Nucleotide deficiency promotes genomic instability in early stages of cancer development.

Chromosomal instability in early cancer stages is caused by stress on DNA replication. The molecular basis for replication perturbation in this context is currently unknown. We studied the replication dynamics in cells in which a regulator of S phase entry and cell proliferation, the Rb-E2F pathway, is aberrantly activated. Aberrant activation of this pathway by HPV-16 E6/E7 or cyclin E oncogenes significantly decreased the cellular nucleotide levels in the newly transformed cells. Exogenously supplied nucleosides rescued the replication stress and DNA damage and dramatically decreased oncogene-induced transformation. Increased transcription of nucleotide biosynthesis genes, mediated by expressing the transcription factor c-myc, increased the nucleotide pool and also rescued the replication-induced DNA damage. Our results suggest a model for early oncogenesis in which uncoordinated activation of factors regulating cell proliferation leads to insufficient nucleotides that fail to support normal replication and genome stability.

Failure of origin activation in response to fork stalling leads to chromosomal instability at fragile sites.

Perturbed DNA replication in early stages of cancer development induces chromosomal instability preferentially at fragile sites. However, the molecular basis for this instability is unknown. Here, we show that even under normal growth conditions, replication fork progression along the fragile site, FRA16C, is slow and forks frequently stall at AT-rich sequences, leading to activation of additional origins to enable replication completion. Under mild replication stress, the frequency of stalling at AT-rich sequences is further increased. Strikingly, unlike in the entire genome, in the FRA16C region additional origins are not activated, suggesting that all potential origins are already activated under normal conditions. Thus, the basis for FRA16C fragility is replication fork stalling at AT-rich sequences and inability to activate additional origins under replication stress. Our results provide a mechanism explaining the replication stress sensitivity of fragile sites and thus, the basis for genomic instability during early stages of cancer development.

Structural variability of the herpes simplex virus 1 genome in vitro and in vivo.

Herpes simplex virus 1 (HSV-1) is a human pathogen that leads to recurrent facial-oral lesions. Its 152-kb genome is organized in two covalently linked segments, each composed of a unique sequence flanked by inverted repeats. Replication of the HSV-1 genome produces concatemeric molecules in which homologous recombination events occur between the inverted repeats. This mechanism leads to four genome isomers (termed P, IS, IL, and ILS) that differ in the relative orientations of their unique fragments. Molecular combing analysis was performed on DNA extracted from viral particles and BSR, Vero, COS-7, and Neuro-2a cells infected with either strain SC16 or KOS of HSV-1, as well as from tissues of experimentally infected mice. Using fluorescence hybridization, isomers were repeatedly detected and distinguished and were accompanied by a large proportion of noncanonical forms (40%). In both cell and viral-particle extracts, the distributions of the four isomers were statistically equivalent, except for strain KOS grown in Vero and Neuro-2a cells, in which P and IS isomers were significantly overrepresented. In infected cell extracts, concatemeric molecules as long as 10 genome equivalents were detected, among which, strikingly, the isomer distributions were equivalent, suggesting that any such imbalance may occur during encapsidation. In vivo, for strain KOS-infected trigeminal ganglia, an unbalanced distribution distinct from the one in vitro was observed, along with a considerable proportion of noncanonical assortment.

A diagnostic genetic test for the physical mapping of germline rearrangements in the susceptibility breast cancer genes BRCA1 and BRCA2.

The BRCA1 and BRCA2 genes are involved in breast and ovarian cancer susceptibility. About 2 to 4% of breast cancer patients with positive family history, negative for point mutations, can be expected to carry large rearrangements in one of these two genes. We developed a novel diagnostic genetic test for the physical mapping of large rearrangements, based on molecular combing (MC), a FISH-based technique for direct visualization of single DNA molecules at high resolution. We designed specific Genomic Morse Codes (GMCs), covering the exons, the noncoding regions, and large genomic portions flanking both genes. We validated our approach by testing 10 index cases with positive family history of breast cancer and 50 negative controls. Large rearrangements, corresponding to deletions and duplications with sizes ranging from 3 to 40 kb, were detected and characterized on both genes, including four novel mutations. The nature of all the identified mutations was confirmed by high-resolution array comparative genomic hybridization (aCGH) and breakpoints characterized by sequencing. The developed GMCs allowed to localize several tandem repeat duplications on both genes. We propose the developed genetic test as a valuable tool to screen large rearrangements in BRCA1 and BRCA2 to be combined in clinical settings with an assay capable of detecting small mutations.

Molecular combing reveals allelic combinations in facioscapulohumeral dystrophy.

OBJECTIVE: The genetic variation underlying facioscapulohumeral muscular dystrophy (FSHD), 1 of the most common hereditary neuromuscular disorders, is complex, and associated with the contraction of a repeat array (D4Z4) at the subtelomeric end of chromosome 4q. Nonpathogenic variants of 4q and the presence of a homologous array on chromosome 10q make FSHD diagnosis extremely challenging, at least in individuals with nonstandard D4Z4 arrays. We aimed to improve FSHD molecular analysis by proposing an alternative technique to the Southern blot. METHODS: We applied molecular combing (MC) to directly visualize allelic combinations associated with FSHD. RESULTS: MC enabled the accurate diagnosis of 32 FSHD patients. Unreported haplotypes and rearrangements, as well as somatic mosaicism, which is common in the 10 to 30% of cases that are sporadic, were detectable by MC. INTERPRETATION: MC enables the detailed exploration of the FSHD locus and accurate diagnosis of FSHD, the first Mendelian disease to benefit from this technique. MC is also likely to be applicable to other copy number-variant or repeat expansion-associated human diseases.

Oncogene-induced senescence is a DNA damage response triggered by DNA hyper-replication.

Early tumorigenesis is associated with the engagement of the DNA-damage checkpoint response (DDR). Cell proliferation and transformation induced by oncogene activation are restrained by cellular senescence. It is unclear whether DDR activation and oncogene-induced senescence (OIS) are causally linked. Here we show that senescence, triggered by the expression of an activated oncogene (H-RasV12) in normal human cells, is a consequence of the activation of a robust DDR. Experimental inactivation of DDR abrogates OIS and promotes cell transformation. DDR and OIS are established after a hyper-replicative phase occurring immediately after oncogene expression. Senescent cells arrest with partly replicated DNA and with DNA replication origins having fired multiple times. In vivo DNA labelling and molecular DNA combing reveal that oncogene activation leads to augmented numbers of active replicons and to alterations in DNA replication fork progression. We also show that oncogene expression does not trigger a DDR in the absence of DNA replication. Last, we show that oncogene activation is associated with DDR activation in a mouse model in vivo. We propose that OIS results from the enforcement of a DDR triggered by oncogene-induced DNA hyper-replication.

Replication dynamics at common fragile site FRA6E.

The replication dynamics at common fragile site FRA6E has been evaluated by molecular combing and interphase fluorescent in situ hybridisation (FISH) in primary human lymphocytes cultured under normal or aphidicolin-induced stress conditions. FRA6E is one of the most frequently expressed common fragile sites of the human genome. It harbours several genes, PARK2 being regarded as the most relevant one. According to the results obtained from interphase FISH analysis, FRA6E can be considered a mid-late-replicating sequence characterised by heterogeneous replication timing. Molecular combing did not reveal specific replication parameters at the fragile site: fork rates were highly comparable to those detected at an early replicating locus (LMNB2) used as control and in very good agreement with the whole-genome data obtained in parallel. The same indication applied to the density of initiation zones, the inter-origin distances from adjacent ongoing forks, the frequencies of unidirectional forks, fork arrest events and asynchronous forks. Interestingly, PARK2 appeared embedded in an early/late replication transition zone, corresponding to intron 8 (162 kb) and to the fragility core of FRA6E. In cells exposed to aphidicolin, few forks progressing at a rather slow rate were observed, the majority of them being unidirectional, but again a specific response of the fragile site was not observed. In summary, at FRA6E the replication process is not impaired per se, but chromosome breakages occur preferentially at an early/late replication transition zone. Aphidicolin might increase the occurrence of breakage events at FRA6E by prolonging the time interval separating the replication of early and late replication domains. These results may be of general significance to address the problem of fragile site instability.

Combed single DNA molecules imaged by secondary ion mass spectrometry.

Studies of replication, recombination, and rearrangements at the level of individual molecules of DNA are often limited by problems of resolution or of perturbations caused by the modifications that are needed for imaging. The Combing-Imaging by Secondary Ion Mass Spectrometry (SIMS) (CIS) method helps solve these problems by combining DNA combing, cesium flooding, and quantitative imaging via the NanoSIMS 50. We show here that CIS can reveal, on the 50 nm scale, individual DNA fibers labeled with different, nonradioactive isotopes and, moreover, that it can quantify these isotopes so as to detect and measure the length of one or more short nucleic acid fragments associated with a longer fiber.

A Cdc7 kinase inhibitor restricts initiation of DNA replication and has antitumor activity.

Cdc7 is an essential kinase that promotes DNA replication by activating origins of replication. Here, we characterized the potent Cdc7 inhibitor PHA-767491 (1) in biochemical and cell-based assays, and we tested its antitumor activity in rodents. We found that the compound blocks DNA synthesis and affects the phosphorylation of the replicative DNA helicase at Cdc7-dependent phosphorylation sites. Unlike current DNA synthesis inhibitors, PHA-767491 prevents the activation of replication origins but does not impede replication fork progression, and it does not trigger a sustained DNA damage response. Treatment with PHA-767491 results in apoptotic cell death in multiple cancer cell types and tumor growth inhibition in preclinical cancer models. To our knowledge, PHA-767491 is the first molecule that directly affects the mechanisms controlling initiation as opposed to elongation in DNA replication, and its activities suggest that Cdc7 kinase inhibition could be a new strategy for the development of anticancer therapeutics.

Replication fork velocities at adjacent replication origins are coordinately modified during DNA replication in human cells.

The spatial organization of replicons into clusters is believed to be of critical importance for genome duplication in higher eukaryotes, but its functional organization still remains to be fully clarified. The coordinated activation of origins is insufficient on its own to account for a timely completion of genome duplication when interorigin distances vary significantly and fork velocities are constant. Mechanisms coordinating origin distribution with fork progression are still poorly elucidated, because of technical difficulties of visualizing the process. Taking advantage of a single molecule approach, we delineated and compared the DNA replication kinetics at the genome level in human normal primary and malignant cells. Our results show that replication forks moving from one origin, as well as from neighboring origins, tend to exhibit the same velocity, although the plasticity of the replication program allows for their adaptation to variable interorigin distances. We also found that forks that emanated from closely spaced origins tended to move slower than those associated with long replicons. Taken together, our results indicate a functional role for origin clustering in the dynamic regulation of genome duplication.

Introduction to molecular combing: genomics, DNA replication, and cancer.

The sequencing of the human genome inaugurated a new era in both fundamental and applied genetics. At the same time, the emergence of new technologies for probing the genome has transformed the field of pharmaco-genetics and made personalized genomic profiling and high-throughput screening of new therapeutic agents all but a matter of routine. One of these technologies, molecular combing, has served to bridge the technical gap between the examination of gross chromosomal abnormalities and sequence-specific alterations. Molecular combing provides a new perspective on the structure and dynamics of the human genome at the whole genome and sub-chromosomal levels with a resolution ranging from a few kilobases up to a megabase and more. Originally developed to study genetic rearrangements and to map genes for positional cloning, recent advances have extended the spectrum of its applications to studying the real-time dynamics of the replication of the genome. Understanding how the genome is replicated is essential for elucidating the mechanisms that both maintain genome integrity and result in the instabilities leading to human genetic disease and cancer. In the following, we will examine recent discoveries and advances due to the application of molecular combing to new areas of research in the fields of molecular cytogenetics and cancer genomics.

DNA replication origin interference increases the spacing between initiation events in human cells.

Mammalian DNA replication origins localize to sites that range from base pairs to tens of kilobases. A regular distribution of initiations in individual cell cycles suggests that only a limited number of these numerous potential start sites are converted into activated origins. Origin interference can silence redundant origins; however, it is currently unknown whether interference participates in spacing functional human initiation events. By using a novel hybridization strategy, genomic Morse code, on single combed DNA molecules from primary keratinocytes, we report the initiation sites present on 1.5 Mb of human chromosome 14q11.2. We confirm that initiation zones are widespread in human cells, map to intergenic regions, and contain sequence motifs found at other mammalian initiation zones. Origins used per cell cycle are less abundant than the potential sites of initiation, and their limited use increases the spacing between initiation events. Between-zone interference decreases in proportion to the distance from the active origin, whereas within-zone interference is 100% efficient. These results identify a hierarchical organization of origin activity in human cells. Functional origins govern the probability that nearby origins will fire in the context of multiple potential start sites of DNA replication, and this is mediated by origin interference.

DNA replication origins fire stochastically in fission yeast.

DNA replication initiates at discrete origins along eukaryotic chromosomes. However, in most organisms, origin firing is not efficient; a specific origin will fire in some but not all cell cycles. This observation raises the question of how individual origins are selected to fire and whether origin firing is globally coordinated to ensure an even distribution of replication initiation across the genome. We have addressed these questions by determining the location of firing origins on individual fission yeast DNA molecules using DNA combing. We show that the firing of replication origins is stochastic, leading to a random distribution of replication initiation. Furthermore, origin firing is independent between cell cycles; there is no epigenetic mechanism causing an origin that fires in one cell cycle to preferentially fire in the next. Thus, the fission yeast strategy for the initiation of replication is different from models of eukaryotic replication that propose coordinated origin firing.

Endogenous gamma-H2AX-ATM-Chk2 checkpoint activation in Bloom's syndrome helicase deficient cells is related to DNA replication arrested forks.

The Bloom syndrome helicase (BLM) is critical for genomic stability. A defect in BLM activity results in the cancer-predisposing Bloom syndrome (BS). Here, we report that BLM-deficient cell lines and primary fibroblasts display an endogenously activated DNA double-strand break checkpoint response with prominent levels of phosphorylated histone H2AX (gamma-H2AX), Chk2 (p(T68)Chk2), and ATM (p(S1981)ATM) colocalizing in nuclear foci. Interestingly, the mitotic fraction of gamma-H2AX foci did not seem to be higher in BLM-deficient cells, indicating that these lesions form transiently during interphase. Pulse labeling with iododeoxyuridine and immunofluorescence microscopy showed the colocalization of gamma-H2AX, ATM, and Chk2 together with replication foci. Those foci costained for Rad51, indicating homologous recombination at these replication sites. We therefore analyzed replication in BS cells using a single molecule approach on combed DNA fibers. In addition to a higher frequency of replication fork barriers, BS cells displayed a reduced average fork velocity and global reduction of interorigin distances indicative of an elevated frequency of origin firing. Because BS is one of the most penetrant cancer-predisposing hereditary diseases, it is likely that the lack of BLM engages the cells in a situation similar to precancerous tissues with replication stress. To our knowledge, this is the first report of high ATM-Chk2 kinase activation and its linkage to replication defects in a BS model.

DNA replication origin plasticity and perturbed fork progression in human inverted repeats.

The stability of metazoan genomes during their duplication depends on the spatiotemporal activation of origins and the progression of forks. Human rRNA genes represent a unique challenge to DNA replication since a large proportion of them exist as noncanonical palindromes in addition to canonical tandem repeats. Whether origin usage and/or fork elongation can cope with the variable structure of these genes is unknown. By analyzing single combed DNA molecules from HeLa cells, we studied the rRNA gene replication program according to the organization of canonical versus noncanonical rRNA genes. Origin positioning, spacing, and timing were not affected by the underlying rRNA gene physical structure. Conversely, fork arrest, both temporary and permanent, occurred more frequently when rRNA gene palindromes were encountered. These findings reveal that while initiation mechanisms are flexible enough to adapt to an rRNA gene structure of any arrangement, palindromes represent obstacles to fork progression, which is a likely source of genomic instability.

Identification of Tah11/Sid2 as the ortholog of the replication licensing factor Cdt1 in Saccharomyces cerevisiae.

Faithful duplication of the genetic material requires that replication origins fire only once per cell cycle. Central to this control is the tightly regulated formation of prereplicative complexes (preRCs) at future origins of DNA replication. In all eukaryotes studied, this entails loading by Cdc6 of the Mcm2-7 helicase next to the origin recognition complex (ORC). More recently, another factor, named Cdt1, was shown to be essential for Mcm loading in fission yeast and Xenopus as well as for DNA replication in Drosophila and humans. Surprisingly, no Cdt1 homolog was found in budding yeast, despite the conserved nature of origin licensing. Here we identify Tah11/Sid2, previously isolated through interactions with topoisomerase and Cdk inhibitor mutants, as an ortholog of Cdt1. We show that sid2 mutants lose minichromosomes in an ARS number-dependent manner, consistent with ScCdt1/Sid2 being involved in origin licensing. Accordingly, cells partially depleted of Cdt1 replicate DNA from fewer origins, whereas fully depleted cells fail to load Mcm2 on chromatin and fail to initiate but not elongate DNA synthesis. We conclude that origin licensing depends in S. cerevisiae as in other eukaryotes on both Cdc6 and Cdt1.

Genomic organization of amplified MYC genes suggests distinct mechanisms of amplification in tumorigenesis.

Integration of the human papillomavirus (HPV) genome into the host genome is associated with the disruption of the HPV E2 gene and with amplification and rearrangement of the viral and flanking cellular sequences. Molecular characterization of the genomic structures of coamplified HPV sequences and oncogenes provides essential information concerning the mechanisms of amplification and their roles in carcinogenesis. Using fluorescent hybridization on stretched DNA molecules in two cervical cancer-derived cell lines, we have elucidated the genomic structures of amplified regions containing HPV/myc genes over several hundreds of kilobases. Direct visualization of hybridization signals on individual DNA molecules suggests that overreplication and breakage-fusion-bridge-type mechanisms are involved in the genomic instability associated with HPV cervical cancers. Further analysis from two other genital cancer-derived cell lines reveals a recurrent motif of amplification, probably generated by a common mechanism involving overreplication upon viral integration. Interestingly, different amplification patterns seem to be correlated with the disease outcome, thus providing new insights into HPV-related cancer development and tumor progression.

Methods to study replication fork collapse in budding yeast.

Replication of the eukaryotic genome is a difficult task, as cells must coordinate chromosome replication with chromatin remodeling, DNA recombination, DNA repair, transcription, cell cycle progression, and sister chromatid cohesion. Yet, DNA replication is a potentially genotoxic process, particularly when replication forks encounter a bulge in the template: forks under these conditions may stall and restart or even break down leading to fork collapse. It is now clear that fork collapse stimulates chromosomal rearrangements and therefore represents a potential source of DNA damage. Hence, the comprehension of the mechanisms that preserve replication fork integrity or that promote fork collapse are extremely relevant for the understanding of the cellular processes controlling genome stability. Here we describe some experimental approaches that can be used to physically visualize the quality of replication forks in the yeast S. cerevisiae and to distinguish between stalled and collapsed forks.

Molecular Combing of Single DNA Molecules on the 10 Megabase Scale.

DNA combing allows the investigation of DNA replication on genomic single DNA molecules, but the lengths that can be analysed have been restricted to molecules of 200-500 kb. We have improved the DNA combing procedure so that DNA molecules can be analysed up to the length of entire chromosomes in fission yeast and up to 12 Mb fragments in human cells. Combing multi-Mb-scale DNA molecules revealed previously undetected origin clusters in fission yeast and shows that in human cells replication origins fire stochastically forming clusters of fired origins with an average size of 370 kb. We estimate that a single human cell forms around 3200 clusters at mid S-phase and fires approximately 100,000 origins to complete genome duplication. The procedure presented here will be adaptable to other organisms and experimental conditions.

Combining combing and secondary ion mass spectrometry to study DNA on chips using (13)C and (15)N labeling.

Dynamic secondary ion mass spectrometry ( D-SIMS) imaging of combed DNA - the combing, imaging by SIMS or CIS method - has been developed previously using a standard NanoSIMS 50 to reveal, on the 50 nm scale, individual DNA fibers labeled with different, non-radioactive isotopes in vivo and to quantify these isotopes. This makes CIS especially suitable for determining the times, places and rates of DNA synthesis as well as the detection of the fine-scale re-arrangements of DNA and of molecules associated with combed DNA fibers. Here, we show how CIS may be extended to (13)C-labeling via the detection and quantification of the (13)C (14)N (-) recombinant ion and the use of the (13)C: (12)C ratio, we discuss how CIS might permit three successive labels, and we suggest ideas that might be explored using CIS.