Non-invasive Providencia alcalifaciens strains fail to attach to HEp-2 cells.

We investigated the adherence properties of six P. alcalifaciens strains with previously characterized differential invasive capabilities in HEp-2 cells. Highly invasive strains were found to attach to HEp-2 cell monolayers within 2 h post-infection and in large numbers on the eukaryotic cell surfaces within 3 h post-infection. In contrast, weakly or non-invasive P. alcalifaciens strains were non-adherent to HEp-2 cells even at 3 h post-infection. Highly invasive isolates were found to weakly bind F-actin using the fluorescent actin staining assay although these strains were negative for Escherichia coli attachment and effacing gene (eaeA) of enteropathogenic E. coli (EPEC). These results suggest that the strain variation in the ability of P. alcalifaciens to invade HEp-2 cells previously noted by several investigators may be linked to expression of key adhesin(s) on the cell surface of invasive isolates.

Biochemical identification and characterization of DNA groups within the Proteus vulgaris complex.

We placed 43 isolates belonging to the Proteus vulgaris complex into proposed DNA groups (genomovars) using five previously recommended tests (tests for esculin hydrolysis, production of acid from salicin, L-rhamnose fermentation, and elaboration of DNase and lipase). On the basis of the results of these five tests, 49% of the isolates fell into DNA groups 5 and 6, 37% fell into DNA group 2, and the remaining 14% fell into DNA groups 3 and 4. Sequencing of the 16S rRNA genes of 11 members of DNA groups 5 and 6 indicated that 10 of these isolates (91%) could be unambiguously assigned to one of these two genomospecies. Overall expression of selected enzymatic and virulence-associated characteristics did not differ significantly among DNA groups.

Identification and initial characterization of elastase activity associated with Vibrio cholerae.

Strains of Vibrio cholerae O1 (Ogawa, Inaba) and non-O1 serogroups have been found to produce an elastolytic protease that can be detected on 0.3% elastin agar plates or in broth cultures. The elastase enzyme appears to be maximally expressed in late log phase (14-18 h postinoculation) and has optimum activity at a pH range between 7 and 8. Comparative studies indicate that more than 60% of V. cholerae strains analyzed quantitatively produce more elastase in broth (two- to fourfold higher) than other elastase-positive Vibrio species such as Vibrio vulnificus. The V. cholerae elastase enzyme was not inhibited by trypsin, serine-protease, or thiol-protease inhibitors, but was inhibited by phosphoramidon. Ultrafiltration studies indicate the V. cholerae elastase enzyme has a molecular weight >30,000, and a 34K protein with possible elastase activity has been detected by SDS-PAGE for one non-O1 isolate (strain 2396). Cumulative results suggest that the V. cholerae elastase is probably a member of the N-type metalloprotease family and shares similar properties with other elastase enzymes described for pathogenic and nonpathogenic species in this genus.

Invasion of HEp-2 and other eukaryotic cell lines by Providenciae: further evidence supporting the role of Providencia alcalifaciens in bacterial gastroenteritis.

Wild-type strains of Providencia species were evaluated for their ability to invade HEp-2 monolayers based upon microscopic and semi-quantitative assays. Of 14 P. alcalifaciens strains tested, 3 (17%) were found to be highly invasive, 4 (22%) moderately invasive, and the remaining 61% weakly or noninvasive. HEp-2 invasion results were confirmed by thin-section electron microscopy. Invasive capabilities of P. alcalifaciens were greater at higher MOIs (100 to 1000) than at lower inocula (<10 MOI). No strain of P. stuartii or P. rettgeri tested invaded HEp-2 cells. Quantitative assays of Triton X-100-lysed, HEp-2-invaded cells indicated that between 0.001% and 0. 013% of the initial bacterial inoculum was gentamicin resistant. Further testing of select strains on various cell lines indicated the efficiency of invasion was Vero > Y1 > INT-407 > HEp-2. Two isolates recovered from a father and son with prolonged diarrhea after returning from Mexico were found to be identical on the basis of biotype, serotype, and genotype. These results provide additional evidence that some P. alcalifaciens strains cause gastroenteritis.

Biochemical and pathogenic properties of Shewanella alga and Shewanella putrefaciens.

We characterized 49 strains of Shewanella spp. from clinical (n = 31) and nonhuman (n = 18) sources. Most Shewanella alga organisms (Gilardi biovar 2; Centers for Disease Control and Prevention [CDC] biotype 2) originated from clinical material (92%), failed to produce acid from carbohydrates other than D-ribose, and were biochemically and enzymatically fairly homogeneous. In contrast, Shewanella putrefaciens organisms (Gilardi biovars 1 and 3; CDC biotype 1) were more often associated with nonhuman sources (70%), were able to utilize a number of sugars (sucrose, L-arabinose, and maltose), and were found to exhibit wider variations in biochemical characteristics; three biotypes within S. putrefaciens were detected. Notable differences between the two species in enzymatic activity, determined with the API-ZYM system (bioMérieux, Hazelwood, Mo.), and cellular fatty acid profiles, determined by the MIDI system (Microbial ID Inc., Newark, Del.), were also detected. Pathogenicity studies of mice indicate that S. alga appears to be the more virulent species, possibly due to the production of a hemolytic substance.

Four additional cases of Burkholderia gladioli infection with microbiological correlates and review.

Burkholderia gladioli has only recently been reported to be a human pathogen. Four cases of B. gladioli infection (including bacteremia, pneumonia, and cervical adenitis) in two adults and two young children are reported. Three of these four patients were severely immunocompromised. Commercial systems were frequently unable to identify this bacterium correctly. Antimicrobial susceptibility patterns indicated that B. gladioli strains were susceptible to the quinolones, aminoglycosides, and imipenem. In vitro laboratory investigations demonstrated that B. gladioli strains were susceptible to complement-mediated lysis of pooled human serum, thus implying that healthy individuals should be immune to infection. These four cases together with three previously reported cases suggest that B. gladioli primarily causes disease in severely immunocompromised individuals. The lack of mortality associated with infection, coupled with susceptibility to serum and lack of recognizable virulence-associated factors, suggests that this species has a low pathogenic potential.

Further studies on biochemical characteristics and serologic properties of the genus Aeromonas.

We characterized a collection of 268 Aeromonas isolates from diverse sources (clinical, animal, and environmental sources) for their species and serogroup designations. Overall, 97% of these strains could be identified to the genomospecies level by using an expanded battery of biochemical tests. Members of the Aeromonas hydrophila complex (A. hydrophila, HG2, and A. salmonicida), a group that has previously been difficult to separate biochemically, could easily be distinguished from one another by using a number of recently described phenotypic properties which included utilization of DL-lactate and urocanic acid. Differences in species distributions on the basis of the source of isolation were noted. Serogroup analysis of these 268 isolates plus a number of reference cultures indicated that (i) each genomospecies is serologically heterogeneous and individual serogroups can be found in more than one species, (ii) most type or reference strains for each hybridization group are not serologically representative of the genomospecies at large, (iii) serogroups O:11, O:34, and O:16 predominate clinically (48%), supporting previous studies indicating their importance in human infections, and (iv) most A. trota strains do not express the O139 antigen of Vibrio cholerae. The collective results suggest that both species and serogroup designations are important factors in establishing which isolates can cause human infections when they are acquired from nonclinical sources (foods, animals, and the environment).

Characterization of Aeromonas hydrophila strains of clinical, animal, and environmental origin expressing the O:34 antigen.

A collection of Aeromonas strains of different origins were characterized for isolates expressing the O:34 somatic antigen. Of over 200 strains tested, approximately 14% belonged to serogroup O:34 with >85% of these strains identified as A. hydrophila regardless of source. A subset of 14 A. hydrophila O:34 strains were further analyzed for a number of structural and pathogenic features. Most O:34 strains expressed similar whole-cell protein profiles with regards to minor bands, but major band differences were noted in outer membrane proteins (OMPs) migrating between the 31K and 58K region. OMP profiles could be subdivided into three distinct patterns. All O:34 strains expressed a heterogeneous O polysaccharide side chain profile in their lipopolysaccharide (LPS), although some variation in the electrophoretic migration of lower and higher molecular weight LPS bands was noted. Polyclonal antisera raised against a 45-K OMP-associated protein of one O:34 strain (AH-195) reacted in immunoblot assays with a major 43 to 46-K OMP in 11 of 14 (79%) O:34 strains tested. Most O:34 strains (69%) were found to be pathogenic in mice with LD-50 values (i.p.) of <1.0 x 10(7) CFU; pathogenicity appeared to correlate best with elevated protease activity. The collective results suggest significant differences in both structural and pathogenic properties between some members of the O:34 group originating from human and nonhuman (fish, water) sources.

Iron utilization studies in Citrobacter species.

Seventy-one strains of Citrobacter were screened for iron scavenging mechanisms by biologic and chemical assays. Essentially all citrobacteria (70/71) were found to elaborate enterobactin-like siderophores by both biologic and chemical assays, however only c. koseri (C. diversus) was found to produce aerobactin. The concentration of ethylenediamine di(o-hydroxyphenylacetic acid) (EDDA) required to inhibit the growth of individual Citrobacter strains by depleting free iron ranged from 250 micrograms/ml to 100 micrograms/ml. Iron utilization studies of selected citrobacter isolates indicated that hemin and hematin could reverse the effects of iron limitation on growth under iron-stressed conditions (1000 micrograms/ml of EDDA). Two C. koseri strains grown under iron-restricted conditions showed similar changes in their whole cell protein profiles including induction of high molecular mass proteins (72-83 kDa) which may play a role in iron acquisition under iron-stressed conditions. The collective results support an additional virulence-associated mechanism for C. koseri strains which may help explain the greater pathogenic potential this group has for causing serious extraintestinal disease in humans.

Biochemical investigations of biogroups and subspecies of Morganella morganii.

We determined the subspecies and biogroup designations for 73 strains of Morganella morganii principally recovered from routine clinical specimens. On the basis of trehalose fermentation, 90% of all strains were identified as M. morganii subsp. morganii (trehalose negative), while the remaining 10% were designated M. morganii subsp. sibonii (trehalose positive). Using three tests (ornithine decarboxylase [ODC] and lysine decarboxylase [LDC] activities and susceptibility to tetracycline), we determined the biogroup designations for these 73 strains. Four of the seven recognized biogroups within the genus Morganella were found in the study, with biogroup A (ODC positive [ODC+], LDC negative [LDC-]) predominating (78%); all M. morganii subsp. sibonii strains were found to belong to biogroup G (ODC+, LDC-). Rapid glycerol fermentation (24 h) was linked to nonmotility and biogroup B strains (ODC+, LDC+). LDC activity but not tetracycline resistance appeared to be associated with the possession of a 40- to 45-MDa plasmid. The use of three commercial systems (API ZYM, API 50 CH, and Biolog GN) failed to detect any new biochemical tests useful for subspecies identification, with the possible exception of L-phenylalanine utilization as a sole carbon source in the Biolog GN system. No Morganella strain was found to invade either HEp-2 or Vero cell lines, but four of seven M. morganii subsp. morganii strains were cytotoxic on sheets of both cells. This cytotoxic activity appeared to correlate with the rapid expression of beta-hemolytic activity.