Alteration of the Pathogenicity of Pasteurella pneumotropica for the Murine Lung Caused by Changes in Pulmonary Antibacterial Activity

Pasteurella pneumotropica is a potential pulmonary pathogen in mice. In healthy animals, this organism was killed rapidly by the normal function of the intrapulmonary phagocytic defense mechanisms. Impairment of this bactericidal activity by the acute renal failure of nephrectomy resulted in multiplication of the Pasteurella in the lung, both when the animals were nephrectomized first and then infected, and when the animals were infected first and nephrectomized several hours after the infection. The study demonstrates that the pathogenicity of the Pasteurella organisms is governed by the functional state of these pulmonary antibacterial mechanisms.     

The Last Passage: Recovering a Death of Our Own

The Last Passage: Recovering. Death of Our Own. Donald Heinz. New York: Oxford University Press. 1999. 296 pp.     

The electrophysiological properties of the resting thyroid follicular cell

Glass microelectrodes have been useful in the study of the electrical properties of the resting thyroid follicular cell membrane. The resting transmembrane potential (RMP) has probably been underestimated in earlier work, possible as a result of leak artefacts, and it is clear that in most species the RMP is certainly greater than -60 mV. The ratio of membrane Na+ permeability to K+ permeability (PNa/PK) is of the order of 0.07 to 0.08, and Cl- is possibly (although not definitely) distributed in a passive fashion across the cell membrane, indicating that the transmembrane K+ gradient is the most important factor in the generation of the RMP. The existence of an electrogenic sodium pump in the follicular cell membrane has been demonstrated: the pump contributes about -2 mV to the RMP under control conditions. Follicular cells are completely electrically coupled, the basic coupled cellular unit probably being equivalent to the individual thyroid follicle, and the specific membrane resistance and specific membrane capacitance have been calculated to be 5 k omega. cm2 and 3.6 microF/cm2 respectively.     

Mobilization of Haemophilus influenzae chromosomal markers by an Escherichia coli F'' factor.

Filter matings between E. coli K-12 strains carrying an F'::Tn5,Tn9 factor with H. influenzae Rd strains gave rise to kanamycin-chloramphenicol-resistant H. influenzae strains at a frequency of approximately 10(-6). Transfer of the F' factor to H. influenzae was verified by expression of unselected markers in H. influenzae (lac+ or cotransfer of the nonselected antibiotic resistance), physical presence of a high-molecular-weight plasmid in recipient H. influenzae cells, and detection by Southern hybridization analysis of DNA sequences specific for the F' factor replication and partition functions in recipient H. influenzae cells. H. influenzae (F' Tn5,Tn9) strains were capable of transferring kanamycin and chloramphenicol resistances to other H. influenzae strains and were capable of mobilizing H. influenzae chromosomal markers at a low frequency. Insertion of a Tn5 element in the H. influenzae genome near the novobiocin resistance gene increased the frequency of transfer of novobiocin resistance about 30-fold. Transfer of other chromosomal markers also increased, although to a lesser extent, and ordered transfer of chromosomal markers could be demonstrated. Gene transfer was insensitive to DNase I, and transfer of chromosomal (but not F' factor) markers was dependent on the H. influenzae rec-1 and rec-2 gene functions.     

Nucleotide sequence of the gene for the hole-forming toxin aerolysin of Aeromonas hydrophila.

The gene for the hole-forming toxin aerolysin from Aeromonas hydrophila was sequenced. Although most of the sequence seems unrelated to that of Staphylococcus aureus alpha-toxin, both proteins are very hydrophilic, and they each contain a nearly identical string of 10 amino acids.     

Kinetic characterization of yeast alcohol dehydrogenases. Amino acid residue 294 and substrate specificity

A three-dimensional model of yeast alcohol dehydrogenase, based on the homologous horse liver enzyme, was used to compare the substrate binding pockets of the three isozymes (I, II, and III) from Saccharomyces cerevisiae and the enzyme from Schizosaccharomyces pombe. Isozyme I and the S. pombe enzyme have methionine at position 294 (numbered as in the liver enzyme, corresponding to 270 in yeast), whereas isozymes II and III have leucine. Otherwise the active sites of the S. cerevisiae enzymes are the same. All four wild-type enzymes were produced from the cloned genes. In addition, oligonucleotide-directed mutagenesis was used to change Met-294 in alcohol dehydrogenase I to leucine. The mechanisms for all five enzymes were predominantly ordered with ethanol (but partially random with butanol) at pH 7.3 and 30 degrees C. The wild-type alcohol dehydrogenases and the leucine mutant had similar kinetic constants, except that isozyme II had 10-20-fold smaller Michaelis and inhibition constants for ethanol. Thus, residue 294 is not responsible for this difference. Apparently, substitutions outside of the substrate binding pocket indirectly affect the interactions of the alcohol dehydrogenases with ethanol. Nevertheless, the substitution of methionine with leucine in the substrate binding site of alcohol dehydrogenase I produced a 7-10-fold increase in reactivity (V/Km) with butanol, pentanol, and hexanol. The higher activity is due to tighter binding of the longer chain alcohols and to more rapid hydrogen transfer.