Home About us Contact
|
Home About us Contact | ||
|
|
||
Natural Transformation (natural + transformation)
Selected AbstractsNatural transformation of Vibrio fischeri requires tfoX and tfoYENVIRONMENTAL MICROBIOLOGY, Issue 8 2010Amber Pollack-Berti Summary Recent evidence has indicated that natural genetic transformation occurs in Vibrio cholerae, and that it requires both induction by chitin oligosaccharides, like chitohexaose, and expression of a putative regulatory gene designated tfoX. Using sequence and phylogenetic analyses we have found two tfoX paralogues in all sequenced genomes of the genus Vibrio. Like V. cholerae, when grown in chitohexaose, cells of V. fischeri are able to take up and incorporate exogenous DNA. Chitohexaose-independent transformation by V. fischeri was observed when tfoX was present in multicopy. The second tfoX paralogue, designated tfoY, is also required for efficient transformation in V. fischeri, but is not functionally identical to tfoX. Natural transformation of V. fischeri facilitates rapid transfer of mutations across strains, and provides a highly useful tool for experimental genetic manipulation in this species. The presence of chitin-induced competence in several vibrios highlights the potential for a conserved mechanism of genetic exchange across this family of environmentally important marine bacteria. [source] Shuffling genes around in hot environments: the unique DNA transporter of Thermus thermophilusFEMS MICROBIOLOGY REVIEWS, Issue 3 2009Beate Averhoff Abstract Natural transformation permits the transport of DNA through bacterial membranes and represents a dominant mode for the transfer of genetic information between bacteria and between microorganisms of distant evolutionary lineages and even between members of different domains. This phenomenon, known as horizontal, or lateral, gene transfer, has been a major force for genome plasticity over evolutionary history, and is largely responsible for the spread of fitness-enhancing traits, including antibiotic resistance and virulence factors. In particular, for adaptation of prokaryotes to extreme environments, lateral gene transfer seems to have played a crucial role. Here, we present a survey of the natural transformation machinery of the thermophile Thermus thermophilus HB27. A tentative model of the transformation machinery comprising of components similar to proteins of type IV pili and type II secretion systems is presented. A comparative discussion of the subunits and the structure of the DNA translocator and the underlying mechanism of transfer of free DNA in T. thermophilus highlights conserved and unique features of the DNA translocator in T. thermophilus. We hypothesize that the extraordinary broad substrate specificity and the high efficiency of the T. thermophilus DNA uptake system is of major importance for thermoadaptation and interdomain DNA transfer in hot environments. [source] Characterization of DNA transport in the thermophilic bacterium Thermus thermophilus HB27FEBS JOURNAL, Issue 18 2006Cornelia Schwarzenlander Horizontal gene transfer has been a major force for genome plasticity over evolutionary history, and is largely responsible for fitness-enhancing traits, including antibiotic resistance and virulence factors. In particular, for adaptation of prokaryotes to extreme environments, lateral gene transfer seems to have played a crucial role. Recently, by performing a genome-wide mutagenesis approach with Thermus thermophilus HB27, we identified the first genes in a thermophilic bacterium for the uptake of free DNA, a process called natural transformation. Here, we present the first data on the biochemistry and bioenergetics of the DNA transport process in this thermophile. We report that linear and circular plasmid DNA are equally well taken up with a high maximal velocity of 1.5 µg DNA·(mg protein),1·min,1, demonstrating an extremely efficient binding and uptake rate of 40 kb·s,1·cell,1. Uncouplers and ATPase inhibitors immediately inhibited DNA uptake, providing clear evidence that DNA translocation in HB27 is an energy-dependent process. DNA uptake studies with genomic DNA of Bacteria, Archaea and Eukarya revealed that Thermus thermophilus HB27 takes up DNA from members of all three domains of life. We propose that the extraordinary broad substrate specificity of the highly efficient Thermus thermophilus HB27 DNA uptake system may contribute significantly to thermoadaptation of Thermus thermophilus HB27 and to interdomain DNA transfer in hot environments. [source] Helicobacter pylori mutagenesis by mariner in vitro transpositionFEMS IMMUNOLOGY & MEDICAL MICROBIOLOGY, Issue 2 2001Betty P Guo Abstract We have developed a method for generating transposon insertion mutants using mariner in vitro mutagenesis. The gene of interest was PCR-amplified and cloned. A kanamycin-marked mariner transposon was randomly inserted into the purified plasmid in an in vitro transposition reaction. After repair and propagation in Escherichia coli, purified mutagenized plasmid was introduced into Helicobacter pylori by natural transformation. Transformants were selected by plating on kanamycin. Mutants were predominantly the result of double homologous recombination, and multiple mutants (with insertions in distinct positions) were often obtained. The site of insertion was determined by PCR or sequencing. We have made mutations in known or potential virulence genes, including ureA, hopZ, and vacA, using kanamycin- and kanamycin/lacZ -marked transposons. Colonies carrying a kanamycin/lacZ transposon appeared blue on medium containing the chromogenic agent X-gal, allowing discrimination of mutant and wild-type H. pylori in mixed competition experiments. [source] Microbial interactions affecting the natural transformation of Bacillus subtilis in a model aquatic ecosystemFEMS MICROBIOLOGY ECOLOGY, Issue 3 2003Kazuaki Matsui Abstract The involvement of microbial interactions in natural transformation of bacteria was evaluated using an aquatic model system. For this purpose, the naturally transformable Bacillus subtilis was used as the model bacterium which was co-cultivated with the protist Tetrahymena thermophila (a consumer) and/or the photosynthetic alga Euglena gracilis (a producer). Co-cultivation with as few as 102 individuals ml,1 of T. thermophila lowered the number of transformants to less than the detectable level (<1×100 ml,1), while co-cultivation with E. gracilis did not. Metabolites from co-cultures of T. thermophila and B. subtilis also decreased the number of transformants to less than the detectable level, while metabolites from co-culture of T. thermophila and B. subtilis with E. gracilis did not. Thus, the introduction of transformation inhibitory factor(s) by the grazing of T. thermophila and the attenuation of this inhibitory factor(s) by E. gracilis is indicated. These observations suggest that biological components do affect the natural transformation of B. subtilis. The study described is the first to suggest that ecological interactions are responsible not only for the carbon and energy cycles, but also for the processes governing horizontal transfer of genes, in microbial ecosystems. [source] Regulation of natural genetic transformation and acquisition of transforming DNA in Streptococcus pneumoniaeFEMS MICROBIOLOGY REVIEWS, Issue 3 2009Ola Johnsborg Abstract The ability of pneumococci to take up naked DNA from the environment and permanently incorporate the DNA into their genome by recombination has been exploited as a valuable research tool for 80 years. From being viewed as a marginal phenomenon, it has become increasingly clear that horizontal gene transfer by natural transformation is a powerful mechanism for generating genetic diversity, and that it has the potential to cause severe problems for future treatment of pneumococcal disease. This process constitutes a highly efficient mechanism for spreading ,-lactam resistance determinants between streptococcal strains and species, and also threatens to undermine the effect of pneumococcal vaccines. Fortunately, great progress has been made during recent decades to elucidate the mechanism behind natural transformation at a molecular level. Increased insight into these matters will be important for future development of therapeutic strategies and countermeasures aimed at reducing the spread of hazardous traits. In this review, we focus on recent developments in our understanding of competence regulation, DNA acquisition and the role of natural transformation in the dissemination of virulence and ,-lactam resistance determinants. [source] MicroReview: Competence-induced fratricide in streptococciMOLECULAR MICROBIOLOGY, Issue 6 2007Jean-Pierre Claverys Summary Competence for natural genetic transformation in Streptococcus pneumoniae is controlled by the extracellular concentration of the competence-stimulating peptide (CSP), an exported peptide pheromone. Upon entering the competent state, pneumococci start transcribing a number of CSP-responsive genes, termed the early and late competence (com) genes. Some of the proteins encoded by these com genes are absolutely required for DNA uptake and transformation, but most of them are dispensable. This finding indicates that the majority of CSP-regulated proteins in S. pneumoniae is involved in processes unrelated to natural genetic transformation. Recently, however, it became clear that the biological role of a few of the dispensable proteins might be linked to the transformation process. Although these proteins are not needed for transformation per se, they constitute a killing mechanism that could be used by competent cells to acquire DNA from non-competent pneumococci. This mechanism, termed fratricide, has so far only been described for pneumococci. In this manuscript, we review evidence that suggests the conservation of fratricide as well as the independent evolution of its genetic control and of its effectors in several species of the genus Streptococcus, and discuss its possible biological significance in relation to natural transformation. [source] The RecJ DNase strongly suppresses genomic integration of short but not long foreign DNA fragments by homology-facilitated illegitimate recombination during transformation of Acinetobacter baylyiMOLECULAR MICROBIOLOGY, Issue 3 2007Klaus Harms Summary Homology-facilitated illegitimate recombination (HFIR) promotes genomic integration of foreign DNA with a single segment homologous to the recipient genome by homologous recombination in the segment accompanied by illegitimate fusion of the heterologous sequence. During natural transformation of Acinetobacter baylyi HFIR occurs at about 0.01% of the frequency of fully homologous recombination. The role of the 5, single-strand-specific exonuclease RecJ in HFIR was investigated. Deletion of recJ increased HFIR frequency about 20-fold compared with wild type while homologous recombination was not affected. Illegitimate fusion sites were predominantly located within 360 nucleotides away from the homology whereas in wild type most fusion sites were distal (500,2500 nucleotides away). RecJ overproduction reduced the HFIR frequency to half compared with wild type, and transformants with short foreign DNA segments were diminished, leading to on average 866 foreign nucleotides integrated per event (682 in wild type, 115 in recJ). In recJ always the 3, ends of donor DNA were integrated at the homology whereas in wild type these were 3, or 5,. RecJ apparently suppresses HFIR by degrading 5, non-homologous DNA tails at the post-synaptic stage. We propose that the RecJ activity level controls the HFIR frequency during transformation and the amount of foreign DNA integrated per event. [source] Mechanisms of homology-facilitated illegitimate recombination for foreign DNA acquisition in transformable Pseudomonas stutzeriMOLECULAR MICROBIOLOGY, Issue 4 2003Petra Meier Summary Intra- and interspecific natural transformation has been observed in many prokaryotic species and is considered a fundamental mechanism for the generation of genetic variation. Recently, it has been described in detail how, in transformable Acinetobacter BD413 and Streptococcus pneumoniae, long stretches of nucleotides lacking homology were integrated into recipient genomes when they were linked on one side to a small piece of DNA with homology to resident DNA serving as a recA -dependent recombination anchor. Now, such homology-facilitated illegitimate recombination (HFIR) has also been detected in transformable Pseudomonas stutzeri. However, analysis of the recombinants revealed qualitative and quantitative differences in their generation compared with that in Acinetobacter BD413. In P. stutzeri, foreign DNA with an anchor sequence was integrated 105 - to 106 -fold less frequently than fully homologous DNA, but still at least 200-fold more frequently than without the anchor. The anchor sequence could be as small as 311 bp. Remarkably, in 98% of the events, the 3, end was integrated within the homologous anchor, whereas the 5, end underwent illegitimate fusion. Moreover, about one-third of the illegitimate fusion sites shared no or only a single identical basepair in foreign and resident DNA. The other fusions occurred within microhomologies of up to 6 bp with a higher GC content on average than the interacting nucleotide sequences. Foreign DNA of 69,1903 bp was integrated, and resident DNA of 22,2345 bp was lost. In a recA mutant, HFIR was not detectable. The findings suggest that genomic acquisition of foreign DNA by HFIR during transformation occurs widely in prokaryotes, but that details of the required recombination and strand fusion mechanisms may differ between organisms from different genera. [source] Ralstonia solanacearum requires type 4 pili to adhere to multiple surfaces and for natural transformation and virulenceMOLECULAR MICROBIOLOGY, Issue 2 2002Yaowei Kang Summary As reported previously for Ralstonia solanacearum strain GMI1000, wild-type strains AW1 and K60 were shown to produce Hrp pili. AW1 and K60 mutants lacking Hrp pili still exhibited twitching motility, which requires type 4 pili (Tfp), and electron microscopy revealed that they still made flexuous polar pili. Twitching-positive cells had an extracellular 17 kDa protein that was associated with piliation, and an internal 43-amino-acid sequence of this protein was typical of type 4 pilins. This amino acid sequence is encoded by an open reading frame, designated pilA, in the genomic sequence of GMI1000. PilA is 46% identical to a Pseudomonas aeruginosa type 4 pilin over its entire length and has all the conserved residues and motifs characteristic of type 4 group A pilins. pilA mutants did not make the 17 kDa PilA protein and did not exhibit twitching motility. When compared with its parent, an AW1 pilA mutant was reduced in virulence on tomato plants and in autoaggregation and biofilm formation in broth culture. Unlike AW1, a pilA mutant did not exhibit polar attachment to tobacco suspension culture cells or to tomato roots; it was also not naturally competent for transformation. We reported previously that twitching motility ceases in maturing AW1 colonies and that inactivation of PhcA, a global transcriptional regulator, results in colonies that continue to exhibit twitching motility. Similarly, in broth culture, expression of a pilA::lacZ fusion in AW1 decreased 10-fold at high cell density, but expression remained high in a phcA mutant. In addition, pilA::lacZ expression was positively regulated 10-fold by PehR, a response regulator that is known to be repressed by PhcA. This signal cascade is sufficient to explain why pilA expression, and thus twitching motility, decreases at high cell densities. [source] | ||||||||||