Unmarked gene deletion mutagenesis of gtfB and gtfC in Streptococcus mutans using a targeted hit-and-run strategy with a thermosensitive plasmid.

Unmarked gene deletion of the Streptococcus mutans gtfB-gtfC locus was achieved using a thermosensitive plasmid. DNA fragments flanking the locus were amplified by polymerase chain reaction and jointly ligated into pG+host5, which was transformed into S. mutans at 37 degrees C to facilitate integration. A transformant was then grown at 28 degrees C for 60 generations without antibiotics to facilitate excision. Antibiotic sensitive clones appeared at a frequency of about 99% and were analyzed for deletions of gtfB, gtfC and a part of mbrA by the lack of insoluble glucan synthesis, sensitivity to bacitracin, and polymerase chain reaction. Targeted gene deletions occurred at a frequency of 2.5%.

Distribution of vacA alleles and cagA status of Helicobacter pylori in peptic ulcer disease and non-ulcer dyspepsia.

The occurrence of cagA and vacA alleles among Helicobacter pylori isolates from Turkish patients and their relationship with ulcer disease outcome was investigated. Among isolates from 47 patients with peptic ulcer disease and 51 patients with non-ulcer dyspepsia, 72.3% and 44.4%, respectively, were cagA-positive (p 0.019). Most (88.8%) isolates were typed as vacA s1, and all of these were subtype s1a. The commonest (51.0%) vacA genotype was s1a m1. The results of multivariate analysis indicated that infection with cagA-positive H. pylori was the only variable associated with an increased risk of peptic ulcer disease (odds ratio, 3.01; 95% confidence interval, 1.27-7.10; p 0.012).

Genetic diversity of vaginal lactobacilli from women in different countries based on 16S rRNA gene sequences.

AIMS: Lactobacilli are widely distributed in food and the environment, and some colonize the human body as commensal bacteria. The aim of this study was to determine the species of lactobacilli that colonize the vagina and compare them with those found in food and the environment. METHODS AND RESULTS: Thirty-five Lactobacillus strains from women from seven countries were isolated, and sequences from 16S rRNA genes were determined and compared with existing data in GenBank. A phylogenetic tree was achieved using the Neighbour-Joining method based on the analysis of 1465 nucleotides. The results showed that most vaginal isolates were L. crispatus, L. jensenii and L. gasseri. Some were L. vaginalis, L. fermentum, L. mucosae, L. paracasei and L. rhamnosus. Two isolates from a native American woman displayed distinct branches, indicating novel phylotypes. Few vaginal isolates matched food or environmental Lactobacillus species. CONCLUSIONS: Most women worldwide were colonized by three common Lactobacillus species: L. crispatus, L. jensenii and L. gasseri. SIGNIFICANCE AND IMPACT OF THE STUDY: Knowledge of vaginal Lactobacillus species richness and distribution in women worldwide may lead to the design of better probiotic products as bacterial replacement therapy.

Comparative study of vaginal Lactobacillus phages isolated from women in the United States and Turkey: prevalence, morphology, host range, and DNA homology.

Lactobacilli play an important role in maintaining vaginal health. However, during bacterial vaginosis lactobacilli decrease for unknown reasons. Our preliminary study showed that phages could infect vaginal lactobacilli. Therefore, the aim of this study was to analyze the distribution, virulence, and types of vaginal Lactobacillus phages isolated from women of two countries: the United States and Turkey. A total of 209 vaginal lactobacilli were isolated from reproductive-aged women in the United States (n = 107) and Turkey (n = 102). By analysis of 16S rRNA gene sequence and by comparison of protein profiles, most lactobacilli were identified as L. crispatus, L. gasseri, and L. jensenii. After mitomycin C induction, 28% of American lactobacilli and 36% of Turkish lactobacilli released phages. A total of 67 phages were isolated and further characterized by their host range, electron microscopy, and DNA homology. All 67 phages were infective against lactobacilli from both collections. The host ranges of most phages were broad, including multiple Lactobacillus species. Even though the phages were all temperate, they were able to cause lytic infection in various strains. The electron micrographs of these phages showed a hexagon-shaped head and a long tail with or without a contractile tail sheath. Based on their morphology, these phages belonged to Bradley's phage groups A and B, and could be further classified into four morphotypes. All four types were found among American phages, but only three were found among Turkish isolates. DNA hybridization with labeled probes of the four types of phages revealed that additional genetic types existed within each morphotype among these phages. The phage genomic sizes ranged between 34 and 55 kb. Many of the lysogenic Lactobacillus strains released phages spontaneously at a high frequency of 10(-3) to 10(-4) PFU/cell. In conclusion, lysogeny in vaginal lactobacilli is widely spread. Some lysogenic lactobacilli spontaneously release phages with a broad host range, which can be lytic against other vaginal lactobacilli regardless of their geographic origin.

Phage infection in vaginal lactobacilli: an in vitro study.

OBJECTIVE: During bacterial vaginosis, an unexplained decrease of vaginal lactobacilli occurs. To identify whether these lactobacilli could be infected by phages, we isolated phages from vaginal lactobacilli and analyzed their potential virulence in attacking vaginal lactobacilli in vitro. METHODS: Vaginal samples were obtained from 39 reproductive-aged women. The selective Rogosa SL agar was used to isolate lactobacilli, from which phages induced by mitomycin C or released spontaneoulsy were analyzed by the agar spot method. RESULTS: Of 20 samples from women with vaginal infections, 12 did not have lactobacilli. From the remaining 8 infection samples and the 19 samples from healthy women, 37 Lactobacillus strains were isolated, from which 7 temperate phages were identified. Upon analysis, all 7 phages infected vaginal lactobacilli from the same and/or different women in vitro. Two phages, Phikc005 and Phikc007, had a broad host range, infecting 7 of 8 species tested. A control intestinal Lactobacillus phage also lysed several vaginal strains. One vaginal phage, Phikc039, was apparently lytic against vaginal lactobacilli from 7 other women. This phage was characterized as follows: plaque morphology, small and clear; burst size, 300 phages per cell; spontaneous induction rate, 1 per 10(6) cells; DNA, double-stranded and linear, 41 kb; and shape, a hexogonal head and a non-contractile tail. CONCLUSIONS: Bacteriophages were isolated from vaginal lactobacilli of some women and were shown in vitro to lyse vaginal Lactobacillus strains from the same and/or different women. It was suggested that vaginal lactobacilli might be suppressed by phages.

Analysis of lactobacillus products for phages and bacteriocins that inhibit vaginal lactobacilli.

OBJECTIVE: Bacterial vaginosis is associated with an unexplained loss of vaginal lactobacilli. Previously, we have identified certain vaginal lactobacilli-released phages that can inhibit in vitro other vaginal lactobacilli. However, there is no apparent route for phages to be transmitted among women. The purpose of this study was to identify whether certain Lactobacillus products commonly used by women release phages or bacteriocins that can inhibit vaginal lactobacilli. METHODS: From 26 Lactobacillus products (2 acidophilus milks, 20 yogurts, 3 Lactobacillus pills, and 1 vaginal douche mix), lactobacilli were isolated with Rogosa SL agar (Difco, Detroit, MI). From these lactobacilli, phages and bacteriocins were induced with mitomycin C and tested against a collection of vaginal Lactobacillus strains. RESULTS: From the 26 products, 43 Lactobacillus strains were isolated. Strains from 11 yogurts released phages, among which 7 inhibited vaginal lactobacilli. Eleven strains released bacteriocins that inhibited vaginal lactobacilli. While about one-half of the vaginal strains were lysed by bacteriocins, less than 20% were lysed by phages. CONCLUSIONS: Some vaginal lactobacilli were inhibited in vitro by phages or bacteriocins released from Lactobacillus products used by women, implying that vaginal lactobacilli may be reduced naturally due to phages or bacteriocins from the environment.

Site-specific nicking in vitro at ori T by the DNA relaxase of Tn5252.

Tn5252 is a promiscuous streptococcal element capable of madiating horizontal spread of multiple antibiotic resistance. To begin understanding the functional role of a transfer-related region in Tn5252, its nucleotide sequence was determined. Sequence of this 3. 3-kb DNA segment revealed the presence of six open reading frames. The predicted amino acid sequence of one of the open reading frames, ORF9, showed similarity to a predicted protein product of the lactococcal conjugative plasmid, pC1528. The deduced primary protein sequence of another, ORF4, showed strong structural similarity to conserved regions of various prokaryotic DNA relaxases that initiate conjugal transfer by strand- and site-specific cleavage at the transfer origin. A hybrid protein containing the ORF4 protein fused to the carboxyl terminal end of maltose binding protein was purified from Escherichia coli and found to specifically nick plasmids carrying a 2-kb DNA segment derived from the transposon. The nicking reaction is protein concentration-dependent. These results imply that the conjugative transposition of Tn5252 may involve rolling circle replication and transfer of a unique DNA strand.

Analysis of Lactobacillus phages and bacteriocins in American dairy products and characterization of a phage isolated from yogurt.

Yogurt and acidophilus milk that contain Lactobacillus acidophilus could promote human health because L. acidophilus can inhibit enteric and food-borne microbial pathogens. To evaluate the stability of diary L. acidophilus cultures, we studied whether some diary lactobacilli could be inhibited by phages or bacteriocins released by other dairy lactobacilli. From 20 yogurts and two acidophilus milks purchased at local food markets, 38 Lactobacillus strains were isolated. Eight Lactobacillus type strains were used as controls. With mitomycin induction and agar spot assay, phages and bacteriocins were isolated from these strains and their activities were analyzed. Lactobacillus strains from 11 yogurts released phages, while the strains from most of the remaining products released bacteriocins. One phage, designated phi y8, was characterized. It was spontaneously released from its host strain L. acidophilus Y8, at a rate of about 10(4)/ml. This phage lysed nine other dairy Lactobacillus strains tested. It had a burst size of 100, an elongated prolate head of 39 by 130 nm, a long, flexible but noncontractile tail of 300 nm, and a 54.3-kb linear double-stranded DNA. DNA fingerprinting analysis indicated that L. acidophilus phages of nine yogurts in this study belonged to the same type as phi y8. Although they may be sensitive to bacteriocins, all lysogens resisted further phage attacks, whereas most nonlysogens were sensitive to both phages and bacteriocins. Therefore, Lacotbacillus cultures of some American yogurts and acidophilus milks may be unstable or unsafe because they can either be inhibited by phages or bacteriocins or release them to inhibit lactobacilli or other diary products.

Identification and nucleotide sequence analysis of a transfer-related region in the streptococcal conjugative transposon Tn5252.

To obtain a functional map of Tn5252, a 47.5-kb streptococcal conjugative transposon, a series of defined deletion and insertion mutations were introduced within the transposon. Interruptions at several regions were found to affect the conjugal transposition functions of the element in filter-mating experiments. The nucleotide sequence of the left terminus of Tn5252 showed two open reading frames, ORF1 and ORF2, adjoining the att site. The organization of this region and the structure of the predicted integrase encoded by ORF1 were found to be similar to those of other site-specific recombination systems.

Tn5253, the pneumococcal omega (cat tet) BM6001 element, is a composite structure of two conjugative transposons, Tn5251 and Tn5252.

Tn5253, carrying tetracycline and chloramphenicol resistance determinants, is a 65.5-kb conjugative transposon originally detected in the chromosome of Streptococcus pneumoniae BM6001. We have identified an 18-kb segment of DNA carrying the tet determinant within Tn5253 to be an independent conjugative transposon when removed from the context of the larger element. In vivo deletion of this DNA segment, now termed Tn5251, from within Tn5253 did not affect the conjugative transposition properties of the remaining sequences. Thus, Tn5253 is a composite element of two conjugative structures: Tn5252, constituting the sequences beyond Tn5251 within Tn5253, and Tn5251. The transfer properties of Tn5252 and Tn5251 suggest that these may belong to two different classes of mobile elements even though they were initially found associated. The notion that a tet-carrying transposon like Tn5251 may have been the ancestral element in the evolution of the larger streptococcal conjugative transposons must be reevaluated in the light of present observations.