A host factor absent from Lactococcus lactis subspecies lactis MG1363 is required for conjugative transposition

Biology of Three ICE Families: SXT/R391, ICEBs1, and ICESt1/ICESt3

Integrative and Conjugative Elements (ICEs) are bacterial mobile genetic elements that play a key role in bacterial genomes dynamics and evolution. ICEs are widely distributed among virtually all bacterial genera. Recent extensive studies have unraveled their high diversity and complexity. The present review depicts the general conserved features of ICEs and describes more precisely three major families of ICEs that have been extensively studied in the past decade for their biology, their evolution and their impact on genomes dynamics. First, the large SXT/R391 family of ICEs disseminates antibiotic resistance genes and drives the exchange of mobilizable genomic islands (MGIs) between many enteric pathogens such as Vibrio cholerae. Second, ICEBs1 of Bacillus subtilis is the most well understood ICE of Gram-positive bacteria, notably regarding the regulation of its dissemination and its initially unforeseen extrachromosomal replication, which could be a common feature of ICEs of both Gram-positive and Gram-negative bacteria. Finally, ICESt1 and ICESt3 of Streptococcus thermophilus are the prototypes of a large family of ICEs widely distributed among various streptococci. These ICEs carry an original regulation module that associates regulators related to those of both SXT/R391 and ICEBs1. Study of ICESt1 and ICESt3 uncovered the cis-mobilization of related genomic islands (CIMEs) by a mechanism called accretion-mobilization, which likely represents a paradigm for the evolution of many ICEs and genomic islands. These three major families of ICEs give a glimpse about ICEs dynamics and their high impact on bacterial adaptation.

Modulation of gut-associated lymphoid tissue functions with genetically modified Lactococcus lactis

Lactic acid bacteria are a group of taxonomically diverse, Gram-positive food-grade bacteria that have been safely consumed throughout history. The lactic acid bacterium Lactococcus lactis, well-known for its use in the manufacture of cheese, can be genetically engineered and orally formulated to deliver therapeutic proteins in the gastrointestinal tract. This review focuses on the genetic engineering of Lactococcus lactis to secrete high-quality, correctly processed bioactive molecules derived from a eukaryotic background. The therapeutic applications of these genetically modified strains are discussed, with special regards to immunomodulation.

Intra- and interspecies conjugal transfer of Tn916-like elements from Lactococcus lactis in vitro and in vivo

Tetracycline-resistant Lactococcus lactis strains originally isolated from Polish raw milk were analyzed for the ability to transfer their antibiotic resistance genes in vitro, using filter mating experiments, and in vivo, using germfree rats. Four of six analyzed L. lactis isolates were able to transfer tetracycline resistance determinants in vitro to L. lactis Bu2-60, at frequencies ranging from 10(-5) to 10(-7) transconjugants per recipient. Three of these four strains could also transfer resistance in vitro to Enterococcus faecalis JH2-2, whereas no transfer to Bacillus subtilis YBE01, Pseudomonas putida KT2442, Agrobacterium tumefaciens UBAPF2, or Escherichia coli JE2571 was observed. Rats were initially inoculated with the recipient E. faecalis strain JH2-2, and after a week, the L. lactis IBB477 and IBB487 donor strains were introduced. The first transconjugants were detected in fecal samples 3 days after introduction of the donors. A subtherapeutic concentration of tetracycline did not have any significant effect on the number of transconjugants, but transconjugants were observed earlier in animals dosed with this antibiotic. Molecular analysis of in vivo transconjugants containing the tet(M) gene showed that this gene was identical to tet(M) localized on the conjugative transposon Tn916. Primer-specific PCR confirmed that the Tn916 transposon was complete in all analyzed transconjugants and donors. This is the first study showing in vivo transfer of a Tn916-like antibiotic resistance transposon from L. lactis to E. faecalis. These data suggest that in certain cases food lactococci might be involved in the spread of antibiotic resistance genes to other lactic acid bacteria.

Meta-analysis of experimental data concerning antimicrobial resistance gene transfer rates during conjugation

This paper presents the results of a meta-analysis of published transfer rates of antimicrobial resistance genes. A total of 34 papers were identified, of which 28 contained rates estimated in relation to either donor or recipient bacterial counts. The published rates ranged from 10(-2) to 10(-9). Generalized linear modeling was conducted to identify the factors influencing this variation. Highly significant associations between transfer frequency and both the donor (P = 1.2 x 10(-4)) and recipient (P = 1.0 x 10(-5)) genera were found. Also significant was whether the donor and recipient strains were of the same genus (P = 0.023) and the nature of the genetic element (P = 0.0019). The type of experiment, in vivo or in vitro, approached statistical significance (P = 0.12). Parameter estimates from a general linear model were used to estimate the probability of transfer of antimicrobial resistance genes to potential pathogens in the intestine following oral ingestion. The mean logarithms of these probabilities are in the range of [-7.0, -3.1]. These probability distributions are suitable for use in the quantitative assessment of the risk of transfer of antimicrobial resistance genes to the intestinal flora of humans and animals.

Comparative analysis of sequences flanking tet(W) resistance genes in multiple species of gut bacteria

tet(W) is one of the most abundant tetracycline resistance genes found in bacteria from the mammalian gut and was first identified in the rumen anaerobe Butyrivibrio fibrisolvens 1.230, where it is highly mobile and its transfer is associated with the transposable chromosomal element TnB1230. In order to compare the genetic basis for tet(W) carriage in different bacteria, we studied sequences flanking tet(W) in representatives of seven bacterial genera originating in diverse gut environments. The sequences 657 bp upstream and 43 bp downstream of tet(W) were 96 to 100% similar in all strains examined. A common open reading frame (ORF) was identified downstream of tet(W) in five different bacteria, while another conserved ORF that flanked tet(W) in B. fibrisolvens 1.230 was also present upstream of tet(W) in a human colonic Roseburia isolate and in another rumen B. fibrisolvens isolate. In one species, Bifidobacterium longum (strain F8), a novel transposase was located within the conserved 657-bp region upstream of tet(W) and was flanked by imperfect direct repeats. Additional direct repeats 6 bp long were identified on each end of a chromosomal ORF interrupted by the insertion of the putative transposase and the tet(W) gene. This tet(W) gene was transferable at low frequencies between Bifidobacterium strains. A putative minielement carrying a copy of tet(W) was identified in B. fibrisolvens transconjugants that had acquired the tet(W) gene on TnB1230. Several different mechanisms, including mechanisms involving plasmids and conjugative transposons, appear to be involved in the horizontal transfer of tet(W) genes, but small core regions that may function as minielements are conserved.

A phase I trial with transgenic bacteria expressing interleukin-10 in Crohn's disease

BACKGROUND & AIMS

The use of living, genetically modified bacteria is an effective approach for topical delivery of immunomodulatory proteins. This strategy circumvents systemic side effects and allows long-term treatment of chronic diseases. However, treatment of patients with a living, genetically modified bacterium raises questions about the safety for human subjects per se and the biologic containment of the transgene.

METHODS

We treated Crohn's disease patients with genetically modified Lactococcus lactis (LL-Thy12) in which the thymidylate synthase gene was replaced with a synthetic sequence encoding mature human interleukin-10. Ten patients were included in a placebo-uncontrolled trial. Patients were assessed daily for the presence of potential adverse effects by direct questioning and assessment of disease activity. We evaluated the presence and kinetics of LL-Thy12 release in the stool of patients by conventional culturing and quantitative polymerase chain reaction of LL-Thy12 gene sequences.

RESULTS

Treatment with LL-Thy12 was safe because only minor adverse events were present, and a decrease in disease activity was observed. Moreover, fecally recovered LL-Thy12 bacteria were dependent on thymidine for growth and interleukin-10 production, indicating that the containment strategy was effective.

CONCLUSIONS

Here we show that the use of genetically modified bacteria for mucosal delivery of proteins is a feasible strategy in human beings. This novel strategy avoids systemic side effects and is biologically contained; therefore it is suitable as maintenance treatment for chronic intestinal disease.

Shaping bacterial genomes with integrative and conjugative elements

Integrative and conjugative elements (ICEs) are self-transmissible mobile genetic elements that are increasingly recognized to contribute to lateral gene flow in prokaryotes. ICEs, like most temperate bacteriophages integrate into the genome and like conjugative plasmids disseminate by conjugative transfer to new hosts. Thought of schematically, the structure of ICEs is similar to that of other types of the mobile elements; ICEs have a backbone composed of three modules ensuring maintenance, dissemination and regulation. This backbone can acquire additional functions probably through the action of insertion sequences, transposons and specific recombinases. Previously, ICEs were thought of as only vectors for transfer of antibiotic resistance genes, but it is now evident that ICEs can mediate the transfer of a very diverse set of functions. ICEs allow bacteria to rapidly adapt to new environmental conditions and to colonize new niches. Like phages and conjugative plasmids they also likely mediate the transfer of virulence determinants. ICEs shape the bacterial genome, promoting variability between strains of the same species and distributing genes between unrelated bacterial genera. Finally, we propose that by utilizing conserved integration sites, ICEs may promote the mobilization of genomic islands.

Biological containment of genetically modified Lactococcus lactis for intestinal delivery of human interleukin 10

Genetically modified Lactococcus lactis secreting interleukin 10 provides a therapeutic approach for inflammatory bowel disease. However, the release of such genetically modified organisms through clinical use raises safety concerns. In an effort to address this problem, we replaced the thymidylate synthase gene thyA of L. lactis with a synthetic human IL10 gene. This thyA- hIL10+ L. lactis strain produced human IL-10 (hIL-10), and when deprived of thymidine or thymine, its viability dropped by several orders of magnitude, essentially preventing its accumulation in the environment. The biological containment system and the bacterium's capacity to secrete hIL-10 were validated in vivo in pigs. Our approach is a promising one for transgene containment because, in the unlikely event that the engineered L. lactis strain acquired an intact thyA gene from a donor such as L. lactis subsp. cremoris, the transgene would be eliminated from the genome.

The frequency of conjugative transposition of Tn916 is not determined by the frequency of excision

Excision and formation of a covalently closed circular transposon molecule are required for conjugative transposition of Tn916 but are not the only factors that limit the frequency of conjugative transposition from one host to another. We found that in gram-positive bacteria, an increase in the frequency of excision and circularization of Tn916 caused by expression of integrase (Int) and excisionase (Xis) from a xylose-inducible promoter does not lead to an increase in the frequency of conjugative transposition. We also found that the concentration of Int and Xis in the recipient cell does not limit the frequency of conjugative transposition and that increased excision does not result in increased expression of transfer functions required to mobilize a plasmid containing the Tn916 origin of transfer. We conclude that in gram-positive hosts in which the Tn916 functions Int and Xis are overexpressed, the frequency of conjugative transposition is limited by the availability of transfer functions.

Excision of the conjugative transposon Tn916 in Lactococcus lactis

In Lactococcus lactis excision of Tn916 is limited by the concentration of integrase and is increased by providing more excisionase. However, even with increased excision of Tn916 in L. lactis, no conjugative transfer is detectable. This suggests that L. lactis is deficient in a host factor(s) required for conjugative transposition.

Circularization of Tn916 is required for expression of the transposon-encoded transfer functions: characterization of long tetracycline-inducible transcripts reading through the attachment site

A detailed transcriptional analysis of the conjugative transposon Tn916 was carried out, which revealed that transcription of the transfer functions requires excision of the element and dramatically increases in the presence of tetracycline. The key components of this regulatory system are two contiguous transposon-borne genes, orf7 and orf8, located downstream from and having the same polarity of transcription as the tetracycline resistance determinant tetM. The gene orf7 encodes a 140-amino-acid (aa) protein exhibiting limited homology with sigmaF of Bacillus subtilis, whereas orf8 encodes a 76-aa peptide that does not share any sequence homology with any cognate proteins. In the presence of tetracycline, an attenuation mechanism enables the transcription of orf7 and orf8 from the tetM promoter. The resulting increased synthesis of ORF7 and ORF8 activates the promoter Porf7 located upstream from orf7, which then directs the expression of the transfer functions in the transposon circular intermediate through long transcripts encompassing the attachment site. The apparently non-regulated promoter Pxis located upstream of the excisionase encoding gene xis could also participate in the expression of the tra genes. We also demonstrate that Tn916 carries another regulated promoter, Porf9, which directs transcription of a single gene, orf9, located downstream from and transcribed counterclockwise to tetM. This gene encodes a 117-aa putative transcriptional repressor, but the exact role of this protein in the mobility of Tn916, as well as the regulation of its expression, remains to be elucidated. Our results constitute the molecular basis for the observation that tetracycline increased the transfer frequency of this type of element.

Use of an excision reporter plasmid to study the intracellular mobility of the conjugative transposon Tn916 in gram-positive bacteria

An excision reporter plasmid was constructed to characterize the intracellular mobility of Tn916 in various Gram-positive bacteria. The reporter component of this plasmid is a chloramphenicol-resistance gene which has been insertionally inactivated with the integrative vector pAT112 containing the attachment site of Tn916. Tn916-mediated excision of pAT112, to produce clones resistant to chloramphenicol, was detected in Enterococcus faecalis BM4110, Listeria monocytogenes L028-Str and Streptococcus gordonii BM120, but not in Lactococcus lactis MG1363-RF or in Streptococcus pneumoniae BM124, and always depended upon the ability of the bacterial host to generate circular forms of the transposon. The results suggest that (i) the excision event, although required, is not sufficient for conjugal transfer to occur and (ii) there is no linear relationship between the donor potential of E. faecalis strains and either the excision frequency of pAT112 or the copy number of Tn916 circular intermediates per cell in these hosts. Excision of pAT112 occurred mainly during the late exponential phase of growth of E. faecalis and L. monocytogenes and this recombination event was not stimulated by heat shock, salt and alcohol stresses or by the presence of tetracycline in the medium.

Transposon mutagenesis of Haemophilus paragallinarum with Tn916

The Gram-positive transposon Tn916 was introduced into two strains of Haemophilus paragallinarum by electroporation of the suicide plasmid pAM120 (pGL101::Tn916). Tetracycline resistant mutants of H. paragallinarum strains Tw-1 and 221 were recovered at frequencies of 2.1 x 10(-6) and 4.5 x 10(-7) per viable cell electroporated, respectively. Tn916 generates stable single insertions within different sites of the H. paragallinarum chromosome. One Tw-1::Tn916 mutant had the Tn916 insertion in the cryptic plasmid p250. This study indicates the potential use of Tn916 as a genetic tool for insertional mutagenesis of H. paragallinarum.

Unconstrained bacterial promiscuity: the Tn916-Tn1545 family of conjugative transposons

Conjugative transposons are highly ubiquitous elements found throughout the bacterial world. Members of the Tn916-Tn1545 family carry the widely disseminated tetracycline-resistance determinant Tet M, as well as additional resistance genes. They have been found naturally in, or been introduced into, over 50 different species and 24 genera of bacteria. Recent investigations have led to insights into the molecular basis of movement of these interesting mobile elements.

Identification and characterization of genes involved in excision of the Lactococcus lactis conjugative transposon Tn5276

The 70-kb transposon Tn5276, originally detected in Lactococcus lactis NIZO R5 and carrying the genes for nisin production and sucrose fermentation, can be conjugally transferred to other L. lactis strains. Sequence analysis and complementation studies showed that the right end of Tn5276 contains two genes, designated xis and int, which are involved in excision. The 379-amino-acid int gene product shows high (up to 50%) similarity with various integrases, including that of the Tn916-related conjugative transposons. The xis gene product, like almost all known excisionase (Xis) proteins, is a small (68-residue), basic protein. Expression of both the Tn5276 int and xis genes is required for efficient excision of the ends of Tn5276 in Escherichia coli that appeared to be circularized in the excision process. Mutational analysis of the xis and int genes showed that excision efficiency is dependent on the integrity of the int gene but that an intact xis gene is also required for efficient excision.

Conjugative transposition of Tn916: preferred targets and evidence for conjugative transfer of a single strand and for a double-stranded circular intermediate

Transposition of conjugative transposons proceeds by excision and formation of a covalently closed circular intermediate that includes at its joint the six flanking bases from its previous host (coupling sequences). To elucidate the role of the coupling sequences in this process and to determine the sequence of targets used by Tn916, we studied its insertion into a plasmid following conjugation. The results differ from those previously observed when Tn916 was introduced by transformation. They suggest that only one specific strand of the transposon molecule is transferred during the conjugation event and that complementary strand synthesis produces a double-stranded transposon circle with no mismatches which serves as the reaction intermediate. Tn916 inserts preferentially at specific sites and the same targets are used when Tn916 comes from donors with different coupling sequences. An analysis of the sequences of preferred targets is presented.

Transfer of Tn916 between Lactococcus lactis subsp. lactis strains is nontranspositional: evidence for a chromosomal fertility function in strain MG1363

Lactococcus lactis subsp. lactis MG1363 can act as a conjugative donor of chromosomal markers. This requires a chromosomally located fertility function that we designate the lactococcal fertility factor (Laff). Using inter- and intrastrain crosses, we identified other L. lactis strains (LMO230 and MMS373) that appear to lack Laff. The selectable marker in our crosses was Tcr, carried by Tn916, a transposon present on the chromosome. The transfer of Tcr was not due to Tn916-encoded conjugative functions, because (i) L. lactis cannot act as a donor in Tn916-promoted conjugation (F. Bringel, G. L. Van Alstine, and J. R. Scott, Mol. Microbiol. 5:2983-2993, 1992) and (ii) transfer occurred when the Tcr marker was present in a Tn916 derivative containing a mutation, tra-641, that prevents Tn916-directed conjugation in any host. In addition, we isolated a strain in which Tn916 appears to be linked to Laff; this strain should be useful for further analysis of this fertility factor. In this strain, Tn916 is on the same 600-kb SmaI fragment as Clu, a fertility factor previously shown to promote lactose plasmid transfer in L. lactis. Thus, it is possible that Clu and Laff are identical.

Conjugative transposition of Tn916: the transposon int gene is required only in the donor

Conjugative transposition of transposon Tn916 has been shown to proceed by excision of the transposon in the donor strain and insertion of this element in the recipient. This process requires the product of the transposon int gene. We report here the surprising finding that the int gene is required only in the donor during conjugative transposition. We find that Tn916 int-1, whose int gene has been inactivated by an insertion mutation, transposes when a complementing wild-type int gene is present only in the donor during mating. When the int+ gene is present in a plasmid and is expressed from the spac promoter, conjugative transposition is very inefficient. However, when the Int+ function is supplied from a coresident distantly linked Tn916 tra-641 mutant, which is defective in a function required for conjugation, efficient conjugative transposition of Tn916 int-1 occurs. This suggests either that Int is not required for integration of Tn916 in gram-positive bacteria or that the protein is transferred from the donor to the transconjugant during the mating event. When the nonconjugative plasmid pAT145 was present in the donor, it was rarely cotransferred with Tn916. This suggests that complete fusion of mating cells is not common during conjugative transposition.