacillus megaterium has served as a model system for the systematic evaluation of single and multiple directed molecular and genetic optimization strategies. Plasmid and genome‐based overexpression of genes involved in vitamin B12 biosynthesis, including cbiX, sirA, modified hemA, the operons hemAXCDBL and cbiXJCDETLFGAcysGAcbiYbtuR,and the regulatory gene fnr, significantly increased cobalamin production. To reduce flux along the heme branch of the tetrapyrrole pathway, an antisense RNA strategy involving silencing of the hemZ gene encoding coproporphyrinogen III oxidase was successfully employed. Feedback inhibition of the initial enzyme of the tetrapyrrole biosynthesis, HemA, by heme was overcome by stabilized enzyme overproduction. Similarly, the removal of the B12 riboswitch upstream of the cbiXJCDETLFGAcysGAcbiYbtuRoperon and the recombinant production of three different vitamin B12 binding proteins (glutamate mutase GlmS, ribonucleotide triphosphate reductase RtpR and methionine synthase MetH) partly abolished B12‐dependent feedback inhibition. All these strategies increased cobalamin production in B. megaterium. Finally, combinations of these strategies enhanced the overall intracellular vitamin B12 concentrations but also reduced the volumetric cellular amounts by placing the organism under metabolic stress.
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