Effects of different serotypes of Escherichia coli lipopolysaccharides on body temperature in rats

The effects of Escherichia coli O55:B5, O127:B8, and O111:B4 serotypes' lipopolysaccharides (LPS) on body temperature were investigated in rats. LPSs were injected intraperitoneally at doses of 2, 50, and 250 microg/kg. A multiphasic and no-dose dependent increase in rectal temperature was observed in response to E. coli O55:B5 LPS at all doses, and in response to E. coli O127:B8 LPS at 2 and 50 microg/kg doses. The highest dose of the latter caused a dual change in rectal temperature, in which hypothermia preceded fever. E. coli O111:B4 LPS was either pyrogenic or hypothermic at 2 and 250 microg/kg doses; respectively, whereas a dual response was observed when the 50 microg/kg dose was injected. Although dual responses were observed after administration of all LPSs at 50 microg/kg dose when the body temperature was recorded by biotelemetry, the hypothermia induced by E. coli O55:B5 LPS was significantly smaller. These data suggest that LPSs induce dose and serotype-specific variable changes on body temperature in rats. This variability may be related to the structure of LPSs. The data also indicate that LPS causes hypothermia with or without fever in rats.     

Variability in LPS composition, antigenicity and reactogenicity of phase variants of Bordetella pertussis

Comparison of lipopolysaccharides (LPS) from phase variants of different strains of Bordetella phase variants of different strains of Bordetella pertussis has shown a difference in their composition, antigenicity and reactogenicity. Phase I variants of B. pertussis, with the exception of strain 134, contain a preponderance of LPS I whereas the major component of LPS of phase IV variants is LPS II. Sera raised to LPSs of phase I strains, other than 134, cross-react with each other but not with phase IV LPSs; and similarly all sera raised to phase IV LPSs cross-react with each other and with LPS from 134 phase I. The LPSs of all phase I variants, including that of 134, are approximately ten-fold or more reactive in the limulus amoebocyte lysate assay (LAL) than phase IV LPSs. In the human mononuclear cell pyrogen assay phase IV LPSs also stimulated a lower response than phase I LPSs. The B. pertussis phase I LPSs are 10-times more reactive than Escherichia coli standard endotoxin in the LAL assay but 100-times less reactive than E. coli LPS in the monocyte test for pyrogen. The SDS-PAGE profiles of B. pertussis LPSs are quite different from those of B. parapertussis and B. bronchiseptica strains. B. pertussis LPSs produced a typical lipo-oligosaccharide (LOS) pattern. B. bronchiseptica LPS produced a similar pattern but was antigenically distinct from B. pertussis LPSs I and II. B. parapertussis in contrast produced a ladder pattern typical of smooth type LPS.     

Interaction of bacterial endotoxins with chitosan. Effect of endotoxin structure, chitosan molecular mass, and ionic strength of the solution on the formation of the complex

The interaction of endotoxins of different structure (lipopolysaccharides (LPS) and lipopolysaccharide-protein complexes (LPPC)) with chitosan has been studied. It was shown that the mechanism of interaction is rather complicated and depends on the macromolecular organization of endotoxin as well as on the degree of polymerization of the chitosan. Chitosan with molecular mass of 20 kD reveals higher affinity to LPS than chitosan with molecular mass of 140 kD. Endotoxins with long O-specific chains can bind completely with chitosan with the formation of LPS-chitosan and LPPC-chitosan complexes with weight ratios between the original components of 1:1 and 1:5. When endotoxins with higher degree of hydrophobicity and short O-specific chains were mixed with chitosan, a part of the LPS remained unbound. The stability of the complexes formed depends on ionic strength. It was shown that, in addition to electrostatic forces, other types of forces take part in the formation of the complexes. A decrease in acute toxicity of various LPSs is observed on their binding with chitosans.     

Escherichia coli lipopolysaccharides produce serotype-specific hypothermic response in biotelemetered rats

We investigated whether LPS-induced hypothermia develops in a serotype-specific manner in biotelemetered conscious rats. Two different Escherichia coli serotypes of LPSs were injected at a dose of 250 mug/kg ip. E. coli O55:B5 LPS elicited an initial hypothermia and subsequent fever, but E. coli O111:B4 LPS caused more potent monophasic hypothermia. Serum tumor necrosis factor (TNF)-alpha levels were dramatically elevated at the initial phase of the hypothermia induced by both LPSs. This elevation tended to subside at the nadir of E. coli O55:B5 LPS-induced response but progressively increased at the nadir of E. coli O111:B4 LPS hypothermia. Serum IL-10 levels were moderately elevated at the initial phase of the hypothermia and persisted at the same level at the nadir of each LPS-induced response. No change was observed at the serum IL-18 levels. A selective cyclooxygenase (COX)-1 enzyme inhibitor, valeryl salicylate (20 mg/kg sc), abolished the hypothermia without any effect on the elevated cytokine levels. Another COX-1-selective inhibitor, 5-(4-chlorophenyl)-1-(4-methoxyphenyl)-3-(trifluoromethyl)-1H-pyrazole (SC-560; 1 mg/kg sc) inhibited hypothermic responses as well. Meanwhile, cytokine levels were also reduced by SC-560 treatment. These findings suggest that LPS-induced hypothermia may have serotype-specific characteristics in rats. E. coli O111:B4 LPS has more potent hypothermic activity than E. coli O55:B5 LPS; that may presumably be related to its higher or sustained capability to release antipyretic cytokines, such as TNF-alpha. COX-1 enzyme may be involved in the generation of the hypothermia, regardless of the type of LPS administered.     

Features of a protein component of the endotoxin from Yersinia pseudotuberculosis

The protein moiety of endotoxin from Yersinia pseudotuberculosis was found to consist of two polypeptides with apparent molecular masses 40 and 14.5 kDa (4:1 w/w). The major protein (40 kDa) was isolated from the endotoxin pretreated with sodium deoxy cholate by gel chromatography on the Sephadex G-200 column. Comparative study of this protein and oligomeric form of porin from the outer membrane of Y. pseudotuberculosis using SDS--PAGE, velocity sedimentation, lipid bilayer experiments, chemical and serological analyses revealed their identity. The deoxycholate treatment of the endotoxin does not affect complexes of the major protein and LPS.     

The effect of temperature on the interaction of Yersinia pseudotuberculosis lipopolysaccharide with chitosan

The mechanism of binding of lipopolysaccharide (LPS) from Yersinia pseudotuberculosis to low-molecular-weight chitosan was investigated using sedimentation analysis, centrifugation in glycerol and percoll density gradients, and isopicnic centrifugation in cesium chloride. The LPS interaction with chitosan was shown to be a multistage process that depended on time and reaction temperature. A stable LPS-chitosan complex could be formed only after preliminary incubation of the initial components at an elevated temperature (37 degrees C). This temperature caused the LPS dissociation and promoted its binding to chitosan. The LPS binding to chitosan results in further dissociation of the endotoxin and formation of the complex with a molecular weight that is tens of times less than the initial molecular weight of LPS. The obtained complex remained stable in solutions of high ionic strength.     

Characterization of the binding of spike H protein of bacteriophage phiX174 with receptor lipopolysaccharides

The spike H protein of bacteriophage phiX174 was prepared as a hexa histidine-tagged fusion (HisH). On enzyme-linked plate assaying, HisH was found to bind specifically to the lipopolysaccharides (LPSs) of phiX174-sensitive strains, Escherichia coli C and Salmonella typhimurium Ra chemotype, having the complete oligosaccharide sequence of the R-core on the LPSs. In sharp contrast, HisH bound weakly to the LPSs of phiX174-insensitive strains, i.e. E. coli F583 (Rd(2)) lacking some terminal saccharides and E. coli O111: B4 (smooth strain) having additional O-repeats on the R-core. The fluorescence spectra of HisH changed dose-dependently in the case of the LPS of E. coli C, the intensity increasing and the emission peak shifting to the shorter wavelength side, which was attributable to the hydrophobic interaction of HisH with the LPS. The binding equilibrium was analyzed by fluorometric titration to determine the dissociation constant K(d), 7.02 +/- 0.37 microM, and the Gibbs free energy change DeltaG(0), -29.1 kJ mol(-1) (at 22 degrees C, pH 7.4). Based on the temperature dependence of (K)d in a van't Hoff plot, the standard enthalpy change DeltaH(0) and the entropy change DeltaS(0) were calculated to be +23.7 kJ mol(-1) and 179 J mol(-1) K(-1) at 22 degrees C, respectively, and this binding was thereby concluded to be an entropy-driven reaction.     

The oxidative effect of bacterial lipopolysaccharide on native and cross-linked human hemoglobin as a function of the structure of the lipopolysaccharide.

The binding of lipopolysaccharide (LPS, also known as bacterial endotoxin) to human hemoglobin is known to result in oxidation of hemoglobin to methemoglobin and hemichrome. We have investigated the effects of the LPSs from smooth and rough Escherichia coli and Salmonella minnesota on the rate of oxidation of native oxyhemoglobin A0 and hemoglobin cross-linked between the alpha-99 lysines. For cross-linked hemoglobin, both smooth LPSs produced a rate of oxidation faster than the corresponding rough LPSs, indicating the importance of the binding of LPS to the hemoglobin. The effect of the LPS appeared to be largely on the initial fast phase of the oxidation reaction, suggesting modification of the heme pocket of the alpha chains. For hemoglobin A0, the rates of oxidation produced by rough and smooth LPSs were very similar, suggesting the possibility that the effect of the LPSs was to cause dissociation of hemoglobin into dimers. The participation of cupric ion in the oxidation process was demonstrated in most cases. In contrast, the rate of oxidation of cross-linked hemoglobin by the LPSs of both the rough and smooth E. coli was not affected by the presence of chelators, suggesting that cupric ion had previously bound to these LPSs. Overall, these data suggest that the physiological effectiveness of hemoglobin solutions now being developed for clinical use may be decreased by the presence of lipopolysaccharide in the circulation of recipients.     

Determination of binding constants of lipopolysaccharides of different structure with chitosan

The interaction of endotoxins--lipopolysaccharides (LPS) different in degree of the O-specific chain polymerization--with 20- and 130-kD chitosan was studied using the competitive binding of LPS with the complex of chitosan-anionic dye (tropaeolin 000-2) and the direct binding of (125)I-labeled LPS with chitosan immobilized on Sepharose 4B. The interaction of 20-kD chitosan with LPS was non-cooperative, and immobilization of the polycation on Sepharose resulted in its binding to (125)I-labeled LPS with a positive cooperativity. The interaction of LPS possessing a long O-specific chain with 130-kD chitosan was characterized by negative cooperativity. Binding constants of LPS with the polycation and the number of binding sites per amino group of chitosan were determined. The interaction affinity and stoichiometry of the LPS-chitosan complexes significantly depend on the LPS structure and concentration in the reaction mixture. The increase in the length of carbohydrate chains of LPS results in increase in the binding constants and decrease in the bound endotoxin amount.     

Rapid purification of extracted bacterial lipopolysaccharides by continuous free-flow electrophoresis

The use of continuous free-flow electrophoresis for the purification of extracted lipopolysaccharides ( LPSs ) was investigated. Commercial (nucleic acid contaminated) LPS preparations, isolated by the hot phenol-water method of Westphal from Salmonella typhimurium and Escherichia coli 0111: B4, were analyzed. Continuous free-flow electrophoresis for purification of crude LPSs proved to be a rapid and useful means for the continuous purification of large amounts of LPS (more than 45 mg crude LPS per hr) and it showed good reproducibility and pure LPS. The electrophoretic profile of both crude LPSs obtained by continuous free-flow electrophoresis showed two distinct, sharp peaks; one representing the nucleic acid fraction and the other the LPS fraction. Under the continuous free-flow electrophoresis conditions employed, nucleic acid in the crude LPSs possessed low electrophoretic mobility, whereas LPS migration was negligible. Thus for both preparations pure LPS (no detectable nucleic acid) was obtained. Electrophoretic profiles of these purified LPSs on sodium dodecylsulfate-polyacrylamide gel electrophoresis were similar in both cases to those of crude LPS and of LPS purified by repeated ultracentrifugation. By immunological analysis using double immunodiffusion and immunoelectrophoresis, it was found that two components of crude E. coli 0111: B4 LPS were eliminated by continuous free-flow electrophoresis, but each component of purified E. coli 0111: B4 LPS was immunologically identical to the corresponding component in its crude LPS. In S. typhimurium LPS, none of its components were influenced by continuous free-flow electrophoresis but not by ultracentrifugation. In spite of these results, both purified LPSs possessed stronger mitogenic activity than each crude LPS. These results indicated that continuous free-flow electrophoresis is a useful means of purifying extracted crude LPS.     

Forming and immunological properties of some lipopolysaccharide-chitosan complexes

The complex formation of lipopolysaccharide (LPS) with chitosan (Ch) was demonstrated using sedimentation velocity analysis in the analytical ultracentrifuge, centrifugation in glycerol gradient and isopicnic centrifugation in cesium chloride. An addition of Ch to the Escherichia coli and Yersinia pseudotuberculosis LPS solutions was found to result in formation of the stable LPS-Ch complexes. The interaction is a complicated process and depends on time and reaction temperature, as well as on the molecular weight of chitosan. A stable LPS-Ch complex could be formed only after preliminary incubation of the initial components at an elevated temperature (37 degrees C). It should be noted that process of LPS complexation with Ch is accompanied by additional dissociating of LPS. The complex formation was shown to be a result not only of ionic binding, but also of other types of interactions. The interaction of Ch with LPS was shown to modulate significantly the biological activity of LPS. The LPS-Ch complex (1:5 w/w) was shown to possess much lower toxicity in a comparison with the parent LPS at injection to mice in the similar concentration. The LPS-Ch complex was shown to maintain an ability to induce of IL-8 and TNF, but induction of IL-8 and TNF biosynthesis by the LPS-Ch complex was lower than that by the parent LPS. The complex LPS-Ch, similarly to the parent LPS, was found stimulated the formation of the IL-8 in the dose-dependent manner in the human embryonal kidney cells (HEK 293 cells) transfected with TLR4 in combination with MD2.     

Structure of the O-specific polysaccharide of Proteus vulgaris O37 and close serological relatedness of the lipopolysaccharides of P. vulgaris O37 and P. vulgaris O46

The O-specific polysaccharide (O-antigen) of the lipopolysaccharide (LPS) of Proteus vulgaris O37 was studied by (1)H and (13)C nuclear magnetic resonance spectroscopy before and after O-deacetylation and found to be structurally similar to that of P. vulgaris O46 studied earlier. The two polysaccharides have the same carbohydrate backbone and differ in the position and number of the O-acetyl groups only. Studies with O-antisera against the two strains using passive hemolysis test, enzyme immunosorbent assay, and Western blot revealed close serological relatedness of the LPSs of P. vulgaris O37 and O46. The O-acetyl groups were found to be of little importance for manifesting the O-specificity but to interfere with binding of anti-P. vulgaris O37 serum to P. vulgaris O46 antigen. Based on the data obtained, it was proposed to combine the strains studied in one Proteus serogroup O37 as subgroups O37a,37b and O37a,37c. A cross-reactivity of O-antisera against P. vulgaris O37 and O46 was observed with LPSs of three more Proteus strains, which could be substantiated by the presence of a common disaccharide fragment in the O-antigens.     

Structure and biological relationships of Coxiella burnetii lipopolysaccharides

Lipopolysaccharides (LPSs) extracted from nine strains of Coxiella burnetii were analyzed for chemical compositions, molecular heterogeneity by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and lethal toxicities in galactosamine-sensitized mice. The structure of a unique disaccharide of hydrolyzed phase I LPS was determined to be galactosaminuronyl-alpha (1-6)-glucosamine (GalNU-alpha (1-6)-GlcN, C12H22N2O10) with an Mr of 354. The Mr of LPSs of C. burnetii intra- and interspecific strains and the content of GalNU-alpha (1-6)-GlcN and two sugars, virenose and dihydrohydroxystreptose, were used as biochemical markers of truncated LPSs. Smooth-phase I LPS contained all three compounds, semi-rough-phase I LPS did not contain virenose, and rough-phase II LPS contained none of the three compounds. These analyses indicate that the intermediate to larger Mr LPSs require the addition of GalNU-alpha (1-6)-GlcN and dihydrohydroxystreptose to obtain the major (10.5 kDa), the intermediate (between 10.5 and 27 kDa), and the minor (23 kDa) LPS bands. The addition of virenose to the major and the minor bands produced the large Mr phase I LPSs. Extreme microheterogeneity in the banding profile ranging in Mr from the 2.5 to 10.5 kDa may be due to unidentified components, while the microheterogeneity in Mr of the 10.5-kDa and larger LPS bands is related to variations in the compounds described here. All of the LPSs were toxic in galactosamine-sensitized mice, albeit they were 100-1000-fold less toxic than Escherichia coli and Salmonella typhimurium endotoxin.     

Structure and serologic properties of O-specific polysaccharide from Citrobacter freundii possessing cross-reactivity with Escherichia coli O157:H7

Citrobacter freundii OCU158 is a serologically cross-reactive strain with Escherichia coli O157:H7. To explore the close relationship between two strains, we have analyzed the chemical structures of O-specific polysaccharides and antigenic properties of lipopolysaccharides (LPSs) of both strains. The structure of O-specific polysaccharides from both strains was found to be identical by chemical and nuclear magnetic resonance analyses, in which D-PerNAc was 4-acetamido-4,6-dideoxy-D-mannose: [-->4)-beta-D-Glc-(1-->3)-alpha-D-PerNAc-(1-->4)-alpha-D-GalNAc-(1 --> 3)-alpha-L-Fuc-(1-->](n). The enzyme immunoassay using LPS derived either from E. coli O157 or from C. freundii could equally detect high levels of serum antibodies against LPS in patients with enterohemorrhagic E. coli (EHEC) O157 infection. Absorption of antibodies in EHEC patient serum by LPS from E. coli O157 or C. freundii, however, showed a difference in the epitopes. This difference was attributable to the epitope specificity of the core region and/or lipid A structure in LPS.     

Structural characteristics and biological properties of Pseudomonas fluorescens lipopolysaccharides

The structure and biological properties of lipopolysaccharides (LPSs) from strains IMB 4125 (=ATCC 13525) and IMB 7769 of the bacterium Pseudomonas fluorescens (biovar I) were studied in vitro. LPSs were similar in the composition of lipid A and the core lipid but differed in the structure of O-specific polysaccharide chains, which was corroborated by the absence of serological relationships between them. The toxicity (LD50) of LPSs of P. fluorescens with respect to D-glucosamine-sensitized mice was 40-50 times lower than the toxicity of the classic endotoxins, LPSs of E. coli. The LPSs studied stimulated the production of tumor necrosis factor (TNF) and nitric oxide (NO) by mouse peritoneal macrophages. The rates of TNF and NO synthesis induced by the LPSs of interest were eight to nine and three to five times lower, respectively, than the corresponding parameters of the control LPSs of E. coli 055:B5 and 026:B6. Additionally, LPS preparations of the P. fluorescens strains induced TNF synthesis by monocytes of human whole-blood preparations. Certain differences in biological properties of these strains have been revealed, which could be due to the characteristic features of LPS structure and composition in different cultures.     

Binding and biological properties of lipopolysaccharide Proteus vulgaris O25 (48/57)–chitosan complexes

In this study the negatively charged Proteus vulgaris O25 LPS was chosen for studying interaction with polycationic chitosan. The complex formation of LPS with chitosan was demonstrated using gradient centrifugation and laser interferometry method. The presented results have shown that laser interferometry method is sensitive enough for LPS–chitosan interaction studies. The changing in the ultra structure of LPS during binding with chitosan was observed by electronic microscope. The interaction of P. vulgaris O25 LPS with chitosan was shown to modulate significantly the biological activities of LPS. The toxicity of P. vulgaris O25 LPS decreased 10-fold after forming complexes with chitosan at injection to mice in the similar concentration of endotoxin. The complex LPS–chitosan was less effective than LPS alone in Limulus amabocyte lysate assay. Induction of TNF biosynthesis by LPS–chitosan complex was found to be 65% lower than that by parent LPS at concentration of 100 ng/ml.     

Effects of growth phase and boiling of enteropathogenic Escherichia coli strains on their interaction with Pseudomonas aeruginosa lectins

Escherichia coli strains from' serotypes O86, 0128 and O111 varied in their reactivity with Pseudomonas aeruginose lectins (PA-I with D-galactose specificity and PA-II which binds L-fucose, D-mannose, L-galactose and D-fructose). Generally, cells of O86 strains were agglutinated by PA-I, but not by PA-II, and those of O128 serotype were agglutinated by PA-II, and not by PA-I. Adsorption tests showed that cells of E. coli O86 strains adsorb PA-I to a greater extent than PA-II, while most E. coli O128 strains adsorbed higher amounts of PA-II. Cells of E. coli O111B4 which were not agglutinated by either Pseudomonas lectin could still adsorb both. Boiling of O86 and O128 cells frequently enhanced their agglutinability as well as their lectin adsorption capacity. The agglutinability enhancement was somewhat more prominent in boiled stationary phase cells than in log phase cells probably due to late synthesis of the O antigen components concomitantly with the heat-sensitive components (K antigens) which masked them. PA-I agglutinating activity was inhibited by the lipopolysaccharide (LPS) extracted from E. coli O86 cells, while PA-II was inhibited by the LPS extracted from E. coli O128 cells. These findings indicate that the receptors to the Pseudomonas lectins probably reside in the terminal part of the O-specific-polysaccharide of the LPSs of these bacteria.     

Escherichia coli serogroup O107/O117 lipopolysaccharide binds and neutralizes Shiga toxin 2

The AB(5) toxin Shiga toxin 2 (Stx2) has been implicated as a major virulence factor of Escherichia coli O157:H7 and other Shiga toxin-producing E. coli strains in the progression of intestinal disease to more severe systemic complications. Here, we demonstrate that supernatant from a normal E. coli isolate, FI-29, neutralizes the effect of Stx2, but not the related Stx1, on Vero cells. Biochemical characterization of the neutralizing activity identified the lipopolysaccharide (LPS) of FI-29, a serogroup O107/O117 strain, as the toxin-neutralizing component. LPSs from FI-29 as well as from type strains E. coli O107 and E. coli O117 were able bind Stx2 but not Stx1, indicating that the mechanism of toxin neutralization may involve inhibition of the interaction between Stx2 and the Gb(3) receptor on Vero cells.     

Characterization of the simultaneous binding of Escherichia coli endotoxin to Kupffer and endothelial liver cells by flow cytometry.

BACKGROUND: The triggering of cellular responses during endotoxic shock is initiated for the binding of endotoxin (lipopolysaccharide; LPS) to the cell surface. Kupffer and endothelial liver cells, involved in the removal of endotoxin from blood circulation, show in vitro a rapid response to LPS in the absence of serum. METHODS: A double-labeling fluorescent assay was designed to evaluate the binding properties of Escherichia coli O111:B4 LPS to individual endothelial and Kupffer cells in suspension, where both populations occurred in the same relative proportion as in liver. After immunolabeling of the Kupffer cell population with the monoclonal antibody ED1 conjugated to R. phycoerythrin, the binding characteristics of LPS labeled with fluorescein to both endothelial and Kupffer cells were simultaneously studied by flow cytometry in serum-free conditions. RESULTS: Specific and saturable binding of endotoxin was observed with both populations, showing properties of a receptor-mediated process. The Kupffer cell population showed a faster capacity and a higher affinity for LPS binding. The Hill coefficients indicated positive cooperativity in the LPS interaction with both populations. CONCLUSIONS: Specific endotoxin binding to liver sinusoidal cells occurs in a serum-independent manner, particularly at high LPS concentrations. Flow cytometry is a fast, precise, and efficient technique to evaluate the simultaneous interaction of a ligand with two different cell types.     

Heterogeneity of lipopolysaccharides from Yersinia pseudotuberculosis: chemical characterization of various molecular types

Prior studies have shown some unusual changes in the lipopolysaccharides (LPSs) from Yersinia pseudotuberculosis that occur when the microbe is grown at low temperature; the specific features of these LPSs in comparison with the LPSs from other enteropathogens may be due to unusual thermal adaptation mechanisms. To gain insight into this question, the chemical composition of Y. pseudotuberculosis LPS has been determined. The data indicate that two different S-form LPS species are produced in "cold"-grown bacteria. These have an identical set of bands after SDS-PAGE, similar elution profiles during gel-filtration on a Sephadex G-200 column in the presence of sodium deoxycholate, identical monosaccharide and fatty acid compositions, and similar polymerization degrees, but they have different acylation degree. On the whole, the macromolecularly different LPS populations, varying not only in their smooth or rough nature and hydrophobicity, but also in their localization in the outer membrane and, probably, their interactions with other cell components, are synthesized in "cold"-grown Y. pseudotuberculosis. The biological sense of the heterogeneity and its connection with psychrophilic and pathogenic properties of pseudotuberculosis organisms are discussed.