Project description:In this study, we compared the genomic landscape of resistant cell line HaCaT/SM to its progenitor HaCaT in order to gain insights into genetic changes associated with continuous alkylation and oxidative stress. We established chromosome numbers by cytogenetics, analyzed DNA copy number changes by means of array CGH, employed the genome-wide chromosome conformation capture technique Hi-C to detect chromosomal translocations and defined mutational signatures based on whole genome sequencing data. We observed the SM-associated elimination of the initially prevailing hypotetraploid cell population in favor of a hyperdiploid one, which contrasts with previous observations that link polyploidization to increased tolerance and adaptability towards genotoxic stress. Furthermore, we observed an accumulation of chromosomal translocations, frequently flanked by DNA copy number changes, which indicates a high rate of DNA double strand break misrepair. HaCaT/SM-specific single nucleotide variants showed enrichment of C>A and T>A transversions and a lower rate of deaminated cytosines in the CpG dinucleotide context. Given the frequent use of HaCaT in toxicology this study provides a valuable data source with respect to the original genotype of HaCaT and the mutational signatures associated with chronic alkylation and oxidative stress.

Project description:In this study, we compared the genomic landscape of resistant cell line HaCaT/SM to its progenitor HaCaT in order to gain insights into genetic changes associated with continuous alkylation and oxidative stress. We established chromosome numbers by cytogenetics, analyzed DNA copy number changes by means of array CGH, employed the genome-wide chromosome conformation capture technique Hi-C to detect chromosomal translocations and defined mutational signatures based on whole genome sequencing data. We observed the SM-associated elimination of the initially prevailing hypotetraploid cell population in favor of a hyperdiploid one, which contrasts with previous observations that link polyploidization to increased tolerance and adaptability towards genotoxic stress. Furthermore, we observed an accumulation of chromosomal translocations, frequently flanked by DNA copy number changes, which indicates a high rate of DNA double strand break misrepair. HaCaT/SM-specific single nucleotide variants showed enrichment of C>A and T>A transversions and a lower rate of deaminated cytosines in the CpG dinucleotide context. Given the frequent use of HaCaT in toxicology this study provides a valuable data source with respect to the original genotype of HaCaT and the mutational signatures associated with chronic alkylation and oxidative stress.

Project description:The goal of this study is to find out the exact mechanisms of action of silymarin (SM), a complex mixture of flavonolignans structures isolated from milk thistle (Silybum marianum), on the biological behavior (phenotype) of human HaCaT keratinocytes.

Project description:Large scale analysis of balanced chromosomal translocation breakpoints has shown nonhomologous end joining and microhomology-mediated repair to be the main drivers of interchromosomal structural aberrations. Breakpoint sequences of de novo unbalanced translocations have not yet been investigated systematically. We analyzed 12 de novo translocations and mapped the breakpoints in 9. Surprisingly, in contrast to balanced translocations, we identify non-allelic homologous recombination (NAHR) between (retro)transposable elements and especially long interspersed elements (LINEs) as the main mutational mechanism. This finding implicates (retro)transposons to be a major driver of genomic rearrangements and exposes a profoundly different mutational mechanism compared to balanced chromosomal translocations. Furthermore, we show the existence of compound maternal/paternal derivative chromosomes, reinforcing the hypothesis that human cleavage stage embryogenesis is a cradle of chromosomal rearrangements. In total 36 non-amplified genomic DNA samples (12 patients plus parents) extracted from blood or amniocytes were analyzed by 250K Nsp I SNP arrays (GEO accession number GPL3718).

Project description:Large scale analysis of balanced chromosomal translocation breakpoints has shown nonhomologous end joining and microhomology-mediated repair to be the main drivers of interchromosomal structural aberrations. Breakpoint sequences of de novo unbalanced translocations have not yet been investigated systematically. We analyzed 12 de novo translocations and mapped the breakpoints in 9. Surprisingly, in contrast to balanced translocations, we identify non-allelic homologous recombination (NAHR) between (retro)transposable elements and especially long interspersed elements (LINEs) as the main mutational mechanism. This finding implicates (retro)transposons to be a major driver of genomic rearrangements and exposes a profoundly different mutational mechanism compared to balanced chromosomal translocations. Furthermore, we show the existence of compound maternal/paternal derivative chromosomes, reinforcing the hypothesis that human cleavage stage embryogenesis is a cradle of chromosomal rearrangements.

Project description:Transcriptional profile of stress in fission yeast (S. pombe) cells. Five different types of stress were employed on wild type and mutant cells (sty1 and atf1 knock-out cells). The 5 stresses were heat, and four types of compound: heavy metal, oxidation, alkylation and osmosis.

Project description:Silymarin (SM) is a popular botanical medicine with purported liver protective effects. SM displays multiple effects in animal models and in cell culture including prevention of liver disease, reduction of inflammation, oxidative stress, and proliferation. Despite a plethora of data indicating that SM impinges on multiple cellular signaling pathways important in inflammation and disease, no unifying mechanisms have been forwarded. To define how SM elicits so many biological effects, the current study presents the first comprehensive transcriptional profiling study of human hepatoma cells treated with SM. The intention of the study was to focus on the early transcriptional events that are associated with SM-induced inhibition of proliferation and inflammation. Collectively, the data demonstrate that SM causes a rapid transcriptional reprogramming of cells that initially manifests as energy stress and slowing of cellular metabolism, leading to inhibition of cell growth and inflammation.

Project description:Germline unbalanced translocations arise from diverse mutational mechanisms including chromothripsis

Project description:Silymarin (SM) is a popular botanical medicine with purported liver protective effects. SM displays multiple effects in animal models and in cell culture including prevention of liver disease, reduction of inflammation, oxidative stress, and proliferation. Despite a plethora of data indicating that SM impinges on multiple cellular signaling pathways important in inflammation and disease, no unifying mechanisms have been forwarded. To define how SM elicits so many biological effects, the current study presents the first comprehensive transcriptional profiling study of human hepatoma cells treated with SM. The intention of the study was to focus on the early transcriptional events that are associated with SM-induced inhibition of proliferation and inflammation. Collectively, the data demonstrate that SM causes a rapid transcriptional reprogramming of cells that initially manifests as energy stress and slowing of cellular metabolism, leading to inhibition of cell growth and inflammation. The effects of silymarin on liver hepatoma Huh7.5.1 cells were detected using a time course approach.

Project description:The majority of sunlight-associated melanomas carry a unique UV-related C to T mutation signature at dipyrimidine sites. UVB radiation is known to induce cyclobutane pyrimidine dimers (CPDs) as the major form of DNA damage, but the mechanism of how these DNA lesions lead to mutations is unknown. To map the genome-wide distribution of CPDs at single base resolution, we developed a new method, circle damage sequencing (circle-damage-seq). We found that in human cells CPDs form in a specific tetranucleotide sequence context (5’PyPy<>PyT/A), but this alone does not explain the mutation patterns. To test whether mutations arise at CPDs by cytosine deamination, we next applied a modification of circle-damage-seq and mapped UVB-induced cytosine-deaminated CPDs. We observed that the transcription start sites (TSS) are the sequences most protected from CPDs and deaminated CPDs. The strongest spike of CPDs and deaminated CPD lesions was found immediately upstream of the TSS, suggesting a mutation-promoting role of bound transcription factors. Most significantly, the genome-wide dinucleotide and trinucleotide sequence specificity of deaminated CPDs matched the prominent mutation signature found in melanomas. Our data identifies the cytosine-deaminated CPD as the leading premutagenic lesion responsible for the vast majority of mutations in sun-exposure-linked melanomas.