Staphylococcal Enterotoxin Gene Cluster: Prediction of Enterotoxin (SEG and SEI) Production and of the Source of Food Poisoning on the Basis of vSaß Typing.

Currently, only 5 (SEA to SEE) out of 27 known staphylococcal enterotoxins can be analyzed using commercially available kits. Six genes (seg, sei, sem, sen, seo, and seu), encoding putative and undetectable enterotoxins, are located on the enterotoxin gene cluster (egc), which is part of the Staphylococcus aureus genomic island vSaß. These enterotoxins have been described as likely being involved in staphylococcal food-poisoning outbreaks. The aim of the present study was to determine if whole-genome data can be used for the prediction of staphylococcal egc enterotoxin production, particularly enterotoxin G (SEG) and enterotoxin I (SEI). For this purpose, whole-genome sequences of 75 Staphylococcus aureus strains from different origins (food-poisoning outbreaks, human, and animal) were investigated by applying bioinformatics methods (phylogenetic analysis using the core genome and different alignments). SEG and SEI expression was tested in vitro using a sandwich enzyme-linked immunosorbent assay method. Strains could be allocated to 14 different vSaß types, each type being associated with a single clonal complex (CC). In addition, the vSaß type and CC were associated with the origin of the strain (human or cattle derived). The amount of SEG and SEI produced also correlated with the vSaß type and the CC of a strain. The present results show promising indications that the in vitro production of SEG and SEI can be predicted based on the vSaß type or CC of a strain. IMPORTANCE Besides having infectious properties in human and animals, S. aureus can produce different enterotoxins in food. The enterotoxins can cause vomiting and diarrhea, often involving many people. Most of these outbreaks remain undiscovered, as detection methods for enterotoxins are only available for a few enterotoxins but not for the more recently discovered enterotoxins G (SEG) and I (SEI). In this study, we show promising results that in vitro production of SEG and SEI can be predicted based on the whole-genome sequencing data of a strain. In addition, these data could be used to find the source (human or cattle derived) of an outbreak strain, which is the key for a better understanding of the role SEG and SEI play in foodborne outbreaks caused by S. aureus.

Tolerance to high osmolality of Lactococcus lactis subsp. lactis and cremoris is related to the activity of a betaine transport system.

Lactococcus lactis strains from the subsp. cremoris are described as more sensitive to osmotic stress than subsp. lactis strains. We examined the relation between osmotic tolerance and the activity of the betaine transporter BusA among 34 strains of L. lactis. The cremoris strains that showed reduced growth at high osmolality failed to accumulate betaine. The nature of the defect was found to vary among cremoris strains: lack of the busA encoding region, absence of synthesis or synthesis of an inactive form of BusA. The results suggest that the selection of strains well fitted to the dairy production lead to the loss of an otherwise efficient adaptation mechanism.

Fatty acid membrane composition and activation of glycine-betaine transport in Lactococcus lactis subjected to osmotic stress.

Lactococcus lactis subsp. cremoris NCDO763 accumulates glycine-betaine (betaine) when submitted to an osmotic stress with NaCl. Betaine transport activity increases with the extent of the osmotic upshock but also with growth temperature, and supplementation of the medium by Tween-80. Fatty acid analysis of the lipid fraction of L. lactis NCDO763 reveals significant modifications of the fatty acid composition of the membrane when cells are submitted to osmotic stress, high temperature or Tween-80 medium supplementation. The main modification in L. lactis membrane fatty acid composition in response to high osmolality is the increase of Cyclopropane Fatty Acid (CFA) deltaC19:0, whereas Unsaturated/Saturated ratio remains unchanged.

Genetic and biochemical characterization of a high-affinity betaine uptake system (BusA) in Lactococcus lactis reveals a new functional organization within bacterial ABC transporters.

The cytoplasmic accumulation of exogenous betaine stimulates the growth of Lactococcus lactis cultivated under hyperosmotic conditions. We report that L. lactis possesses a single betaine transport system that belongs to the ATP-binding cassette (ABC) superfamily of transporters. Through transposon mutagenesis, a mutant deficient in betaine transport was isolated. We identified two genes, busAA and busAB, grouped in an operon, busA (betaine uptake system). The transcription of busA is strongly regulated by the external osmolality of the medium. The busAA gene codes for the ATP-binding protein. busAB encodes a 573-residue polypeptide which presents two striking features: (i) a fusion between the regions encoding the transmembrane domain (TMD) and the substrate-binding domain (SBD) and (ii) a swapping of the SBD subdomains when compared to the Bacillus subtilis betaine-binding protein, OpuAC. BusA of L. lactis displays a high affinity towards betaine (K(m) = 1.7 microM) and is an osmosensor whose activity is tightly regulated by external osmolality, leading the betaine uptake capacity of L. lactis to be under dual control at the biochemical and genetic levels. A protein presenting the characteristics predicted for BusAB was detected in the membrane fraction of L. lactis. The fusion between the TMD and the SBD is the first example of a new organization within prokaryotic ABC transporters.

Deletion of the four C-terminal residues of PepC converts an aminopeptidase into an oligopeptidase.

The aminopeptidase PepC is a cysteine peptidase isolated from lactic acid bacteria. Its structural and enzymatic properties closely resembles those of the bleomycin hydrolases, a group of cytoplasmic enzymes isolated from eukaryotes. Previous biochemical and structural data have shown that the C-terminal end of PepC partially occupies the active site cleft. In this work the substrate specificity of PepC was engineered by deletion of the four C-terminal residues. The mutant PepCDelta432-435 cleaved peptide substrates as an oligopeptidase while the aminopeptidase specificity was totally abolished. The substrate size dependency indicated that PepCDelta432-435 possesses an extended binding site able to accommodate four residues of the substrate on both sides of the cleaved bond. The activity of PepCDelta432-435 towards tryptic fragments of casein revealed a preference for peptides with hydrophobic amino acids at positions P2 and P3 and for Gly, Asn and Gln at position P1. PepCDelta432-435 was shown to be highly sensitive to the thiol peptidase inhibitors leupeptin or E64 which are inefficient towards the wild-type PepC. In conclusion, deletion of the four C-terminal residues in PepC produces a new enzyme with properties resembling those of an endopeptidase from the papain family.

Catalytic properties of the cysteine aminopeptidase PepC, a bacterial bleomycin hydrolase.

PepC is a cytoplasmic thiol aminopeptidase widely conserved among lactic acid bacteria. PepC from Lactococcus lactis shares 35-38% identity with aminopeptidases of eukaryotic origins: the yeast and mammalian bleomycin hydrolases (BLMase). In this work we investigated the hydrolytic activity of PepC towards various substrates: bleomycin A2, aminoacyl-p-nitroanilides (pNA) and peptides. First, we found the bleomycin hydrolase activity of lactococcal PepC and measured similar kinetics parameters to those reported for the mammalian BLMase. Second, the results obtained on aminoacyl-pNA confirmed the capacity of the enzyme to release a broad range of amino acids and the pH activity profile suggests the presence of an ionic interaction between the enzyme and the free alpha-amino group of the substrate. Third, the aminopeptidase activity measured on peptide substrates revealed that PepC possesses an extended binding site which interacts with the peptidic backbone of the substrate. The hydrolytic efficiency is highly dependent on the length of the peptide, optimal for tetrapeptides and further enhanced by the presence of hydrophobic residues in the P' positions of the substrate. These enzymatic properties are of importance for the design of specific inhibitors and the biological function of the bleomycin hydrolases.

Experimental evidence for the essential role of the C-terminal residue in the strict aminopeptidase activity of the thiol aminopeptidase PepC, a bacterial bleomycin hydrolase.

PepCs isolated from lactic acid bacteria and bleomycin hydrolases of eukaryotic organisms are strict aminopeptidases which belong to the papain family of thiol peptidases. The structural basis of the enzymic specificity of the lactococcal PepC has been investigated by site-directed mutagenesis. The deletion of the C-terminal residue (Ala-435) abolished the aminopeptidase activity, whereas this deletion led to a new peptidase specificity. The enzymic properties of wild-type and mutant PepCs demonstrate that the terminal alpha-carboxy group plays a key role in the strict aminopeptidase activity.

Crystallization and preliminary X-ray analysis of PepC, a thiol aminopeptidase from Lactoccocus lactis homologous to bleomycin hydrolase.

Crystals of the recombinant thiol aminopeptidase PepC, from Lactoccocus lactis, have been obtained using the hanging-drop method of vapor diffusion from ammonium sulfate solutions. Crystals are rhombohedral, the space group is R32, a = 175.2 A, c = 94.5 A (hexagonal setting). The asymmetric unit probably contains one monomer of a hexameric molecule-arrangement of 300 kDa which exhibits the crystallographic point group of symmetry 32. The crystals diffract to at least 3 A resolution.

Mutations of Ha-ras p21 that define important regions for the molecular mechanism of the SDC25 C-domain, a guanine nucleotide dissociation stimulator.

The SDC25 C-domain is a very active guanine nucleotide dissociation stimulator (GDS) isolated from Saccharomyces cerevisiae which acts equally well on Ha-ras p21 and yeast RAS2. These properties make the SDC25 C-domain a suitable tool to study the basic mechanism of a GDS. The action of the SDC25 C-domain was analysed by mutation of structurally important regions of p21. Substitutions that influence the coordination of Mg2+.GDP or the interaction of the guanine ring were found to stimulate the intrinsic dissociation of GDP and suppress the action of the SDC25 C-domain. No relevant effects were observed with mutations in the phosphate binding loop L1 or by deleting the last 23 C-terminal residues of p21. Substitutions in the switch region 1 (loop L2) and 2 (loop L4) of p21 strongly impaired the action of this GDS; however, we show that this effect is not related to a decreased affinity of the SDC25 C-domain for the mutated p21. No functional competition could be found between this GDS and the catalytic domain of the human GTPase activating protein (GAP). This indicates that GDS and GAP bind to different sites of the p21.nucleotide complex, even though the same mutations in loops L2 and L4 regions affect the activity of both effectors. Since these two regions appear not to be involved directly in the interaction with GDS, we conclude that the negative effect induced by their mutation is related to their function as switches of selective conformations during the GDP to GTP exchange reaction catalysed by GDS.

Effects of ions on the intrinsic activities of c-H-ras protein p21. A comparison with elongation factor Tu.

The influence of the ionic environment on the intrinsic GTPase activity and the guanine-nucleotide interaction of Ha-ras protein p21 were studied in various experimental conditions and compared with the behaviour of elongation factor (EF) Tu. To this purpose, nucleotide-free p21 was prepared, which is much more stable than by any other reported method. Specific differences between p21 and EF-Tu were found in the action of divalent anions which strongly enhance the dissociation rate of p21.GDP without affecting that of EF-Tu. Unlike EF-Tu, the GTPase activity of p21 is only slightly dependent on the presence and concentration of monovalent cations. The concentrations of Mg2+ influencing the dissociation rate of the p21.GDP complex are much higher than for the intrinsic GTPase activity, an effect also observed for EF-Tu. These results point to two distinct roles of Mg2+: as a conformational regulator of the interaction with the substrate and as a key element for the hydrolysis of GTP. The GTPase activity of p21 is not affected by changes in pH over the range 6-9.2, different from that of EF-Tu. However, stabilization by kirromycin confers a pH independence to the GTPase of EF-Tu in the pH range 6.5-10, suggesting that the bell-shaped behaviour of this activity in the absence of the antibiotic is due to denaturation. This implies similar properties in the catalytic mechanism of these two guanine-nucleotide-binding proteins.

Structure-function relationships of elongation factor Tu as studied by mutagenesis.

We have modified elongation factor Tu (EF-Tu) from Escherichia coli via mutagenesis of its encoding tufA gene to study its function-structure relationships. The isolation of the N-terminal half molecule of EF-Tu (G domain) has facilitated the analysis of the basic EF-Tu activities, since the G domain binds the substrate GTP/GDP, catalyzes the GTP hydrolysis and is not exposed to the allosteric constraints of the intact molecule. So far, the best studied region has been the guanine nucleotide-binding pocket defined by the consensus elements typical for the GTP-binding proteins. In this area most substitutions were carried out in the G domain and were found to influence GTP hydrolysis. In particular, the mutation VG20 (in both G domain and EF-Tu) decreases this activity and enhances the GDP to GTP exchange; PT82 induces autophosphorylation of Thr82 and HG84 strongly affects the GTPase without altering the interaction with the substrate. SD173, a residue interacting with (O)6 of the guanine, abolishes the GTP and GDP binding activity. Substitution of residues Gln114 and Glu117, located in the proximity of the GTP binding pocket, influences respectively the GTPase and the stability of the G domain, whereas the double replacement VD88/LK121, located on alpha-helices bordering the GTP-binding pocket, moderately reduces the stability of the G domain without greatly affecting GTPase and interaction with GTP(GDP). Concerning the effect of ligands, EF-TuVG20 supports a lower poly(Phe) synthesis but is more accurate than wild-type EF-Tu, probably due to a longer pausing on the ribosome.(ABSTRACT TRUNCATED AT 250 WORDS)

Enhancement of the GDP-GTP exchange of RAS proteins by the carboxyl-terminal domain of SCD25.

In Saccharomyces cerevisiae, the product of the CDC25 gene controls the RAS-mediated production of adenosine 3',5'-monophosphate (cAMP). In vivo the carboxyl-terminal third of the CDC25 gene product is sufficient for the activation of adenylate cyclase. The 3'-terminal part of SCD25, a gene of S. cerevisiae structurally related to CDC25, can suppress the requirement for CDC25. Partially purified preparations of the carboxy-terminal domain of the SCD25 gene product enhanced the exchange rate of guanosine diphosphate (GDP) to guanosine triphosphate (GTP) of pure RAS2 protein by stimulating the release of GDP. This protein fragment had a similar effect on the human c-H-ras-encoded p21 protein. Thus, the SCD25 carboxyl-terminal domain can enhance the regeneration of the active form of RAS proteins.