Enterotoxigenic Escherichia coli or Vibrio cholerae 569B (Inaba) grown in the presence of the antibiotic lincomycin, an inhibitor of protein synthesis, produced elevated levels of heat-labile enterotoxin or choleragen, respectively, as assayed by both vascular permeability factor and capacity to elicit fluid accumulation in rabbit ileal loops. This induction of enterotoxin did not reflect either a coupling of lincomycin resistance with increased enterotoxigenicity or an effect of lincomycin on cellular release of enterotoxin, since spontaneously isolated lincomycin-resistant mutants ofboth E. coli and V. cholerae still required lincomycin for induction, and large increases in E. coli permeability factor activity were found intracellularly as well as extracellularly. After the period of exponential growth, E. coli became refractory to induction by lincomycin, although most of the induced enterotoxin activity appeared only after this period. No increase in copy number of the enterotoxin plasmid in E. coli 711 (P307) was found in induced cells by analysis of deoxyribonucleic acid reassociation kinetics. These and other data suggest that synthesis of enterotoxin, or at least its accumulation, is normally limited by cellular factors whose synthesis is preferentially inhibited by lincomycin. A possible connection between this phenomenon and lincomycinassociated diarrhea is considered.
Both adult and baby hamsters infected intranasally with human adenovirus type 5 exhibited virologic, serologic, and histologic evidence of infection. When 8-day old hamsters were infected with 4 x 10(6) pfu, concentrations of virus up to 2 x 10(6) pfu/animal were detected in the lung, peaking on day 2. The minimum infectious dose was 1 x 10(3) pfu/animal. This model may be useful in studies of conventional and recombinant adenoviral vaccines for humans.
Increased enterotoxigenicity of Vibrio cholerae 569B grown with low concentrations of lincomycin, previously described in terms of increased extracellular biological activity (capillary permeability factor and fluid accumulation in ligated rabbit ileal loops), was further characterized. Polyacrylamide gel electrophoresis and single radial immunodiffusion showed that lincomycin-stimulated cells produced increased molar quantities of cholera toxin (CT) both extra-and intracellularly. The intracellular CT was released in comparable amounts by sonication, deoxycholate extraction, and polymyxin B treatment. Polymyxin B release of CT was nearly complete under conditions wherein only 6% of total cellular,tf-galactosidase was released, implying a periplasmic pool of CT in stimulated cells. No intracellular choleragenoid (CT subunit B) was found in stimulated cells by polymyxin B release. No proteolysis of '4C-labeled CT was detected after prolonged incubation with sonicated nonstimulated cultures or sonicated concentrated cells. These data support the conclusion that the stimulatory effect of lincomycin involves an increase in the rate of synthesis of the CT molecule, and argue against alternative models involving inhibition of putative normal degradation of CT, increased release of otherwise cell-bound CT, or activation of inactive, or less active, forms of CT.Cholera toxin (CT) is a protein enterotoxin consisting of subunits A and B. The A portion has been shown to catalyze the intracellular ADP ribosylation and activation of adenylate cyclase (8), and it contains two polypeptide chains, Al and A2, linked by a disulfide bond (6). It appears that subunit A is synthesized as a single polypeptide chain which is nicked extracellularly to produce Al and A2 (9). The B portion, which binds to receptors of CT target cells (7), is composed of four or five identical polypeptide chains (6, 13), here denoted Bm (for monomer). The molecular weights of Al, A2, and Bm have been reported to be 23,000, 6,000, and 11,000, respectively (6).Cellular mechanisms which regulate the synthesis of cholera toxin in Vibrio cholerae are of particular interest because of both the relevance of the toxin to human health and its apparent irrelevance to the producing organism. Largely because of this absence of any known function of CT in the growth of V. cholerae, little is known about the regulation of its synthesis. As a possible means of probing this regulation, we have been examining the increased enterotoxigenicity caused by lincomycin.We have previously described large increases in extracellular CT in V. cholerae 569B when cells are grown with low concentrations of lincomycin, an inhibitor of protein synthesis (14), as measured either by capillary permeability factor or by fluid accumulation in ligated rabbit ileal loops. Heat-labile Escherichia coli enterotoxin (LT) was also shown to be increased by lincomycin (14). Data are presented here which strongly support the conclusion that lincomycin stimulates an increase in the rate of synthesis of t...
A covalent hybrid plasminogen activator was prepared from the sulfhydryl forms of the NH2-terminal A chain of human plasmin (Pln^) containing the fibrin-binding domain, and the COOH-terminal B chain of tissue plasminogen activator (t-PAB) containing the catalytic domain. The PlnA (SH)2 and t-PAB(SH) chains were mixed in a 1:1 molar ratio, and hybridization was allowed to proceed at 4 °C for 6 days. The covalent PlnA-t-PAB hybrid activator was isolated from the mixture by a two-step affinity chromatography method, with L-lysine-substituted Sepharose and Zn-chelated agarose. The protein yield of purified hybrid was 10% with a major component (77%) of Mr ∼92,000. The covalent PlnA-t-PAB hybrid activator, contained 1 mol of each chain; after reduction, it gave the two parent chains, PlnA and t-PAA, also shown to be present by double immunodiffusion. The specific plasminogen activator activity, with soluble fibrin, and the specific amidolytic activity, of the purified covalent hybrid activator was determined to be 200,000 IU/mg of protein, about 40% of the specific activity of the parent t-PA. In a fibrin clot lysis assay, the covalent hybrid activator and t-PA have similar specific fibrinolytic activities, 500,000 IU/mg of protein; however, the clot lysis time curves were not parallel. The binding of the covalent PlnA-t-PAB hybrid activator and t-PA to forming fibrin were found to be similar; at physiological fibrinogen concentrations, binding of both activators to forming fibrin was about 90%.
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