Extrachromosomal and chromosomal gene conversion in mammalian cells.

We constructed substrates to study gene conversion in mammalian cells specifically without the complication of reciprocal recombination events. These substrates contain both an insertion mutation of the neomycin resistance gene (neoX) and an internal, homologous fragment of the neo gene (neo-526), such that gene conversion from neo-526 to neoX restores a functional neo gene. Although two reciprocal recombination events can also produce an intact neo gene, these double recombination events occur much less frequently that gene conversion in mammalian cells, We used our substrates to characterize extrachromosomal gene conversion in recombination-deficient bacteria and in monkey COS cells. Chromosomal recombination was also studied after stable integration of these substrates into the genome of mouse 3T6 cells. All extrachromosomal and chromosomal recombination events analyzed in mammalian cells resulted from gene conversion. Chromosomal gene conversion events occurred at frequencies of about 10(-6) per cell generation and restored a functional neo gene without overall effects on sequence organization.     

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.     

Estimating meiotic gene conversion rates from population genetic data

Gene conversion plays an important part in shaping genetic diversity in populations, yet estimating the rate at which it occurs is difficult because of the short lengths of DNA involved. We have developed a new statistical approach to estimating gene conversion rates from genetic variation, by extending an existing model for haplotype data in the presence of crossover events. We show, by simulation, that when the rate of gene conversion events is at least comparable to the rate of crossover events, the method provides a powerful approach to the detection of gene conversion and estimation of its rate. Application of the method to data from the telomeric X chromosome of Drosophila melanogaster, in which crossover activity is suppressed, indicates that gene conversion occurs approximately 400 times more often than crossover events. We also extend the method to estimating variable crossover and gene conversion rates and estimate the rate of gene conversion to be approximately 1.5 times higher than the crossover rate in a region of human chromosome 1 with known recombination hotspots.     

Optimal Gene Trees from Sequences and Species Trees Using a Soft Interpretation of Parsimony

Gene duplication and gene loss as well as other biological events can result in multiple copies of genes in a given species. Because of these gene duplication and loss dynamics, in addition to variation in sequence evolution and other sources of uncertainty, different gene trees ultimately present different evolutionary histories. All of this together results in gene trees that give different topologies from each other, making consensus species trees ambiguous in places. Other sources of data to generate species trees are also unable to provide completely resolved binary species trees. However, in addition to gene duplication events, speciation events have provided some underlying phylogenetic signal, enabling development of algorithms to characterize these processes. Therefore, a soft parsimony algorithm has been developed that enables the mapping of gene trees onto species trees and modification of uncertain or weakly supported branches based on minimizing the number of gene duplication and loss events implied by the tree. The algorithm also allows for rooting of unrooted trees and for removal of in-paralogues (lineage-specific duplicates and redundant sequences masquerading as such). The algorithm has also been made available for download as a software package, Softparsmap.     

Investigation of Tissue-Specific Human Orthologous Alternative Splice Events in Pig

Alternative splicing of pre-mRNA can contribute to differences between tissues or cells either by regulating gene expression or creating proteins with various functions encoded by one gene. The number of investigated alternative splice events in pig has so far been limited. In this study we have investigated alternative splice events detected in humans, in orthologous pig genes. A total of 17 genes with predicted exon skipping events were selected for further studies. The splice events for the selected genes were experimentally verified using real-time quantitative PCR analysis (qPCR) with splice-specific primers in 19 different tissues. The same splice variants as reported in humans were detected in 15 orthologous pig genes, however, the expression pattern predicted in the in silico analyses was only experimentally verified in a few cases. The results support the findings that splice events resulting in preservation of open reading frame are indicative of a functional significance of the splice variants of the gene.     

Investigation of tissue-specific human orthologous alternative splice events in pig

Alternative splicing of pre-mRNA can contribute to differences between tissues or cells either by regulating gene expression or creating proteins with various functions encoded by one gene. The number of investigated alternative splice events in pig has so far been limited. In this study we have investigated alternative splice events detected in humans, in orthologous pig genes. A total of 17 genes with predicted exon skipping events were selected for further studies. The splice events for the selected genes were experimentally verified using real-time quantitative PCR analysis (qPCR) with splice-specific primers in 19 different tissues. The same splice variants as reported in humans were detected in 15 orthologous pig genes, however, the expression pattern predicted in the in silico analyses was only experimentally verified in a few cases. The results support the findings that splice events resulting in preservation of open reading frame are indicative of a functional significance of the splice variants of the gene.     

Genetic and Molecular Analysis of Recombination Events in Saccharomyces Cerevisiae Occurring in the Presence of the Hyper-Recombination Mutation Hpr1

The hyper-recombination mutation hpr1 specifically increases mitotic intrachromatid crossovers, with no effect on other mitotic recombination events such as unequal sister chromatid exchange and plasmid-chromosome recombination, and no effect on meiotic recombination and a lesser effect on intrachromosomal gene conversion. The excision repair RAD1 gene is partially required for the expression on the hpr1 phenotype. The simplest hypothesis to account for some of the hpr1 stimulated recombination events is that a heteroduplex DNA intermediate and localized gene conversion are involved. hpr1 stimulated crossover events are independent of intrachromosomal gene conversion events stimulated by the hyper-gene conversion mutation hpr5. This result suggests that different intrachromosomal recombination processes are affected in each mutant strain. We propose that HPR1 may function to inhibit intrachromatid crossovers.     

Molecular analysis of sister chromatid recombination in mammalian cells

Sister chromatid recombination (SCR) is a potentially error-free pathway for the repair of double-strand breaks arising during replication and is thought to be important for the prevention of genomic instability and cancer. Analysis of sister chromatid recombination at a molecular level has been limited by the difficulty of selecting specifically for these events. To overcome this, we have developed a novel "nested intron" reporter that allows the positive selection in mammalian cells of "long tract" gene conversion events arising between sister chromatids. We show that these events arise spontaneously in cycling cells and are strongly induced by a site-specific double-strand break (DSB) caused by the restriction endonuclease, I-SceI. Notably, some I-SceI-induced sister chromatid recombination events entailed multiple rounds of gene amplification within the reporter, with the generation of a concatemer of amplified gene segments. Thus, there is an intimate relationship between sister chromatid recombination control and certain types of gene amplification. Dysregulated sister chromatid recombination may contribute to cancer progression, in part, by promoting gene amplification.     

The organization of the prosystemin gene

The organization of the gene encoding tomato prosystemin, a 200 amino acid protein precursor of the 18 amino acid polypeptide inducer of proteinase inhibitor synthesis in tomato and potato plants, is reported. The prosystemin sequence reveals that the gene, which is composed of five homologous pairs of exons plus a non-homologous exon at the C-terminus containing the systemin sequence, has evolved by several gene duplication-elongation events from a much smaller ancestral gene. The nucleotide and amino acid sequence homologies among the exons suggest that a small ancestral gene was duplicated to form at least two tandem repeats, followed by subsequent duplication-elongation events that resulted in five tandemly repeated nucleotide sequences and three duplicated amino acid sequence elements. Since the systemin nucleotide or amino acid sequence was not duplicated, it was either not part of the gene duplication-elongation events or its coding region evolved separately and may even have been added to the tandemly repeated part of the gene at a later time.     

Ancient horizontal gene transfer can benefit phylogenetic reconstruction

Although horizontal gene transfer (HGT) is usually considered a disruptive force in recovering organismal phylogeny, it creates important phylogenetic information. In the 'net of life', the recipient of an ancient gene transfer can be the ancestor of a lineage that inherits the transferred gene; thus, the transferred gene marks the recipient and its descendants as a monophyletic group. Ancient gene transfer events can also reveal the order of emergence of donor and recipient lineages. In addition, these ancient events can significantly shape the genetic systems of the recipients and can play a part in their long-term evolution. In this article, we discuss the recent progress in phylogenetic application of ancient HGTs and describe two examples of transfer events to the ancestor of red algae and green plants that support a common origin of these two groups. We also address the potential pitfalls of this application.     

Gene targeting with retroviral vectors: recombination by gene conversion into regions of nonhomology.

We have designed and constructed integration-defective retroviral vectors to explore their potential for gene targeting in mammalian cells. Two nonoverlapping deletion mutants of the bacterial neomycin resistance (neo) gene were used to detect homologous recombination events between viral and chromosomal sequences. Stable neo gene correction events were selected at a frequency of approximately 1 G418r cell per 3 x 10(6) infected cells. Analysis of the functional neo gene in independent targeted cell clones indicated that unintegrated retroviral linear DNA recombined with the target by gene conversion for variable distances into regions of nonhomology. In addition, transient neo gene correction events which were associated with the complete loss of the chromosomal target sequences were observed. These results demonstrated that retroviral vectors can recombine with homologous chromosomal sequences in rodent and human cells.     

iGTP: A software package for large-scale gene tree parsimony analysis

Background  

The ever-increasing wealth of genomic sequence information provides an unprecedented opportunity for large-scale phylogenetic analysis. However, species phylogeny inference is obfuscated by incongruence among gene trees due to evolutionary events such as gene duplication and loss, incomplete lineage sorting (deep coalescence), and horizontal gene transfer. Gene tree parsimony (GTP) addresses this issue by seeking a species tree that requires the minimum number of evolutionary events to reconcile a given set of incongruent gene trees. Despite its promise, the use of gene tree parsimony has been limited by the fact that existing software is either not fast enough to tackle large data sets or is restricted in the range of evolutionary events it can handle.     

Nonrandom divergence of gene expression following gene and genome duplications in the flowering plant Arabidopsis thaliana

Background  

Genome analyses have revealed that gene duplication in plants is rampant. Furthermore, many of the duplicated genes seem to have been created through ancient genome-wide duplication events. Recently, we have shown that gene loss is strikingly different for large- and small-scale duplication events and highly biased towards the functional class to which a gene belongs. Here, we study the expression divergence of genes that were created during large- and small-scale gene duplication events by means of microarray data and investigate both the influence of the origin (mode of duplication) and the function of the duplicated genes on expression divergence.     

Different Types of Recombination Events Are Controlled by the Rad1 and Rad52 Genes of Saccharomyces Cerevisiae

Intrachromosomal recombination within heteroallelic duplications located on chromosomes III and XV of Saccharomyces cerevisiae has been examined. Both possible orientations of alleles have been used in each duplication. Three recombinant classes, gene conversions, pop-outs and triplications, were recovered. Some of the recombinant classes were not anticipated from the particular allele orientation of the duplication. Recovery of these unexpected recombinants requires the RAD1 gene. These studies show that RAD1 has a role in recombination between repeated sequences, and that the recombination event is a gene conversion associated with a crossover. These events appear to involve very localized conversion of a heteroduplex region and are distinct from RAD52 mediated gene conversion events. Evidence is also presented to suggest that most recombination events between direct repeats are intrachromatid, not between sister chromatids.     

Cell division from a genetic perspective

A novel view of the eukaryotic cell cycle is taking form as genetic strategies borrowed from investigations of microbial gene regulation and bacteriophage morphogenesis are being applied to the process of cell division. It is a genetic construct in which mutational lesions identify the primary events, thermolabile gene products reveal temporal order, mutant phenotypes yield pathways of causality, and regulatory events are localized within sequences of gene controlled steps.     

RAD52-Independent Mitotic Gene Conversion in SACCHAROMYCES CEREVISIAE Frequently Results in Chromosomal Loss

We have examined spontaneous, interchromosomal mitotic recombination events between his4 alleles in both Rad+ and rad52 strains of Saccharomyces cerevisiae. In Rad+ strains, 74% of the His+ prototrophs resulted from gene conversion events without exchange of flanking markers. In diploids homozygous for the rad52-1 mutation, the frequency of His+ prototroph formation was less than 5% of the wild-type value, and more than 80% of the gene conversion events were accompanied by an exchange of flanking markers. Most of the rad52 intragenic recombination events arose by gene conversion accompanied by an exchange of flanking markers and not by a simple reciprocal exchange between the his4A and his4C alleles. There were also profound effects on the kinds of recombinant products that were recovered. The most striking effect was that RAD52-independent mitotic recombination frequently results in the loss of one of the two chromosomes participating in the gene conversion event.     

Genome reduction by deletion of paralogs in the marine cyanobacterium Prochlorococcus

Several isolates of the marine cyanobacterial genus Prochlorococcus have smaller genome sizes than those of the closely related genus Synechococcus. In order to test whether loss of protein-coding genes has contributed to genome size reduction in Prochlorococcus, we reconstructed events of gene family evolution over a strongly supported phylogeny of 12 Prochlorococcus genomes and 9 Synechococcus genomes. Significantly, more events both of loss of paralogs within gene families and of loss of entire gene families occurred in Prochlorococcus than in Synechococcus. The number of nonancestral gene families in genomes of both genera was positively correlated with the extent of genomic islands (GIs), consistent with the hypothesis that horizontal gene transfer (HGT) is associated with GIs. However, even when only isolates with comparable extents of GIs were compared, significantly more events of gene family loss and of paralog loss were seen in Prochlorococcus than in Synechococcus, implying that HGT is not the primary reason for the genome size difference between the two genera.     

Models, algorithms and programs for phylogeny reconciliation

Gene sequences contain a gold mine of phylogenetic information. But unfortunately for taxonomists this information does not only tell the story of the species from which it was collected. Genes have their own complex histories which record speciation events, of course, but also many other events. Among them, gene duplications, transfers and losses are especially important to identify. These events are crucial to account for when reconstructing the history of species, and they play a fundamental role in the evolution of genomes, the diversification of organisms and the emergence of new cellular functions. We review reconciliations between gene and species trees, which are rigorous approaches for identifying duplications, transfers and losses that mark the evolution of a gene family. Existing reconciliation models and algorithms are reviewed and difficulties in modeling gene transfers are discussed. We also compare different reconciliation programs along with their advantages and disadvantages.