Genotoxicity

Genotoxicity is the property of chemical agents that damage the genetic information within a cell causing mutations, which may lead to cancer. While genotoxicity is often confused with mutagenicity, all mutagens are genotoxic, but some genotoxic substances are not mutagenic. The alteration can have direct or indirect effects on the DNA: the induction of mutations, mistimed event activation, and direct DNA damage leading to mutations. The permanent, heritable changes can affect either somatic cells of the organism or germ cells to be passed on to future generations. Cells prevent expression of the genotoxic mutation by either DNA repair or apoptosis; however, the damage may not always be fixed leading to mutagenesis. To assay for genotoxic molecules, researchers assay for DNA damage in cells exposed to the toxic substrates. This DNA damage can be in the form of single- and double-strand breaks, loss of excision repair, cross-linking, alkali-labile sites, point mutations, and structural

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On the replication of adeno-associated virus in the presence or absence of viral helper functions

Anika Ekrut

Adeno-associated virus (AAV) is a small non-enveloped virus and as a member of the parvovirus family, it contains a single stranded DNA genome. AAV's life cycle in vitro is strongly dependent not only on cellular factors but also on helper functions provided by other viruses, for example adenovirus, herpes virus and, to a certain extent, papillomavirus (HPV). Although AAVs are wide spread throughout the human population, no disease is yet associated with them. Accordingly, AAV became attractive as a vector for gene therapy studies, but even though the virus is well studied in vitro and now used in clinical trials as a vector, not much is known about AAV infection in vivo. AAV was initially isolated from humans together with its helper adenovirus. However, adenovirus-independent replication of AAV has been reported for a number of cellular situations, including differentiating keratinocytes with or without the presence of HPV, and in cells with an activated DNA damage response due to genotoxic agents. In the work reported here we have undertaken a systematic study of these alternative helper activities with a view to evaluating their contribution to natural infections by AAV. We used three different systems of cultured keratinocytes and showed that in each case in vitro differentiation was achieved. In two of these, the cells were from HPV-induced lesions. We found that AAV replicates efficiently in differentiating monolayer foreskin keratinocytes in the presence but not in the absence of adenovirus. Likewise naturally HPV-infected cervical keratinocytes only support the full life cycle of AAV if adenovirus is present. Even though HPV can provide certain helper functions, it is less efficient as a helper than adenovirus. We also exploited osteosarcoma cells, which are particularly well infected by AAV. Our results indicate that U2OS osteosarcoma cells are semi-permissive for AAV growth. Induction of a DNA damage response in these cells, or in HPV-containing keratinocytes, stimulates AAV genome amplification. Although AAV replication in the absence of helper virus can readily be demonstrated, this is either at a relatively low level or limited to part of the AAV growth cycle. We conclude that although these alternative helper systems can contribute to the natural history of AAV, the presence of an efficient helper virus seems likely to be needed for AAV to persist in the human population.

EPFL2009

Non-specific SIRT inhibition as a mechanism for the cytotoxicity of ginkgolic acids and urushiols

Pierre-Alain Carrupt

Ginkgolic acids and urushiols are natural alkylphenols known for their mutagenic, carcinogenic and genotoxic potential. However, the mechanism of toxicity of these compounds has not been thoroughly elucidated so far. Considering that the SIRT inhibitory potential of anacardic acids has been hypothesized by in silico techniques, we herein demonstrated through both in vitro and computational methods that structurally related compounds such as ginkgolic acids and urushiols are able to modulate SIRT activity. Moreover, their SIRT inhibitory profile and cytotoxicity were comparable to sirtinol, a non-specific SIRT inhibitor (SIRT1 and SIRT2), and different from EX-527, a SIRT1 specific inhibitor. This is the first report on the SIRT inhibition of ginkgolic acids and urushiols. The results reported here are in line with previously observed effects on the induction of apoptosis by this class of compounds, and the non-specific SIRT inhibition is suggested as a new mechanism for their in vitro cytotoxicity.

Elsevier2014

Hominoid-Specific Transposable Elements and KZFPs Facilitate Human Embryonic Genome Activation and Control Transcription in Naive Human ESCs

Alexandre Coudray, Julien Léonard Duc, Julien Duc, Sandra Eloise Offner, Evaristo Jose Planet Letschert, Julien Paul André Pontis, Didier Trono, Priscilla Turelli

Expansion of transposable elements (TEs) coincides with evolutionary shifts in gene expression. TEs frequently harbor binding sites for transcriptional regulators, thus enabling coordinated genome-wide activation of species- and context-specific gene expression programs, but such regulation must be balanced against their genotoxic potential. Here, we show that Krüppel-associated box (KRAB)-containing zinc finger proteins (KZFPs) control the timely and pleiotropic activation of TE-derived transcriptional cis regulators during early embryogenesis. Evolutionarily recent SVA, HERVK, and HERVH TE subgroups contribute significantly to chromatin opening during human embryonic genome activation and are KLF-stimulated enhancers in naive human embryonic stem cells (hESCs). KZFPs of corresponding evolutionary ages are simultaneously induced and repress the transcriptional activity of these TEs. Finally, the same KZFP-controlled TE-based enhancers later serve as developmental and tissue-specific enhancers. Thus, by controlling the transcriptional impact of TEs during embryogenesis, KZFPs facilitate their genome-wide incorporation into transcriptional networks, thereby contributing to human genome regulation.

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Mutagen

In genetics, a mutagen is a physical or chemical agent that permanently changes genetic material, usually DNA, in an organism and thus increases the frequency of mutations above the natural backgrou

Cancer

Cancer is a group of diseases involving abnormal cell growth with the potential to invade or spread to other parts of the body. These contrast with benign tumors, which do not spr

Carcinogen

A carcinogen kɑːrˈsɪnədʒən is any substance, radionuclide, or radiation that promotes carcinogenesis (the formation of cancer). This may be due to the ability to damage the genome or to the disruptio