Vicente Monedero scite author profile

The oligomeric bifunctional HPr kinase/P‐Ser‐HPr phosphatase (HprK/P) regulates many metabolic functions in Gram‐positive bacteria by phosphorylating the phosphocarrier protein HPr at Ser46. We isolated Lactobacillus casei hprK alleles encoding mutant HprK/Ps exhibiting strongly reduced phosphatase, but almost normal kinase activity. Two mutations affected the Walker motif A of HprK/P and four a conserved C‐terminal region in contact with the ATP‐binding site of an adjacent subunit in the hexamer. Kinase and phosphatase activity appeared to be closely associated and linked to the Walker motif A, but dephosphorylation of seryl‐phosphorylated HPr (P‐Ser‐HPr) is not simply a reversal of the kinase reaction. When the hprKV267F allele was expressed in Bacillus subtilis, the strongly reduced phosphatase activity of the mutant enzyme led to increased amounts of P‐Ser‐HPr. The hprK V267F mutant was unable to grow on carbohydrates transported by the phosphoenolpyruvate:glycose phosphotransferase system (PTS) and on most non‐PTS carbohydrates. Disrupting ccpA relieved the growth defect only on non‐PTS sugars, whereas replacing Ser46 in HPr with alanine also restored growth on PTS substrates.

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Pyrophosphate-producing protein dephosphorylation by HPr kinase/phosphorylase: A relic of early life?

Mijaković

Poncet

Galinier

et al. 2002

Proc. Natl. Acad. Sci. U.S.A.

113

120

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In most Gram-positive bacteria, serine-46-phosphorylated HPr (PSer-HPr) controls the expression of numerous catabolic genes (Ϸ10% of their genome) by acting as catabolite corepressor. HPr kinase͞phosphorylase (HprK͞P), the bifunctional sensor enzyme for catabolite repression, phosphorylates HPr, a phosphocarrier protein of the sugar-transporting phosphoenolpyruvate/glycose phosphotransferase system, in the presence of ATP and fructose-1,6-bisphosphate but dephosphorylates P-Ser-HPr when phosphate prevails over ATP and fructose-1,6-bisphosphate. We demonstrate here that P-Ser-HPr dephosphorylation leads to the formation of HPr and pyrophosphate. HprK͞P, which binds phosphate at the same site as the ␤ phosphate of ATP, probably uses the inorganic phosphate to carry out a nucleophilic attack on the phosphoryl bond in P-Ser-HPr. HprK͞P is the first enzyme known to catalyze P-protein dephosphorylation via this phosphophosphorolysis mechanism. This reaction is reversible, and at elevated pyrophosphate concentrations, HprK͞P can use pyrophosphate to phosphorylate HPr. Growth of Bacillus subtilis on glucose increased intracellular pyrophosphate to concentrations (Ϸ6 mM), which in in vitro tests allowed efficient pyrophosphatedependent HPr phosphorylation. To effectively dephosphorylate P-Ser-HPr when glucose is exhausted, the pyrophosphate concentration in the cells is lowered to 1 mM. In B. subtilis, this might be achieved by YvoE. This protein exhibits pyrophosphatase activity, and its gene is organized in an operon with hprK.

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Functional Analysis of the p40 and p75 Proteins from <i>Lactobacillus casei</i> BL23

et al. 2010

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The genomes of Lactobacillus casei/paracasei and Lactobacillus rhamnosus strains carry two genes encoding homologues of p40 and p75 from L. rhamnosus GG, two secreted proteins which display anti-apoptotic and cell protective effects on human intestinal epithelial cells. p40 and p75 carry cysteine, histidine-dependent aminohydrolase/peptidase (CHAP) and NLPC/P60 domains, respectively, which are characteristic of proteins with cell-wall hydrolase activity. In L. casei BL23 both proteins were secreted to the growth medium and were also located at the bacterial cell surface. The genes coding for both proteins were inactivated in this strain. Inactivation of LCABL_00230 (encoding p40) did not result in a significant difference in phenotype, whereas a mutation in LCABL_02770 (encoding p75) produced cells that formed very long chains. Purified glutathione-S-transferase (GST)-p40 and -p75 fusion proteins were able to hydrolyze the muropeptides from L. casei cell walls. Both fusions bound to mucin, collagen and to intestinal epithelial cells and, similar to L. rhamnosus GG p40, stimulated epidermal growth factor receptor phosphorylation in mouse intestine ex vivo. These results indicate that extracellular proteins belonging to the machinery of cell-wall metabolism in the closely related L. casei/paracasei-L. rhamnosus group are most likely involved in the probiotic effects described for these bacteria

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