A new Bacteroides conjugative transposon that carries an ermB gene

The erythromycin resistance gene ermB has been found in a variety of gram-positive bacteria. This gene has also been found in Bacteroides species but only in six recently isolated strains; thus, the gene seems to have entered this genus only recently. One of the six Bacteroides ermB-containing isolates, WH207, could transfer ermB to Bacteroides thetaiotaomicron strain BT4001 by conjugation. WH207 was identified as a Bacteroides uniformis strain based on the sequence of its 16S rRNA gene. Results of pulsed-field gel electrophoresis experiments demonstrated that the transferring element was normally integrated into the Bacteroides chromosome. The element was estimated from pulsed-field gel data to be about 100 kb in size. Since the element appeared to be a conjugative transposon (CTn), it was designated CTnBST. CTnBST was able to mobilize coresident plasmids and the circular form of the mobilizable transposon NBU1 to Bacteroides and Escherichia coli recipients. A 13-kb segment that contained ermB was cloned and sequenced. Most of the open reading frames in this region had little similarity at the amino acid sequence level to any proteins in the sequence databases, but a 1,723-bp DNA segment that included a 950-bp segment downstream of ermB had a DNA sequence that was virtually identical to that of a segment of DNA found previously in a Clostridium perfringens strain. This finding, together with the finding that ermB is located on a CTn, supports the hypothesis that CTnBST could have entered Bacteroides from some other genus, possibly from gram-positive bacteria. Moreover, this finding supports the hypothesis that many transmissible antibiotic resistance genes in Bacteroides are carried on CTns.     

A Newly Discovered Bacteroides Conjugative Transposon, CTnGERM1, Contains Genes Also Found in Gram-Positive Bacteria

Results of a recent study of antibiotic resistance genes in human colonic Bacteroides strains suggested that gene transfer events between members of this genus are fairly common. The identification of Bacteroides isolates that carried an erythromycin resistance gene, ermG, whose DNA sequence was 99% identical to that of an ermG gene found previously only in gram-positive bacteria raised the further possibility that conjugal elements were moving into Bacteroides species from other genera. Six of seven ermG-containing Bacteroides strains tested were able to transfer ermG by conjugation. One of these strains was chosen for further investigation. Results of pulsed-field gel electrophoresis experiments showed that the conjugal element carrying ermG in this strain is an integrated element about 75 kb in size. Thus, the element appears to be a conjugative transposon (CTn) and was designated CTnGERM1. CTnGERM1 proved to be unrelated to the predominant type of CTn found in Bacteroides isolates—CTns of the CTnERL/CTnDOT family—which sometimes carry another type of erm gene, ermF. A 19-kbp segment of DNA from CTnGERM1 was cloned and sequenced. A 10-kbp portion of this segment hybridized not only to DNA from all the ermG-containing strains but also to DNA from strains that did not carry ermG. Thus, CTnGERM1 seems to be part of a family of CTns, some of which have acquired ermG. The percentage of G+C content of the ermG region was significantly lower than that of the chromosome of Bacteroides species—an indication that CTnGERM1 may have entered Bacteroides strains from some other bacterial genus. A survey of strains isolated before 1970 and after 1990 suggests that the CTnGERM1 type of CTn entered Bacteroides species relatively recently. One of the genes located upstream of ermG encoded a protein that had 85% amino acid sequence identity with a macrolide efflux pump, MefA, from Streptococcus pyogenes. Our having found >90% sequence identity of two upstream genes, including mefA, and the remnants of two transposon-carried genes downstream of ermG with genes found previously only in gram-positive bacteria raises the possibility that gram-positive bacteria could have been the origin of CTnGERM1.     

Possible Origins of CTnBST, a Conjugative Transposon Found Recently in a Human Colonic Bacteroides Strain

A previous survey of Bacteroides isolates suggested that the ermB gene entered Bacteroides spp. recently. Previously, ermB had been found almost exclusively in gram-positive bacteria. In one Bacteroides strain, ermB was located on 100-kb conjugative transposon (CTn) CTnBST. To assess the possible origin of this CTn, we obtained the full DNA sequence of CTnBST and used this information to investigate its possible origins. Over one-half of CTnBST had high sequence identity to a putative CTn found in the genome of Bacteroides fragilis YCH46. This included the ends of the CTn and genes involved in integration, transfer, and excision. However, the region around the ermB gene contained genes that appeared to originate from gram-positive organisms. In particular, a 7-kb segment containing the ermB gene was 100% identical to an ermB region found in the genome of the gram-positive bacterium Arcanobacterium pyogenes. A screen of Bacteroides isolates whose DNA cross-hybridized with a CTnBST probe revealed that several isolates did not carry the 7-kb region, implying that the acquisition of this region may be more recent than the acquisition of the entire CTnBST element by Bacteroides spp. We have also identified other Bacteroides isolates that carry a slightly modified 7-kb region but have no other traces of CTnBST. Thus, it is possible that this 7-kb region could itself be part of a mobile element that has inserted in a Bacteroides CTn. Our results show that CTnBST is a hybrid element which has acquired a portion of its coding region from gram-positive bacteria but which may originally have come from Bacteroides spp. or some related species.     

Conjugative Plasmid from Lactobacillus gasseri LA39 That Carries Genes for Production of and Immunity to the Circular Bacteriocin Gassericin A

Gassericin A is a circular bacteriocin produced by Lactobacillus gasseri strain LA39. We found a 33,333-bp plasmid, designated pLgLA39, in this strain. pLgLA39 contained 44 open reading frames, including seven genes related to gassericin A production/immunity (gaa), as well as genes for replication, plasmid maintenance, and conjugative transfer. pLgLA39 was transferred from LA39 to the type strain of L. gasseri (JCM 1131) by filter mating. The transconjugant exhibited >30-fold-higher more resistance to gassericin A and produced antibacterial activity. Lactobacillus reuteri LA6, the producer of reutericin 6, was proved to harbor a plasmid indistinguishable from pLgLA39 and carrying seven genes 100% identical to gaa. This suggests that pLgLA39 might have been transferred naturally between L. gasseri LA39 and L. reuteri LA6. The seven gaa genes of pLgLA39 were cloned into a plasmid vector to construct pGAA. JCM 1131^T transformed with pGAA expressed antibacterial activity and resistance to gassericin A. pGAA was segregationally more stable than a pGAA derivative plasmid from which gaaA was deleted and even was more stable than the vector. This suggests the occurrence of postsegregational host killing by the gaa genes. pLgLA39 carried a pemIK homolog, and segregational stabilization of a plasmid by the pLgLA39-type pemIK genes was also confirmed. Thus, pLgLA39 was proved to carry the genes for at least two plasmid maintenance mechanisms, i.e., gaa and pemIK. Plasmids containing a repA gene similar to pLgLA39 repA were distributed in several L. gasseri strains.Lactobacillus species are normal inhabitants of the human gastrointestinal tract, and Lactobacillus gasseri is one of the most commonly detected of these species (37, 47). Health-promoting effects of this species, such as immunomodulation (35), suppression of Helicobacter pylori-induced interleukin-8 production (44), and improvement of intestinal conditions (34), have been reported, and some L. gasseri strains are used in commercial probiotic products.Bacteriocins are antimicrobial peptides, proteins, or protein complexes produced by bacteria and active mainly against related bacterial species (38). Several bacteriocins also inhibit the growth of food-borne pathogens, such as Listeria, Bacillus cereus, and Clostridium perfringens. Production of bacteriocin is thought to be a desired feature for probiotic strains, since bacteriocin is believed to provide an advantage for survival in the ecological niche and to prevent the growth of pathogens. Several L. gasseri strains are known to produce bacteriocins (18). The classification of bacteriocins remains controversial. We use the definition proposed by Maqueda et al. (30), where bacteriocins are classified into class I (lantibiotics), class II (nonlantibiotics), class III (large heat-labile bacteriocins), and class IV (circular bacteriocins linked at the N- and C-terminal ends). Among these, the class IV circular bacteriocins have attracted increasing attention, since they are the simplest prokaryotic representatives of the ubiquitous circular peptides with various physiological activities (6). Enterocin AS-48 from Enterococcus faecalis strain S-48 is the first and most vigorously characterized member of the class IV bacteriocins (30). L. gasseri strain LA39 (JCM 11657) produces a 58-amino-acid (aa) circular bacteriocin, gassericin A (18). Gassericin A is a representative of the non-AS-48-like circular bacteriocin group including butyrivibriocin AR10 from Butyrivibrio fibrisolvens AR10 (15) and carnocyclin A from Carnobacterium maltaromaticum UAL307 (32), as well as reutericin 6 from Lactobacillus reuteri LA6 (17) and acidocin B from Lactobacillus acidophilus M46 (26). The last two bacteriocins have nearly identical amino acid sequences to that of gassericin A. Though the number of reported circular bacteriocins has been increasing, their primary sequences and the genes responsible for production of and immunity to them are diversified (for a review, see reference 31). Recently, we isolated and sequenced seven genes (gaaBCADITE) from LA39 deduced to be responsible for production of and immunity to gassericin A (20). The gaa genes add new information to the complex world of the class IV bacteriocin genes.The structural gene of gassericin A, gaaA, was reported to be located on the chromosome of LA39 (19). However, the high amino acid sequence identity of gassericin A to reutericin 6 (100%) and to acidocin B (98%) suggests recent horizontal gene transfers of the relevant bacteriocin genes, possibly via mobile elements. In fact, the acidocin B genes were reported to be located on a plasmid, namely, pCV461 (26). Many Lactobacillus strains are known to harbor one or more plasmids of various sizes, and several Lactobacillus plasmids have been reported to contain genes for production of bacteriocins (48). To our knowledge, however, only three have been sequenced entirely: these are pLA103 from Lactobacillus acidophilus TK8912 (16), pRC18 from Lactobacillus curvatus (previously known as Lactobacillus casei) CRL705 (7), and pMP118 from Lactobacillus salivarius subsp. salivarius UCC118 (5). Thus, genetic information about bacteriocin-producing Lactobacillus plasmids is still limited. Furthermore, little has been known about plasmids of L. gasseri, even though the existence of plasmids in a few strains has been reported, including a 26.5-kb anonymous plasmid in strain ADH (27) and pK7 in strain K7 (28).Here we describe a 33.3-kb plasmid, designated pLgLA39, from L. gasseri LA39. The gaa genes are located on this plasmid. pLgLA39 carries a set of genes for conjugative transfer and was shown to be transmitted to another L. gasseri strain. L. reuteri LA6 also harbors a plasmid almost identical to pLgLA39. We demonstrated that production of gassericin A increased the apparent segregational stability of a plasmid carrying the gaa genes. A pemIK homolog in pLgLA39 was also functional as a plasmid-stabilizing mechanism. This is the first report describing the entire nucleotide sequence and detailed genetic analysis of an L. gasseri plasmid, which contains functional genes for circular bacteriocin production, conjugation, and plasmid maintenance.     

A New Large-DNA-Fragment Delivery System Based on Integrase Activity from an Integrative and Conjugative Element

During the past few decades, numerous plasmid vectors have been developed for cloning, gene expression analysis, and genetic engineering. Cloning procedures typically rely on PCR amplification, DNA fragment restriction digestion, recovery, and ligation, but increasingly, procedures are being developed to assemble large synthetic DNAs. In this study, we developed a new gene delivery system using the integrase activity of an integrative and conjugative element (ICE). The advantage of the integrase-based delivery is that it can stably introduce a large DNA fragment (at least 75 kb) into one or more specific sites (the gene for glycine-accepting tRNA) on a target chromosome. Integrase recombination activity in Escherichia coli is kept low by using a synthetic hybrid promoter, which, however, is unleashed in the final target host, forcing the integration of the construct. Upon integration, the system is again silenced. Two variants with different genetic features were produced, one in the form of a cloning vector in E. coli and the other as a mini-transposable element by which large DNA constructs assembled in E. coli can be tagged with the integrase gene. We confirmed that the system could successfully introduce cosmid and bacterial artificial chromosome (BAC) DNAs from E. coli into the chromosome of Pseudomonas putida in a site-specific manner. The integrase delivery system works in concert with existing vector systems and could thus be a powerful tool for synthetic constructions of new metabolic pathways in a variety of host bacteria.     

Gain-of-Function Mutations in Tnsc, an Atp-Dependent Transposition Protein That Activates the Bacterial Transposon Tn7

The bacterial transposon Tn7 encodes five genes whose protein products are used in different combinations to direct transposition to different types of target sites. TnsABC+D directs transposition to a specific site in the Escherichia coli chromosome called attTn7, whereas TnsABC+E directs transposition to non-attTn7 sites. These transposition reactions can also recognize and avoid ``immune' targets that already contain a copy of Tn7. TnsD and TnsE are required to activate TnsABC as well as to select a target site; no transposition occurs with wild-type TnsABC alone. Here, we describe the isolation of TnsC gain-of-function mutants that activate the TnsA+B transposase in the absence of TnsD or TnsE. Some of these TnsC mutants enable the TnsABC machinery to execute transposition without sacrificing its ability to discriminate between different types of targets. Other TnsC mutants appear to constitutively activate the TnsABC machinery so that it bypasses target signals. We also present experiments that suggest that target selection occurs early in the Tn7 transposition pathway in vivo: favorable attTn7 targets appear to promote the excision of Tn7 from the chromosome, whereas immune targets do not allow transposon excision to occur. This work supports the view that TnsC plays a central role in the evaluation and utilization of target DNAs.     

A Novel Plasmid Gene Involved in Bacteriophage PRD1 Infection and Conjugative Host-Range

PRD1 infects bacteria carrying IncN plasmids by binding to their conjugative pili. Mutations in a plasmid locuskikAclose to the pilus region result in PRD1 resistance and reduced conjugation proficiency toKlebsiellabut not toEscherichia coli.One of the two genes ofkikAis sufficient to restore both normal phenotypes. PRD1 binds to cells carrying the mutant plasmid but fails to inject its genome.     

A Novel Gene Encoding an Enzyme That Degrades a Polysaccharide from the Sheath of Sphaerotilus natans

A gene encoding an enzyme that is able to depolymerize the basic polysaccharide prepared from the sheath of Sphaerotilus natans was identified in a sheath-degrading bacterium, Paenibacillus koleovorans. The gene was constructed from 2217 bp coding for 738 amino acids, including the signal sequence of 34 amino acids. No closely related protein or gene was indicated by a homology search. The gene was expressed in Escherichia coli as a glutathione S-transferase fusion protein. The fusion protein depolymerized the sheath polysaccharide into an oligosaccharide, introducing an unsaturated sugar residue, suggesting that the gene codes for a polysaccharide lyase acting on a basic polysaccharide.     

ADAP2 Is an Interferon Stimulated Gene That Restricts RNA Virus Entry

Interferon stimulated genes (ISGs) target viruses at various stages of their infectious life cycles, including at the earliest stage of viral entry. Here we identify ArfGAP with dual pleckstrin homology (PH) domains 2 (ADAP2) as a gene upregulated by type I IFN treatment in a STAT1-dependent manner. ADAP2 functions as a GTPase-activating protein (GAP) for Arf6 and binds to phosphatidylinositol 3,4,5-trisphosphate (PI(3,4,5)P₃) and PI(3,4)P₂. We show that overexpression of ADAP2 suppresses dengue virus (DENV) and vesicular stomatitis virus (VSV) infection in an Arf6 GAP activity-dependent manner, while exerting no effect on coxsackievirus B (CVB) or Sendai virus (SeV) replication. We further show that ADAP2 expression induces macropinocytosis and that ADAP2 strongly associates with actin-enriched membrane ruffles and with Rab8a- and LAMP1-, but not EEA1- or Rab7-, positive vesicles. Utilizing two techniques—light-sensitive neutral red (NR)-containing DENV and fluorescence assays for virus internalization—we show that ADAP2 primarily restricts DENV infection at the stage of virion entry and/or intracellular trafficking and that incoming DENV and VSV particles associate with ADAP2 during their entry. Taken together, this study identifies ADAP2 as an ISG that exerts antiviral effects against RNA viruses by altering Arf6-mediated trafficking to disrupt viral entry.     

Transposon Assisted Gene Insertion Technology (TAGIT): A Tool for Generating Fluorescent Fusion Proteins

We constructed a transposon (transposon assisted gene insertion technology, or TAGIT) that allows the random insertion of gfp (or other genes) into chromosomal loci without disrupting operon structure or regulation. TAGIT is a modified Tn5 transposon that uses Kan^R to select for insertions on the chromosome or plasmid, β-galactosidase to identify in-frame gene fusions, and Cre recombinase to excise the kan and lacZ genes in vivo. The resulting gfp insertions maintain target gene reading frame (to the 5′ and 3′ of gfp) and are integrated at the native chromosomal locus, thereby maintaining native expression signals. Libraries can be screened to identify GFP insertions that maintain target protein function at native expression levels, allowing more trustworthy localization studies. We here use TAGIT to generate a library of GFP insertions in the Escherichia coli lactose repressor (LacI). We identified fully functional GFP insertions and partially functional insertions that bind DNA but fail to repress the lacZ operon. Several of these latter GFP insertions localize to lacO arrays integrated in the E. coli chromosome without producing the elongated cells frequently observed when functional LacI-GFP fusions are used in chromosome tagging experiments. TAGIT thereby faciliates the isolation of fully functional insertions of fluorescent proteins into target proteins expressed from the native chromosomal locus as well as potentially useful partially functional proteins.     

Transposon Mutagenesis of Probiotic Lactobacillus casei Identifies asnH,an Asparagine Synthetase Gene Involved in Its Immune-Activating Capacity

Lactobacillus casei ATCC 27139 enhances host innate immunity, and the J1 phage-resistant mutants of this strain lose the activity. A transposon insertion mutant library of L. casei ATCC 27139 was constructed, and nine J1 phage-resistant mutants out of them were obtained. Cloning and sequencing analyses identified three independent genes that were disrupted by insertion of the transposon element: asnH, encoding asparagine synthetase, and dnaJ and dnaK, encoding the molecular chaperones DnaJ and DnaK, respectively. Using an in vivo mouse model of Listeria infection, only asnH mutant showed deficiency in their ability to enhance host innate immunity, and complementation of the mutation by introduction of the wild-type asnH in the mutant strain recovered the immuno-augmenting activity. AsnH protein exhibited asparagine synthetase activity when the lysozyme-treated cell wall extracts of L. casei ATCC 27139 was added as substrate. The asnH mutants lost the thick and rigid peptidoglycan features that are characteristic to the wild-type cells, indicating that AsnH of L. casei is involved in peptidoglycan biosynthesis. These results indicate that asnH is required for the construction of the peptidoglycan composition involved in the immune-activating capacity of L. casei ATCC 27139.     

诱导免疫应答的一种新手段──基因免疫

近年来,一种诱导免疫应答的新手段─—基因免疫,正在引起人们越来越多的关注．所谓基因免疫,是将含有编码序列及必要表达调控元件的质粒DNA,直接导入动物组织,经诱导动物免疫系统对编码序列所表达的蛋白质发生免疫应答,达到免疫的目的．文章介绍了基因免疫的基本方法,综述了这一新兴领域中涉及传染病、肿瘤、移植等方面的研究成果及存在的问题,并展望了研究前景.