Gene conversions and their relation to homologous chromosome pairing

Gene conversion is the non-reciprocal transfer of DNA sequences from one gene to a related gene elsewhere in the genome. Molecular evidence for its occurrence in higher eukaryotes was first described by our laboratory in 1980 in the two linked human foetal gamma-globin genes. Over a kilobase of DNA was converted in this initial example. Other investigators have since described more examples of gene conversion including some in which the sequence that was transferred is much shorter. We have now accumulated evidence for a series of such small gene conversions in the human foetal globin gene pair. The number of small gene conversions that we have been able to detect leads us to suggest that gene conversions are the consequence of a general mechanism whereby DNA strand invasions enable chromosomes to find their homologues during meiosis.     

Nonallelic gene conversion is not GC-biased in Drosophila or primates

Gene conversion is the unidirectional transfer of genetic information between allelic (orthologous) or nonallelic (paralogous) DNA segments. Recently, there has been much interest in understanding how gene conversion shapes the nucleotide composition of the genomic landscape. A widely held hypothesis is that gene conversion is universally GC-biased. However, direct experimental evidence of this hypothesis is limited to a single study of meiotic crossovers in yeast. Although there have been a number of indirect studies of gene conversion, evidence of GC-biased replacements gathered from such studies can also be attributed to positive selection, which has the same evolutionary dynamics as biased gene conversion. Here, we apply a direct phylogenetic approach to examine nucleotide replacements produced by nonallelic gene conversion in Drosophila and primate genomes. We find no evidence for GC-biased gene conversion in either lineage, suggesting that previously observed GC biases may be due to positive selection rather than to biased gene conversion.     

Recovery and evolutionary analysis of complete integron gene cassette arrays from Vibrio

Background  

Integrons are genetic elements capable of the acquisition, rearrangement and expression of genes contained in gene cassettes. Gene cassettes generally consist of a promoterless gene associated with a recombination site known as a 59-base element (59-be). Multiple insertion events can lead to the assembly of large integron-associated cassette arrays. The most striking examples are found in Vibrio, where such cassette arrays are widespread and can range from 30 kb to 150 kb. Besides those found in completely sequenced genomes, no such array has yet been recovered in its entirety. We describe an approach to systematically isolate, sequence and annotate large integron gene cassette arrays from bacterial strains.     

Evidence against reciprocal recombination as the basis for tuf gene conversion in Salmonella enterica serovar Typhimurium

The duplicate tuf genes on the Salmonella enterica serovar Typhimurium chromosome co-evolve by a RecA-, RecB-dependent gene conversion mechanism. Gene conversion is defined as a non-reciprocal transfer of genetic information. However, in a replicating bacterial chromosome there is a possibility that a reciprocal genetic exchange between different tuf genes sitting on sister chromosomes could result in "apparent" gene conversion. We asked whether the major mechanism of tuf gene conversion was classical or apparent. We devised a genetic selection that allowed us to isolate and examine both expected products from a reciprocal recombination event between the tuf genes. Using this selection we tested within individual cultures for a correlation in the frequency of jackpots as expected if recombination were reciprocal. We found no correlation, either in the frequency of each type of recombinant product, or in the DNA sequences of the products resulting from each recombination event. We conclude that the evidence argues in favor of a non-reciprocal gene conversion mechanism as the basis for tuf gene co-evolution.     

基因芯片技术检测细菌耐药性的研究进展

基因芯片技术是将无数预先设计好的寡核苷酸、cDNA、基因组 (Genomic)DNA在芯片上做成点阵 ,与样品中同源核酸分子杂交 ,对样品的序列信息进行高效的解读和分析 ,大规模获取相关生物信息。该技术应用领域主要有表达谱分析、基因突变及多态性分析、疾病诊断和预测、DNA测序、药物筛选、检测筛选耐药基因、微生物菌种鉴定及致病机制研究等。着重介绍了基因芯片技术检测细菌耐药性方面的国外研究进展。基因芯片可以大量、快捷地检测出细菌耐药性菌株以及引起细菌耐药性的基因的突变 ,由于其在检测中的高效率 ,因此要优越于传统的细菌学检测技术。基因芯片技术在细菌耐药性检测中有着巨大的应用价值 ,具有广阔的应用前景。     

Recombination induced by triple-helix-targeted DNA damage in mammalian cells.

Gene therapy has been hindered by the low frequency of homologous recombination in mammalian cells. To stimulate recombination, we investigated the use of triple-helix-forming oligonucleotides (TFOs) to target DNA damage to a selected site within cells. By treating cells with TFOs linked to psoralen, recombination was induced within a simian virus 40 vector carrying two mutant copies of the supF tRNA reporter gene. Gene conversion events, as well as mutations at the target site, were also observed. The variety of products suggests that multiple cellular pathways can act on the targeted damage, and data showing that the triple helix can influence these pathways are presented. The ability to specifically induce recombination or gene conversion within mammalian cells by using TFOs may provide a new research tool and may eventually lead to novel applications in gene therapy.     

Mass-murder deletion of 19 ORFs from Saccharomyces cerevisiae chromosome XI

In eukaryote genomes, there are many kinds of gene families. Gene duplication and conversion are sources of the evolution of gene families, including those with uniform members and those with diverse functions. Population genetics theory on identity coefficients among gene members of a gene family shows that the balance between diversification by mutation, and homogenization by unequal crossing over and gene conversion, is important. Also, evolution of new functions is due to gene duplication followed by differentiation. Positive selection is necessary for the evolution of novel functions. However, many examples of current gene families suggest that both drift and selection are at work on their evolution.     

Gene conversion: mechanisms, evolution and human disease

Gene conversion, one of the two mechanisms of homologous recombination, involves the unidirectional transfer of genetic material from a 'donor' sequence to a highly homologous 'acceptor'. Considerable progress has been made in understanding the molecular mechanisms that underlie gene conversion, its formative role in human genome evolution and its implications for human inherited disease. Here we assess current thinking about how gene conversion occurs, explore the key part it has played in fashioning extant human genes, and carry out a meta-analysis of gene-conversion events that are known to have caused human genetic disease.     

Biased gene conversion is not occurring among rDNA repeats in the Brassica triangle.

Hybridization is a common phenomenon that results in complex genomes. How ancestral genomes interact in hybrids has long been of great interest. Recombination among ancestral genomes may increase or decrease genetic variation. This study examines rDNA from members of the Brassica triangle for evidence of gene conversion across ancestral genomes. Gene conversion is a powerful force in the evolution of multigene families. It has previously been shown that biased gene conversion can act to homogenize rDNA repeats within hybrid genomes. Here, we find no evidence for biased gene conversion or unequal crossing over across ancestral genomes in allotetraploid Brassica species. We suggest that, while basic genomic processes are shared by all organisms, the relative frequency of these processes and their evolutionary importance may differ among lineages. Key words : Brassica, rDNA, gene conversion, allotetraploids.     

Gene Therapy for ALS: progress and prospects

Amyotrophic lateral sclerosis (ALS) is a devastating disease for which there are no effective drug treatments to date. Recent advances in Gene Therapy open up the possibility of developing an effective treatment aiming at halting or delaying the degeneration of motor neurons. Viral vectors such as lentiviral vectors and adeno-associated virus can transfer genes into many different types of primary neurons from a broad range of species including man and the resulting gene expression is long-term. Numerous animal studies have now been undertaken with these vectors and correction of disease models has been obtained. These vectors have been refined to a very high level and can be produced safely for the clinic. However, we believe that there are some major issues that need to be addressed in order to see a Gene Therapy approach with viral vectors proceed to the clinic for ALS patients. This review will describe the general features of lentiviral vectors. It will then describe some key examples of gene transfer and genetic correction in animal models of motor neuron disease. The prospects for the clinical evaluation of lentiviral vectors for the treatment of human motor neuron disease will be outlined.     

Elimination of deleterious mutations in plastid genomes by gene conversion

Asexual reproduction is believed to be detrimental, mainly because of the accumulation of deleterious mutations over time, a hypothesis known as Muller's ratchet. In seed plants, most asexually reproducing genetic systems are polyploid, with apomictic species (plants forming seeds without fertilization) as well as plastids and mitochondria providing prominent examples. Whether or not polyploidy helps asexual genetic systems to escape Muller's ratchet is unknown. Gene conversion, particularly when slightly biased, represents a potential mechanism that could allow asexual genetic systems to reduce their mutation load in a genome copy number-dependent manner. However, direct experimental evidence for the operation of gene conversion between genome molecules to correct mutations is largely lacking. Here we describe an experimental system based on transgenic tobacco chloroplasts that allows us to analyze gene conversion events in higher plant plastid genomes. We provide evidence for gene conversion acting as a highly efficient mechanism by which the polyploid plastid genetic system can correct deleterious mutations and make one good genome out of two bad ones. Our finding that gene conversion can be biased may provide a molecular link between asexual reproduction, high genome copy numbers and low mutation rates.     

Evolution of the interferon alpha gene family in eutherian mammals

Interferon alpha (IFNA) genes code for proteins with important signaling roles during the innate immune response. Phylogenetically, IFNA family members in eutherians (placental mammals) cluster together in a species-specific manner except for closely related species (i.e. Homo sapiens and Pan troglodytes) where gene-specific clustering is evident. Previous research has been unable to clarify whether gene conversion or recent gene duplication accounts for gene-specific clustering, partly because the similarity of members of the IFNA family within species has made it historically difficult to identify the exact composition of IFNA gene families. IFNA gene families were fully characterized in recently available genomes from Canis familiaris, Macaca mulatta, P. troglodytes and Rattus norvegicus, and combined with previously characterized IFNA gene families from H. sapiens and Mus musculus, for the analysis of both whole and partial gene conversion events using a variety of statistical methods. Gene conversion was inferred in every eutherian species analyzed and comparison of the IFNA gene family locus between primate species revealed independent gene duplication in M. mulatta. Thus, both gene conversion and gene duplication have shaped the evolution of the IFNA gene family in eutherian species. Scenarios may be envisaged whereby the increased production of a specific IFN-alpha protein would be beneficial against a particular pathogenic infection. Gene conversion, similar to duplication, provides a mechanism by which the protein product of a specific IFNA gene can be increased.     

Gene conversion tracts associated with crossovers in Rhizobium etli

Gene conversion has been defined as the nonreciprocal transfer of information between homologous sequences. Despite its broad interest for genome evolution, the occurrence of this mechanism in bacteria has been difficult to ascertain due to the possible occurrence of multiple crossover events that would mimic gene conversion. In this work, we employ a novel system, based on cointegrate formation, to isolate gene conversion events associated with crossovers in the nitrogen-fixing bacterium Rhizobium etli. In this system, selection is applied only for cointegrate formation, with gene conversions being detected as unselected events. This minimizes the likelihood of multiple crossovers. To track the extent and architecture of gene conversions, evenly spaced nucleotide changes were made in one of the nitrogenase structural genes (nifH), introducing unique sites for different restriction endonucleases. Our results show that (i) crossover events were almost invariably accompanied by a gene conversion event occurring nearby; (ii) gene conversion events ranged in size from 150 bp to 800 bp; (iii) gene conversion events displayed a strong bias, favoring the preservation of incoming sequences; (iv) even small amounts of sequence divergence had a strong effect on recombination frequency; and (v) the MutS mismatch repair system plays an important role in determining the length of gene conversion segments. A detailed analysis of the architecture of the conversion events suggests that multiple crossovers are an unlikely alternative for their generation. Our results are better explained as the product of true gene conversions occurring under the double-strand break repair model for recombination.     

Mitotic gene conversion of large DNA heterologies in Saccharomyces cerevisiae

Summary Gene conversion of large DNA heterologous fragments has been shown to take place efficiently in Saccharomyces cerevisiae. It has been found that a 2.6 kb LEU2 DNA fragment in a multicopy plasmid was replaced by a 3.1 kb PG11 chromosomal DNA fragment, when both fragments were flanked by homologous DNA regions. Gene conversion was asymmetric in a total of 481 recombinants analyzed. In contrast, truncated PG11 or LEU2 genes in multicopy plasmids, gave no recombinants that restored a complete plasmid copy of these genes in a total of 242 recombinants studied, confirming that a conversion tract is disrupted by a heterologous region. The asymmetry of the events detected suggest that gene conversion of large DNA heterologies involves a process whereby a gap first covers one heterologous fragment and then this is followed by new DNA synthesis using the other heterologous fragment as a template. Therefore, it is likely that large DNA heterologies are converted by a double-strand gap repair mechanism.     

Mitotic gene conversion can be as important as meiotic conversion in driving genetic variability in plants and other species without early germline segregation

In contrast to common meiotic gene conversion, mitotic gene conversion, because it is so rare, is often ignored as a process influencing allelic diversity. We show that if there is a large enough number of premeiotic cell divisions, as seen in many organisms without early germline sequestration, such as plants, this is an unsafe position. From examination of 1.1 million rice plants, we determined that the rate of mitotic gene conversion events, per mitosis, is 2 orders of magnitude lower than the meiotic rate. However, owing to the large number of mitoses between zygote and gamete and because of long mitotic tract lengths, meiotic and mitotic gene conversion can be of approximately equivalent importance in terms of numbers of markers converted from zygote to gamete. This holds even if we assume a low number of premeiotic cell divisions (approximately 40) as witnessed in Arabidopsis. A low mitotic rate associated with long tracts is also seen in yeast, suggesting generality of results. For species with many mitoses between each meiotic event, mitotic gene conversion should not be overlooked.

Gene conversion associated with meiosis has long been a focus of attention in population genomics, but mitotic conversion has been relatively overlooked as it was thought to be rare. Analysis in plants suggests that this could be a mistake; long tract lengths and multiple mitoses in species lacking germline sequestration suggest that mitotic conversion, although rare per mitosis, should not be ignored.     

The evolutionary history of quorum-sensing systems in bacteria

Communication among bacterial cells through quorum-sensing (QS) systems is used to regulate ecologically and medically important traits, including virulence to hosts. QS is widespread in bacteria; it has been demonstrated experimentally in diverse phylogenetic groups, and homologs to the implicated genes have been discovered in a large proportion of sequenced bacterial genomes. The widespread distribution of the underlying gene families (LuxI/R and LuxS) raises the questions of how often QS genes have been transferred among bacterial lineages and the extent to which genes in the same QS system exchange partners or coevolve. Phylogenetic analyses of the relevant gene families show that the genes annotated as LuxI/R inducer and receptor elements comprise two families with virtually no homology between them and with one family restricted to the gamma-Proteobacteria and the other more widely distributed. Within bacterial phyla, trees for the LuxS and the two LuxI/R families show broad agreement with the ribosomal RNA tree, suggesting that these systems have been continually present during the evolution of groups such as the Proteobacteria and the Firmicutes. However, lateral transfer can be inferred for some genes (e.g., from Firmicutes to some distantly related lineages for LuxS). In general, the inducer/receptor elements in the LuxI/R systems have evolved together with little exchange of partners, although loss or replacement of partners has occurred in several lineages of gamma-Proteobacteria, the group for which sampling is most intensive in current databases. For instance, in Pseudomonas aeruginosa, a transferred QS system has been incorporated into the pathway of a native one. Gene phylogenies for the main LuxI/R family in Pseudomonas species imply a complex history of lateral transfer, ancestral duplication, and gene loss within the genus.     

Gene delivery by functional inorganic nanocarriers

Gene delivery into cells to elicit cellular response has received a great attention recently. Viruses, lipids, peptides, cationic polymers and certain inorganic nanomaterials have been reported as gene delivery vectors. In this review, we focus on the recent literature on gene delivery using inorganic nanoparticles. This emerging field of study is concisely summarized and illustrated by selected examples and recent patents. New approaches and directions towards the practical use of multifunctional nanocarriers are highlighted.     

High-frequency germ line gene conversion in transgenic mice.

Gene conversion is the nonreciprocal transfer of genetic information between two related genes or DNA sequences. It can influence the evolution of gene families, having the capacity to generate both diversity and homogeneity. The potential evolutionary significance of this process is directly related to its frequency in the germ line. While measurement of meiotic inter- and intrachromosomal gene conversion frequency is routine in fungal systems, it has hitherto been impractical in mammals. We have designed a system for identifying and quantitating germ line gene conversion in mice by analyzing transgenic male gametes for a contrived recombination event. Spermatids which undergo the designed intrachromosomal gene conversion produce functional beta-galactosidase (encoded by the lacZ gene), which is visualized by histochemical staining. We observed a high incidence of lacZ-positive spermatids (approximately 2%), which were produced by a combination of meiotic and mitotic conversion events. These results demonstrate that gene conversion in mice is an active recombinational process leading to nonparental gametic haplotypes. This high frequency of intrachromosomal gene conversion seems incompatible with the evolutionary divergence of newly duplicated genes. Hence, a process may exist to uncouple gene pairs from frequent conversion-mediated homogenization.     

Gene conversion in the Escherichia coli RecF pathway: a successive half crossing-over model.

Summary Gene conversion - apparently non-reciprocal transfer of sequence information between homologous DNA sequences - has been reported in various organisms. Frequent association of gene conversion with reciprocal exchange (crossing-over) of the flanking sequences in meiosis has formed the basis of the current view that gene conversion reflects events at the site of interaction during homologous recombination. In order to analyze mechanisms of gene conversion and homologous recombination in an Escherichia coli strain with an active RecF pathway (recBC sbcBC), we first established in cells of this strain a plasmid carrying two mutant neo genes, each deleted for a different gene segment, in inverted orientation. We then selected kanamycin-resistant plasmids that had reconstituted an intact neo ⁺ gene by homologous recombination. We found that all the neo ⁺ plasmids from these clones belonged to the gene-conversion type in the sense that they carried one neo ⁺ gene and retained one of the mutant neo genes. This apparent gene conversion was, however, only very rarely accompanied by apparent crossing-over of the flanking sequences. This is in contrast to the case in a rec ⁺ strain. or in a strain with an active RecE pathway (recBC sbcA). Our further analyses, especially comparisons with apparent gene conversion in the rec ⁺ strain, led us to propose a mechanism for this biased gene conversion. This successive half crossing-over model proposes that the elementary recombinational process is half crossing;-over in the sense that it generates only one recombinant DNA duplex molecule, and leaves one or two free end(s), out of two parental DNA duplexes. The resulting free end is, the model assumes, recombinogenic and frequently engages in a second round of half crossing-over with the recombinant duplex. The products resulting from such interaction involving two molecules of the plasmid would be classified as belonging to the gene-conversion type without crossing-over. We constructed a dimeric molecule that mimics the intermediate form hypothesized in this model and introduced it into cells. Biased gene conversion products were obtained in this reconstruction experiment. The half crossing-over mechanism can also explain formation of huge linear multimers of bacterial plasmids, the nature of transcribable recombination products in bacterial conjugation, chromosomal gene conversion not accompanied by flanking exchange (like that in yeast mating-type switching), and antigenic variation in microorganisms.     

Phylogenetic analysis reveals gene conversions in multigene families of rhizobia

Gene families are an important and intrinsic trait of rhizobial species. These gene copies can participate in non-reciprocal recombination events, also called gene conversions. Gene conversion has diverse roles, but it is usually implicated in the evolution of multigene families. Here, we searched for gene conversions in multigene families of six representative rhizobial genomes. We identified 11 gene families with different numbers of copies, genome location and function in CFN42 and CIAT652 strains of Rhizobium etli, Rhizobium sp NGR234, Mesorhizobium loti MAFF303099, Sinorhizobium meliloti 1021, and Bradyrhizobium japonicum USDA110. Gene conversions were detected by phylogenetic inference in the nifD and nifK gene families in R. etli. Sequence analysis confirmed multiple gene conversions in these two gene families. We suggest that gene conversion events have an important role in homogenizing multigene families in rhizobia.