Home About us Contact | |||
Exogenous Agents (exogenous + agent)
Selected AbstractsInterleukin-1 receptor antagonist and tumour necrosis factor-alpha gene polymorphisms in Turkish patients with allergic contact dermatitisCONTACT DERMATITIS, Issue 2 2009Ilgen Ertam Background: It has been shown that the family of interleukin-1 receptor antagonist (IL-1 RA) and tumour necrosis factor-alpha (TNF,) genes are polymorphic and related to some inflammatory diseases. Allergic contact dermatitis is the classic presentation of delayed-type hypersensitivity responses to exogenous agents. A number of genes playing role in inflammatory response may be associated with allergic contact dermatitis. Objectives: To investigate whether there is an association between IL-1RA and TNF, gene polymorphisms and allergic contact dermatitis in Turkish patients with allergic contact dermatitis. Methods: This study was performed by the collaboration of Departments of Dermatology and Medical Genetics, Ege University, Faculty of Medicine. A total of 50 patients (31 females and 19 males) with allergic contact dermatitis, and 100 age- and sex-matched controls (58 females and 42 males) were included in the study. IL-1RA Variable Number of Tandem Repeats (VNTR) polymorphism in intron 2 and TNF,-308G-A polymorphism were genotyped by using polymerase chain reaction and agarose gel electrophoresis. Results: The frequency of IL-1RA 1/2 (48%) genotype was significantly higher (P = 0.002) in patient group than that is found in control group (22%). The frequency of TNF, (TNF G-308A) G/G genotype was significantly higher in patient group (68%) than that is found in control group (31%) (P = 0.008). Conclusions: Our findings suggest that TNF, (G/G) gene polymorphism may play role in susceptibility to allergic contact dermatitis in Turkish patients. [source] Environmental carcinogens and p53 tumor-suppressor gene interactions in a transgenic mouse model for mammary carcinogenesisENVIRONMENTAL AND MOLECULAR MUTAGENESIS, Issue 2-3 2002Daniel Medina Abstract Mouse mammary tumorigenesis is greatly influenced by a variety of exogenous agents, such as MMTV, chemical carcinogens (i.e., polycyclic aromatic hydrocarbons), and radiation, as well as by endogenous/physiological factors, such as steroid hormones, tumor-suppressor genes (i.e., Brca1/2,p53), and gene products of modifier genes. In the mouse model, the most frequently used chemical carcinogen has been 7,12-dimethylbenz[a]anthracene (DMBA), which activates the Ha- ras gene but does not alter the p53 tumor-suppressor gene. However, on an existing background of p53 gene alteration, low doses of DMBA are strongly cocarcinogenic. Using a transgenic model system, in which the p53 gene was deleted in the mammary gland, we examined the carcinogenic effects of a variety of external agents and internal factors given at either low doses or physiological doses. These agents/factors included DMBA, ,-radiation, Brca2 heterozygosity, and steroid hormones. All agents/factors increased the tumorigenic response of the p53 null mammary cells, even under conditions where no tumorigenic response was observed in the p53 wildtype mammary cell. The strongest cocarcinogenic effect was observed with the steroid hormone progesterone. The majority of tumors were highly aneuploid and composed of nuclear igh-grade cells. The mechanism for the aneuploidy and secondary events associated with high tumorigenicity were examined using array technology. These results demonstrate that, on a background of underlying genetic instability, very low doses of environmental mutagens and mitogens can produce strong cocarcinogenic effects. Environ. Mol. Mutagen. 39:178,183, 2002. © 2002 Wiley-Liss, Inc. [source] Comparative analysis of colonic gene expression of three experimental colitis models mimicking inflammatory bowel diseaseINFLAMMATORY BOWEL DISEASES, Issue 3 2007Anje A. te Velde PhD Abstract Background: Mouse models of inflammatory bowel diseases (IBD) are used to unravel the pathophysiology of IBD and to study new treatment modalities, but their relationship to Crohn's disease (CD) or ulcerative colitis (UC) is speculative. Methods: Using Agilent mouse TOX oligonucleotide microarrays, we analyzed colonic gene expression profiles in three widely used models of experimental colitis. In 2 of the models (TNBS and DSS-induced colitis), exogenous agents induce the colitis. In the third model the colitis is induced after transfer of a T-cell population (CD4+CD45RBhigh T cells) that lacks regulatory cells into an immunodeficient host. Results: Compared with control mice, in DSS, TNBS, and the CD45RB transfer colitis mice, 387, 21, and 582 genes were more than 2-fold upregulated in the intestinal mucosa. Analyses of exclusively shared gene expression profiles between the different models revealed that DSS/transfer colitis share 69 concordantly upregulated genes, DSS/TNBS 6, and TNBS/transfer colitis 1. Seven genes were upregulated in all three models. The CD45RB transfer model expression profile included the most genes that are known to be upregulated in IBD. Of 32 genes that are known to change transcriptional activity in IBD (TNF, IFN -,, Lt,, IL - 6, IL - 16, IL - 18R1, IL - 22, CCR2, 7, CCL2, 3, 4, 5, 7, 11, 17, 20, CXCR3, CXCL1, 5, 10, Mmp3, 7,9, 14, Timp1, Reg3,, and Pap, S - 100a8, S - 100a9, Abcb1, and Ptgs2), 2/32 are upregulated in TNBS, 15/32 are upregulated or downregulated in DSS and 30/32 are upregulated or downregulated in the CD45RB transfer colitis. Conclusion: The pattern of gene expression in the CD45RB transfer model most closely reflects altered gene expression in IBD. (Inflamm Bowel Dis 2007) [source] KEYNOTE ADDRESS Ku80-deletion causes early ageing and suppresses cancerJOURNAL OF ANIMAL PHYSIOLOGY AND NUTRITION, Issue 2 2009P. Hasty Ageing is widespread cellular decline resulting in a loss of fitness that is both pleiotropic and stochastic and influenced by both genetics and environment. As a result the fundamental underling causes of ageing are diverse and controversial. One potential ageing target is nuclear DNA, as it is a permanent blueprint that controls cellular processes. Thus, DNA replication and genome maintenance are highly regulated events that ensure faithful reproduction and maintenance of the blueprint and these pathways assure sufficient longevity for reproduction and survival of the species. As a consequence, imperfections or defects in maintaining the genome may contribute to ageing. Therefore, genome maintenance pathways are longevity-assurance mechanisms that sustain an organism long enough to reproduce and propagate. Chief among these mechanisms are those that respond to damaged DNA. There are two basics responses to genomic damage: DNA repair and cell cycle checkpoints. Both are considered to be tumour suppressors and are categorized as either caretakers or gatekeepers, respectively. Interestingly, observations of human and mouse pre-mature ageing models suggest these anti-tumour pathways impact the ageing process. Caretakers suppress cancer by repairing DNA damage caused by defects in replication or by a variety of agents including endogenously produced reactive by-products of oxygen metabolism and exogenous agents naturally encountered in our environment. As a consequence DNA is subject to a variety of insults that cause a diverse range of lesions and phenotypic outcomes. There are many forms of DNA damage including base lesions and double-strand breaks (DSBs) with the latter being more toxic. Cancer-causing chromosomal rearrangements may result if DSBs are not repaired properly. Additionally, an accumulation of these rearrangements may contribute to ageing since they increase in some cell types as humans and mice age. Furthermore, early ageing models suggest that defects in repairing DSBs lead to early ageing in humans and mice. Non-homologous end joining (NHEJ) is an important pathway for repairing DNA DSBs and is considered a caretaker. The Ku heterodimer (composed of Ku70 and Ku80) binds to DNA ends to initiate NHEJ, and defects in either Ku70 or Ku80 lead to increased levels of DNA DSBs and chromosomal rearrangements, leading many to believe Ku is a caretaker. Ku-mutant mice display increased GCRs, but without increased cancer. Instead, these mice show early ageing and shortened life span. Thus, Ku's role as a caretaker is uncertain as the low cancer levels may be due to Ku80-deletion or, instead, the low cancer levels may simply be a consequence of the shortened life span that prohibits sufficient time for tumours to develop. Gatekeepers respond to DNA damage by halting the cell cycle long enough for the DNA to be repaired. If the damage is irreparable, gatekeepers induce either apoptosis or senescence. These responses are deleterious to the cell but protect the organism from cancer as one potential outcome of genetic mutations is uncontrolled proliferation. p53 is critical for checkpoints and is the best-known gatekeeper because it is mutated in over half of all cancers. In addition, p53 activity influences many aspects of the Ku-mutant phenotype suggesting that Ku-deletion leads to persistent p53-mediated responses and presenting the possibility that low cancer levels and early ageing are caused by elevated gatekeeper responses. Our hypothesis is that Ku-mutant mice exhibit low cancer levels and, perhaps, ageing due to persistent p53-mediated responses to inefficiently repaired DNA. To test this hypothesis, Ku80-mutant mice were crossed to cancer-prone mice with either non-functional or functional gatekeeper responses. Ku80-mutant mice were crossed to p53-mutant mice to determine if Ku80-deletion exacerbates oncogenesis when gatekeeper responses are diminished. Ku80-mutant mice deleted for p53 exhibit early onset and high levels of two forms of cancer: pro-B cell lymphoma and medulloblastoma, thus supporting the hypothesis. Ku80-mutant mice were also crossed to APCMIN mice to determine if Ku80-deletion ameliorates oncogenesis gatekeeper responses are intact. APCMIN mice exhibit high levels of intestinal adenomas and adenocarcinomas but have normal p53-mediated responses to DNA damage. APCMIN mice, deleted for Ku80, exhibit about 67% fewer tumours than APCMIN mice with Ku80. Thus, deletion of Ku80 suppresses tumour formation, again supporting the hypothesis. Ku80-mutant cells and tissues were tested for p53-mediated DNA damage responses, levels of DNA damage, and mutations. Ku80-mutant fibroblasts exhibit elevated levels of p53-mediated DNA damage responses that increase p21-mediated cellular senescence. In addition, there are elevated levels DNA damage as seen by increased 53BP1 foci and elevated levels of chromosomal rearrangements. Thus, these data support the hypothesis that Ku80-deletion reduces tumors by elevating DNA damage gatekeeper responses to inefficiently repaired DNA. These data also support the possibility that the Ku80-mutant ageing phenotype is also due to elevated gatekeeper responses. [source] |