Genome-wide mapping of spontaneous genetic alterations in diploid yeast cells.

Genomic alterations including single-base mutations, deletions and duplications, translocations, mitotic recombination events, and chromosome aneuploidy generate genetic diversity. We examined the rates of all of these genetic changes in a diploid strain of Saccharomyces cerevisiae by whole-genome sequencing of many independent isolates (n = 93) subcloned about 100 times in unstressed growth conditions. The most common alterations were point mutations and small (<100 bp) insertion/deletions (n = 1,337) and mitotic recombination events (n = 1,215). The diploid cells of most eukaryotes are heterozygous for many single-nucleotide polymorphisms (SNPs). During mitotic cell divisions, recombination can produce derivatives of these cells that have become homozygous for the polymorphisms, termed loss-of-heterozygosity (LOH) events. LOH events can change the phenotype of the cells and contribute to tumor formation in humans. We observed two types of LOH events: interstitial events (conversions) resulting in a short LOH tract (usually less than 15 kb) and terminal events (mostly cross-overs) in which the LOH tract extends to the end of the chromosome. These two types of LOH events had different distributions, suggesting that they may have initiated by different mechanisms. Based on our results, we present a method of calculating the probability of an LOH event for individual SNPs located throughout the genome. We also identified several hotspots for chromosomal rearrangements (large deletions and duplications). Our results provide insights into the relative importance of different types of genetic alterations produced during vegetative growth.

Strong suppression of gene conversion with increasing DNA double-strand break load delimited by 53BP1 and RAD52.

In vertebrates, genomic DNA double-strand breaks (DSBs) are removed by non-homologous end-joining processes: classical non-homologous end-joining (c-NHEJ) and alternative end-joining (alt-EJ); or by homology-dependent processes: gene-conversion (GC) and single-strand annealing (SSA). Surprisingly, these repair pathways are not real alternative options restoring genome integrity with equal efficiency, but show instead striking differences in speed, accuracy and cell-cycle-phase dependence. As a consequence, engagement of one pathway may be associated with processing-risks for the genome absent from another pathway. Characterization of engagement-parameters and their consequences is, therefore, essential for understanding effects on the genome of DSB-inducing agents, such as ionizing-radiation (IR). Here, by addressing pathway selection in G2-phase, we discover regulatory confinements in GC with consequences for SSA- and c-NHEJ-engagement. We show pronounced suppression of GC with increasing DSB-load that is not due to RAD51 availability and which is delimited but not defined by 53BP1 and RAD52. Strikingly, at low DSB-loads, GC repairs ∼50% of DSBs, whereas at high DSB-loads its contribution is undetectable. Notably, with increasing DSB-load and the associated suppression of GC, SSA gains ground, while alt-EJ is suppressed. These observations explain earlier, apparently contradictory results and advance our understanding of logic and mechanisms underpinning the wiring between DSB repair pathways.

Adaptation by Loss of Heterozygosity in Saccharomyces cerevisiae Clones Under Divergent Selection.

Loss of heterozygosity (LOH) is observed during vegetative growth and reproduction of diploid genotypes through mitotic crossovers, aneuploidy caused by nondisjunction, and gene conversion. We aimed to test the role that LOH plays during adaptation of two highly heterozygous Saccharomyces cerevisiae genotypes to multiple environments over a short time span in the laboratory. We hypothesized that adaptation would be observed through parallel LOH events across replicate populations. Using genome resequencing of 70 clones, we found that LOH was widespread with 5.2 LOH events per clone after ∼500 generations. The most common mode of LOH was gene conversion (51%) followed by crossing over consistent with either break-induced replication or double Holliday junction resolution. There was no evidence that LOH involved nondisjunction of whole chromosomes. We observed parallel LOH in both an environment-specific and environment-independent manner. LOH largely involved recombining existing variation between the parental genotypes, but also was observed after de novo, presumably beneficial, mutations occurred in the presence of canavanine, a toxic analog of arginine. One highly parallel LOH event involved the ENA salt efflux pump locus on chromosome IV, which showed repeated LOH to the allele from the European parent, an allele originally derived by introgression from S. paradoxus Using CRISPR-engineered LOH we showed that the fitness advantage provided by this single LOH event was 27%. Overall, we found extensive evidence that LOH could be adaptive and is likely to be a greater source of initial variation than de novo mutation for rapid evolution of diploid genotypes.

The impact of poly-A microsatellite heterologies in meiotic recombination.

Meiotic recombination has strong, but poorly understood effects on short tandem repeat (STR) instability. Here, we screened thousands of single recombinant products with sperm typing to characterize the role of polymorphic poly-A repeats at a human recombination hotspot in terms of hotspot activity and STR evolution. We show that the length asymmetry between heterozygous poly-A's strongly influences the recombination outcome: a heterology of 10 A's (9A/19A) reduces the number of crossovers and elevates the frequency of non-crossovers, complex recombination products, and long conversion tracts. Moreover, the length of the heterology also influences the STR transmission during meiotic repair with a strong and significant insertion bias for the short heterology (6A/7A) and a deletion bias for the long heterology (9A/19A). In spite of this opposing insertion-/deletion-biased gene conversion, we find that poly-A's are enriched at human recombination hotspots that could have important consequences in hotspot activation.

Homoeologous exchange is a major cause of gene presence/absence variation in the amphidiploid Brassica napus.

Homoeologous exchanges (HEs) have been shown to generate novel gene combinations and phenotypes in a range of polyploid species. Gene presence/absence variation (PAV) is also a major contributor to genetic diversity. In this study, we show that there is an association between these two events, particularly in recent Brassica napus synthetic accessions, and that these represent a novel source of genetic diversity, which can be captured for the improvement of this important crop species. By assembling the pangenome of B. napus, we show that 38% of the genes display PAV behaviour, with some of these variable genes predicted to be involved in important agronomic traits including flowering time, disease resistance, acyl lipid metabolism and glucosinolate metabolism. This study is a first and provides a detailed characterization of the association between HEs and PAVs in B. napus at the pangenome level.

Complex Breakpoints and Template Switching Associated with Non-canonical Termination of Homologous Recombination in Mammalian Cells.

A proportion of homologous recombination (HR) events in mammalian cells resolve by "long tract" gene conversion, reflecting copying of several kilobases from the donor sister chromatid prior to termination. Cells lacking the major hereditary breast/ovarian cancer predisposition genes, BRCA1 or BRCA2, or certain other HR-defective cells, reveal a bias in favor of long tract gene conversion, suggesting that this aberrant HR outcome might be connected with genomic instability. If termination of gene conversion occurs in regions lacking homology with the second end of the break, the normal mechanism of HR termination by annealing (i.e., homologous pairing) is not available and termination must occur by as yet poorly defined non-canonical mechanisms. Here we use a previously described HR reporter to analyze mechanisms of non-canonical termination of long tract gene conversion in mammalian cells. We find that non-canonical HR termination can occur in the absence of the classical non-homologous end joining gene XRCC4. We observe obligatory use of microhomology (MH)-mediated end joining and/or nucleotide addition during rejoining with the second end of the break. Notably, non-canonical HR termination is associated with complex breakpoints. We identify roles for homology-mediated template switching and, potentially, MH-mediated template switching/microhomology-mediated break-induced replication, in the formation of complex breakpoints at sites of non-canonical HR termination. This work identifies non-canonical HR termination as a potential contributor to genomic instability and to the formation of complex breakpoints in cancer.

Inter-genomic DNA Exchanges and Homeologous Gene Silencing Shaped the Nascent Allopolyploid Coffee Genome (Coffea arabica L.).

Allopolyploidization is a biological process that has played a major role in plant speciation and evolution. Genomic changes are common consequences of polyploidization, but their dynamics over time are still poorly understood. Coffea arabica, a recently formed allotetraploid, was chosen to study genetic changes that accompany allopolyploid formation. Both RNA-seq and DNA-seq data were generated from two genetically distant C. arabica accessions. Genomic structural variation was investigated using C. canephora, one of its diploid progenitors, as reference genome. The fate of 9047 duplicate homeologous genes was inferred and compared between the accessions. The pattern of SNP density along the reference genome was consistent with the allopolyploid structure. Large genomic duplications or deletions were not detected. Two homeologous copies were retained and expressed in 96% of the genes analyzed. Nevertheless, duplicated genes were found to be affected by various genomic changes leading to homeolog loss or silencing. Genetic and epigenetic changes were evidenced that could have played a major role in the stabilization of the unique ancestral allotetraploid and its subsequent diversification. While the early evolution of C. arabica mainly involved homeologous crossover exchanges, the later stage appears to have relied on more gradual evolution involving gene conversion and homeolog silencing.

Remarkably Long-Tract Gene Conversion Induced by Fragile Site Instability in Saccharomyces cerevisiae.

Replication stress causes breaks at chromosomal locations called common fragile sites. Deletions causing loss of heterozygosity (LOH) in human tumors are strongly correlated with common fragile sites, but the role of gene conversion in LOH at fragile sites in tumors is less well studied. Here, we investigated gene conversion stimulated by instability at fragile site FS2 in the yeast Saccharomyces cerevisiae In our screening system, mitotic LOH events near FS2 are identified by production of red/white sectored colonies. We analyzed single nucleotide polymorphisms between homologs to determine the cause and extent of LOH. Instability at FS2 increases gene conversion 48- to 62-fold, and conversions unassociated with crossover represent 6-7% of LOH events. Gene conversion can result from repair of mismatches in heteroduplex DNA during synthesis-dependent strand annealing (SDSA), double-strand break repair (DSBR), and from break-induced replication (BIR) that switches templates [double BIR (dBIR)]. It has been proposed that SDSA and DSBR typically result in shorter gene-conversion tracts than dBIR. In cells under replication stress, we found that bidirectional tracts at FS2 have a median length of 40.8 kb and a wide distribution of lengths; most of these tracts are not crossover-associated. Tracts that begin at the fragile site FS2 and extend only distally are significantly shorter. The high abundance and long length of noncrossover, bidirectional gene-conversion tracts suggests that dBIR is a prominent mechanism for repair of lesions at FS2, thus this mechanism is likely to be a driver of common fragile site-stimulated LOH in human tumors.

Frequent Interchromosomal Template Switches during Gene Conversion in S. cerevisiae.

Although repair of double-strand breaks (DSBs) by gene conversion is the most accurate way to repair such lesions, in budding yeast there is a 1,000-fold increase in accompanying mutations, including interchromosomal template switches (ICTS) involving highly mismatched (homeologous) ectopic sequences. Although such events are rare and appear at a rate of 2 × 10(-7) when template jumps occur between 71% identical sequences, they are surprisingly frequent (0.3% of all repair events) when the second template is identical to the first, revealing the remarkable instability of repair DNA synthesis. With homeologous donors, ICTS uses microhomologies as small as 2 bp. Cells lacking mismatch repair proteins Msh6 and Mlh1 form chimeric recombinants with two distinct patches of microhomology, implying that these proteins are crucial for strand discrimination of heteroduplex DNA formed during ICTS. We identify the chromatin remodeler Rdh54 as the first protein required for template switching that does not affect simple gene conversion.

BRCA1 controls homologous recombination at Tus/Ter-stalled mammalian replication forks.

Replication fork stalling can promote genomic instability, predisposing to cancer and other diseases. Stalled replication forks may be processed by sister chromatid recombination (SCR), generating error-free or error-prone homologous recombination (HR) outcomes. In mammalian cells, a long-standing hypothesis proposes that the major hereditary breast/ovarian cancer predisposition gene products, BRCA1 and BRCA2, control HR/SCR at stalled replication forks. Although BRCA1 and BRCA2 affect replication fork processing, direct evidence that BRCA gene products regulate homologous recombination at stalled chromosomal replication forks is lacking, due to a dearth of tools for studying this process. Here we report that the Escherichia coli Tus/Ter complex can be engineered to induce site-specific replication fork stalling and chromosomal HR/SCR in mouse cells. Tus/Ter-induced homologous recombination entails processing of bidirectionally arrested forks. We find that the Brca1 carboxy (C)-terminal tandem BRCT repeat and regions of Brca1 encoded by exon 11-two Brca1 elements implicated in tumour suppression-control Tus/Ter-induced homologous recombination. Inactivation of either Brca1 or Brca2 increases the absolute frequency of 'long-tract' gene conversions at Tus/Ter-stalled forks, an outcome not observed in response to a site-specific endonuclease-mediated chromosomal double-strand break. Therefore, homologous recombination at stalled forks is regulated differently from homologous recombination at double-strand breaks arising independently of a replication fork. We propose that aberrant long-tract homologous recombination at stalled replication forks contributes to genomic instability and breast/ovarian cancer predisposition in BRCA mutant cells.

Assessment of anti-recombination and double-strand break-induced gene conversion in human cells by a chromosomal reporter.

Gene conversion is one of the frequent end results of homologous recombination, and it often underlies the inactivation of tumor suppressor genes in cancer cells. Here, we have developed an integrated assay system that allows simultaneous examination of double-strand break (DSB)-induced gene conversion events at the site of a DSB (proximal region) and at a surrounding region ~1 kb away from the break (distal region). Utilizing this assay system, we find that gene conversion events at the proximal and distal regions are relatively independent of one another. The results also indicate that synthesis-dependent strand annealing (SDSA) plays a major role in DSB-induced gene conversion. In addition, our current study has demonstrated that hMLH1 plays an essential role in anti-recombination and gene conversion. Specifically, the anti-recombination activity of hMLH1 is partially dependent on its interaction with hMRE11. Our data suggests that the role of hMLH1 and hMRE11 in the process of gene conversion is complex, and these proteins play different roles in DSB-induced proximal and distal gene conversions. In particular, the involvement of hMLH1 and hMRE11 in the distal gene conversion requires both hMSH2 and heteroduplex formation.

Interhomolog recombination and loss of heterozygosity in wild-type and Bloom syndrome helicase (BLM)-deficient mammalian cells.

Genomic integrity often is compromised in tumor cells, as illustrated by genetic alterations leading to loss of heterozygosity (LOH). One mechanism of LOH is mitotic crossover recombination between homologous chromosomes, potentially initiated by a double-strand break (DSB). To examine LOH associated with DSB-induced interhomolog recombination, we analyzed recombination events using a reporter in mouse embryonic stem cells derived from F1 hybrid embryos. In this study, we were able to identify LOH events although they occur only rarely in wild-type cells (≤2.5%). The low frequency of LOH during interhomolog recombination suggests that crossing over is rare in wild-type cells. Candidate factors that may suppress crossovers include the RecQ helicase deficient in Bloom syndrome cells (BLM), which is part of a complex that dissolves recombination intermediates. We analyzed interhomolog recombination in BLM-deficient cells and found that, although interhomolog recombination is slightly decreased in the absence of BLM, LOH is increased by fivefold or more, implying significantly increased interhomolog crossing over. These events frequently are associated with a second homologous recombination event, which may be related to the mitotic bivalent structure and/or the cell-cycle stage at which the initiating DSB occurs.

Obtención de suspensiones celulares y embriones somáticos de cafeto (Coffea canephora P) con el empleo de metabolitos bacterianos / Obtaining of cell suspensions and somatic embryos of coffee (Coffea canephora P) using of bacterial metabolites

La embriogénesis somática es importante como sistema modelo para estudiar el desarrollo de eventos fisiológicos, citológicos y moleculares que sustentan la embriogénesis en plantas, por ser un sistema adecuado para la propagación masiva de especies vegetales y servir de herramienta para el mejoramiento genético, la conservación de germoplasma y la validación de nuevos productos biológicos, y facilitar la producción a gran escala a través del cultivo en medio líquido y su aplicación en biorreactores, proporcionando alta frecuencia de multiplicación, rápido crecimiento del embrión, facilidad de absorción de nutrientes y reducción de la labor de subcultivo. En este trabajo se empleó la embriogénesis somática como vía de multiplicación para evaluar el efecto de metabolitos bacterianos en la inducción de suspensiones celulares y embriones somáticos en tres genotipos de cafeto pertenecientes a Coffea canephora P. variedad Robusta. Para ello se estudiaron densidades de inóculo entre 0,2, 0,5, 1,0 y 3,0 gMF/L-1, y se evaluó el efecto de diferentes medios de cultivo en el desarrollo del proceso. Los resultados mostraron un comportamiento diferenciado en el genotipo M-28, en medios de cultivo suplementados con reguladores de crecimiento convencionales y en los alternativos. Se evidenció una fuerte relación entre la viabilidad celular y el número de células, ante las diferentes condiciones de cultivo y según la densidad de inóculo, se observó un amplio rango de tamaño y forma en las poblaciones de embriones somáticos. Los porcentajes de conversión de ES con el medio MDE-2 evidenciaron mejoras de este indicador para el cultivo del cafeto.

The somatic embryogenesis is important as model system to study the development of physiologic and molecular events that sustain the embryogenesis in plants, is an appropriate system for the massive propagation of vegetable species and as tool for the genetic improvement, the germplasm conservation and the validation of new biological products and to facilitate the multiplication to great scale through the culture in liquid medium, as well as application in bioreactores, providing high multiplication frequency, quick growth of the embryo, easiness of absorption of nutritious and reduction of the subculturing. In this paper the somatic embryogenesis was used to evaluate the effect of bacterial compounds in the induction of cellular suspensions and somatic embryos in three coffee genotypes of Coffea canephora P. var. Robusta. Were studied inoculo densities among 0.2, 0.5, 1.0 and 3.0 gMF/L-1 and the effect of different culture medium in the development of the process. The results showed a behavior differed in the genotype M-28, in medium culture with conventional regulators of growth and the alternatives. Strong relationship was evidenced between the cellular viability and the number of cells, in the different cultivation conditions and according to the inoculo density, a wide range of size and forms as observed in the populations of somatic embryos. The conversion percentages with the medium MDE-2, evidenced improvements of this indicator for the coffee.

Evolutionary history of the cancer immunity antigen MAGE gene family.

The evolutionary mode of a multi-gene family can change over time, depending on the functional differentiation and local genomic environment of family members. In this study, we demonstrate such a change in the melanoma antigen (MAGE) gene family on the mammalian X chromosome. The MAGE gene family is composed of ten subfamilies that can be categorized into two types. Type I genes are of relatively recent origin, and they encode epitopes for human leukocyte antigen (HLA) in cancer cells. Type II genes are relatively ancient and some of their products are known to be involved in apoptosis or cell proliferation. The evolutionary history of the MAGE gene family can be divided into four phases. In phase I, a single-copy state of an ancestral gene and the evolutionarily conserved mode had lasted until the emergence of eutherian mammals. In phase II, eight subfamily ancestors, with the exception for MAGE-C and MAGE-D subfamilies, were formed via retrotransposition independently. This would coincide with a transposition burst of LINE elements at the eutherian radiation. However, MAGE-C was generated by gene duplication of MAGE-A. Phase III is characterized by extensive gene duplication within each subfamily and in particular the formation of palindromes in the MAGE-A subfamily, which occurred in an ancestor of the Catarrhini. Phase IV is characterized by the decay of a palindrome in most Catarrhini, with the exception of humans. Although the palindrome is truncated by frequent deletions in apes and Old World monkeys, it is retained in humans. Here, we argue that this human-specific retention stems from negative selection acting on MAGE-A genes encoding epitopes of cancer cells, which preserves their ability to bind to highly divergent HLA molecules. These findings are interpreted with consideration of the biological factors shaping recent human MAGE-A genes.

FancJ/Brip1 helicase protects against genomic losses and gains in vertebrate cells.

Defects in the FANCJ/BRIP1 helicase gene are associated with genome instability disorders such as familial breast cancer or Fanconi anemia (FA). Although FANCJ has an in vitro activity to resolve G-quadruplex (G4) structures, and FANCJ ortholog in C. elegans prevents G4-associated deletions during replication, how FANCJ loss affects genome integrity in higher organisms remains unclear. Here, we report that FANCJ, but not other FA genes FANCD2 or FANCC, protected against large-scale genomic deletion that occurred frequently at the rearranged immunoglobulin heavy chain (IgH) locus in chicken DT40 cell line, suggesting that FancJ protects the genome independently of the FA ubiquitination pathway. In a more unbiased approach using array-comparative genomic hybridization, we identified de novo deletions as well as amplifications in fancj cells kept in culture for 2 months. A cluster of G4 sequence motifs was found near the breakpoint of one amplified region, but G4 sequence motifs were not detected at the breakpoints of two deleted regions. These results collectively suggest that, unlike in C. elegans, actions of vertebrate FANCJ to promote genome stability may not be limited to protection against the G4-mediated gene deletions.

The BRCT domain of PARP-1 is required for immunoglobulin gene conversion.

Genetic variation at immunoglobulin (Ig) gene variable regions in B-cells is created through a multi-step process involving deamination of cytosine bases by activation-induced cytidine deaminase (AID) and their subsequent mutagenic repair. To protect the genome from dangerous, potentially oncogenic effects of off-target mutations, both AID activity and mutagenic repair are targeted specifically to the Ig genes. However, the mechanisms of targeting are unknown and recent data have highlighted the role of regulating mutagenic repair to limit the accumulation of somatic mutations resulting from the more widely distributed AID-induced lesions to the Ig genes. Here we investigated the role of the DNA damage sensor poly-(ADPribose)-polymerase-1 (PARP-1) in the repair of AID-induced DNA lesions. We show through sequencing of the diversifying Ig genes in PARP-1(-/-) DT40 B-cells that PARP-1 deficiency results in a marked reduction in gene conversion events and enhanced high-fidelity repair of AID-induced lesions at both Ig heavy and light chains. To further characterize the role of PARP-1 in the mutagenic repair of AID-induced lesions, we performed functional analyses comparing the role of engineered PARP-1 variants in high-fidelity repair of DNA damage induced by methyl methane sulfonate (MMS) and the mutagenic repair of lesions at the Ig genes induced by AID. This revealed a requirement for the previously uncharacterized BRCT domain of PARP-1 to reconstitute both gene conversion and a normal rate of somatic mutation at Ig genes, while being dispensable for the high-fidelity base excision repair. From these data we conclude that the BRCT domain of PARP-1 is required to initiate a significant proportion of the mutagenic repair specific to diversifying antibody genes. This role is distinct from the known roles of PARP-1 in high-fidelity DNA repair, suggesting that the PARP-1 BRCT domain has a specialized role in assembling mutagenic DNA repair complexes involved in antibody diversification.

New CYP2A6 gene deletion and conversion variants in a population of Black African descent.

AIMS: Cytochrome P450 2A6 (CYP2A6) is a human enzyme best known for metabolizing nicotine and nitrosamine precarcinogens. Our aim was to discover and characterize new CYP2A6 alleles in a population of Black African descent. MATERIALS & METHODS: We used cloning, sequencing and genotyping of genomic DNA to discover new variants, and in vivo nicotine pharmacokinetic phenotyping to characterize the functional effect of the new alleles. RESULTS: Four new CYP2A6 alleles, CYP2A6*4G, *4H, *1B4 and *1L, were discovered and characterized in a population of Black African descent. The two new deletion alleles, CYP2A6*4G and *4H, are distinguished by different crossover junctions at 7.9 and 7.8 kb downstream of the CYP2A6 +1ATG start site, respectively; their combined allele frequency is 1.6%. The new gene conversion alleles, CYP2A6*1B4 and CYP2A6*1L, contain 27 and 10 bp of CYP2A7 sequence in the CYP2A6 3 -flanking region, respectively; their combined allele frequency is 7.3%. CYP2A6*4 appears to associate with lower CYP2A6 activity in vivo, while CYP2A6*1L does not; however, CYP2A6*1L confounds genotyping assays that use the 2A6R3 and 2A6R4 primers. CONCLUSION: As new variants are discovered, the relationships between CYP2A6 genotype, nicotine metabolism, smoking behaviors and tobacco-related cancer risk will be further clarified.

Parallel detection of crossovers and noncrossovers in mouse germ cells.

The recombination between homologous chromosomes during the prophase of the first meiotic division plays an essential role in the formation of euploid gametes, as well as contributing to genetic diversity through the generation of new allele combinations. Two types of products are formed, crossovers (CO) and gene conversions not associated with a crossover, also called noncrossovers (NCO). They result from the repair through differentiated pathways of a common initiating event, DNA double-strand breaks, formation of which is programmed during early meiotic prophase. In contrast to CO, little is known on the frequency, distribution, and regulation of NCO in mammals, mostly due to the technical challenge represented by their detection. However, the development of batch sperm-typing methods allowed for the detection of meiotic NCO products at meiotic recombination hotspots in human and mice. Several recent studies based on this technique demonstrated that mammalian CO hotspots are sites of recombination initiation and that the formation of CO and NCO has different genetic requirements. Here, we describe a method for detecting and characterizing CO and NCO, which has been applied to the analysis of the mouse Psmb9 recombination hotspot.

Selection to maintain paralogous amino acid differences under the pressure of gene conversion in the heat-shock protein genes in yeast.

A genome scan for the signatures of selection for paralogous functional amino acid differences was performed with yeast genomes. This recently developed method makes it possible to localize the target sites of selection under the pressure of gene conversion. We found that two gene pairs have strong signatures of selection. The two pairs of duplicated genes happened to be heat shock genes (Ssa1/ Ssa2 and Ssb1/Ssb2), which have similar protein structures to each other, although the amino acid sequence identity between Ssa and Ssb is not high ( approximately 60%). Interestingly, the two gene pairs exhibit signature of selection at almost identical positions within the substrate-binding domain beta. Because this domain specifies the substrate polypeptides, it is presumed that functional divergence may be advantageous in this domain. Evolutionary analysis demonstrated that the observed divergence in the two gene pairs has been maintained in many yeast species independently, suggesting long-term operation of strong selection.

DQB1*0323 is the result of a gene conversion event between a DQB1*06 and a DQB1*030303 allele.

A novel human leukocyte antigen-DQB1 allele, DQB1*0323, was identified in a volunteer hematopoietic stem cell donor. DQB1*0323 differs from the closely related allele DQB1*030303 in five nucleotide positions.