Are meteorological parameters associated with acute respiratory tract infections?

BACKGROUND: Information on the onset of epidemics of acute respiratory tract infections (ARIs) is useful in timing preventive strategies (eg, the passive immunization of high-risk infants against respiratory syncytial virus [RSV]). Aiming at better predictions of the seasonal activity of ARI pathogens, we investigated the influence of climate on hospitalizations for ARIs. METHODS: Samples obtained from 3044 children hospitalized with ARIs in Mainz, Germany, were tested for pathogens with a multiplex reverse-transcriptase polymerase chain reaction enzyme-linked immunosorbent assay from 2001 through 2006. Hospitalizations for ARIs were correlated with meteorological parameters recorded at the University of Mainz. The frequency of hospitalization for RSV infection was predicted on the basis of multiple time series analysis. RESULTS: Influenza A, RSV, and adenovirus were correlated with temperature and rhinovirus to relative humidity. In a time series model that included seasonal and climatic conditions, RSV-associated hospitalizations were predictable. CONCLUSIONS: Seasonality of certain ARI pathogens can be explained by meteorological influences. The model presented herein is a first step toward predicting annual RSV epidemics using weather forecast data.

Mutations are involved in emergence of aminoglycoside-induced small colony variants of Staphylococcus aureus.

Staphylococcus aureus small colony variants (SCVs) occur frequently after local treatment with aminoglycosides and cause persistent as well as recurrent infections. So far, the molecular mechanism of the emergence of SCVs is not understood and regulatory as well as genetic mechanisms seem conceivable. To screen for possible mutations, the hemin biosynthetic gene cluster of a gentamicin-induced SCV was sequenced and was found to contain a deletion in the gene hemH. To further assess the influence of a high mutation rate on the development of SCVs, we tested the emergence of SCVs in a strain that had been inactivated in the DNA proofreading enzyme MutS. In the mutant, spontaneous SCVs emerged 556-fold more frequently than in the parent strain. By incubation in the presence of subinhibitory concentrations of gentamicin, the SCV frequency in the parent strain could be increased to 9.7 x 10(-6), whereas it remained rather stable in the mutant (1.8 x 10(-5)). Eighty percent of the gentamicin-induced SCVs were hemin auxotrophic in contrast to only 20% of the spontaneous SCVs which may explain the large proportion of hemin auxotrophs among clinical SCVs from patients previously treated with aminoglycosides. Additionally, a clinical S. aureus SCV isolate with a mutator phenotype, indicated by the generation of rifampicin-resistant mutants at a 16-fold higher frequency than in the reference strain S. aureus NCTC 8325, was characterized. The results demonstrate that a high mutation rate favours the emergence of SCVs, and suggest that mutations in general play an important role in the development of SCVs.

An elevated mutation frequency favors development of vancomycin resistance in Staphylococcus aureus.

The emergence of intermediate vancomycin resistance, mainly in methicillin-resistant Staphylococcus aureus strains, has become a great concern. Thorough characterization of clinical and laboratory vancomycin-intermediately resistant S. aureus (VISA) strains identified multiple, resistance-associated changes most probably due to stepwise mutations. We hypothesized that an elevated mutation frequency as found, e.g., in mutator strains defective in DNA mismatch repair could allow rapid acquisition of adaptive mutations in the presence of vancomycin. We therefore subjected S. aureus RN4220 and its isogenic mutator strain, the mutS-knockout mutant RN4220DeltamutS, to a stepwise vancomycin selection procedure. Vancomycin resistance evolved much more quickly in the mutator background than in the wild type (5 versus 19 passages, respectively). In addition, a higher resistance level could be reached (MIC, 32 versus 4 micro g/ml, respectively). The susceptibility to other antibiotics with the exception of teicoplanin remained unchanged. Concomitantly with increasing vancomycin resistance, a loss of phage typeability and differences in growth behavior as well as an improved ability to regrow at high vancomycin concentrations were observed. In conclusion, an elevated mutation rate in S. aureus led to the rapid development of vancomycin resistance, indicating that a high mutation frequency could be one of the factors that favor the emergence of vancomycin resistance in S. aureus.

Physiology and antibiotic susceptibility of Staphylococcus aureus small colony variants.

Small colony variants (SCV) are slow-growing subpopulations with altered metabolism and reduced antibiotic susceptibility which, in the case of Staphylococcus aureus, can cause persisting and recurrent infections. We studied four SCVs and their corresponding parent strains: one clinical strain pair, one menaquinone-deficient spontaneous mutant, and two constructed mutants obtained by inactivation of hemB in S. aureus 8325-4 and COL, respectively. SCVs growing in chemically defined medium (CDM) with glucose limitation and enhanced buffering capacity were found to generate deltapsi of -120 to -140 mV, which is comparable to the parent strains. However, glucose is consumed inefficiently with small growth yields. In contrast to wild-type strains, deltapsi dropped immediately to values below -100 mV when glucose expired and other nutrients such as acetate and lactate did not allow for further growth. Accordingly, the sensitivity of SCVs toward antibiotics known to be taken up through deltapsi, such as aminoglycosides, dropped 10- to 30-fold when compared to the parent strain under routine MIC determination conditions. When growing in CDM, the susceptibility of SCVs varied according to the magnitude of deltapsi.