Nathalie Bastien

Influence of cytosine methylation on ultraviolet-induced cyclobutane pyrimidine dimer formation in genomic DNA.

The ultraviolet (UV) component of sunlight is the main cause of skin cancer. More than 50% of all non-melanoma skin cancers and >90% of squamous cell carcinomas in the US carry a sunlight-induced mutation in the p53 tumor suppressor gene. These mutations have a strong tendency to occur at methylated cytosines. Ligation-mediated PCR (LMPCR) was used to compare at nucleotide resolution DNA photoproduct formation at dipyrimidine sites either containing or lacking a methylated cytosine. For this purpose, we exploited the fact that the X chromosome is methylated in females only on the inactive X chromosome, and that the FMR1 (fragile-X mental retardation 1) gene is methylated only in fragile-X syndrome male patients. Purified genomic DNA was irradiated with UVC (254nm), UVB (290-320nm) or monochromatic UVB (302 and 313nm) to determine the effect of different wavelengths on cyclobutane pyrimidine dimer (CPD) formation along the X-linked PGK1 (phosphoglycerate kinase 1) and FMR1 genes. We show that constitutive methylation of cytosine increases the frequency of UVB-induced CPD formation by 1.7-fold, confirming that methylation per se is influencing the probability of damage formation. This was true for both UVB sources used, either broadband or monochromatic, but not for UVC. Our data prove unequivocally that following UVB exposure methylated cytosines are significantly more susceptible to CPD formation compared with unmethylated cytosines.

Human cells bearing homozygous mutations in the DNA mismatch repair genes hMLH1 or hMSH2 are fully proficient in transcription-coupled nucleotide excision repair

The transcription-coupled nucleotide excision repair (TCNER) pathway maintains genomic stability by rapidly eliminating helix-distorting DNA adducts, such as UV-induced cyclobutane pyrimidine dimers (CPDs), specifically from the transcribed strands of active genes. DNA mismatch repair (MMR) constitutes yet another critical antimutagenic pathway that removes mispaired bases generated during semiconservative replication. It was previously reported that the human colon adenocarcinoma strains HCT116 and LoVo (bearing homozygous mutations in the MMR genes hMLH1 and hMSH2, respectively), besides manifesting hallmark phenotypes associated with defective DNA mismatch correction, are also completely deficient in TCNER of UV-induced CPDs. This revealed a direct mechanistic link between MMR and TCNER in human cells, although subsequent studies have either supported, or argued against, the validity of this important notion. Here, the ligation-mediated polymerase chain reaction was used to show at nucleotide resolution that MMR-deficient HCT116 and LoVo retain the ability to excise UV-induced CPDs much more rapidly from the transcribed vs the nontranscribed strands of active genes. Moreover, relative to DNA repair-proficient counterparts, MMR-deficient cells were not more sensitive to the cytotoxic effects of UV, and displayed equal ability to recover mRNA synthesis following UV challenge. These results conclusively demonstrate that hMLH1- and hMSH2-deficient human colon adenocarcinoma cells are fully proficient in TCNER.

p53 Pre- and Post-Binding Event Theories Revisited: Stresses Reveal Specific and Dynamic p53-Binding Patterns on the p21 Gene Promoter

p53 is a master transcription factor that prevents neoplasia and genomic instability. It is an important target for anticancer drug design. Understanding the molecular mechanisms behind its transcriptional activities in normal cells is a prerequisite to further understand the deregulation effected by mutant p53 in cancerous cells. Currently, how p53 coordinates transcription programs in response to stress remains unclear. One theory proposes that stresses induce pre-binding events that direct p53 to bind to specific response elements, whereas a second posits that, in response to stress, p53 binds most response elements and post-binding events then regulate transcription initiation. It is critical to establish the relevance of both theories and investigate whether stresses induce specific p53-binding patterns correlated with effector gene induction. Using unique in cellulo genomic footprinting experiments, we studied p53 binding to the five response elements of p21 in response to stresses and monitored p21 mRNA variant transcription. We show clear footprints of p53 bound to response elements in living cells and reveal that the binding of p53 to response elements is transient, subject to dynamic changes during stress responses, and influenced by response element pentamer orientations. We show further that stresses lead to specific p53-binding patterns correlated with particular p21 mRNA variant transcription profiles and that p53 binding is necessary but not sufficient to induce p21 transcription. Our results indicate that pre- and post-binding events act together to regulate adapted stress responses; this paves the way to the unification of pre- and post-binding event theories.

The 3895-bp mitochondrial DNA deletion in the human eye: a potential involvement in corneal ageing and macular degeneration

In human skin, the 3895-bp deletion of mitochondrial DNA (mtDNA(3895)) is catalysed by ultraviolet (UV) light through the generation of reactive oxygen species. Given its function in vision, the human eye is exposed to oxidising UV and blue light in its anterior (cornea, iris) and posterior (retina) structures. In this study, we employed a highly sensitive quantitative PCR technique to determine mtDNA(3895) occurrence in human eye. Our analysis shows that the mtDNA(3895) is concentrated in both the cornea and the retina. Within the cornea, the highest mtDNA(3895) level is found in the stroma, the cellular layer conferring transparency and rigidity to the human cornea. Moreover, mtDNA(3895) accumulates with age in the stroma, suggesting a role of this deletion in corneal ageing. Within the retina, mtDNA(3895) is concentrated in the macular region of both the neural retina and the retinal pigment epithelium, supporting the hypothesis that this deletion is implicated in retinal pathologies such as age-related macular degenerescence. Taken together, our results imply that UV and blue light catalyse mtDNA(3895) induction in the human eye.

Mitochondrial DNA common deletion in the human eye: A relation with corneal aging

The most frequent mitochondrial DNA (mtDNA) mutation is a 4977 bp deletion known as the common deletion (mtDNA(CD4977)). mtDNA(CD4977) is related to skin photo-aging and to chronological aging of cells with high-energy demands such as neurons and muscle cells. The human eye contains both sun-exposed (cornea, iris) and high-energy demand structures (retina). In this study, we employed a highly sensitive quantitative PCR technique to determine mtDNA(CD4977) occurrence in different structures of the human eye. We found that the cornea, the most anterior structure of the eye, contains the highest amount of mtDNA(CD4977) (2.6%, 0.25% and 0.06% for the cornea, iris and retina, respectively). Within the cornea, mtDNA(CD4977) is almost exclusively found in the stroma, the cellular layer conferring transparency and rigidity to the human cornea (8.59%, 0.13% and 0.05% in the stroma, endothelium and epithelium, respectively). Moreover, we show that mtDNA(CD4977) accumulates with age in the corneal stroma. Taken together, our results suggest that mtDNA(CD4977) is related to photo-aging rather than chronological aging in the human eye. Similar to the involvement of mtDNA(CD4977) in skin photo-aging phenotypes, we believe that the clinical manifestations of corneal aging, including clouding and stiffening, are associated with the accumulation of mtDNA(CD4977) in the corneal stroma.

Pyrimidine (6-4) pyrimidone photoproduct mapping after sublethal UVC doses: nucleotide resolution using terminal transferase-dependent PCR.

Abstract UVC irradiation of genomic DNA induces two main types of potentially mutagenic base modifications: cyclobutane pyrimidine dimers (CPDs) and the less frequent (15–30% of CPD levels) pyrimidine (6-4) pyrimidone photoproducts (6-4PP). Ligation-mediated PCR (LMPCR), a genomic sequencing technique, allows CPD mapping at nucleotide resolution following irradiation with sublethal doses of UVB or UVC for most cell types. In contrast, a dose of 80 J/m2 of UVC that is lethal for the majority of cell types is necessary to map 6-4PP by the LMPCR technique. This compromises the use of LMPCR to study the repair of 6-4PP. To date, no other techniques have been developed to study 6-4PP repair at nucleotide resolution. We have therefore adapted a recently developed technique for the mapping of 6-4PP: terminal transferase-dependent PCR (TDPCR). TDPCR is in many ways similar to LMPCR. This technique is more sensitive and allows the mapping of 6-4PP at UVC doses as low as 10 J/m2 in genomic DNA and in living cells.

In cellulo DNA analysis (LMPCR footprinting).

The in cellulo analysis of DNA protein interactions and chromatin structure is very important to better understand the mechanisms involved in the regulation of gene expression. The nuclease-hypersensitive sites and sequences bound by transcription factors often correspond to genetic regulatory elements. Using the Ligation-mediated polymerase chain reaction (LMPCR) technology, it is possible to precisely analyze these DNA sequences to demonstrate the existence of DNA-protein interactions or unusual DNA structures directly in living cells. Indeed, the ideal chromatin substrate is, of course, found inside intact cells. LMPCR, a genomic-sequencing, technique that map DNA single-strand breaks at the sequence level of resolution, is the method of choice for in cellulo footprinting and DNA structure studies because it can be used to investigate any complex genomes, including human. The detailed conventional and automated LMPCR protocols are presented in this chapter.

Expression of Genes Associated with Telomere Homeostasis in TP53 Mutant LoVo Cell Lines as a Model for Genomic Instability

We describe a method that assesses the impact of specific mutations of TP53 and genomic instability on gene expression of the most important genes involved in telomere length and structure homeostasis. The approaches consist of using a reverse transcriptase method and a quantitative PCR that were applied to isogenic cell lines from a colon cancer.

Study of Telomere Dysfunction in TP53 Mutant LoVo Cell Lines as a Model for Genomic Instability

Telomere restriction fragment, 3D quantitative FISH on nuclei, and quantitative FISH on metaphases are complementary approaches that explore telomere dysfunction genomically, cellularly, and chromosomally, respectively. We used these approaches to study association between telomere dysfunction and degree of genomic instability related to TP53 mutations in LoVo isogenic cell lines. We found a strong correlation between degree of genomic instability, telomere dysfunction, and specific mutations of TP53. The use of complementary approaches to study telomere biology is essential to have a comprehensive understanding of telomere involvement in genomic instability.