European surveillance study on antimicrobial susceptibility of Gram-positive anaerobic cocci.

Gram-positive anaerobic cocci (GPAC) are a heterogeneous group of microorganisms frequently isolated from local and systemic infections. In this study, the antimicrobial susceptibilities of clinical strains isolated in 10 European countries were investigated. After identification of 299 GPAC to species level, the minimum inhibitory concentrations of penicillin, imipenem, clindamycin, metronidazole, vancomycin and linezolid were determined by the agar dilution method according to the Clinical and Laboratory Standards Institute. The majority of isolates were identified as Finegoldia magna and Parvimonas micra (formerly Peptostreptococcus micros), isolated from skin and soft tissue infections. All isolates were susceptible to imipenem, metronidazole, vancomycin and linezolid. Twenty-one isolates (7%) were resistant to penicillin (n=13) and/or to clindamycin (n=12). Four isolates were resistant to both agents. The majority of resistant isolates were identified as F. magna and originated from blood, abscesses and soft tissue infections.

Conversion of glutaconate CoA-transferase from Acidaminococcus fermentans into an acyl-CoA hydrolase by site-directed mutagenesis.

The heterooctameric (alphabeta)4 glutaconate CoA-transferase (EC 2.8.3.12) from the anaerobic bacterium Acidaminococcus fermentans catalyses the transfer of CoASH from acetyl-CoA to the 1-carboxylate of glutaconate. During this reaction the glutamate residue 54 of the beta-subunit (betaE54) forms a CoA-ester. The single amino acid replacement betaE54D resulted in a drastic change of enzymatic function. The CoA-transferase activity decreased from 140 to less than 0.01 s(-1), whereas the acyl-CoA hydrolase activity increased from less than 0.01 to 16 s(-1). The new enzyme was able to catalyse the hydrolysis of glutaryl-CoA, acetyl-CoA and 3-butenoyl-CoA. Since the mutants betaE54A and betaE54N showed neither acyl-CoA hydrolase nor CoA-transferase activity, it was concluded that the aspartate carboxylate of the mutant betaE54D acted as a general base which facilitated the attack of water at the thiolester carbonyl. Surprisingly, Km for glutaryl-CoA hydrolysis by the mutant (0.7 microM) as compared to CoA-transfer by the wild-type (28 microM) was 40 times lower. A 65 kDa protein, obtained by fusing the genes, gctA-gctB, coding for glutaconate CoA-transferase, retained 30% of the wild-type activity. Comparison of the amino acid sequences of 13 related enzymes demonstrated that Nature already has applied gene fusion in the case of pig heart CoA-transferase and has been using the E --> D mutation for catalysis by a yeast acetyl-CoA hydrolase.

Glutaconate CoA-transferase from Acidaminococcus fermentans: the crystal structure reveals homology with other CoA-transferases.

BACKGROUND: Coenzyme A-transferases are a family of enzymes with a diverse substrate specificity and subunit composition. Members of this group of enzymes are found in anaerobic fermenting bacteria, aerobic bacteria and in the mitochondria of humans and other mammals, but so far none have been crystallized. A defect in the human gene encoding succinyl-CoA: 3-oxoacid CoA-transferase causes a metabolic disease which leads to severe ketoacidosis, thus reflecting the importance of this family of enzymes. All CoA-transferases share a common mechanism in which the CoA moiety is transferred from a donor (e.g. acetyl CoA) to an acceptor, (R)-2-hydroxyglutarate, whereby acetate is formed. The transfer has been described by a ping-pong mechanism in which CoA is bound to the active-site residue of the enzyme as a covalent thiol ester intermediate. We describe here the crystal structure of glutaconate CoA-transferase (GCT) from the strictly anaerobic bacterium Acidaminococcus fermentans. This enzyme activates (R)-2-hydroxyglutarate to (R)-2-hydroxyglutaryl-CoA in the pathway of glutamate fermentation. We initiated this project to gain further insight into the function of this enzyme and the structural basis for the characteristics of CoA-transferases. RESULTS: The crystal structure of GCT was solved by multiple isomorphous replacement to 2.55 A resolution. The enzyme is a heterooctamer and its overall arrangement of subunits can be regarded as an (AB)4tetramer obeying 222 symmetry. Both subunits A and B belong to the open alpha/beta-protein class and can be described as a four-layered alpha/alpha/beta/alpha type with a novel composition and connectivity of the secondary structure elements. The core of subunit A consists of seven alpha/beta repeats resulting in an all parallel central beta sheet, against which helices pack from both sides. In contrast, the centre of subunit B is formed by a ninefold mixed beta sheet. In both subunits the helical C terminus is folded back onto the N-terminal domain to form the third layer of helices. CONCLUSIONS: The active site of GCT is located at the interface of subunits A and B and is formed by loops of both subunits. The funnel-shaped opening to the active site has a depth and diameter of about 20 A with the catalytic residue, Glu54 of subunit B, at the bottom. The active-site glutamate residue is stabilized by hydrogen bonds. Despite very low amino acid sequence similarity, subunits A and B reveal a similar overall fold. Large parts of their structures can be spatially superimposed, suggesting that both subunits have evolved from a common ancestor.