Proteus mirabilis ambient-temperature fimbriae: cloning and nucleotide sequence of the aft gene cluster.

Uropathogenic Proteus mirabilis produces at least four types of fimbriae. Amino acid sequences from two peptides, derived by tryptic digestion of the structural subunit of one type of these fimbriae, the ambient-temperature fimbriae, were determined: NVVPGQPSSTQ and LIEGENQLNYNA. PCR primers, based on these sequences and that of the N terminus, were used to amplify a 359-bp fragment. A cosmid clone, isolated from a P. mirabilis genomic library by hybridization with the 359-bp PCR product, was used to determine the nucleotide sequence of the atf gene cluster. A 3,903-bp region encodes three polypeptides: AtfA, the structural subunit; AtfB, the chaperone; and AtfC, the outer membrane molecular usher. No fimbria-related genes are evident either 5' or 3' to the three contiguous genes. AtfA demonstrates significant amino acid sequence identity with type 1 major fimbrial subunits of several enteric species. The 359-bp PCR product hybridized strongly with all Proteus isolates (n = 9) and 25% of 355 Escherichia coli isolates but failed to hybridize with any of 26 isolates among nine other uropathogenic species. Ambient-temperature fimbriae of P. mirabilis may represent a novel type of fimbriae of enteric species.

Proteus mirabilis amino acid deaminase: cloning, nucleotide sequence, and characterization of aad.

Proteus, Providencia, and Morganella species produce deaminases that generate alpha-keto acids from amino acids. The alpha-keto acid products are detected by the formation of colored iron complexes, raising the possibility that the enzyme functions to secure iron for these species, which do not produce traditional siderophores. A gene encoding an amino acid deaminase of uropathogenic Proteus mirabilis was identified by screening a genomic library hosted in Escherichia coli DH5 alpha for amino acid deaminase activity. The deaminase gene, localized on a cosmid clone by subcloning and Tn5::751 mutagenesis, was subjected to nucleotide sequencing. A single open reading frame, designated aad (amino acid deaminase), which appears to be both necessary and sufficient for deaminase activity, predicts a 473-amino-acid polypeptide (51,151 Da) encoded within an area mapped by transposon mutagenesis. The predicted amino acid sequence of Aad did not share significant amino acid sequence similarity with any other polypeptide in the PIR or SwissProt database. Amino acid deaminase activity in both P. mirabilis and E. coli transformed with aad-encoding plasmids was not affected by medium iron concentration or expression of genes in multicopy in fur, cya, or crp E. coli backgrounds. Enzyme expression was negatively affected by growth with glucose or glycerol as the sole carbon source but was not consistent with catabolite repression.

Genetic organization and complete sequence of the Proteus mirabilis pmf fimbrial operon.

Proteus mirabilis, commonly associated with urinary tract infection, pyelonephritis and bacteremia, produces a number of fimbriae, including PMF (P. mirabilis fimbriae). Genes encoding PMF were isolated and the complete nucleotide (nt) sequence was determined. The pmf gene cluster, encoded by 5655 bp, predicts five polypeptides: PmfA (18,921 Da), PmfC (93,107 Da), PmfD (28,208 Da), PmfE (38,875 Da) and PmfF (19,661 Da). PmfA, PmfC, PmfD and PmfF share > 25% amino acid (aa) sequence identity with gene products of the pap, mrp and sfa fimbrial gene clusters. PmfE shares no similarity with any polypeptide in the SwissProt database. No regulatory gene(s) or regulatory elements were evident in the sequence. The pmf cluster shares common features with other enteric fimbrial gene clusters, but also displays features that are unique.

Virulence determinants of uropathogenic Escherichia coli and Proteus mirabilis.

The urinary tract is among the most common sites of bacterial infection and E. coli is by far the most common infecting agent. In patients with urinary catheters in place or structural abnormalities of the urinary tract, Proteus mirabilis is also a frequent isolate. To study virulence of these bacterial species, we have isolated the genes that encode putative virulence factors, constructed specific mutations within these genes, introduced the mutation back into the wild type strain by allelic exchange, and analyzed these mutants for virulence in appropriate in vitro and in vivo models. Specific virulence markers have been identified for strains that cause urinary tract infection. For E. coli, these include P fimbriae, S fimbriae, hemolysin, aerobactin, serum resistance, and a small group of O-serotypes. Redundant virulence factors must be present in these organisms as mutation of the most clearly identified epidemiological marker, P fimbriae, does not result in attenuation of a virulent strain. For P. mirabilis, urease appears to contribute most significantly to virulence. Fimbriae play a significant but more subtle role in colonization. Hemolysin, although potently cytotoxic to renal cells in vitro, does not appear to contribute significantly to the pathogenesis of ascending urinary tract infection. We can conclude that the pathogenesis of urinary tract infection and acute pyelonephritis caused by uropathogenic E. coli and P. mirabilis are multifactorial, as mutation of single genes rarely causes significant attenuation of virulence.

Construction of an MR/P fimbrial mutant of Proteus mirabilis: role in virulence in a mouse model of ascending urinary tract infection.

Proteus mirabilis, a cause of acute pyelonephritis, produces at least four types of fimbriae, including MR/P (mannose-resistant/Proteus-like) fimbriae. To investigate the contribution of MR/P fimbriae to colonization of the urinary tract, we constructed an MR/P fimbrial mutant by allelic exchange. A 4.2-kb BamHI fragment carrying the mrpA gene was subcloned into a mobilizable plasmid, pSUP202. A 1.3-kb Kanr cassette was inserted into the mrpA open reading frame, and the construct was transferred to the parent P. mirabilis strain by conjugation. Following passage on nonselective medium, 1 of 500 transconjugants screened was found to have undergone allelic exchange as demonstrated by Southern blot. Colony immunoblot, Western immunoblot, and immunogold labeling with a monoclonal antibody to MR/P fimbriae revealed that MrpA was not expressed. Complementation with cloned mrpA restored MR/P expression as shown by hemagglutination, Western blot, and immunogold electron microscopy. To assess virulence, we challenged 40 CBA mice transurethrally with 10(7) CFU of wild-type or mutant strains. After 1 week, geometric means of log10 CFU per milliliter of urine or per gram of bladder or kidney for the wild-type and mutant strains were as follows: urine, 7.79 (wild type) versus 7.02 (mutant) (P = 0.035); bladder, 6.22 versus 4.78 (P = 0.019); left kidney, 5.02 versus 3.31 (P = 0.009); and right kidney, 5.28 versus 4.46 (P = 0.039). Mice challenged with the wild-type strain showed significantly more severe renal damage than did mice challenged with the MR/P-negative mutant (P = 0.007). We conclude that MR/P fimbriae contribute significantly to colonization of the urinary tract and increase the risk of development of acute pyelonephritis.

Diversity of siderophore genes encoding biosynthesis of 2,3-dihydroxybenzoic acid in Aeromonas spp.

Most species of the genus Aeromonas produce the siderophore amonabactin, although two species produce enterobactin, the siderophore of many enteric bacteria. Both siderophores contain 2,3-dihydroxybenzoic acid (2,3-DHB). Siderophore genes (designated aebC, -E, -B and -A, for aeromonad enterobactin biosynthesis) that complemented mutations in the enterobactin genes of the Escherichia coli 2,3-DHB operon, entCEBA(P15), were cloned from an enterobactin-producing isolate of the Aeromonas spp. Mapping of the aeromonad genes suggested a gene order of aebCEBA, identical to that of the E. coli 2,3-DHB operon. Gene probes for the aeromonad aebCE genes and for amoA (the entC-equivalent gene previously cloned from an amonabactin-producing Aeromonas spp.) did not cross-hybridize. Gene probes for the E. coli 2,3-DHB genes entCEBA did not hybridize with Aeromonas spp. DNA. Therefore, in the genus Aeromonas, 2,3-DHB synthesis is encoded by two distinct gene groups; one (amo) is present in the amonabactin-producers, while the other (aeb) occurs in the enterobactin-producers. Each of these systems differs from (but is functionally related to) the E. coli 2,3-DHB operon. These genes may have diverged from an ancestral group of 2,3-DHB genes.

Proteus mirabilis fimbriae: identification, isolation, and characterization of a new ambient-temperature fimbria.

Urinary tract infections involving Proteus mirabilis may lead to complications including bladder and kidney stones, acute pyelonephritis, and bacteremia. This bacterium produces a number of fimbriae, two of which, MR/P fimbria and P. mirabilis fimbria, have been shown to contribute to the ability of this pathogen to colonize the bladder and kidney. We have now purified and characterized a previously undescribed fimbria of P. mirabilis, named ambient-temperature fimbria (ATF). Electron microscopy of a pure preparation and immunogold labeling of cells demonstrated that ATF was fimbrial in nature. The major fimbrial subunit of ATF has an apparent molecular weight of 24,000. The N-terminal amino acid sequence, E-X-T-G-T-P-A-P-T-E-V-T-V-D-G-G-T-I-D-F, did not show significant similarity to that of any previously described fimbrial protein. ATF was expressed by all eight P. mirabilis strains examined. Culture conditions affected expression of ATF, with optimal expression observed in static broth cultures at 23 degrees C. This fimbria was not produced by cells grown at 42 degrees C or on solid medium. Expression of ATF did not correlate with mannose-resistant/Proteus-like (MR/P) or mannose-resistant/Klebsiella-like (MR/K) hemagglutination and represents a novel fimbria of P. mirabilis.

Proteus mirabilis fimbriae: construction of an isogenic pmfA mutant and analysis of virulence in a CBA mouse model of ascending urinary tract infection.

Proteus mirabilis, a cause of urinary tract infection and acute pyelonephritis, produces a number of different fimbriae. An isogenic fimbrial mutant of P. mirabilis HI4320 was constructed by marker exchange with delta pmfA::aphA to determine the role of the P. mirabilis fimbriae (PMF) in hemagglutination and in virulence in the CBA mouse model of ascending urinary tract infection. The pmfA mutant, which did not express the 19,500-Da major subunit of PMF, colonized the bladders of transurethrally challenged CBA mice (n = 20 in each group) in numbers 83-fold lower than those of the wild-type strain (mutant, log10 4.87 CFU/g; wild-type strain, log10 6.79 CFU/g; P = 0.023). However, the mutant colonized the kidneys in numbers similar to those of the wild-type strain. Hemagglutination patterns of the mutant ruled out the involvement of PMF in both mannose-resistant, Proteus-like and mannose-resistant, Klebsiella-like hemagglutination. Similarly, PMF does not appear to be involved in adherence to uroepithelial cells (UEC), since the mutant was as adherent as the wild-type strain (mutant, 14.1 +/- 11.7 mean bacteria per UEC, 60% of UEC with > or = 10 bacteria; wild-type strain, 18.1 +/- 16.2 mean bacteria per UEC, 68% of UEC with > or = 10 bacteria; not significantly different). These data suggest a role for PMF in colonization of the bladder but not in colonization of kidney tissue. PMF appear not to be responsible for mannose-resistant, Proteus-like or mannose-resistant, Klebsiella-like hemagglutination.

Proteus mirabilis fimbriae: N-terminal amino acid sequence of a major fimbrial subunit and nucleotide sequences of the genes from two strains.

Proteus mirabilis, a common cause of urinary tract infection in hospitalized and catheterized patients, produces mannose-resistant/klebsiella-like (MR/K) and mannose-resistant/proteus-like (MR/P) hemagglutinins. The gene encoding the major structural subunit of a fimbria, possibly MR/K, was identified in two strains. A degenerate oligonucleotide probe based on the N terminus of the Proteus uroepithelial cell adhesin and antiserum raised against the denatured polypeptide were used to screen a cosmid gene bank of strain HU1069. A cosmid clone that reacted with the probe and antiserum was identified, and a fimbria-like open reading frame was determined by nucleotide sequencing. The predicted N-terminal amino acid sequence of the processed polypeptide, ENETPAPKVSSTKGEIQLKG (residues 23 to 42), did not match the uroepithelial cell adhesin N terminus but, rather, matched exactly the N-terminal amino acid sequence of a polypeptide with an apparent molecular size of 19.5 kDa isolated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis of a fimbrial preparation from strain HI4320 expressing MR/K hemagglutinin. By using an oligonucleotide from the HU1069 open reading frame, the fimbrial gene was isolated and sequenced from a cosmid gene bank clone of strain HI4320. A 552-bp open reading frame predicts a 184-amino-acid polypeptide including a 22-amino-acid hydrophobic leader sequence. The unprocessed polypeptide is predicted to be 18,921 Da; the processed polypeptide is predicted to be 16,749 Da. The predicted amino acid sequence of the polypeptide encoded by the gene, designated pmfA, displayed 36% exact matches with the mannose-resistant fimbrial subunit encoded by smfA of Serratia marcescens but only 15% exact matches with the predicted sequence encoded by mrkA of Klebsiella pneumoniae.

Novel heme-binding component in the serum of the channel catfish (Ictalurus punctatus).

The serum of the channel catfish (Ictalurus punctatus) was examined for heme- and hemoglobin-binding proteins. Electrophoretic mobility retardation assays failed to detect a hemoglobin-binding material similar to mammalian haptoglobin; however, a heme-binding component (not previously described) was identified in catfish serum. The heme-binding component was purified by gel filtration chromatography; electrophoretic analyses suggested it to be composed of two polypeptide subunits of molecular masses about 115 and 98 kDa. This composition is inconsistent with hemopexin, the known heme-binding serum protein of mammals. Although it was not fully saturated with heme, the catfish component contained detectable heme in normal sera. When complexed by the binding material, heme was used as an iron source by isolates of the bacterial Gram-negative genus Aeromonas; the capacity of other bacteria to use the complex was not tested. The physiological function of the catfish heme-binding serum protein is presently not clear.

Iron acquisition and virulence in the motile aeromonads: siderophore-dependent and -independent systems.

During an infection, a microbial pathogen must acquire all of its iron from the host. Aeromonas isolated producing the siderophore amonabactin obtain iron either from host Fe-transferrin (siderophore dependent) or from host heme-containing molecules (siderophore independent). Isolates producing the siderophore enterobactin do not utilize Fe-transferrin in serum and probably rely exclusively on host heme iron.

Acquisition of iron from host sources by mesophilic Aeromonas species.

The mesophilic Aeromonas species are opportunistic pathogens that produce either of the siderophores amonabactin or enterobactin. Acquisition of iron for growth from Fe-transferrin in serum was dependent on the siderophore amonabactin; 50 of 54 amonabactin-producing isolates grew in heat-inactivated serum, whereas none of 30 enterobactin-producing strains were able to grow. Most isolates (regardless of siderophore produced) used haem as a sole source of iron for growth; all of 33 isolates grew with either haematin or haemoglobin and 30 of these used haemoglobin when complexed to human haptoglobin. Mutants unable to synthesize a siderophore used iron from haem, suggesting that this capacity was unrelated to siderophore production. Some members of the mesophilic Aeromonas species have evolved both siderophore-dependent and -independent mechanisms for acquisition of iron from a host.

Ability of Vibrio vulnificus to obtain iron from hemoglobin-haptoglobin complexes.

It has been suggested that the normal serum protein, haptoglobin (Hp), serves a bacteriostatic role by binding free hemoglobin (Hm), thus making heme iron unavailable for bacterial growth. Previous studies showed that, unlike Escherichia coli, Vibrio vulnificus was able to overcome this Hp-blocking effect. We report here a study on the iron-withholding property of the three major human Hp phenotypes, Hp 1, 2, and 2-1. Results of experiments with human serum showed that V. vulnificus C7184 was able to obtain iron from Hm bound to Hp types 1 and 2, but not that bound to Hp 2-1. E. coli 2395-80, on the other hand, was unable to overcome the blocking effect of any Hp phenotype. Using purified Hp 1, we also demonstrated that, although V. vulnificus was unable to grow in a deferrated medium without an additional iron source, it was able to grow with the addition of the Hm-Hp complex.

New selective and differential medium for Vibrio cholerae and Vibrio vulnificus.

Thiosulfate-citrate-bile salts-sucrose agar has been routinely used for the isolation of pathogenic vibrios, although its selectivity for Vibrio cholerae and Vibrio vulnificus is inadequate. Therefore, a new plating medium, cellobiose-polymyxin B-colistin agar, was developed for the isolation of these two species. Cellobiose-polymyxin B-colistin agar demonstrated a significant advantage over other media designed for the isolation or differentiation of vibrios: of both the 136 strains representing 19 Vibrio species and the marine isolates of the genera Pseudomonas, Flavobacterium, and Photobacterium, only V. vulnificus and V. cholerae were able to grow. Furthermore, the fermentation of cellobiose by V. vulnificus allowed for the easy differentiation of these two species. This medium offers significant potential as a selective and differential medium for these two pathogenic vibrios.