FNR-Type Regulator GoxR of the Obligatorily Aerobic Acetic Acid Bacterium Gluconobacter oxydans Affects Expression of Genes Involved in Respiration and Redox Metabolism.

Gene expression in the obligately aerobic acetic acid bacterium Gluconobacter oxydans responds to oxygen limitation, but the regulators involved are unknown. In this study, we analyzed a transcriptional regulator named GoxR (GOX0974), which is the only member of the fumarate-nitrate reduction regulator (FNR) family in this species. Evidence that GoxR contains an iron-sulfur cluster was obtained, suggesting that GoxR functions as an oxygen sensor similar to FNR. The direct target genes of GoxR were determined by combining several approaches, including a transcriptome comparison of a ΔgoxR mutant with the wild-type strain and detection of in vivo GoxR binding sites by chromatin affinity purification and sequencing (ChAP-Seq). Prominent targets were the cioAB genes encoding a cytochrome bd oxidase with low O2 affinity, which were repressed by GoxR, and the pnt operon, which was activated by GoxR. The pnt operon encodes a transhydrogenase (pntA1A2B), an NADH-dependent oxidoreductase (GOX0313), and another oxidoreductase (GOX0314). Evidence was obtained for GoxR being active despite a high dissolved oxygen concentration in the medium. We suggest a model in which the very high respiration rates of G. oxydans due to periplasmic oxidations cause an oxygen-limited cytoplasm and insufficient reoxidation of NAD(P)H in the respiratory chain, leading to inhibited cytoplasmic carbohydrate degradation. GoxR-triggered induction of the pnt operon enhances fast interconversion of NADPH and NADH by the transhydrogenase and NADH reoxidation by the GOX0313 oxidoreductase via reduction of acetaldehyde formed by pyruvate decarboxylase to ethanol. In fact, small amounts of ethanol were formed by G. oxydans under oxygen-restricted conditions in a GoxR-dependent manner.IMPORTANCEGluconobacter oxydans serves as a cell factory for oxidative biotransformations based on membrane-bound dehydrogenases and as a model organism for elucidating the metabolism of acetic acid bacteria. Surprisingly, to our knowledge none of the more than 100 transcriptional regulators encoded in the genome of G. oxydans has been studied experimentally until now. In this work, we analyzed the function of a regulator named GoxR, which belongs to the FNR family. Members of this family serve as oxygen sensors by means of an oxygen-sensitive [4Fe-4S] cluster and typically regulate genes important for growth under anoxic conditions by anaerobic respiration or fermentation. Because G. oxydans has an obligatory aerobic respiratory mode of energy metabolism, it was tempting to elucidate the target genes regulated by GoxR. Our results show that GoxR affects the expression of genes that support the interconversion of NADPH and NADH and the NADH reoxidation by reduction of acetaldehyde to ethanol.

Identification of a terminal rhamnopyranosyltransferase (RptA) involved in Corynebacterium glutamicum cell wall biosynthesis.

A bioinformatics approach identified a putative integral membrane protein, NCgl0543, in Corynebacterium glutamicum, with 13 predicted transmembrane domains and a glycosyltransferase motif (RXXDE), features that are common to the glycosyltransferase C superfamily of glycosyltransferases. The deletion of C. glutamicum NCgl0543 resulted in a viable mutant. Further glycosyl linkage analyses of the mycolyl-arabinogalactan-peptidoglycan complex revealed a reduction of terminal rhamnopyranosyl-linked residues and, as a result, a corresponding loss of branched 2,5-linked arabinofuranosyl residues, which was fully restored upon the complementation of the deletion mutant by NCgl0543. As a result, we have now termed this previously uncharacterized open reading frame, rhamnopyranosyltransferase A (rptA). Furthermore, an analysis of base-stable extractable lipids from C. glutamicum revealed the presence of decaprenyl-monophosphorylrhamnose, a putative substrate for the cognate cell wall transferase.

The serine hydroxymethyltransferase gene glyA in Corynebacterium glutamicum is controlled by GlyR.

Serine hydroxymethyltransferase (SHMT) occupies a central position in one-carbon metabolism, and we here study its regulation in Corynebacterium glutamicum. Enzyme quantifications revealed an about 3-fold increase of SHMT activity during exponential growth with a further increase at the onset of the stationary phase. The SHMT encoding glyA gene was shown to be transcribed as a monocistronic mRNA, and its transcriptional start site was determined. Using DNA affinity chromatography the regulator GlyR (Cg0527) was identified and its chromosomal deletion shown to abolish the increase in SHMT activity in the stationary phase. The involvement of GlyR in glyA control was further confirmed by a transcriptional fusion of the glyA promoter with cat and chloramphenicol acetyltransferase quantifications. GlyR was isolated and mutational studies together with electrophoretic mobility shift assays showed that it binds to the imperfect palindromic motif CACT-N(2)-AATG in the -119 to -96 upstream region of the glyA promoter. These and further data illustrate that the essential SHMT has highest activity in the stationary phase and that GlyR acts as an activator of glyA transcription in this growth phase.

Reduced folate supply as a key to enhanced L-serine production by Corynebacterium glutamicum.

The amino acid L-serine is required for pharmaceutical purposes, and the availability of a sugar-based microbial process for its production is desirable. However, a number of intracellular utilization routes prevent overproduction of L-serine, with the essential serine hydroxymethyltransferase (SHMT) (glyA) probably occupying a key position. We found that constructs of Corynebacterium glutamicum strains where chromosomal glyA expression is dependent on Ptac and lacIQ are unstable, acquiring mutations in lacIQ, for instance. To overcome the inconvenient glyA expression control, we instead considered controlling SHMT activity by the availability of 5,6,7,8-tetrahydrofolate (THF). The pabAB and pabC genes of THF synthesis were identified and deleted in C. glutamicum, and the resulting strains were shown to require folate or 4-aminobenzoate for growth. Whereas the C. glutamicum DeltasdaA strain (pserACB) accumulates only traces of L-serine, with the C. glutamicum DeltapabABCDeltasdaA strain (pserACB), L-serine accumulation and growth responded in a dose-dependent manner to an external folate supply. At 0.1 mM folate, 81 mM L-serine accumulated. In a 20-liter controlled fed-batch culture, a 345 mM L-serine accumulation was achieved. Thus, an efficient and highly competitive process for microbial l-serine production is available.

Metabolic engineering of Corynebacterium glutamicum for L-serine production.

Although L-serine proceeds in just three steps from the glycolytic intermediate 3-phosphoglycerate, and as much as 8% of the carbon assimilated from glucose is directed via L-serine formation, previous attempts to obtain a strain producing L-serine from glucose have not been successful. We functionally identified the genes serC and serB from Corynebacterium glutamicum, coding for phosphoserine aminotransferase and phosphoserine phosphatase, respectively. The overexpression of these genes, together with the third biosynthetic serA gene, serA(delta197), encoding an L-serine-insensitive 3-phosphoglycerate dehydrogenase, yielded only traces of L-serine, as did the overexpression of these genes in a strain with the L-serine dehydratase gene sdaA deleted. However, reduced expression of the serine hydroxymethyltransferase gene glyA, in combination with the overexpression of serA(delta197), serC, and serB, resulted in a transient accumulation of up to 16 mM L-serine in the culture medium. When sdaA was also deleted, the resulting strain, C. glutamicum delta sdaA::pK18mobglyA'(pEC-T18mob2serA(delta197)CB), accumulated up to 86 mM L-serine with a maximal specific productivity of 1.2 mmol h(-1) g (dry weight)(-1). This illustrates a high rate of L-serine formation and also utilization in the C. glutamicum wild type. Therefore, metabolic engineering of L-serine production from glucose can be achieved only by addressing the apparent key position of this amino acid in the central metabolism.