Brief heat treatment increases cytotoxicity of Mannheimia haemolytica leukotoxin in an LFA-1 independent manner.

Mannheimia haemolytica is an important respiratory pathogen in cattle. Its predominant virulence factor is a leukotoxin (LKT) that is a member of the RTX family of exotoxins produced by a variety of Gram negative bacteria. LKT binds to the CD18 chain of beta(2) integrins on bovine leukocytes, resulting in cell death. In this study, we show that brief heat treatment of native LKT (95 degrees C for 3 min) results in increased cytotoxicity for BL-3 (bovine lymphoblastoid) cells. Similar heat treatment restored the activity of LKT that had been rendered inactive by incubation at 22 degrees C for 3 days. A hallmark of LKT is that its toxicity is restricted to leukocytes from cattle or other ruminant species. Surprisingly, heat treatment rendered LKT cytotoxic for human, porcine and canine leukocytes. Membrane binding studies suggested that heat-treated LKT binds to membrane proteins other than LFA-1, and is distributed diffusely along the BL-3 cell membrane. Circular Dichroism spectroscopy studies indicate that heat treatment induced a small change in the secondary structure of the LKT that was not reversed when the LKT was cooled to room temperature. Thus, we speculate that these structural changes might contribute to the altered biological properties of heat-treated LKT.

Pseudomonas syringae pv. phaseolicola genomic clones harboring heterologous DNA sequences suppress the same phaseolotoxin-deficient mutants.

Cosmid cloning and mutagenesis were used to identify genes involved in the production of phaseolotoxin, the chlorosis-inducing phytotoxin of Pseudomonas syringae pv. phaseolicola, the causal agent of halo blight of bean (Phaseolus vulgaris L.). Eight stable clones were isolated from a genomic cosmid library by en masse mating to 10 ethyl methanesulfonate (EMS)-induced Tox- mutants. In cross-matings, each suppressed all 10 mutants as well as an additional 70 EMS-induced Tox- mutants (and one UV-induced Tox- mutant). On the basis of restriction endonuclease analysis and hybridization studies, the clones were grouped into three classes. Clones in a particular class shared common fragments, whereas clones in different classes did not. Clones from class I (but not classes II and III) also suppressed Tn5-induced Tox- mutants. Interposon mutagenesis and marker exchange of a representative clone from class III into the wild-type genome did not alter its Tox+ phenotype, indicating that this clone does not harbor structural or regulatory genes involved in phaseolotoxin production. We suggest that the genome of P. syringae pv. phaseolicola contains a "hot spot" in one of the functions involved in toxin production which is affected by EMS and UV and that heterologous clones are able to suppress the Tox- phenotype because their inserts encode products that are able to substitute for the product of the mutated gene. Alternatively, the inserts may contain sequences which titrate a repressor protein. In either case, the data suggest that suppression of EMS- and UV-induced mutants occurs when heterologous clones are present in multiple copies.

Active site of Pseudomonas aeruginosa exotoxin A. Glutamic acid 553 is photolabeled by NAD and shows functional homology with glutamic acid 148 of diphtheria toxin.

Photoaffinity labeling with native NAD, a method employed earlier with diphtheria toxin (DT), was used to identify an active site residue of Pseudomonas aeruginosa exotoxin A (ETA). An enzymically active fragment (Mr 27,000), derived by partial digestion of ETA with thermolysin, was irradiated with ultraviolet light (254 nm) in the presence of various radiolabeled preparations of NAD. Label from the nicotinamide moiety was efficiently transferred to the protein (maximally 0.79 mol/mol), and the label was exclusively located at position 553. This position, like that photolabeled in DT (position 148), corresponds to glutamic acid in the native protein. Chromatographically identical photo-products were generated at these positions in the two toxins. Glu-553 lies in a cleft in domain III that is believed to represent the active site of ETA, and other evidence supports the notion that Glu-553 of ETA and Glu-148 of DT are directly involved in catalysis. When Glu-553 of ETA was aligned with Glu-148 of DT, we found similarities of local primary structure not detected earlier. These results suggest that the catalytically active domains of ETA and DT may be evolutionarily related, and they provide information that should prove useful for preparing vaccines against ETA by recombinant DNA methods.

Photoaffinity labeling of diphtheria toxin fragment A with NAD: structure of the photoproduct at position 148.

Irradiation of mixtures of diphtheria toxin fragment A and [carbonyl-14C]NAD with UV light (253.7 nm) is known to induce efficient transfer of the radiolabel to position 148, corresponding to glutamic acid in the unmodified protein. Here we report the structure of the photoproduct at position 148, as determined by chemical and photochemical methods, fast-atom-bombardment mass spectrometry, and nuclear magnetic resonance. The photoproduct [an alpha-amino-gamma-(6-nicotin-amidyl)butyric acid residue] contains the entire nicotinamide moiety of NAD linked via its number 6 carbon to the decarboxylated gamma-methylene carbon of Glu-148. No portion of the ADP-ribosyl group of NAD is present. These findings are consistent with the idea that Glu-148 lies at or near the catalytic center of diphtheria toxin.

[Effect of gamma radiation on the immunobiological and immunochemical properties of cholera exotoxin. III. The serological activity and immunochemical properties of irradiated unpurified toxin]. / Vliianie gamma-izlucheniia na immunobiologicheskie i immunokhimicheskie svoistva kholernogo ékzotoksina. Soobshchenie III. Serologicheskaia aktivnost' i immunokhimicheskie svoistva obluchennogo neochischennogo toksina.

The immunochemical properties and serological activity of irradiated preparations of crude cholera exotoxin have been studied. This study has revealed that with the increase of the dose of ionizing radiation changes occur in the physico-chemical properties of the preparations of the toxin, which leads to an increase in the electrophoretic motility of the protein components of the toxin, to the aggregation and polymerization of individual fragments. The preparations of antigen exotoxins have been shown to retain their serological activity within the range of radiation doses under study (10-350 kGy).

[Effect of gamma radiation on the immunobiological and immunochemical properties of cholera exotoxin. I. Change in the biological activity of nonpurified cholera exotoxin as affected by ionizing radiation]. / Vliianie gamma-izlucheniia na immunobiologicheskie i immunokhimicheskie svoistva kholernogo ékzotoksina. Soobshchenie I. Izmenenie biologicheskoi aktivnosti neochishchennogo kholernogo ékzotoksina pod vozdeistviem ioniziruiushchei radiatsii.

Crude cholera exotoxin (filtrate toxin) was irradiated with increasing doses of gamma radiation. A significant drop in enterotoxicity, in the activity of the permeation factor and a decrease in toxicity were shown to occur as radiation doses increased. Radiation doses of 50-70 kGy were found to completely inactivate enterotoxicity in liquid toxic preparations. A higher radioresistance of dried preparations in comparison with liquid ones was registered: inactivation occurred at 150-200 kGy. Different batches of the initial filtrate toxin had varying radiosensitivity. The sterilizing effect of gamma radiation was achieved at doses of 20 kGy for liquid preparations and 30 kGy for dried preparations. During the prolonged storage of the irradiated preparations of crude toxin (the term of observation being 1.5 years) at different temperatures no reversion of toxicity was found to occur, while their immunogenic properties remained unchanged.