Heterologous expression of the Bacteroides ruminicola xylanase gene in Bacteroides fragilis and Bacteroides uniformis

A cloned xylanase gene from the ruminal bacterium Bacteroides ruminicola 23 was transferred by conjugation into the colonic species Bacteroides fragilis and Bacteroides uniformis by using the Escherichia coli-Bacteroides shuttle vector pVAL-1. The cloned gene was expressed in both species, and xylanase specific activity in crude extracts was found to be at least 1400-fold greater than that found in the B. ruminicola strain. Analysis of crude extract proteins from the recombinant B. fragilis by SDS-PAGE demonstrated a new 60,000 molecular weight protein. The xylanase activity expressed in both E. coli and B. fragilis was capable of degrading xylan to xylooligosaccharides in vitro. This is the first demonstration that colonic Bacteroides species can express a gene from a ruminal Bacteroides species.     

Heterologous gene expression in Bacteroides fragilis.

Bacteroides fragilis and other gastrointestinal tract Bacteroides are unusual gram-negative eubacteria in that genes from other gram-negative eubacteria are not expressed when introduced into these organisms. To analyze gene expression in Bacteroides, expression vector and promoter probe (detection) vector systems were developed. The essential feature of the expression vector was the incorporation of a Bacteroides insertion sequence element, IS4351, which possesses promoter activity directed outward from its ends. Genes inserted into the multiple cloning site downstream from an IS4351 DNA fragment were readily expressed in B. fragilis. The chloramphenicol acetyltransferase (cat) structural gene from Tn9 was tested and conferred chloramphenicol resistance on B. fragilis. Both chloramphenicol resistance and CAT activity were shown to be dependent on the IS4351 promoters. Similar results were obtained with the Escherichia coli beta-glucuronidase gene (uidA) but activity was just 30% of the levels seen with cat. Two tetracycline resistance determinants, tetM from Streptococcus agalactiae and tetC from E. coli, also were examined. tetC did not result in detectable tetracycline resistance but the gram-positive tetM gene conferred high-level resistance to tetracycline and minocycline in Bacteroides hosts. Based on the cat results, promoter probe vectors containing the promoterless cat gene were constructed. These vectors were used to clone random B. fragilis promoters from partial genomic libraries and the recombinants displayed a range of CAT activities and chloramphenicol MICs in B. fragilis hosts. In addition, known E. coli promoters (Ptet, Ptac, Ptrc, Psyn, and P1P2rrnB) were tested for activity in B. fragilis. No chloramphenicol resistance or CAT activity was observed in B. fragilis with these promoters.     

Expression and purification of glutamine synthetase cloned from Bacteroides fragilis

A glutamine synthetase (GS) gene, glnA, from Bacteroides fragilis was cloned on a recombinant plasmid pJS139 which enabled Escherichia coli glnA deletion mutants to utilize (NH4)2SO4 as a sole source of nitrogen. DNA homology was not detected between the B. fragilis glnA gene and the E. coli glnA gene. The cloned B fragilis glnA gene was expressed from its own promoter and was subject to nitrogen repression in E. coli, but it was not able to activate histidase activity in an E. coli glnA ntrB ntrC deletion mutant containing the Klebsiella aerogenes hut operon. The GS produced by pJS139 in E. coli was purified; it had an apparent subunit Mr of approximately 75,000, which is larger than that of any other known bacterial GS. There was very slight antigenic cross-reactivity between antibodies to the purified cloned B. fragilis GS and the GS subunit of wild-type E. coli.     

Cloning and expression of the Bacteroides fragilis TAL2480 neuraminidase gene, nanH, in Escherichia coli.

We have cloned the Bacteroides fragilis TAL2480 neuraminidase (NANase) structural gene, nanH, in Escherichia coli. This was accomplished by using the cloning shuttle vector pJST61 and a partial Sau3A library of TAL2480 chromosomal inserts created in E. coli. The library was mobilized into the NANase-deficient B. fragilis TM4000 derivative TC2. NANase-producing colonies were enriched by taking advantage of the inability of TC2, but not the wild-type of NANase+ revertant, to grow in vitro in fluid aspirated from the rat granuloma pouch. Plasmids pJST61-TCN1 and pJST61-TCN3, containing inserts of 9.1 and 4.5 kilobases (kb), respectively, were found in the TC2 derivatives that grew in the rat pouch medium. In B. fragilis, NANase production from the two plasmids was inducible by free N-acetylneuraminic acid or sialic acid-containing substrates, just as in the parental TAL2480 strain. However, when these plasmids were transferred back to E. coli, NANase activity was barely detectable. A 3.5-kb portion of the insert in pJST61-TCN3 was subcloned in pJST61 to give plasmid pJST61-SC3C; NANase was produced from this plasmid both in E. coli and in B. fragilis. In E. coli, NANase expression was under the control of the vector promoter lambda pR and was therefore completely abolished by the presence of a lambda prophage. In B. fragilis, NANase production was inducible by free N-acetylneuraminic acid or sialic acid-containing substrates. By using deletion analysis and Tn1000 mutagenesis, the NANase structural gene and control region that functions in B. fragilis were localized to a 1.5- to 2.0-kb region of the insert. A partial nucleotide sequence of the NANase-deficient Tn1000 insertion mutants allowed us to identify the nanH gene and deduce the amino acid sequence of a portion of the NANase protein. We identified five regions showing great similarity to the Asp boxes, -Ser-X-Asp-X-Gly-X-Thr-Trp-, of other bacterial and viral NANase proteins.     

Construction of shuttle cloning vectors for Bacteroides fragilis and use in assaying foreign tetracycline resistance gene expression

Shuttle vectors capable of replication in both Escherichia coli and Bacteroides fragilis have been developed. Conjugal transfer of these plasmids from E. coli to B. fragilis is facilitated by inclusion of the origin of transfer of the IncP plasmid RK2. The vectors pDK1 and pDK2 provide unique sites for cloning selectable markers in Bacteroides. pOA10 is a cosmid vector containing the replication region of pCP1 necessary for maintenance in Bacteroides. pDK3, pDK4.1, and pDK4.2 contain the Bacteroides clindamycin resistance gene allowing selection and maintenance in B. fragilis of plasmids containing inserted DNA fragments. pDK3 was used to test the expression in B. fragilis of five foreign tetracycline resistance (TcR) genes. The tetA, -B, and -C markers from facultative gram-negative bacteria, as well as a TcR determinant from Clostridium perfringens, did not express TcR in B. fragilis. The tetM gene, originally described in streptococci, encoded a small but reproducible increase of TcR in Bacteroides. These studies demonstrate the utility of shuttle vectors for introducing cloned genes into Bacteroides and underscore the differences in gene expression in these anaerobes.     

Development and use of cloning systems for Bacteroides fragilis: cloning of a plasmid-encoded clindamycin resistance determinant.

Chimeric plasmids able to replicate in Bacteroides fragilis or in B. fragilis and Escherichia coli were constructed and used as molecular cloning vectors. The 2.7-kilobase pair (kb) cryptic Bacteroides plasmid pBI143 and the E. coli cloning vector pUC19 were the two replicons used for these constructions. Selection of the plasmid vectors in B. fragilis was made possible by ligation to a restriction fragment bearing the clindamycin resistance (Ccr) determinant from a Bacteroides R plasmid, pBF4;Ccr was not expressed in E. coli. The chimeric plasmids ranged from 5.3 to 7.3 kb in size and contained at least 10 unique restriction enzyme recognition sites suitable for cloning. Transformation of B. fragilis with the chimeric plasmids was dependent upon the source of the DNA; generally 10(5) transformants micrograms-1 of DNA were recovered when plasmid purified from B. fragilis was used. When the source of DNA was E. coli, there was a 1,000-fold decrease in the number of transformants obtained. Two of the shuttle plasmids not containing the pBF4 Ccr determinant were used in an analysis of the transposon-like structure encoding Ccr in the R plasmid pBI136. This gene encoding Ccr was located on a 0.85-kb EcoRI-HaeII fragment and cloned nonselectively in E. coli. Recombinants containing the gene inserted in both orientations at the unique ClaI site within the pBI143 portion of the shuttle plasmids could transform B. fragilis to clindamycin resistance. These results together with previous structural data show that the gene encoding Ccr lies directly adjacent to one of the repeated sequences of the pBI136 transposon-like structure.     

Screening for the presence of the insertion sequence IS1 in the genus Bacteroides

Abstract A specific DNA probe, containing a conserved region of the insertion sequence IS1, was hybridised to dot blots of total genomic DNA from 2 oral and 5 intestinal Bacteroides spp. Using Escherichia coli K12 as a positive control and Pseudomonas aeruginosa as a negative control, DNA homologous to the probe could not be detected in Bacteroides corporis, Bacteroides intermedius, Bacteroides ovatus, Bacteroides vulgatus, Bacteroides thetaiotaomicron or 2 strains of Bacteroides fragilis . The total DNA included plasmid DNA of 30.2, 42.7 and 42.7 MDa from B. fragilis, B. intermedius and B. corporis , respectively.
IS1 is commonly found in members of the Enterobacteriaceae, and it was concluded that the 2 groups of bacteria are not closely related.     

Pbp, a cell-surface exposed plasminogen binding protein of Bacteroides fragilis

The Gram-negative anaerobic bacterium B. fragilis is a member of the commensal flora of the human intestine, but is also frequently found in severe intra-abdominal infections. Several B. fragilis virulence factors have been implicated in the development of these infections. A B. fragilis protein of circa 60-kDa was identified as a putative plasminogen binding protein (Pbp). The corresponding gene was located, cloned, sequenced and the subcellular localization of the protein was investigated. Pbp was both determined in the outer membrane of B. fragilis and of E. coli that expressed the cloned protein. Protease accessibility studies showed that the protein is expressed at the cell surface. Importantly, we demonstrated that Pbp is sufficient and required for plasminogen binding to whole cells in both E. coli and B. fragilis. Pbp-like proteins were also detected in some other Bacteroides subspecies. The role of this potential B. fragilis virulence factor in pathogenicity is discussed.     

Toxins of Bacteroides fragilis and Bacteroides thetaiotaomicron rods as stimulators of adhesion molecule expression on the surface of vascular endothelial cells

Lipopolysaccharides from four Bacteroides fragilis strains: one nonenterotoxigenic (NTBF) and three enterotoxigenic (ETBF), and from three B. thetaiotaomicron strains were extracted by hot phenol-water method and purified. B. fragilis enterotoxin was prepared according to the procedure of van Tassell et al. (1992). The influence of the examined toxins on the expression of adhesion molecules: ICAM-1, VCAM-1 and E-selectin on HMEC-1 (human dermal microvascular endothelial cells) was assayed in ELISA test with monoclonal antibodies. Four concentrations of toxins were applied: 0.01, 0.1, 1.0 and 10.0 (micrograms/ml). Endothelial cells were activated for 24 hours (ICAM-1 and VCAM-1 expression) and for 4 hours (E-selectin expression). The coloured product of immunoenzymatic reaction was measured by reading the absorbance at wavelength 492 nm. Two controls were performed in each experiment: with resting HMEC-1 and E. coli O55:B5 LPS (Sigma, USA). Bacteroides fragilis and B. thetaiotaomicron lipopolysaccharides stimulated three adhesion molecules under investigation. Their activity was comparable, but weaker than the activity of E. coli O55:B5 LPS. ICAM-1 was the most stimulated molecule. B. fragilis enterotoxin induced two adhesion molecules: VCAM-1 and E-selectin demonstrating weaker stimulatory activity than E. coli LPS. Stimulation of adhesion molecules on vascular endothelial cells should be considered to be a biological activity of B. fragilis and B. thetaiotaomicron endotoxins and B. fragilis enterotoxin.     

Neuraminidase production by Bacteroides species

Abstract 128 strains of Bacteroides isolated from clinical specimens were surveyed for their ability to produce neuraminidase. All strains of Bacteroides fragilis and the B. fragilis group were neuraminidase-positive, as were strains of B. oralis and B. bivius . All strains of B. capillosus, B. ruminicola, B. disiens, B. multiacidus and B. uniformis did not produce a detectable neuraminidase. When human erythrocytes were exposed to cell extracts of neuraminidase-producing Bacteroides , and then tested with peanut ( Arachis hypogeae ) lectin, agglutination occurred. It was concluded that the production of neuraminidase by clinical isolates of Bacteroides may be associated with the pathophysiology of severe Bacteroides infections.     

Isolation of a ferritin from Bacteroides fragilis

A ferritin was isolated from the obligate anaerobe Bacteroides fragilis. Estimated molecular masses were 400 kDa for the holomer and 16.7 kDa for the subunits. A 30-residue N-terminal amino acid sequence was determined and found to resemble the sequences of other ferritins (human H-chain ferritin, 43% identity; Escherichia coli gen-165 product, 37% identity) and to a lesser degree, bacterioferritins (E. coli bacterioferritin, 20% identity). The protein stained positively for iron, and incorporated 59Fe when B. fragilis was grown in the presence of [59Fe]citrate. However, the isolated protein contained only about three iron atoms per molecule, and contained no detectable haem. This represents the first isolation of a ferritin protein from bacteria. It may alleviate iron toxicity in the presence of oxygen.     

Cloning and expression in Escherichia coli of a recA-like gene from Bacteroides fragilis

The recombinant plasmid pHG100, containing a 5.2-kb DNA fragment from Bacteroides fragilis, complemented defects in homologous recombination, DNA repair and prophage induction to various levels in an Escherichia coli recA mutant strain. There was no DNA homology between the cloned B. fragilis recA-like gene and E. coli chromosomal DNA. pHG100 produced two proteins with Mr of approx. 39,000 and 37,000 which cross-reacted with antibodies raised against E. coli RecA protein. The production of these proteins was not increased after UV induction. The cloned B. fragilis recA-like gene product did not enhance the production of native but defective E. coli RecA protein after UV irradiation.     

Identification of three porins in the outer membrane of Bacteroides fragilis

Abstract Four outer membrane proteins were purified to homogeneity from isolated outer membranes of Bacteroides fragilis ; three ( M _r 51000, 92000 and 125 000) had pore-forming activity in reconstituted liposomes as determined by swelling assay. Membrane vesicles containing the M _rmr 55 000 outer membrane protein showed no detectable pore-forming activity. The three B. fragilis porins formed pores that allowed the penetration of uncharged saccharides of M _r lower than 340–400, even though the efficiency of solute diffusion showed slight differences. The diffusion rates of glucose through the porins appeared to be lower than those through Escherichia coli porins.     

Cloning and characterization of a Bacteroides conjugal tetracycline-erythromycin resistance element by using a shuttle cosmid vector.

The Bacteroides conjugal tetracycline resistance (Tcr) elements appear not to be plasmids. In many cases, resistance to erythromycin (Emr) is cotransferred with Tcr. Using a newly constructed shuttle cosmid, pNJR1, we cloned 44 to 50 kilobase pairs of a conjugal Tcr Emr element on overlapping cosmid clones. Cosmid libraries were made in Escherichia coli with DNA from the original clinical Bacteroides thetaiotaomicron DOT strain containing Tcr Emr-DOT or from a Bacteroides uniformis Tcr Emr-DOT transconjugant strain. The cosmid clones were mobilized from E. coli into B. uniformis in groups of 10 to 20 per filter mating, with selection for Tcr or Emr transconjugants. The Tcr and Emr genes were cloned both separately and together on 30-kilobase-pair fragments. Several of the Tcr clones also contained transfer genes that permitted self-transfer of the cosmid from B. uniformis donors to E. coli or B. uniformis recipients. Neither the Tcr nor the Emr gene conferred resistance on E. coli, and the transfer-proficient clones did not self-transfer out of E. coli. Southern blot analysis was used to compare DNA from independently isolated Bacteroides strains carrying conjugal Tcr or Tcr Emr elements and their respective B. uniformis transconjugants. Results of these analyses indicate that there are large regions of homology, including regions outside the Tcr and Emr genes, but that the elements are not identical. Some Tcr clones contained a region which hybridized to chromosomal DNA from the wild-type B. uniformis recipient strain that did not carry the Tcr Emr-DOT element. This region of homology appeared not to be a junction fragment. It was not required in a Bacteroides recipient for successful transfer of the Tcr Emr element. Although we are not sure we have cloned a junction fragment between the Tcr Emr-DOT element and the B. uniformis chromosome, the preliminary function and restriction map appears to be linear.     

Expression and regulation of a Bacteroides fragilis sucrose utilization system cloned in Escherichia coli.

A Bacteroides fragilis strain isolated from human feces was the source of chromosomal DNA in the construction of plasmid pBS100. The cloned 6-kilobase insert of plasmid pBS100 conferred a sucrose positivity phenotype on transformed cells of Escherichia coli JA221. E. coli JA221(pBS100) cells were able to utilize sucrose as the sole source of carbon because of the presence of sucrase enzyme and sucrose uptake activities. Sucrase activity was inducible in B. fragilis but constitutive in E. coli JA221(pBS100) cells. In sucrose-minimal medium, both B. fragilis and E. coli JA221(pBS100) produced intracellular and extracellular sucrase activities throughout the growth cycle. Osmotic shock experiments performed on E. coli JA221(pBS100) indicated that up to 55% of the sucrase activity was localized in the periplasmic space, 30% was in the cytoplasm, and the remaining 15% was in the cell-free extracellular supernatant fluid. B. fragilis and E. coli JA221(pBS100) actively transported sucrose. Sucrose uptake was induced by sucrose in B. fragilis, whereas the uptake activity in E. coli JA221(pBS100) was constitutive. E. coli JA221(pBS100) appeared to transport sucrose by a phosphotransferase-independent system. B. fragilis transported sucrose only under strictly anaerobic conditions. No uptake activity was detected under aerobic conditions with or without addition of catalase.     

Expression and regulation of a Bacteroides fragilis sucrose utilization system cloned in Escherichia coli

A Bacteroides fragilis strain isolated from human feces was the source of chromosomal DNA in the construction of plasmid pBS100. The cloned 6-kilobase insert of plasmid pBS100 conferred a sucrose positivity phenotype on transformed cells of Escherichia coli JA221. E. coli JA221(pBS100) cells were able to utilize sucrose as the sole source of carbon because of the presence of sucrase enzyme and sucrose uptake activities. Sucrase activity was inducible in B. fragilis but constitutive in E. coli JA221(pBS100) cells. In sucrose-minimal medium, both B. fragilis and E. coli JA221(pBS100) produced intracellular and extracellular sucrase activities throughout the growth cycle. Osmotic shock experiments performed on E. coli JA221(pBS100) indicated that up to 55% of the sucrase activity was localized in the periplasmic space, 30% was in the cytoplasm, and the remaining 15% was in the cell-free extracellular supernatant fluid. B. fragilis and E. coli JA221(pBS100) actively transported sucrose. Sucrose uptake was induced by sucrose in B. fragilis, whereas the uptake activity in E. coli JA221(pBS100) was constitutive. E. coli JA221(pBS100) appeared to transport sucrose by a phosphotransferase-independent system. B. fragilis transported sucrose only under strictly anaerobic conditions. No uptake activity was detected under aerobic conditions with or without addition of catalase.     

Escherichia coli chromosomal mutations that permit direct cloning of the Bacteroides fragiiis metallo-β-lactamase gene, ccrA

The class B, metallo-beta-lactamase genes ccrA (carbapenem- and cephamycin resistance) from three Bacteroides fragilis isolates--QMCN3, QMCN4, and TAL3636--were cloned and expressed in Escherichia coli. Cloning of the genes, by selecting for ampicillin resistance, was facilitated by two classes of Escherichia coli chromosomal mutations which resulted in at least a 5-10-fold increase in metallo-beta-lactamase enzymatic activity. The observed increase in enzymatic activity is due to either increased translation of the ccrA gene or an effect on localization or stability of the protein. Comparison of the DNA sequences of the three ccrA genes revealed that their protein-coding sequences shared greater than 97% DNA sequence identity. However, the 5' upstream sequence for the TAL3636 ccrA gene was unrelated to that of the other two genes.