The mevalonate auxotrophic mutant of Staphylococcus aureus can adapt to mevalonate depletion.

In this study, we attempted to adopt the auxotrophic mevalonate synthase mutant (ΔmvaS mutant) of Staphylococcus aureus to study whether a nongrowing but viable cell population is tolerant to bactericidal antibiotics. The mevalonate-depleted nongrowing ΔmvaS mutant was found tolerant to antibiotics. Surprisingly, after prolonged cultivation, we obtained stable ΔmvaS variants that were able to grow without mevalonate, which suggested unknown mechanisms for compensating undecaprenyl pyrophosphate production without mevalonate in S. aureus.

Role of N-terminal protein formylation in central metabolic processes in Staphylococcus aureus.

BACKGROUND: Bacterial protein biosynthesis usually depends on a formylated methionyl start tRNA but Staphylococcus aureus is viable in the absence of Fmt, the tRNAMet formyl transferase. fmt mutants exhibit reduced growth rates indicating that the function of certain proteins depends on formylated N-termini but it has remained unclear, which cellular processes are abrogated by the lack of formylation. RESULTS: In order to elucidate how global metabolic processes are affected by the absence of formylated proteins the exometabolome of an S. aureus fmt mutant was compared with that of the parental strain and the transcription of corresponding enzymes was analyzed to identify possible regulatory changes. The mutant consumed glucose and other carbon sources slower than the wild type. While the turnover of several metabolites remained unaltered fmt inactivation led to increases pyruvate release and, concomitantly, reduced pyruvate dehydrogenase activity. In parallel, the release of the pyruvate-derived metabolites lactate, acetoin, and alanine was reduced. The anaerobic degradation of arginine was also reduced in the fmt mutant compared to the wild-type strain. Moreover, the lack of formylated proteins caused increased susceptibility to the antibiotics trimethoprim and sulamethoxazole suggesting that folic acid-dependant pathways were perturbed in the mutant. CONCLUSIONS: These data indicate that formylated proteins are crucial for specific bacterial metabolic processes and they may help to understand why it has remained important during bacterial evolution to initiate protein biosynthesis with a formylated tRNAMet.

Pyruvate formate lyase acts as a formate supplier for metabolic processes during anaerobiosis in Staphylococcus aureus.

Previous studies demonstrated an upregulation of pyruvate formate lyase (Pfl) and NAD-dependent formate dehydrogenase (Fdh) in Staphylococcus aureus biofilms. To investigate their physiological role, we constructed fdh and pfl deletion mutants (Δfdh and Δpfl). Although formate dehydrogenase activity in the fdh mutant was lost, it showed little phenotypic alterations under oxygen-limited conditions. In contrast, the pfl mutant displayed pleiotropic effects and revealed the importance of formate production for anabolic metabolism. In the pfl mutant, no formate was produced, glucose consumption was delayed, and ethanol production was decreased, whereas acetate and lactate production were unaffected. All metabolic alterations could be restored by addition of formate or complementation of the Δpfl mutant. In compensation reactions, serine and threonine were consumed better by the Δpfl mutant than by the wild type, suggesting that their catabolism contributes to the refilling of formyl-tetrahydrofolate, which acts as a donor of formyl groups in, e.g., purine and protein biosynthesis. This notion was supported by reduced production of formylated peptides by the Δpfl mutant compared to that of the parental strain, as demonstrated by weaker formyl-peptide receptor 1 (FPR1)-mediated activation of leukocytes with the mutant. FPR1 stimulation could also be restored either by addition of formate or by complementation of the mutation. Furthermore, arginine consumption and arc operon transcription were increased in the Δpfl mutant. Unlike what occurred with the investigated anaerobic conditions, a biofilm is distinguished by nutrient, oxygen, and pH gradients, and we thus assume that Pfl plays a significant role in the anaerobic layer of a biofilm. Fdh might be critical in (micro)aerobic layers, as formate oxidation is correlated with the generation of NADH/H(+), whose regeneration requires respiration.

New architectures for Tet-on and Tet-off regulation in Staphylococcus aureus.

Inducible expression is a valuable approach for the elucidation of gene functions. Here, we present new configurations of the tetracycline-dependent gene regulation (tet) system for Staphylococcus aureus. To provide improved and expanded modes of control, strains and plasmids were constructed for the constitutive expression of tetR or a variant allele, rev-tetR(r2). The encoded regulators respond differently to the effector anhydrotetracycline (ATc), which causes target gene expression to be induced with TetR or repressed with rev-TetR. To quantify and compare regulation mediated by episomal or chromosomal (rev-)tetR constructs, expression from a chromosomal P(xyl/tet)-gfpmut2 fusion was measured. Chromosomally encoded TetR showed tight repression and allowed high levels of dose-dependent gene expression in response to ATc. Regulatory abilities were further verified using a strain in which a native S. aureus gene (zwf) was put under tet control in its native chromosomal location. Tight repression was reflected by transcript amounts, which were barely detectable under repressed conditions and high in ATc-treated cells. In reporter gene assays, this type of control, termed Tet-on, was more efficient than Tet-off regulation, in which addition of ATc causes downregulation of a target gene. The latter was achieved and quantified by direct rev-TetR control of P(xyl/tet)-gfpmut2. Additionally, TetR was used in trans to control the expression of antisense RNA for posttranscriptional gene silencing. Induction of antisense RNA expression of the fabI gene caused pronounced growth retardation lasting several hours. These results demonstrate the efficiency of the new tet systems and their flexible use for different purposes.

Marker removal in staphylococci via Cre recombinase and different lox sites.

Allelic replacement in staphylococci is frequently aided by antibiotic resistance markers that replace the gene(s) of interest. In multiply modified strains, the number of mutated genes usually correlates with the number of selection markers in the strain's chromosome. Site-specific recombination systems are capable of eliminating such markers, if they are flanked by recombinase recognition sites. In this study, a Cre-lox setting was established that allowed the efficient removal of resistance genes from the genomes of Staphylococcus carnosus and S. aureus. Two cassettes conferring resistance to erythromycin or kanamycin were flanked with wild-type or mutant lox sites, respectively, and used to delete single genes and an entire operon. After transformation of the cells with a newly constructed cre expression plasmid (pRAB1), genomic eviction of the resistance genes was observed in approximately one out of ten candidates analyzed and subsequently verified by PCR. Due to its thermosensitive origin of replication, the plasmid was then easily eliminated at nonpermissive temperatures. We anticipate that the system presented here will prove useful for generating markerless deletion mutants in staphylococci.