Detailed four-way comparative mapping and gene order analysis of the canine ctvm locus reveals evolutionary chromosome rearrangements.

Canine tricuspid valve malformation (CTVM) maps to canine chromosome 9 (CFA9), in a region syntenic with gene-dense human chromosome 17q. To define synteny blocks, we analyzed 148 markers on CFA9 using radiation hybrid mapping and established a four-way comparative map for human, mouse, rat, and dog. We identified a large number of rearrangements, allowing us to reconstruct the evolutionary history of individual synteny blocks and large chromosomal segments. A most parsimonious rearrangement scenario for all four species reveals that human chromosome 17q differs from CFA9 and the syntenic rodent chromosomes through two macroreversals of 9.2 and 23 Mb. Compared to a recovered ancestral gene order, CFA9 has undergone 11 reversals of <3 Mb and 2 reversals of >3 Mb. Interspecies reuse of breakpoints for micro- and macrorearrangements was observed. Gene order and content of the ctvm interval are best extrapolated from murine data, showing that multispecies genome rearrangement scenarios contribute to identifying gene content in canine mapping studies.

Genetic variation and inferences about perceived taste intensity in mice and men.

The study of genetic variation in taste produces parallels between mice and men. In mice, genetic variation across strains has been documented with psychophysical and anatomical measures as well as with recordings from whole nerves. In humans, the variation has been documented with psychophysical and anatomical measures. Whole-nerve recordings from animals and psychophysical ratings of perceived intensities from human subjects have a similar logical limitation: absolute comparisons across individuals require a standard stimulus that can be assumed equally intense to all. Comparisons across whole-nerve recordings are aided by single-fiber recordings. Comparisons across psychophysical ratings of perceived intensity have been aided by recent advances in methodology; these advances now reveal that the magnitude of genetic variation in human subjects is larger than previously suspected. In females, hormones further contribute to variation in taste. There is evidence that the ability to taste (particularly bitter) cycles with hormones in women of child-bearing age, rises to a maximum early in pregnancy and declines after menopause. Taste affects food preferences, which in turn affect dietary behavior and thus disease risks. Valid assessment of taste variation now permits measurement of the impact of taste variation on health. Advances in psychophysical methodology were essential to understanding genetic variation in taste. In turn, the association of perceived taste intensities with tongue anatomy now provides a new tool for psychophysics. The ability of a psychophysical scale to provide across-subject comparisons can be assessed through its ability to show the fungiform papillae density-taste association.

Differential effects of mucosal pH on human (Caco-2) intestinal epithelial cell motility, proliferation, and differentiation.

Mucosal pH abnormalities are associated with anastomotic dehiscence, ischemia, and malignancy. We postulated that intraluminal pH influences intestinal epithelial motility, proliferation, and differentiation and studied extracellular pHo (7.0-8.5) effects on human (Caco-2) intestinal epithelial motility, proliferation, and differentiation. Mucosal healing was modeled by sheet migration and differentiation by alkaline phosphatase and dipeptidyl dipeptidase specific activity. In parallel differentiation and motility studies, we inhibited proliferation with mitomycin to dissociate indirect mitogenic effects. Intracellular pHi was quantitated using BCECF/AM at varying extracellular pHo and in migrating cells. Motility was maximal at pHo 7.6 and proliferation at 7.2. Each decreased with acidity and alkalinity. By contrast, brush border enzyme activity was lowest at pHo 7.0 and highest at pHo 8.5. pHi was highest at pHo 8.5. Migrating cell pHi was higher than static cell pHi. Thus, extracellular pHo deviations perturb Caco-2 pHi homeostasis and motility. Alkalinity promotes differentiation while acidity induces proliferation and limits differentiation.

Teicoplanin-resistant Staphylococcus aureus expresses a novel membrane protein and increases expression of penicillin-binding protein 2 complex.

In the recent clinical trials of teicoplanin therapy of endocarditis caused by Staphylococcus aureus, at least one instance of the emergence of teicoplanin-resistant strains during therapy has been reported (G.W. Kaatz, S. M. Seo, N. J. Dorman, and S. A. Lerner, J. Infect. Dis 162:103-108, 1990). We have confirmed, using conventional electrophoresis of EcoRI-digested chromosomal DNA and pulsed-field gel electrophoresis of SmaI-digested chromosomal DNA, that the resistant strain (12873) (MIC, 16 micrograms/ml) is genetically very similar to the susceptible parent (12871) (MIC, 4 micrograms/ml). Kaatz et al. were able to select spontaneous teicoplanin-resistant mutants (10(-9)), suggesting that a single gene might be involved. We have shown that the mutation is highly stable during growth in the absence of teicoplanin. Using Tn551, we have selected insertion mutants of 12873 that become teicoplanin susceptible. We have examined a number of aspects of cell wall physiology in strains 12871 and 12873 and the teicoplanin-susceptible Tn551 mutants of 12873. 12873 was more susceptible to lysostaphin lysis than 12871 and the susceptible Tn551 derivatives of 12873. Autolysis in phosphate buffer (pH 7.5) and cell wall turnover rates were similar in 12871 and 12873. An analysis of membrane proteins revealed the expression of a ca. 35-kDa protein and increased expression of both polypeptides of penicillin-binding protein (PBP) 2 (PBP2) in 12873 relative to 12871 and the Tn551 mutants of 12873. This increased expression was not related to PBP2', since both strains were susceptible to oxacillin in 2% NaCl (MIC, < or = 0.25 microgram/ml) and cellular DNA from neither strain hybridized with a specific mec gene probe. Two independent Tn551 inserts have been mapped to a ca. 117-kb SmaI fragment of the chromosome. These data suggest the possibility that the mutation resulting in resistance to teicoplanin involves the regulation of expression of both polypeptides of PBP2 and a 35-kDa membrane protein.

Resistance to cefoperazone-sulbactam in Klebsiella pneumoniae: evidence for enhanced resistance resulting from the coexistence of two different resistance mechanisms.

We investigated the in vitro activity and the in vivo efficacy of the beta-lactam-beta-lactamase inhibitor combination cefoperazone-sulbactam against an isogenic series of Klebsiella pneumoniae strains. Both cefoperazone and cefoperazone-sulbactam were active in vitro against a susceptible clinical strain, and the combination was highly effective in the treatment of rat intra-abdominal abscesses. Loss of expression of a 39-kDa outer membrane protein resulted in at least a fourfold increase in the MICs of cefoperazone and cefoperazone-sulbactam but did not appreciably affect the in vivo efficacy of either regimen. Introduction of plasmid RP4, which encodes the TEM-2 beta-lactamase, into the susceptible strain resulted in the loss of in vitro activity and in vivo efficacy for cefoperazone. The in vitro activity of cefoperazone-sulbactam against this strain was diminished, but the antibiotic combination remained highly active in vivo. Introduction of RP4 into the strain lacking the 39-kDa outer membrane protein resulted in a fourfold increase in the in vitro MIC of cefoperazone-sulbactam in comparison with the beta-lactamase-producing susceptible strain and resulted in a loss of in vivo efficacy against infections caused by this strain. These results suggest that the combination of different resistance mechanisms, neither of which alone results in substantially diminished cefoperazone-sulbactam efficacy in vivo, can cause in vivo resistance to the beta-lactam-beta-lactamase inhibitor combination in K. pneumoniae.

Vancomycin resistance in Enterococcus gallinarum.

The vancomycin resistance expressed by several strains of Enterococcus gallinarum was studied. Resistance was expressed constitutively, as demonstrated by analysis of growth and inhibition of peptidoglycan synthesis. E. gallinarum strains were moderately resistant to vancomycin (MIC, 16 micrograms/ml) but were as susceptible as vancomycin-susceptible enterococci to the glycopeptides, teicoplanin, A35512B, A47934, A4103A, and A41030E and the glycopeptide actaplanins A1, B2, and C1. Vancomycin resistance in E. gallinarum was inhibited by beta-lactam antibiotics at concentrations that saturated penicillin-binding protein 6 (PBP 6), as demonstrated by binding competition experiments. Spontaneous mutants (frequency, 10(-8)) were two- to fourfold more resistant to beta-lactam inhibition of vancomycin resistance than the parent strain. PBP binding competition experiments suggested that PBP 6 in the mutants bound less cefotaxime, while binding of penicillin and cefoxitin was unaffected. Both a bioassay method and high-performance liquid chromatography showed that E. gallinarum membranes have enzymatic activity which modifies a model pentapeptide yielding a product that is thought to be a tetrapeptide. This activity could be a D,D-carboxypeptidase. In both the parent E. gallinarum strain and its derivatives that were resistant to the synergistic drug combination, the activity was inhibited by beta-lactams at concentrations which correlated with those that inhibit vancomycin resistance and those that saturate PBP 6. These results suggest the possibility that PBP 6 may be involved in the vancomycin resistance of E. gallinarum and that the putative D,D-carboxypeptidase activity seen in E. gallinarum membranes may be attributable to PBP 6.

Synergistic killing of vancomycin-resistant enterococci of classes A, B, and C by combinations of vancomycin, penicillin, and gentamicin.

Using both high and low inocula for time-kill curves, we examined the antibiotic killing of clinical isolates of glycopeptide-resistant enterococci (Enterococcus faecium, E. faecalis, and E. gallinarum) belonging to phenotypic resistance classes A, B, and C. None were resistant to high levels (greater than 500 mg/liter) of gentamicin. Vancomycin-penicillin-gentamicin resulted in 2 or more logs of killing above that of the most effective two-antibiotic combination for all strains except two of three E. gallinarum (VanC) strains and a constitutive mutant of a VanB strain. This strategy may be useful clinically.