Three-Dimensional Nuclear Telomere Profiling as a Biomarker for Recurrence in Oligodendrogliomas: A Pilot Study.

Mechanisms of recurrence in oligodendrogliomas are poorly understood. Recurrence might be driven by telomere dysfunction-mediated genomic instability. In a pilot study, we investigated ten patients with oligodendrogliomas at the time of diagnosis (first surgery) and after recurrence (second surgery) using three-dimensional nuclear telomere analysis performed with quantitative software TeloView® (Telo Genomics Corp, Toronto, Ontario, Canada). 1p/19q deletion status of each patient was determined by fluorescent in situ hybridization on touch preparation slides. We found that a very specific 3D telomeric profile was associated with two pathways of recurrence in oligodendrogliomas independent of their 1p/19q status: a first group of 8 patients displayed significantly different 3D telomere profiles between both surgeries (p < 0.0001). Their recurrence happened at a mean of 231.375 ± 117.42 days and a median time to progression (TTP) of 239 days, a period defined as short-term recurrence; and a second group of three patients displayed identical 3D telomere profiles between both surgery samples (p > 0.05). Their recurrence happened at a mean of 960.666 ± 86.19 days and a median TTP of 930 days, a period defined as long-term recurrence. Our results suggest a potential link between nuclear telomere architecture and telomere dysfunction with time to recurrence in oligodendrogliomas, independently of the 1p/19q status.

Reproductive outsourcing: an empirical ethics account of cross-border reproductive care in Canada.

Cross-border reproductive care (CBRC) can be defined as the movement from one jurisdiction to another for medically assisted reproduction (MAR). CBRC raises many ethical concerns that have been addressed extensively. However, the conclusions are still based on scarce evidence even considering the global scale of CBRC. Empirical ethics appears as a way to foster this ethical reflection on CBRC while attuning it with the experiences of its main actors. To better understand the 'in and out' situation of CBRC in Canada, we conducted an ethnographic study taking a 'critically applied ethics' approach. This article presents a part of the findings of this research, obtained by data triangulation from qualitative analysis of pertinent literature, participant observation in two Canadian fertility clinics and 40 semidirected interviews. Based on participants' perceptions, four themes emerged: (1) inconsistencies of the Canadian legal framework; (2) autonomy and the necessity to resort to CBRC; (3) safety and the management of CBRC individual risks; and (4) justice and solidarity. The interaction between these four themes highlights the problematic of 'reproductive outsourcing' that characterised the Canadian situation, a system where the controversial aspects of MAR are knowingly pushed outside the borders.

Functional organization of an Mbp enhancer exposes striking transcriptional regulatory diversity within myelinating glia.

In mammals, large caliber axons are ensheathed by myelin, a glial specialization supporting axon integrity and conferring accelerated and energy-efficient action potential conduction. Myelin basic protein (MBP) is required for normal myelin elaboration with maximal mbp transcription in oligodendrocytes requiring the upstream M3 enhancer. To further characterize the mechanism regulating mbp transcription, we defined M3 structure/function relationships by evaluating its evolutionary conservation, DNA footprints and the developmental programing conferred in mice by M3 derivatives. Multiple M3 regulatory element combinations were found to drive expression in oligodendrocytes and Schwann cells with a minimal 129 bp sequence conferring expression in oligodendrocytes throughout myelin elaboration, maintenance and repair. Unexpectedly, M3 derivatives conferred markedly different spatial and temporal expression programs thus illuminating striking transcriptional heterogeneity within post-mitotic oligodendrocytes. Finally, one M3 derivative engaged only during primary myelination, not during adult remyelination, demonstrating that transcriptional regulation in the two states is not equivalent.

Three new cases of terminal deletion of the long arm of chromosome 7 and literature review to correlate genotype and phenotype manifestations.

Partial monosomy of the long arm of chromosome 7 has been characterized by wide phenotypic manifestations, but holoprosencephaly (HPE) and sacral agenesis have frequently been associated with this chromosomal deletion. A clear relationship between genotype and phenotype remains to be defined in the 7q deletion syndrome. Three patients (1, 2, and 3) were investigated with 7q terminal deletion and compared with similar deletion cases in the literature in order to stratify the phenotypes associated with 7q35 and 7q36 terminal deletion patients. Patients 1, 2, and 3 were carrying a de novo terminal deletion at bands 7q36.2, 7q35, and 7q36.1, respectively. In patient 3, a small Xq28 duplication was also identified by array-CGH. Our patients presented with heterogeneous phenotypic manifestations, which could imply the possible role of environmental factors (multifactorial inheritance), structural variations in the non-coding regions, penetrance, and/or polymorphism. The varying length of deletion was also taken into account. Growth retardation was the most frequent symptom found in both 7q35 and 7q36 patients we reviewed. The occurrence of HPE and sacral malformation together was seen in less than 10% of the reviewed cases in both kinds of deletion. HPE was associated mainly in cases with an unbalanced translocation.

Rapid Aneuploidy Detection of Chromosomes 13, 18, 21, X and Y Using Quantitative Fluorescent Polymerase Chain Reaction with Few Microdissected Fetal Cells.

OBJECTIVES: Analysis of DNA from small numbers of cells, such as fetal cells in maternal blood, is a major limiting factor for their use in clinical applications. Traditional methods of single-cells whole genome amplification (SCs-WGA) and accurate analysis have been challenging to date. Our purpose was to assess the feasibility of using a few fetal cells to determine fetal sex and major chromosomal abnormalities by quantitative fluorescent polymerase chain reaction (QF-PCR). METHODS: Cultured cells from 26 amniotic fluid samples were used for standard DNA extraction and recovery of 5 fetal cells by laser-capture microdissection. SCs-WGA was performed using the DNA from the microdissected cells. PCR amplification of short tandem repeats specific for chromosomes 13, 18, 21, X and Y was performed on extracted and amplified DNA. Allele dosage and sexing were quantitatively analyzed following separation by capillary electrophoresis. RESULTS: Microsatellite QF-PCR analysis showed high concordance in chromosomal copy number between extracted and amplified DNA when 5 or more cells were used. Results were in concordance with that of conventional cytogenetic analysis. CONCLUSION: Satisfactory genomic coverage can be obtained from SCs-WGA. Clinically, SCs-WGA coupled with QF-PCR can provide a reliable, accurate, rapid and cost-effective method for detection of major fetal chromosome abnormalities.

Different TP53 mutations are associated with specific chromosomal rearrangements, telomere length changes, and remodeling of the nuclear architecture of telomeres.

TP53 mutations are the most common mutations in human cancers, and TP53-R175H and TP53-R273H are the most frequent. The impact of these mutations on genomic instability after tumor initiation is still uncovered. To gain insight into this, we studied the effects of three specific TP53 mutants (TP53-V143A, TP53-R175H, and TP53-R273H) on genomic instability using four isogenic lines of LoVo cells. Multicolor fluorescence in situ hybridization (FISH), three-dimensional (3D) quantitative FISH (Q-FISH) on interphase and Q-FISH on metaphases were used to investigate genomic instability. We found that LoVo cells expressing mutant TP53-R175H displayed the highest level of chromosomal instability among the LoVo cell lines. Furthermore, we observed that mutant TP53-R175H and TP53-V143A showed more alterations in their 3D nuclear architecture of telomeres than the mutant TP53-R273H and the wild type. Moreover, we noted an association between some chromosomal abnormalities and telomere elongation in the mutant TP53-R175H. Taken together, our results indicate that the mutation TP53-R175H is more likely to cause higher levels of genomic instability than the other TP53 mutations. We proposed that the type of TP53 mutations and the genetic background of a cancer cell are major determinants of the TP53-dependent genomic instability.

Strengths and pitfalls of Canadian gamete and embryo donor registries: searching for beneficent solutions.

For the gamete and embryo donation community, it is well recognized that the implementation of a gamete and embryo donor registry (GEDR) represents a good initiative to ensure the best possible health conditions for donor-conceived individuals. Be they national, institutional or independent, GEDR can play a major role in the transmission of health-related genetic and medical information. However, from a bioethical analysis standpoint, GEDR raise many questions regarding the extent of their beneficent nature. Based on the recent Canadian GEDR aborted attempt, this article will focus on bioethical issues and paradoxes that can impact the wellbeing of donor-conceived individuals, half-siblings, donors and parents. On one hand, the implementation of a GEDR can be ethically justified as a beneficent action towards lessening harm associated with the transmission of hereditary disease and increasing the effectiveness of preventive and therapeutic approaches. On the other hand, examined through the concept of nonpaternalistic beneficence, GEDR challenge us to recognize beneficiaries' free agency, as well as the importance to transmit reliable and pertinent information. Ultimately, beyond an individualistic application of the principle of beneficence, socioethics invite us to consider consistency with societal values as a prerequisite for achieving a common good. Because the issue of whether or not to protect the donor's anonymity occupies the forefront of the discussion surrounding gamete and embryo donation, there is less interest in other initiatives, which may be implemented to ensure the best possible medical and psychosocial conditions for donor-conceived individuals. In this article, we propose a bioethical analysis of the use of gamete and embryo donor registries (GEDR) from the angle of the principle of beneficence. More specifically, we will concentrate on the Canadian situation regarding GEDR. We will look at the strengths and pitfalls of this mechanism and suggest a solution to maximize the benefits of a GEDR. Many have suggested that such an initiative could have a beneficial impact on the wellbeing of donor-conceived individuals, half-siblings, donors and parents, by ensuring the constant flow of health-related medical and genetic information. As self-evident as the social acceptability of a GEDR may seem, we wish to show the limitations of the benefits that a registry is supposed to provide. We argue that a GEDR has to do more than simply transmit health-related information between parties. It also has to be based on pertinent and reliable data, be useful for health promotion and recognize beneficiaries' free agency. Ultimately, the implementation of a GEDR has to take into consideration wider social values.

Evaluation of the impact of density gradient centrifugation on fetal cell loss during enrichment from maternal peripheral blood.

OBJECTIVE: Physical separation by density gradient centrifugation (DGC) is usually used as an initial step of multistep enrichment protocols for purification of fetal cells (FCs) from maternal blood. Many protocols were designed but no single approach was efficient enough to provide noninvasive prenatal diagnosis. Procedures and methods were difficult to compare because of the nonuniformity of protocols among different groups. Recovery of FCs is jeopardized by their loss during the process of enrichment. Any loss of FCs must be minimized because of the multiplicative effect of each step of the enrichment process. The main objective of this study was to evaluate FC loss caused by DGC. METHODS: Fetal cells were quantified in peripheral blood samples obtained from both euploid and aneuploid pregnancies before and after enrichment by buoyant DGC using Histopaque 1.119 g/mL. RESULTS: Density gradient centrifugation results in major loss of 60% to 80% of rare FCs, which may further complicate subsequent enrichment procedures. Eliminating aggressive manipulations can significantly minimize FC loss. CONCLUSION: Data obtained raise questions about the appropriateness of the DGC step for the enrichment of rare FCs and argues for the use of the alternative nonaggressive version of the procedure presented here or prioritizing other methods of enrichments.

Validation of automatic scanning of microscope slides in recovering rare cellular events: application for detection of fetal cells in maternal blood.

OBJECTIVE: Detection of rare fetal cells (FCs) in the maternal circulation could be used for non-invasive prenatal diagnosis. Considering that FCs in maternal blood are present in extremely low frequency, manual scanning is cumbersome, time-consuming, and unsuitable for clinical applications. As an alternative, we optimized a custom-made classifier for automatic detection of FCs. METHODS: Using MetaSystems' automated platform, we developed a robust detection algorithm and validated its efficiency on retrieval of rare XY cells in a pure population of XX cells. Slides were scanned for presence of predefined XY cells after fluorescence in situ hybridization (FISH) and primed in situ labeling (PRINS). Retrieval of FCs was also performed on samples from maternal blood. RESULTS: The efficiency of detection of rare XY cells was 88% using FISH (117/133) in comparison with 78% (53/68) with PRINS. FC frequencies per 1 mL of maternal blood ranged from 3 to 6 FCs in normal pregnancies versus 13 to 21 FCs in Down syndrome pregnancies. CONCLUSION: Automatic scanning was more efficient and consistent than manual scanning for detection of rare FCs and required considerably less operator time. Automatic scanning using FISH is more sensitive than that using PRINS. The study validates automatic scanning retrieval of FCs from maternal blood.

A new der(1;7)(q10;p10) leading to a singular 1p loss in a case of glioblastoma with oligodendroglioma component.

The combined 1p-/19q- deletions in oligodendrogliomas originate from translocation between both chromosomes. In the few cases of oligoastrocytomas and glioblastomas with an oligodendroglioma component (GBMO) where only 1p deletion was described, the origin remains unknown. We report the first case of GBMO, in which a single 1p deletion was detected and was linked to a translocation between chromosomes 1 and 7. Fresh surgical specimens were collected during surgery and the samples were used for cell culture, touch preparation smear slides (TP slides) and DNA extraction. Peripheral venous blood was also collected from the patient. G-banding using Trypsin and stained with Giemsa (GTG) banding and karyotyping were performed and 1p-/19q-, TP53, PTEN and c-MYC were analyzed by fluorescent in situ hybridization (FISH). Multicolor FISH (mFISH) and microsatellites analyses were also performed to complete the investigation. Three-dimensional quantitative FISH (3D-QFISH) of telomeres was performed on nuclei from TP slides and analyzed using TeloView(TM) to determine whether the 3D telomere profile as an assessment of telomere dysfunction and a characterization of genomic instability could predict the disease aggressiveness. An unbalanced chromosomal translocation was found in all metaphases and confirmed by mFISH. The karyotype of the case is: 50∼99,XXX, +der(1;7)(q10;p10),inc[47] The derivative chromosome was found in all 47 analyzed cells, but the number of derivatives varied from one to four. There was neither imbalance in copy number for genes TP53 and PTEN, nor amplification of c-MYC gene. We did not find loss of heterozygosity with analysis of microsatellite markers for chromosomes 1p and 19q in tumor cells. The 3D-telomere profile predicted a very poor prognostic and short-term survival of the patient and highlights the potential clinical power of telomere signatures as a solid biomarker of GBMO. Furthermore, this translocation between chromosomes 1 and 7 led to a singular 1p deletion in this GBMO and may generate the 1p and 7q deletions.

Differences between selective termination of pregnancy and fetal reduction in multiple pregnancy: a narrative review.

Although selective termination of pregnancy and fetal reduction in multiple pregnancy both involve the termination in utero of the development of live fetuses, these two procedures are different in several aspects. Nevertheless, several authors tend to amalgamate and confuse their psychosocial consequences and the ethical issues they raise. Therefore, this narrative review, derived from a comparative analysis of 91 articles, shines a light on these amalgamations and confusions, as well as on the medical, contextual, experiential and ethical differences specific to selective termination and fetal reduction.

Cytosine containing dipyrimidine sites can be hotspots of cyclobutane pyrimidine dimer formation after UVB exposure.

Exposure to the UV component of sunlight is the principal factor leading to skin cancer development. Cyclobutane pyrimidine dimers (CPD) are considered to be the most important pre-mutagenic type of DNA damage involved in skin carcinogenesis. To better understand the biological mechanisms of UV carcinogenesis, it is critical to understand the CPD distribution between the four types of dipyrimidine sites. Most of our knowledge regarding CPD distribution comes from in vitro studies or from investigations using UVC, even though we are not naturally exposed to these UV wavelengths. We exposed normal human fibroblasts and purified DNA to UVB. Using ligation-mediated PCR, we quantified the CPD formation at 952 dipyrimidine sites among the PGK1 (phosphoglycerate kinase 1), JUN, HRAS, KRAS, NRAS and TP53 genes. In cellulo, we found a CPD distribution of 27 : 27 : 25 : 21 for TT : CC : TC : CT. This distribution is similar to that observed in vitro. In the analysed genes, we observed some extremely frequently damaged dipyrimidine sites and many of these occurred at potentially frequently mutated sites, i.e. at dipyrimidine sites containing cytosine. Also, most of the frequently damaged dipyrimidine sites in cellulo that are not frequently damaged in vitro are found on TP53 and NRAS. This indicates that many of the frequently damaged dipyrimidine sites in cellulo are on genes frequently mutated in skin cancer. All these results support the view that CPD are the main UVB-induced mutagenic photoproducts and provide evidence of the importance of CPD formation at sites containing cytosine.

Formation of stress-specific p53 binding patterns is influenced by chromatin but not by modulation of p53 binding affinity to response elements.

The p53 protein is crucial for adapting programs of gene expression in response to stress. Recently, we revealed that this occurs partly through the formation of stress-specific p53 binding patterns. However, the mechanisms that generate these binding patterns remain largely unknown. It is not established whether the selective binding of p53 is achieved through modulation of its binding affinity to certain response elements (REs) or via a chromatin-dependent mechanism. To shed light on this issue, we used a microsphere assay for protein-DNA binding to measure p53 binding patterns on naked DNA. In parallel, we measured p53 binding patterns within chromatin using chromatin immunoprecipitation and DNase I coupled to ligation-mediated polymerase chain reaction footprinting. Through this experimental approach, we revealed that UVB and Nutlin-3 doses, which lead to different cellular outcomes, induce similar p53 binding patterns on naked DNA. Conversely, the same treatments lead to stress-specific p53 binding patterns on chromatin. We show further that altering chromatin remodeling using an histone acetyltransferase inhibitor reduces p53 binding to REs. Altogether, our results reveal that the formation of p53 binding patterns is not due to the modulation of sequence-specific p53 binding affinity. Rather, we propose that chromatin and chromatin remodeling are required in this process.

Update of PAX2 mutations in renal coloboma syndrome and establishment of a locus-specific database.

Renal coloboma syndrome, also known as papillorenal syndrome is an autosomal-dominant disorder characterized by ocular and renal malformations. Mutations in the paired-box gene, PAX2, have been identified in approximately half of individuals with classic findings of renal hypoplasia/dysplasia and abnormalities of the optic nerve. Prior to 2011, there was no actively maintained locus-specific database (LSDB) cataloguing the extent of genetic variation in the PAX2 gene and phenotypic variation in individuals with renal coloboma syndrome. Review of published cases and the collective diagnostic experience of three laboratories in the United States, France, and New Zealand identified 55 unique mutations in 173 individuals from 86 families. The three clinical laboratories participating in this collaboration contributed 28 novel variations in 68 individuals in 33 families, which represent a 50% increase in the number of variations, patients, and families published in the medical literature. An LSDB was created using the Leiden Open Variation Database platform: www.lovd.nl/PAX2. The most common findings reported in this series were abnormal renal structure or function (92% of individuals), ophthalmological abnormalities (77% of individuals), and hearing loss (7% of individuals). Additional clinical findings and genetic counseling implications are discussed.

Efficiency of manual scanning in recovering rare cellular events identified by fluorescence in situ hybridization: simulation of the detection of fetal cells in maternal blood.

Fluorescence in situ hybridization (FISH) and manual scanning is a widely used strategy for retrieving rare cellular events such as fetal cells in maternal blood. In order to determine the efficiency of these techniques in detection of rare cells, slides of XX cells with predefined numbers (1-10) of XY cells were prepared. Following FISH hybridization, the slides were scanned blindly for the presence of XY cells by different observers. The average detection efficiency was 84% (125/148). Evaluation of probe hybridization in the missed events showed that 9% (2/23) were not hybridized, 17% (4/23) were poorly hybridized, while the hybridization was adequate for the remaining 74% (17/23). In conclusion, manual scanning is a relatively efficient method to recover rare cellular events, but about 16% of the events are missed; therefore, the number of fetal cells per unit volume of maternal blood has probably been underestimated when using manual scanning.

p53 functions and cell lines: have we learned the lessons from the past?

p53 has a determinant role in cancer prevention and is among the most studied proteins in the world. The majority of studies devoted to this protein are carried out in cell lines because they are easy to use and have naturally emerged as the main research tool in laboratories. However, the p53 pathway is commonly deregulated in cancer cells, from which the experimental cell lines are generally derived. The fact that the pathway is deregulated challenges the relevance of using cancer-derived cell lines to study wild-type p53 activities, or, in a broader sense, to study any normal cellular process. In the present article, we identify and discuss a number of limitations of cell lines using examples related to p53. Finally, we point out the general limitations of cell lines and propose solutions as alternatives to these cells.

Early diagnosis and successful long-term management of a rare, severe lysosomal acid lipase deficiency/Wolman disease patient: Infancy to age five.

Background: This report describes a unique case of long-term survival of a young girl who was diagnosed with severe, rapidly progressive lysosomal acid lipase deficiency (LAL-D; historically "Wolman disease") at three months of age and began receiving therapeutic interventions at four months of age. This disease involves rapidly progressive multisystemic impairments and limited survival (6-12 months) without treatment. Methods: Case report taking into account clinical aspects and patient management including a semi-structured interview with the main family caregiver. Results: Presentation at two months of age: severe malnutrition and chronic diarrhea; hypoalbuminemia; low iron, vitamin A, and vitamin D levels; high triglyceride levels; profound anemia; thrombocytopenia; adrenal calcifications; and mild hepatosplenomegaly. Enzyme replacement therapy (ERT) with sebelipase alfa, parenteral nutrition, and a low-fat diet began at age four months. The patient has received sebelipase alfa for >5 years with good tolerability and is thriving, with a body mass index of 16.35 kg/m2 (80th percentile) despite a stature delay (height <3rd percentile), and mild developmental delay. Optimal medical management requires that family caregivers and health professionals have the knowledge and skills to provide appropriate care and supports multidisciplinary teams through transfer of knowledge to all stakeholders. Effective coordination of services and activities related to child health and development, including navigation of administrative and financial barriers, is also imperative. Conclusions: Formerly fatal in untreated infants, severe LAL-D, when diagnosed early, can be promptly and effectively treated by combining sebelipase alfa ERT, modified diet, involvement of family caregivers, and multidisciplinary team collaboration.

Disruption of AP1S1, causing a novel neurocutaneous syndrome, perturbs development of the skin and spinal cord.

Adaptor protein (AP) complexes regulate clathrin-coated vesicle assembly, protein cargo sorting, and vesicular trafficking between organelles in eukaryotic cells. Because disruption of the various subunits of the AP complexes is embryonic lethal in the majority of cases, characterization of their function in vivo is still lacking. Here, we describe the first mutation in the human AP1S1 gene, encoding the small subunit sigma1A of the AP-1 complex. This founder splice mutation, which leads to a premature stop codon, was found in four families with a unique syndrome characterized by mental retardation, enteropathy, deafness, peripheral neuropathy, ichthyosis, and keratodermia (MEDNIK). To validate the pathogenic effect of the mutation, we knocked down Ap1s1 expression in zebrafish using selective antisens morpholino oligonucleotides (AMO). The knockdown phenotype consisted of perturbation in skin formation, reduced pigmentation, and severe motility deficits due to impaired neural network development. Both neural and skin defects were rescued by co-injection of AMO with wild-type (WT) human AP1S1 mRNA, but not by co-injecting the truncated form of AP1S1, consistent with a loss-of-function effect of this mutation. Together, these results confirm AP1S1 as the gene responsible for MEDNIK syndrome and demonstrate a critical role of AP1S1 in development of the skin and spinal cord.

Calvarial doughnut lesions with bone fragility in a French-Canadian family; case report and review of the literature.

Calvarial Doughnut Lesions with Bone Fragility (CDL) is an autosomal dominant genetic disease, characterized by low bone mineral density, multiple fractures starting in childhood, and sclerotic doughnut-shaped lesions in the cranial bones. Aubé and colleagues described in 1988 a French-Canadian family of 12 affected members who had a clinical diagnosis of doughnut lesions of the skull, with pathological fractures, osteopenia, "bone in bone" in the vertebral bodies and squaring of metatarsal and metacarpal bones. Herein we study new members of this family. Sequential genetic testing identified a nonsense variant c.148C>T, p. Arg50⁎ in SGMS2 previously reported in other families. SGMS2 encodes Sphingomyelin Synthase 2, which produces Sphingomyelin (SM), a major lipid component of the plasma membrane that plays a role in bone mineralization. The nonsense variant is associated with milder phenotype. The proband presents with bone in bone vertebral appearance that had been defined uniquely in the first cases described in the same family. The proband's son was identified to carry the same variant, which makes him the sixth generation with the diagnosis of CDL. We also report that the same pathogenic variant was identified in another previously described family, from France. These reports further confirm the genetic basis of CDL, the recurrence of the same variant (p.Arg50*) in individuals of the same ancestry, and the variable penetrance of some of the clinical findings.

[Mapping DNA damage to understand somatic mutagenesis]. / Comprendre la mutagenèse somatique grâce à la cartographie des dommages à l'ADN.

Somatic mutation theory explains how DNA damage can lead to the malignant transformation of cells. It therefore elucidates the connection between genotoxic agents and cancers. Mutational spectra, which tend to be characteristic of a cancer type, are available for certain genes like p53 which is frequently mutated in tumors. A mutational spectrum could therefore be the signature of the genotoxic agent(s) at the origin of the malignant transformation. Ligation-mediated PCR (LMPCR) is a genomic sequencing method that can be used for the mapping of DNA damage at nucleotide resolution. Such a mapping can then be compared to a mutational spectrum to test the hypothesis that implies one agent can cause mutations into one cancer type. LMPCR has been used this way to map DNA damage generated by different UV wavelengths. The frequently damaged sites following UVB irradiation correlate with the mutational spectrum of p53 in skin cancer. Similarly, BPDE, the activated form of the benzo[a]pyrene present in tobacco smoke, generates frequent adducts at sites corresponding to mutation hotspots of p53 in lung cancers. Still, the correlation between BPDE damage sites and p53 mutations is not perfect and this suggests a role of other genotoxic substances that are also present in tobacco smoke, such as the nitrosamine NNK. Finally, and beyond this objective of better understanding somatic mutagenesis, LMPCR is commonly used whenever DNA damage frequency and/or repair is to be investigated.