The impact of foodborne calicivirus disease: the Minnesota experience.

The first outbreaks of Norwalk virus gastroenteritis in Minnesota were confirmed in 1982. Since then, Norwalk-like caliciviruses have been recognized to be the most common cause of foodborne disease outbreaks, accounting for 41% of all confirmed foodborne outbreaks in Minnesota from 1981-1998. Although laboratory confirmation of caliciviruses in stool samples was not attempted in most of these outbreaks, all conformed to epidemiologic criteria for defining outbreaks of Norwalk virus. Since 1996, the availability of polymerase chain reaction testing at the Minnesota Department of Health has allowed for the confirmation of calicivirus infection among patients involved in epidemiologically defined outbreaks of viral gastroenteritis. Results have confirmed the usefulness of characterizing foodborne disease outbreaks by epidemiologic criteria and also confirmed the importance of human caliciviruses as the leading cause of foodborne disease outbreaks in Minnesota.

Characterization of a nucleotide stimulated aspartic proteinase in rat liver plasma membranes.

Inositol phosphoglycan molecules are believed to mediate multiple intracellular actions of insulin. They are released from plasma membranes in response to insulin binding and are transported into the cell. Release of insulin mediators is stimulated by MnATP and MgATP and is inhibited by p-aminobenzamidine. Inositol phosphoglycan mediators may be released by a poorly characterized mechanism requiring proteolytic cleavage of an attached protein from the mediator and phospholipase cleavage of the mediator from its membrane anchor. We examined rat liver plasma membranes for proteinase activity stimulated by insulin and MnATP. Although we could not demonstrate insulin stimulation, we have found and characterized a nucleotide-stimulated aspartic proteinase bound to rat liver plasma membranes. We also detected and separated a soluble activating factor for the proteinase. The activating factor appears to be a protein with M(r) approximately 70 kDa.

Insulin stimulates the biosynthesis of chiro-inositol-containing phospholipids in a rat fibroblast line expressing the human insulin receptor.

HIRc-B cells (rat fibroblasts expressing the human insulin receptor) were incubated with myo-[3H]inositol for 48 hr, and the biosynthesis of chiro-[3H]inositol was investigated in the absence and presence of insulin following a time course up to 60 min. After phase separation, treatment with insulin for 15 min caused a 2.2-fold increase in the specific radioactivity of chiro-[3H]inositol-containing phospholipids in contrast to a 1.2-fold increase in the specific radioactivity of myo-[3H]inositol-containing phospholipids. No insulin-mediated change in the specific radioactivity was observed in the inositol phosphates or free inositols. Further detailed analysis of individual [3H]inositol-containing phospholipids demonstrated marked increases in specific activity of the chiro-[3H]inositol phospholipids after 15 min of incubation with insulin: phosphatidylinositol 4-phosphate and 4,5-bisphosphate, 4.2-fold; lysophosphatidylinositol, 1.5-fold; phosphatidylinositol, 3.2-fold. In contrast, myo-[3H]inositol-containing phospholipids demonstrated relatively small increases (1.1- to 1.4-fold) after 5 min of incubation with insulin. These findings indicate that insulin stimulates de novo synthesis of chiro-inositol-containing phospholipids at the inositol phospholipid level.

Mutations in three of the putative transmembrane helices of subunit a of the Escherichia coli F1F0-ATPase disrupt ATP-driven proton translocation.

Three missense mutants in subunit a of the Escherichia coli F1F0-ATPase were isolated and characterized after hydroxylamine mutagenesis of a plasmid carrying the uncB (subunit a) gene. The mutations resulted in Asp119----His, Ser152----Phe, or Gly197----Arg substitutions in subunit a. Function was not completely abolished by any of the mutations. The F0 membrane sector was assembled in all three cases as judged by restoration of dicyclohexylcarbodiimide sensitivity to the F1F0-ATPase. The H+ translocation capacity of F0 was reduced in all three mutants. ATP-driven H+-translocation was also reduced, with the response in the Gly197----Arg mutant being almost nil and that in the Asp119----His and Ser152----Phe mutants less severely affected. The substituted residues are predicted to lie in the second, third, and fourth transmembrane helices suggested in most models for subunit a. The Gly197----Arg mutation lies in a very conserved region of the protein and the substitution may disrupt a structure that is critical to function. The Asp119----His and Ser152----Phe mutations also lie in areas with sequence conservation. A further analysis of randomly generated mutants may provide more information on regions of the protein that are crucial to function. Heterodiploid transformants, carrying plasmids with either the wild-type uncB gene or mutant uncB genes in an uncB (Trp231----stop) background, were characterized biochemically. The truncated subunit a was not detected in membranes of the background strain by Western blotting, and the uncB+ plasmid complemented strain showed normal biochemistry. The uncB mutant genes were shown to cause equivalent defects in either the heterodiploid background configuration, or after incorporation into an otherwise wild-type unc operon. The subunit a (Trp231----stop) background strain was shown to bind F1-ATPase nearly normally despite lacking subunit a in its membrane.

Mutations in the conserved proline 43 residue of the uncE protein (subunit c) of Escherichia coli F1F0-ATPase alter the coupling of F1 to F0.

The conserved Pro43 residue of the uncE protein (subunit c) of the Escherichia coli F1F0-ATPase was changed to Ser or Ala by oligonucleotide-directed mutagenesis, and the mutations were incorporated into the chromosome. The resultant mutant strains were capable of oxidative phosphorylation as indicated by their ability to grow on succinate and had growth yields on glucose that were 80-90% of wild type. Membrane vesicles from the mutants were slightly less efficient than wild type vesicles in ATP-driven proton pumping as indicated by ATP-dependent quenching of quinacrine fluorescence. The decreased quenching response was not due to increased H+ leakiness of the mutant membranes or to loss of F1-ATPase activity from the membrane. These results indicate that the mutant F1F0-ATPases are defective in coupling ATP hydrolysis to H+ translocation. The membrane ATPase activity of the mutants was inhibited less by dicyclohexylcarbodiimide than that of wild type. The decrease in sensitivity to inhibition by dicyclohexylcarbodiimide was caused primarily by dissociation of the F1-ATPase from the mutant F0 in the ATPase assay mixture. These results support the idea that Pro43, and neighboring conserved polar residues play an important role in the binding and functional coupling of F1 to F0. Although a Pro residue is found at position 43 in all species of subunit c studied, surprisingly, it is not absolutely essential to function.

Mutations altering aspartyl-61 of the omega subunit (uncE protein) of Escherichia coli H+ -ATPase differ in effect on coupled ATP hydrolysis.

Mutations in the H+-translocating ATPase complex (F1F0) of Escherichia coli have been described in which aspartyl-61 of the omega subunit ( uncE protein) is substituted by either glycine ( uncE105 ) or asparagine ( uncE107 ). Either substitution blocks the H+-translocation activity of the F0 sector of the complex. Here we report a difference in the effects of the two substitutions on the coupled ATPase activity of F1 bound to F0. Wild-type F1 was bound to the F0 of either mutant with affinities comparable to wild-type. The ATPase activity of F1 bound to uncE107 F0 was inhibited by 50%, whereas that bound to uncE105 F0 was not inhibited. Complementation studies with a pBR322-derived plasmid that carried the E gene of the unc operon only indicated that a single mutation in the host strain was responsible for the respective phenotypes. In mutants complemented by the uncE + plasmid, restoration of wild-type biochemical properties was only partial and may be attributed to a mixing of wild-type and mutant omega subunits in a hybrid F0 complex. The activity of membrane-bound F1 was less inhibited in the uncE +/ uncE107 hybrid. Paradoxically, complementation of uncE105 by the uncE + plasmid resulted in substantial inhibition of the activity of membrane-bound F1. The results indicate that a glycine-versus-asparagine substitution for aspartyl-61 must lead to altered conformations of omega and that these differences in conformation are important in the coupling between the F0 and F1 sectors of the complex.