Sites of genetic instability in mitosis and cancer

Certain chromosomal regions called common fragile sites are prone to difficulty during replication. Many tumors have been shown to contain alterations at fragile sites. Several models have been proposed to explain why these sites are unstable. Here we describe work to investigate models of fragile site instability using a yeast artificial chromosome carrying human DNA from a common fragile site region. In addition, we describe a yeast system to investigate whether repair of breaks at a naturally occurring fragile site in yeast, FS2, involves mitotic recombination between homologous chromosomes, leading to loss of heterozygosity (LOH). Our initial evidence is that repair of yeast fragile site breaks does lead to LOH, suggesting that human fragile site breaks may similarly contribute to LOH in cancer. This work is focused on gaining understanding that may enable us to predict and prevent the situations and environments that promote genetic changes that contribute to tumor progression.     

129 The molecular mechanism of breakage at fragile site FRA16D

Replication stress induces physical breakage at discrete loci in chromosomes, which can be visualized on a metaphase chromosome spread. These common fragile sites (CFS) are conserved across species and are hotspots for sister chromatid recombination, viral integration, rearrangements, translocations, and deletions (Glover et al 2005). Despite multiple theories, the molecular mechanisms of CFS expression and genomic instability are still not well understood. The fragile site FRA16D is of special interest because it is the second most highly expressed fragile site and is located within the WWOX tumor suppressor gene. Previous data identified a polymorphic AT repeat within a FRA16D subregion called F1 that causes chromosome fragility and replication fork stalling in a yeast model (Zhang and Freudenreich 2007). Recently, we have found that breakage increases in an AT repeat length-dependent manner. Our results suggest that the AT repeat in the context of F1 forms a secondary structure, making the region more vulnerable to breakage.     

Chromosomal translocations in yeast induced by low levels of DNA polymerase a model for chromosome fragile sites

In the yeast Saccharomyces cerevisiae, reduced levels of the replicative alpha DNA polymerase result in greatly elevated frequencies of chromosome translocations and chromosome loss. We selected translocations in a small region of chromosome III and found that they involve homologous recombination events between yeast retrotransposons (Ty elements) on chromosome III and retrotransposons located on other chromosomes. One of the two preferred sites of these translocations on chromosome III involve two Ty elements arrayed head-to-head; disruption of this site substantially reduces the rate of translocations. We demonstrate that this pair of Ty elements constitutes a preferred site for double-strand DNA breaks when DNA replication is compromised, analogous to the fragile sites observed in mammalian chromosomes.     

A genetic screen for increased loss of heterozygosity in Saccharomyces cerevisiae

Loss of heterozygosity (LOH) can be a driving force in the evolution of mitotic/somatic diploid cells, and cellular changes that increase the rate of LOH have been proposed to facilitate this process. In the yeast Saccharomyces cerevisiae, spontaneous LOH occurs by a number of mechanisms including chromosome loss and reciprocal and nonreciprocal recombination. We performed a screen in diploid yeast to identify mutants with increased rates of LOH using the collection of homozygous deletion alleles of nonessential genes. Increased LOH was quantified at three loci (MET15, SAM2, and MAT) on three different chromosomes, and the LOH events were analyzed as to whether they were reciprocal or nonreciprocal in nature. Nonreciprocal LOH was further characterized as chromosome loss or truncation, a local mutational event (gene conversion or point mutation), or break-induced replication (BIR). The 61 mutants identified could be divided into several groups, including ones that had locus-specific effects. Mutations in genes involved in DNA replication and chromatin assembly led to LOH predominantly via reciprocal recombination. In contrast, nonreciprocal LOH events with increased chromosome loss largely resulted from mutations in genes implicated in kinetochore function, sister chromatid cohesion, or relatively late steps of DNA recombination. Mutants of genes normally involved in early steps of DNA damage repair and signaling produced nonreciprocal LOH without an increased proportion of chromosome loss. Altogether, this study defines a genetic landscape for the basis of increased LOH and the processes by which it occurs.     

Elevated incidence of loss of heterozygosity (LOH) in an sgs1 mutant of Saccharomyces cerevisiae: roles of yeast RecQ helicase in suppression of aneuploidy,interchromosomal rearrangement,and the simultaneous incidence of both events during mitotic growth

The SGS1 gene of Saccharomyces cerevisiae is a member of the RecQ helicase family, which includes the human BLM, WRN and RECQL4 genes responsible for Bloom and Werner's syndrome and Rothmund-Thomson syndrome, respectively. Cells defective in any of these genes exhibit a higher incidence of genome instability. We previously demonstrated that various genetic alterations were detectable as events leading to loss of heterozygosity (LOH) in S. cerevisiae diploid cells, utilizing a hemizygous URA3 marker placed at the center of the right arm of chromosome III. Analyses of chromosome structure in LOH clones by pulse field gel electrophoresis (PFGE) and PCR, coupled with a genetic method, allow identification of genetic alterations leading to the LOH. Such alterations include chromosome loss, chromosomal rearrangements at various locations and intragenic mutation. In this work, we have investigated the LOH events occurring in cells lacking the SGS1 gene. The frequencies of all types of LOH events, excluding intragenic mutation, were increased in sgs1 null mutants as compared to the wild-type cells. Loss of chromosome III and chromosomal rearrangements were increased 13- and 17-fold, respectively. Further classification of the chromosomal rearrangements confirmed that two kinds of events were especially increased in the sgs1 mutants: (1) ectopic recombination between chromosomes, that is, unequal crossing over and translocation (46-fold); and (2) allelic crossing over associated with chromosome loss (40-fold). These findings raise the possibility that the Sgs1 protein is involved in the processing of recombination intermediates as well as in the prevention of recombination repair during chromosome DNA replication. On the other hand, intrachromosomal deletions between MAT and HMR were increased only slightly (2.9-fold) in the sgs1 mutants. These results clearly indicate that defects in the SGS1 gene function lead to an elevated incidence of LOH in multiple ways, including chromosome loss and interchromosomal rearrangements, but not intrachromosomal deletion.     

High-Resolution Mapping of Spontaneous Mitotic Recombination Hotspots on the 1.1 Mb Arm of Yeast Chromosome IV

Although homologous recombination is an important pathway for the repair of double-stranded DNA breaks in mitotically dividing eukaryotic cells, these events can also have negative consequences, such as loss of heterozygosity (LOH) of deleterious mutations. We mapped about 140 spontaneous reciprocal crossovers on the right arm of the yeast chromosome IV using single-nucleotide-polymorphism (SNP) microarrays. Our mapping and subsequent experiments demonstrate that inverted repeats of Ty retrotransposable elements are mitotic recombination hotspots. We found that the mitotic recombination maps on the two homologs were substantially different and were unrelated to meiotic recombination maps. Additionally, about 70% of the DNA lesions that result in LOH are likely generated during G1 of the cell cycle and repaired during S or G2. We also show that different genetic elements are associated with reciprocal crossover conversion tracts depending on the cell cycle timing of the initiating DSB.     

Recombinogenic Conditions Influence Partner Choice in Spontaneous Mitotic Recombination

Mammalian common fragile sites are loci of frequent chromosome breakage and putative recombination hotspots. Here, we utilized Replication Slow Zones (RSZs), a budding yeast homolog of the mammalian common fragile sites, to examine recombination activities at these loci. We found that rates of URA3 inactivation of a hisG-URA3-hisG reporter at RSZ and non-RSZ loci were comparable under all conditions tested, including those that specifically promote chromosome breakage at RSZs (hydroxyurea [HU], mec1Δ sml1Δ, and high temperature), and those that suppress it (sml1Δ and rrm3Δ). These observations indicate that RSZs are not recombination hotspots and that chromosome fragility and recombination activity can be uncoupled. Results confirmed recombinogenic effects of HU, mec1Δ sml1Δ, and rrm3Δ and identified temperature as a regulator of mitotic recombination. We also found that these conditions altered the nature of recombination outcomes, leading to a significant increase in the frequency of URA3 inactivation via loss of heterozygosity (LOH), the type of genetic alteration involved in cancer development. Further analyses revealed that the increase was likely due to down regulation of intrachromatid and intersister (IC/IS) bias in mitotic recombination, and that RSZs exhibited greater sensitivity to HU dependent loss of IC/IS bias than non RSZ loci. These observations suggest that recombinogenic conditions contribute to genome rearrangements not only by increasing the overall recombination activity, but also by altering the nature of recombination outcomes by their effects on recombination partner choice. Similarly, fragile sites may contribute to cancer more frequently than non-fragile loci due their enhanced sensitivity to certain conditions that down-regulate the IC/IS bias rather than intrinsically higher rates of recombination.     

Initiation of DNA Replication from Non-Canonical Sites on an Origin-Depleted Chromosome

Eukaryotic DNA replication initiates from multiple sites on each chromosome called replication origins (origins). In the budding yeast Saccharomyces cerevisiae, origins are defined at discrete sites. Regular spacing and diverse firing characteristics of origins are thought to be required for efficient completion of replication, especially in the presence of replication stress. However, a S. cerevisiae chromosome III harboring multiple origin deletions has been reported to replicate relatively normally, and yet how an origin-deficient chromosome could accomplish successful replication remains unknown. To address this issue, we deleted seven well-characterized origins from chromosome VI, and found that these deletions do not cause gross growth defects even in the presence of replication inhibitors. We demonstrated that the origin deletions do cause a strong decrease in the binding of the origin recognition complex. Unexpectedly, replication profiling of this chromosome showed that DNA replication initiates from non-canonical loci around deleted origins in yeast. These results suggest that replication initiation can be unexpectedly flexible in this organism.     

Structural analysis of aberrant chromosomes that occur spontaneously in diploid Saccharomyces cerevisiae: retrotransposon Ty1 plays a crucial role in chromosomal rearrangements.

The structural analysis of aberrant chromosomes is important for our understanding of the molecular mechanisms underlying chromosomal rearrangements. We have identified a number of diploid Saccharomyces cerevisiae clones that have undergone loss of heterozygosity (LOH) leading to functional inactivation of the hemizygous URA3 marker placed on the right arm of chromosome III. Aberrant-sized chromosomes derived from chromosome III were detected in approximately 8% of LOH clones. Here, we have analyzed the structure of the aberrant chromosomes in 45 LOH clones with a PCR-based method that determines the ploidy of a series of loci on chromosome III. The alterations included various deletions and amplifications. Sequencing of the junctions revealed that all the breakpoints had been made within repeat sequences in the yeast genome, namely, MAT-HMR, which resulted in intrachromosomal deletion, and retrotransposon Ty1 elements, which were involved in various translocations. Although the translocations involved different breakpoints on different chromosomes, all breakpoints were exclusively within Ty1 elements. Some of the resulting Ty1 elements left at the breakpoints had a complex construction that indicated the involvement of other Ty1 elements not present at the parental breakpoints. These indicate that Ty1 elements are crucially involved in the generation of chromosomal rearrangements in diploid yeast cells.     

Extensive loss of heterozygosity is suppressed during homologous repair of chromosomal breaks

Loss of heterozygosity (LOH) is a common genetic alteration in tumors and often extends several megabases to encompass multiple genetic loci or even whole chromosome arms. Based on marker and karyotype analysis of tumor samples, a significant fraction of LOH events appears to arise from mitotic recombination between homologous chromosomes, reminiscent of recombination during meiosis. As DNA double-strand breaks (DSBs) initiate meiotic recombination, a potential mechanism leading to LOH in mitotically dividing cells is DSB repair involving homologous chromosomes. We therefore sought to characterize the extent of LOH arising from DSB-induced recombination between homologous chromosomes in mammalian cells. To this end, a recombination reporter was introduced into a mouse embryonic stem cell line that has nonisogenic maternal and paternal chromosomes, as is the case in human populations, and then a DSB was introduced into one of the chromosomes. Recombinants involving alleles on homologous chromosomes were readily obtained at a frequency of 4.6 x 10(-5); however, this frequency was substantially lower than that of DSB repair by nonhomologous end joining or the inferred frequency of homologous repair involving sister chromatids. Strikingly, the majority of recombinants had LOH restricted to the site of the DSB, with a minor class of recombinants having LOH that extended to markers 6 kb from the DSB. Furthermore, we found no evidence of LOH extending to markers 1 centimorgan or more from the DSB. In addition, crossing over, which can lead to LOH of a whole chromosome arm, was not observed, implying that there are key differences between mitotic and meiotic recombination mechanisms. These results indicate that extensive LOH is normally suppressed during DSB-induced allelic recombination in dividing mammalian cells.     

Chromosome breakage and recombination at fragile sites.

Chromosomal fragile sites are points on chromosomes that usually appear as nonstaining chromosome or chromatid gaps. It has frequently been suggested that fragile sites may be involved in chromosome breakage and recombination events. We and others have previously shown that fragile sites predispose to intrachromosomal recombination as measured by sister-chromatid exchanges. These findings suggested that fragile site expression often, if not always, is accompanied by DNA strand breakage. In the present report, fragile sites are shown to predispose to deletions and interchromosomal recombination. By use of somatic cell hybrids containing either human chromosome 3 or the fragile X chromosome, deletions and translocations were induced by FUdR or aphidicolin with breakpoints at the fragile sites Xq27 or 3p14.2 (FRA3B) or at points so close to the fragile sites as to be cytogenetically indistinguishable. Southern blot analysis of DNA from a panel of chromosome 3 deletion and translocation hybrids was then utilized to detect loss or retention of markers flanking FRA3B and to corroborate the cytogenetic evidence that the breakpoints were at this fragile site. One cell line with a reciprocal translocation between human chromosome 3 (with breakpoint at 3p14.2) and a hamster chromosome showed cytogenetically that the fragile site was expressed on both derivative chromosomes, supporting the hypothesis that the fragile site represents a repeated sequence. The approach described provides a means of generating specific rearrangements in somatic cell hybrids with a breakpoint at a fragile site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Spontaneous chromosome loss in Saccharomyces cerevisiae is suppressed by DNA damage checkpoint functions.

Genomic instability is one of the hallmarks of cancer cells and is often the causative factor in revealing recessive gene mutations that progress cells along the pathway to unregulated growth. Genomic instability can take many forms, including aneuploidy and changes in chromosome structure. Chromosome loss, loss and reduplication, and deletions are the majority events that result in loss of heterozygosity (LOH). Defective DNA replication, repair, and recombination can significantly increase the frequency of spontaneous genomic instability. Recently, DNA damage checkpoint functions that operate during the S-phase checkpoint have been shown to suppress spontaneous chromosome rearrangements in haploid yeast strains. To further study the role of DNA damage checkpoint functions in genomic stability, we have determined chromosome loss in DNA damage checkpoint-deficient yeast strains. We have found that the DNA damage checkpoints are essential for preserving the normal chromosome number and act synergistically with homologous recombination functions to ensure that chromosomes are segregated correctly to daughter cells. Failure of either of these processes increases LOH events. However, loss of the G2/M checkpoint does not result in an increase in chromosome loss, suggesting that it is the various S-phase DNA damage checkpoints that suppress chromosome loss. The mec1 checkpoint function mutant, defective in the yeast ATR homolog, results in increased recombination through a process that is distinct from that operative in wild-type cells.     

Topoisomerase II– and Condensin-Dependent Breakage of MEC1ATR-Sensitive Fragile Sites Occurs Independently of Spindle Tension,Anaphase, or Cytokinesis

Fragile sites are loci of recurrent chromosome breakage in the genome. They are found in organisms ranging from bacteria to humans and are implicated in genome instability, evolution, and cancer. In budding yeast, inactivation of Mec1, a homolog of mammalian ATR, leads to chromosome breakage at fragile sites referred to as replication slow zones (RSZs). RSZs are proposed to be homologous to mammalian common fragile sites (CFSs) whose stability is regulated by ATR. Perturbation during S phase, leading to elevated levels of stalled replication forks, is necessary but not sufficient for chromosome breakage at RSZs or CFSs. To address the nature of additional event(s) required for the break formation, we examined involvement of the currently known or implicated mechanisms of endogenous chromosome breakage, including errors in replication fork restart, premature mitotic chromosome condensation, spindle tension, anaphase, and cytokinesis. Results revealed that chromosome breakage at RSZs is independent of the RAD52 epistasis group genes and of TOP3, SGS1, SRS2, MMS4, or MUS81, indicating that homologous recombination and other recombination-related processes associated with replication fork restart are unlikely to be involved. We also found spindle force, anaphase, or cytokinesis to be dispensable. RSZ breakage, however, required genes encoding condensin subunits (YCG1, YSC4) and topoisomerase II (TOP2). We propose that chromosome break formation at RSZs following Mec1 inactivation, a model for mammalian fragile site breakage, is mediated by internal chromosomal stress generated during mitotic chromosome condensation.     

Replicative age induces mitotic recombination in the ribosomal RNA gene cluster of Saccharomyces cerevisiae

Somatic mutations contribute to the development of age-associated disease. In earlier work, we found that, at high frequency, aging Saccharomyces cerevisiae diploid cells produce daughters without mitochondrial DNA, leading to loss of respiration competence and increased loss of heterozygosity (LOH) in the nuclear genome. Here we used the recently developed Mother Enrichment Program to ask whether aging cells that maintain the ability to produce respiration-competent daughters also experience increased genomic instability. We discovered that this population exhibits a distinct genomic instability phenotype that primarily affects the repeated ribosomal RNA gene array (rDNA array). As diploid cells passed their median replicative life span, recombination rates between rDNA arrays on homologous chromosomes progressively increased, resulting in mutational events that generated LOH at >300 contiguous open reading frames on the right arm of chromosome XII. We show that, while these recombination events were dependent on the replication fork block protein Fob1, the aging process that underlies this phenotype is Fob1-independent. Furthermore, we provide evidence that this aging process is not driven by mechanisms that modulate rDNA recombination in young cells, including loss of cohesion within the rDNA array or loss of Sir2 function. Instead, we suggest that the age-associated increase in rDNA recombination is a response to increasing DNA replication stress generated in aging cells.     

Failed gene conversion leads to extensive end processing and chromosomal rearrangements in fission yeast

Loss of heterozygosity (LOH), a causal event in cancer and human genetic diseases, frequently encompasses multiple genetic loci and whole chromosome arms. However, the mechanisms by which such extensive LOH arises, and how it is suppressed in normal cells is poorly understood. We have developed a genetic system to investigate the mechanisms of DNA double‐strand break (DSB)‐induced extensive LOH, and its suppression, using a non‐essential minichromosome, Ch¹⁶, in fission yeast. We find extensive LOH to arise from a new break‐induced mechanism of isochromosome formation. Our data support a model in which Rqh1 and Exo1‐dependent end processing from an unrepaired DSB leads to removal of the broken chromosome arm and to break‐induced replication of the intact arm from the centromere, a considerable distance from the initial lesion. This process also promotes genome‐wide copy number variation. A genetic screen revealed Rhp51, Rhp55, Rhp57 and the MRN complex to suppress both isochromosome formation and chromosome loss, in accordance with these events resulting from extensive end processing associated with failed homologous recombination repair.     

Common fragile sites as targets for chromosome rearrangements

Common fragile sites are large chromosomal regions that preferentially exhibit gaps or breaks after DNA synthesis is partially perturbed. Fragile site instability in cultured cells is well documented and includes gaps and breaks on metaphase chromosomes, translocation and deletions breakpoints, and sister chromosome exchanges. In recent years, much has been learned about the genomic structure at fragile sites and the cellular mechanisms that monitor their stability. The study of fragile sites has merged with that of cell cycle checkpoints and DNA repair, with multiple proteins from these pathways implicated in fragile site stability, including ATR, BRCA1, CHK1, and RAD51. Since their discovery, fragile sites have been implicated in constitutional and cancer chromosome rearrangements in vivo and recent studies suggest that common fragile sites may serve as markers of chromosome damage caused by replication stress during early tumorigenesis. Here we review the relationship of fragile sites to chromosome rearrangements, particularly in tumor cells, and discuss the mechanisms that may be involved.     

Demonstration of loss of heterozygosity by single-nucleotide polymorphism microarray analysis and alterations in strain morphology in Candida albicans strains during infection

Candida albicans is a diploid yeast with a predominantly clonal mode of reproduction, and no complete sexual cycle is known. As a commensal organism, it inhabits a variety of niches in humans. It becomes an opportunistic pathogen in immunocompromised patients and can cause both superficial and disseminated infections. It has been demonstrated that genome rearrangement and genetic variation in isolates of C. albicans are quite common. One possible mechanism for generating genome-level variation among individuals of this primarily clonal fungus is mutation and mitotic recombination leading to loss of heterozygosity (LOH). Taking advantage of a recently published genome-wide single-nucleotide polymorphism (SNP) map (A. Forche, P. T. Magee, B. B. Magee, and G. May, Eukaryot. Cell 3:705-714, 2004), an SNP microarray was developed for 23 SNP loci residing on chromosomes 5, 6, and 7. It was used to examine 21 strains previously shown to have undergone mitotic recombination at the GAL1 locus on chromosome 1 during infection in mice. In addition, karyotypes and morphological properties of these strains were evaluated. Our results show that during in vivo passaging, LOH events occur at observable frequencies, that such mitotic recombination events occur independently in different loci across the genome, and that changes in karyotypes and alterations of phenotypic characteristics can be observed alone, in combination, or together with LOH.     

A search for novel tumour suppressor genes for adult acute leukaemia by allelotyping at sub-telomeric chromosomal regions

A search was initiated towards the localization of novel mutated tumour suppressor genes that may be involved in adult leukaemia. For this purpose, we measured the occurrence of loss of heterozygosity (LOH) in nine patients with acute B-lineage leukaemia (ALL) and one with undifferentiated leukaemia (AUL). Eight leukaemias exhibited a diploid karyotype. For each patient, PCR products of 130 polymorphic microsatellite markers, located in subtelomeric areas of every autosomal chromosome arm were analysed to visualize LOH events resulting from reduplication of a single mutated chromosome or from mitotic recombination. These kinds of LOH events contribute most to LOH in model systems but cannot be detected by classical cytogenetic techniques. By comparing allelic PCR products in tumour cells with those in normal cells, LOH was found in tumour cells of one ALL patient at 9p which harbours the known p16^INK44 tumour suppressor gene. In the AUL patient, however, LOH was detected at the telomeres of 4q and 21q, suggesting that these sites may contain novel tumour suppressor genes specifically involved in this form of leukaemia. In the DNA of tumour cells from eight out of 10 patients no LOH was detected. This is in contrast with the general assumption that LOH is a frequent phenomenon in ALL. However, some markers at telomeric regions of chromosomes were already homozygous in the control T-cells of several patients. For instance, we found in the DNA of control cells from one patient five consecutive microsatellites on 9p up to 9p43 which were homozygous and in three other patients homozygosity was observed in band 8q24, which includes the MYC gene. These observations indicate that LOH events already are present in non-cancerous putative stem cells and that mitotic recombination may be a very early event in leukaemogenesis.     

Dynamics of homologous chromosome pairing during meiotic prophase in fission yeast

Pairing of homologous chromosomes is important for homologous recombination and correct chromosome segregation during meiosis. It has been proposed that telomere clustering, nuclear oscillation, and recombination during meiotic prophase facilitate homologous chromosome pairing in fission yeast. Here we examined the contributions of these chromosomal events to homologous chromosome pairing, by directly observing the dynamics of chromosomal loci in living cells of fission yeast. Homologous loci exhibited a dynamic process of association and dissociation during the time course of meiotic prophase. Lack of nuclear oscillation reduced association frequency for both centromeric and arm regions of the chromosome. Lack of telomere clustering or recombination reduced association frequency at arm regions, but not significantly at centromeric regions. Our results indicate that homologous chromosomes are spatially aligned by oscillation of telomere-bundled chromosomes and physically linked by recombination at chromosome arm regions; this recombination is not required for association of homologous centromeres.