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Protective Effects of Milk Phospholipids Against UV-Induced DNA Damage in Human Skin CellsNguyen, Lan-Anh 01 December 2014 (has links) (PDF)
Skin cancer is the most common type of cancer in the US. The American Academy of Dermatology estimated that more than 3.5 million new cases of skin cancer are diagnosed in the US each year and 1 in 5 Americans will likely to develop skin cancer in their life time. Most cases of skin cancer are caused by exposure to ultraviolet (UV) radiation from the sun. Some of the most common sunscreen ingredients are unstable and can form harmful radicals upon exposure to UV radiation. There is a strong clinical need for a more stable and effective sunscreen ingredient such as bovine milk phospholipids (MP). Phospholipids were shown to have beneficial health effects such as regulation of the inflammatory reactions, protective effects against colon cancer, and reducing cardiovascular risk factors. Previous histology and MTT tissue viability research studies suggested that MP act upon skin cells in a protective manner against UV radiation.
This thesis aims to further investigate the protective effects of bovine milk phospholipids by evaluating the expression of a UV-induced DNA damage marker, cyclin-dependent kinase inhibitor, p21WAF1/CIP1. Western blots were used to quantify p21 expression in human keratinocytes in four categories of samples: No-UV, UV, UV+MP, MP and in HeLa (p21 positive control). In the No-UV samples, cells were not irradiated by UV light. However, in the UV samples, keratinocytes were exposed to a UV dosage of 10 mJ/cm2. In the UV+MP samples, keratinocytes were first treated with 1% MP solution (w/v) in their culture media for 24 hours then exposed to a UV dosage of 10 mJ/cm2. In MP, keratinocytes were treated with 1% MP solution in their culture media for 24 hours. Total cell proteins were extracted 24 hours post-UV irradiation. The same amount of protein from each sample (determined by BCA assay) was loaded into a 4-12% Bis-Tris SDS-PAGE gel, run under denaturing, non-reducing conditions then blotted and treated with antibodies for the quantitative detection of p21 proteins. Finally, intensities of p21 protein bands were analyzed by using ImageJ software.
Under non-reducing conditions, three p21 proteins covalently bonded with each other showed up as 63 KDa molecules on the PVDF membrane. The UV, and HeLa samples showed a 2.28 fold, and 1.23 fold increase in p21 expression, respectively, compared with the No-UV samples control. The MP samples showed a 0.948 fold decrease in p21 compared with the No-UV samples, and the UV+MP samples showed only a 1.13 fold increase in p21. When comparing with the UV sample, the UV+MP sample has 50.4% less p21 expression. Less p21 expression in the UV+MP sample compare with the UV sample suggested that less DNA damage occurred in the sample that was treated with milk phospholipids. This result strongly suggests that 1% bovine milk phospholipids can protect skin cells from UV induced DNA damage.
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Chemically Induced DNA Damage in Extended-term Cultures of Human LymphocytesAndersson, Maria January 2006 (has links)
<p>Generation of DNA damage is regarded to be an important initial event in the development cancer. Consequently, a battery of tests have been developed to detect different types of genotoxic effects in order to be able to predict the potential genotoxicity and mutagenicity of chemicals, including both pharmaceutical drugs and various types of environmental and occupational agents, as well as dietary factors. The aim of this thesis was to evaluate whether the combination of the comet assay and the extended-term cultures of human lymphocytes (ETC) can be used as an alternative <i>in vitro</i> system to more commonly used transformed mammalian cell lines, and primary cell cultures from humans, when testing the potential genotoxicity of chemicals. </p><p>Using the comet assay, a panel of reference compounds showed that the ETC were found to detect the DNA-damaging effects with no remarkable difference to what has been reported in other cell types. Moreover, in comparison with a well-established rodent cell line, the mouse lymphoma L5178Y cells, the ETC showed similar sensitivity to the DNA damaging effects of the genotoxic agents hydrogen peroxide and catechol. Although there was an interindividual variation in induced DNA damage and the subsequent repair when using ETC from different blood donors, it did not seem to be of crucial importance for the identification of DNA-damaging agents. The demonstrated difference in sensitivity to catechol-induced DNA damage between freshly isolated peripheral lymphocytes and ETC may very well be due to their different proliferative status but despite this difference, both <i>in vitro</i> systems were able to identify catechol as a DNA-damaging agent at the same concentration.</p><p>Based on these results, it is proposed that the ETC and the comet assay are a useful combination when testing for the potential DNA damaging effects of chemicals. Representing easily cultivated cells possessing the normal human karyotype, where one blood sample can be used for numerous experiments performed over a long time, extended-term cultures appear to be a useful alternative, both to transformed mammalian cell lines, and primary cell cultures from humans. In fact, the extended-term lymphocytes, with or without S9 and/or lesion specific DNA repair enzymes, should be used more frequently when screening for the potential genotoxicity of chemicals.</p>
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Chemically Induced DNA Damage in Extended-term Cultures of Human LymphocytesAndersson, Maria January 2006 (has links)
Generation of DNA damage is regarded to be an important initial event in the development cancer. Consequently, a battery of tests have been developed to detect different types of genotoxic effects in order to be able to predict the potential genotoxicity and mutagenicity of chemicals, including both pharmaceutical drugs and various types of environmental and occupational agents, as well as dietary factors. The aim of this thesis was to evaluate whether the combination of the comet assay and the extended-term cultures of human lymphocytes (ETC) can be used as an alternative in vitro system to more commonly used transformed mammalian cell lines, and primary cell cultures from humans, when testing the potential genotoxicity of chemicals. Using the comet assay, a panel of reference compounds showed that the ETC were found to detect the DNA-damaging effects with no remarkable difference to what has been reported in other cell types. Moreover, in comparison with a well-established rodent cell line, the mouse lymphoma L5178Y cells, the ETC showed similar sensitivity to the DNA damaging effects of the genotoxic agents hydrogen peroxide and catechol. Although there was an interindividual variation in induced DNA damage and the subsequent repair when using ETC from different blood donors, it did not seem to be of crucial importance for the identification of DNA-damaging agents. The demonstrated difference in sensitivity to catechol-induced DNA damage between freshly isolated peripheral lymphocytes and ETC may very well be due to their different proliferative status but despite this difference, both in vitro systems were able to identify catechol as a DNA-damaging agent at the same concentration. Based on these results, it is proposed that the ETC and the comet assay are a useful combination when testing for the potential DNA damaging effects of chemicals. Representing easily cultivated cells possessing the normal human karyotype, where one blood sample can be used for numerous experiments performed over a long time, extended-term cultures appear to be a useful alternative, both to transformed mammalian cell lines, and primary cell cultures from humans. In fact, the extended-term lymphocytes, with or without S9 and/or lesion specific DNA repair enzymes, should be used more frequently when screening for the potential genotoxicity of chemicals.
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Physiological And Exogenous Means of Regulating DNA Damage Response : Insights into Mechanisms of DNA Repair And Genomic InstabilitySebastian, Robin January 2016 (has links) (PDF)
Maintenance of genomic integrity with high fidelity is of prime importance to any organism. An insult which may result in compromised genome integrity is prevented or its consequences are monitored by advanced cellular networks, collectively called the DNA damage response (DDR). Various DNA repair pathways, which are part of DDR, constantly correct the genome in the event of any undesirable change in the genetic material and prevent the transmission of any impairment to daughter cells. Non homologous DNA end joining (NHEJ) is the predominant DNA repair pathway associated with DDR in higher eukaryotes, correcting double-strand breaks (DSBs). Microhomology mediated end joining (MMEJ), an alternate mechanism to NHEJ also exists in cells, which is associated with erroneous joining of broken DNA, leading to mutagenesis. DDR is of paramount importance in cellular viability and therefore, any defects in DDR or the imbalance of repair pathways contribute to mutations, cellular transformations and various neurodegenerative and congenital abnormalities. Here, we investigate the DDR via NHEJ and MMEJ pathways during embryonic development in mice as well as in presence of an environmental pollutant, Endosulfan, in order to understand how physiological and exogenous factors condition the balance of repair pathways.
Among various classes of pesticides known to cause side effects, organochlorine pesticides (OCPs) lead the list, possessing high transport potential, and a variety of toxic and untoward health effects. Endosulfan is a widely used organochlorine pesticide and is speculated to be detrimental to human health. However, very little is known about mechanism of its genotoxicity. Using in vivo and ex vivo model systems, we showed that exposure to Endosulfan induced reactive oxygen species (ROS) in a concentration dependent manner. Using an array of assays and equivalents of sub-lethal concentrations comparable to the detected level of Endosulfan in humans living in active areas of exposure, we demonstrated that ROS production by Endosulfan resulted in DNA double-strand breaks in mice, rats and human cells. In mice, the DNA damage was predominantly detected in type II pneumocytes of lung tissue; spermatogonial mother cells and primary spermatids of testes. Importantly, Endosulfan-induced DNA damage evoked DDR, which further resulted in elevated levels of classical NHEJ. However, sequence analyses of NHEJ junctions revealed that Endosulfan treatment resulted in extensive processing of broken DNA, culminating in increased and long junctional deletions, thereby favouring erroneous repair. We also find that exposure to Endosulfan led to significantly increased levels of MMEJ, which is a LIGASE III dependent, alternative, non classical repair pathway, encompassing long deletions and processing of DNA. Further, we show that the differential expression of proteins following exposure to Endosulfan correlated with activation of alternative DNA repair.
At the physiological level, using mouse model system, we showed that exposure to Endosulfan affected physiology and cellular architecture of organs and tissues. Among all organs, damage to testes was extensive and it resulted in death of different testicular cell populations. We also found that the damage in testes resulted in qualitative and quantitative defects during spermatogenesis in a time dependent manner, increasing epididymal ROS levels and affecting sperm chromatin integrity. This further culminated in reduced number of epididymal sperms and actively motile sperms, which finally resulted in reduced fertility in male but not in female mice.
Repair of DSBs is important for maintaining genomic integrity during the successful development of a fertilized egg into a whole organism. To date, the mechanism of DSB repair in post implantation embryos has been largely unknown except for the differential requirement of DNA repair genes in the course of development. These studies relied on null mutation analysis of animal phenotypes and therefore a quantitative understanding of repair pathways was absent. In the present study, using a cell free repair system derived from different embryonic stages of mice, we found that canonical NHEJ is predominant at 14.5 day of embryonic development. Interestingly, all types of DSBs tested were repaired by LIGASE IV/XRCC4 and Ku-dependent classical NHEJ. Characterization of end-joined junctions and expression studies further showed evidence for C-NHEJ. Strikingly, we observed non canonical end joining accompanied by DSB resection, dependent on microhomology and LIGASE III in 18.5-day embryos. Further we observed an elevated expression of CtIP, MRE11, and NBS1 at this stage, suggesting that it could act as a switch between classical and microhomology-mediated end joining at later stages of embryonic development. Keeping these observations in mind, we wondered if Endosulfan affected the differential regulation of DDR during development, similar to mice tissues. Upon analysing the effect of endosulfan on NHEJ/MMEJ at above mentioned stages of mouse embryonic development, we found that C-NHEJ efficiency remained low or unaltered while the efficiency of MMEJ was upregulated significantly, perturbing the repair balance during embryo development and hence facilitating mutagenic repair.
Thus, our results establish the existence of both classical and non classical NHEJ pathways during the post implantation stages of mammalian embryonic development. Our studies also provide deeper insights into physiological and molecular events leading to male infertility upon Endosulfan exposure and its impact on impairing the differential regulation of DNA repair during embryonic development. Our findings suggest the plasticity of DNA repair pathways in physiological and pathological conditions and provide insights into mechanism of genome instability due to DNA repair imbalance, when exposed to environmental mutagens.
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