Global ETD Search

31	Regulation of BACH1/FANCJ Function in DNA Damage Repair: A Dissertation Xie, Jenny X. 11 August 2009 (has links) The DNA damage response (DDR) pathway is a complicated network of interacting proteins that function to sense and remove DNA damage. Upon exposure to DNA damage, a signaling cascade is generated. The damage is either removed, restoring the original genetic sequence, or apoptosis is activated. In the absence of DDR, cells are unable to effectively process DNA damage. Unprocessed DNA damage can lead to chromosomal changes, gene mutations, and malignant transformation. Thus, the proteins involved in DDR are critical for maintaining genomic stability. One essential DDR protein is the BRCA1 Associated C-terminal Helicase, BACH1. BACH1 was initially identified through its direct association with the BRCT domain of the Breast Cancer Associated Gene, BRCA1. Similar to BRCA1, germline mutations in BACH1were identified in patients with early onset breast cancer. Interestingly, the disease-associated mutations in BACH1 were shown to have altered helicase activity in vitro, providing a direct link between BACH1 helicase activity and disease development. The correlation between BACH1 and cancer predisposition was further confirmed by the identification of BACH1 as the cancer syndrome Fanconi anemia (FA) gene product, FANCJ. Similar to other FA proteins, suppression of FANCJ leads to decreased homologous recombination, enhanced sensitivity to DNA interstrand crosslinking (ICL) agents, and chromosomal instability. In an effort to further understand the function of FANCJ in DDR, FANCJ was shown to directly associate with the mismatch repair (MMR) protein MLH1. This interaction is facilitated by lysines 141 and 142 within the helicase domain of FANCJ. Importantly, the FANCJ/MLH1 interaction is critical for ICL repair. Furthermore, in an attempt to dissect the binding site of FANCJ on MLH1, we discovered an HNPCC associated MLH1 mutation (L607H) that has intact mismatch repair, but lacks FANCJ interaction. In contrast to the MLH1 interaction, the FANCJ/BRCA1 interaction was not required for correcting the cellular defects in FANCJ null cells. Thus, in an effort to understand the functional significance of the FANCJ/BRCA1 interaction, we discovered that FANCJ promotes Pol η dependent translesion synthesis (TLS) bypass when uncoupled from BRCA1. In this thesis, we provide evidence suggesting that FANCJ and MLH1 are functionally linked and that the interaction of these proteins is critical for repair choice. DNA Repair Enzymes Fanconi Anemia Colorectal Neoplasms Hereditary Nonpolyposis DNA Mismatch Repair Amino Acids, Peptides, and Proteins Enzymes and Coenzymes Genetic Phenomena Neoplasms
32	FANCM et ses cofacteurs MHF1-MHF2, ainsi que FIDGETIN-Like-1 limitent la formation des crossovers méiotiques chez Arabidopsis thaliana / FANCM and its co-factors MHF1-MHF2, as well as FIDGETIN-Like-1 limit meiotic CO formation in Arabidopsis thaliana Girard, Chloé 03 October 2014 (has links) La grand majorité des espèces forment très peu de crossovers (CO) par chromosome en méiose, et ce quelle que soit la taille des chromosomes et en dépit de l'excès de précurseurs de recombinaison disponibles. Les mécanismes qui sous-tendent cette limitation restent, pour une grande part, inconnus. Pour identifier des facteurs limitant la formation des CO en méiose, nous avons mis en place un crible permettant d'isoler des mutants formant plus de CO que le sauvage. Chez Arabidopsis thaliana, les mutants présentant un défaut de CO (ex: les mutants zmm) présentent une réduction de fertilité directement observable sur la longueur des fruits. Notre crible repose sur l'idée qu'une mutation augmentant la formation des CO devrait restaurer la fertilité des mutants zmm.Le premier suppresseur identifié nous a permis de montrer que FANCM est un régulateur majeur de la formation des CO méiotiques, en limitant la voie dépendante de MUS81, normalement minoritaire chez Arabidopsis (Crismani et al., 2012). Nous avons ensuite montré que deux des cofacteurs de FANCM au sein de la voie de l'anémie de Fanconi (FA), MHF1 et MHF2, agissent dans la même voie pour limiter les CO. En dehors de ces trois protéines, les autres protéines FA ne sont pas des protéines anti-CO (Girard et al., 2014).Nous avons ensuite identifié FIDGETIN-Like-1 comme une protéine anti-CO agissant en parallèle de FANCM. En effet, si les deux mutations figl1 et fancm alimentent la voie dépendante de MUS81 de formation des CO, leurs effets sont cumulatifs et mènent à une augmentation d'un facteur 6 du nombre CO par méiose, et ce sans affecter la ségrégation des chromosomes. Ce résultat montre que FIGL1 et FANCM agissent à deux étapes indépendantes de la recombinaison, et nos données suggèrent que FIGL1 pourrait agir en amont de FANCM.Ce travail a révélé l'existence d'au moins deux mécanismes de limitation des CO méiotiques, et montre que la fréquence de CO peut être largement augmentée sans que la ségrégation des chromosomes ne soit affectée. / Most species only few meiotic crossovers (COs) per chromosome irrespective of their physical size and despite an excess of recombination precursors. However, the underlying mechanisms constraining CO frequency remain largely unknown. In order to find factors limiting meiotic COs, we performed a genetic screen to find mutants with increased CO frequency. CO-deficient mutants (e.g. zmm) of Arabidopsis thaliana display reduced fertility, easily noticeable by their obvious reduction in fruit length. We designed a screen based on the idea that mutations that increase CO frequency will restore the fertility of the zmm mutants.We showed first identified FANCM as a major anti-CO protein limiting MUS81-dependent COs, a normally minor pathway in Arabidopsis (Crismani et al., 2012). We then showed that two of FANCM's cofactors from the Fanconi anemia pathway of DNA repair, namely MHF1 and MHF2, act along FANCM to limit meiotic crossovers, whereas the other Fanconi proteins do not (Girard:2014).Another mutant revealed FIDGETIN-Like-1 (FIGL1) as an anti-CO factor that acts in parallel to FANCM. While both figl1 and fancm mutations fuels the MUS81-dependent CO pathway, the effect of both mutations is cumulative, leading to a six-fold increase in CO formation, without impairing chromosome segregation. This shows that FIGL1 and FANCM act independently, and our data suggest that FIGL1 could act at an earlier step in the recombination pathway than FANCM.This work reveals that at least two different mechanisms limit meiotic CO number and shows that CO frequency can be largely increased without affecting chromosome distribution at meiosis. Meiose Crossovers Chromosomes FANCM Anémie de Fanconi FIDGETIN-Like-1 Recombinaison Meiosis Crossovers Chromosomes FANCM Fanconi anemia FIDGETIN-Like-1 Recombination
33	Rôle de FANCA dans la régulation de la neddylation de protéines membranaires. / Role of the FANCA protein in neddylation of membrane associated proteins. Renaudin, Xavier 17 September 2014 (has links) Le but de cette thèse était d’identifier de nouveaux substrats au complexe FANC Core,déficient dans l’Anémie de Fanconi, une pathologie génétique rare. Cette maladie estcaractérisée par un phénotype hétérogène associant une pancytopénie à des malformationscongénitales et une prédisposition accrues aux leucémies myéloïdes aigues.L’anémie de Fanconi est causée par la mutation biallélique dans un des seize gènesFANC. Les protéines produites par ces gènes participent à une même voie moléculaireimpliquée dans la signalisation des dommages de l’ADN. Huit de ces protéines forment lecomplexe FANC Core, une E3 ubiquitine ligase, dont les seuls substrats à ce jour sontFANCD2 et FANCI.Dans le but d’identifier de nouveaux substrats du complexe FANC Core, j’ai réalisé uneanalyse protéomique après immunoprécipitation des peptides modifiés par l’ubiquitine ou parles ubiquitin-like NEDD8 et ISG15. Cette expérience a été faite dans des cellules déficientespour la voie FANC, mutées sur les gène FANCA ou FANCC et comparée à des cellulescorrigées par l’expression de ces gènes.Cette analyse révèle que FANCD2 et FANCI sont les seules cibles du complexe FANCCore en réponse à des dommages de l’ADN.Néanmoins, je montre l’existence d’autres protéines qui sont modifiées d’une manièreFANCA dépendante. Ces protéines sont pour la grande majorité des protéines membranairesou associées aux membranes cytoplasmiques. Parmi celles-ci, j’ai pu déterminer que lerécepteur aux chimiokines, CXCR5, était modifié d’une manière FANCA dépendante parl’ubiquitin-like NEDD8. Cette modification impacte sur la localisation de la protéine à lamembrane et à des conséquences sur la migration des cellules.J’ai aussi montré que FANCA participe d’une manière similaire à la régulation de lalocalisation membranaire d’autres protéines comme APLP2.Ainsi, il est proposé par ce travail un rôle de la protéine FANCA en dehors du complexeFANC Core et en dehors de la réparation des dommages à l’ADN. Comment la protéineFANCA participe à la régulation du trafic des protéines membranaires reste un point nonrésolu à ce jour. / The aim of this thesis was to find new substrates of the E3-ubiquitin ligase activity of theFANC Core complex, mutated in the rare genetic disorder Fanconi Anemia. This disease ischaracterized by bone marrow failure, developmental abnormalities and predisposition tocancer. Eight of the 16 known FANC proteins participate in the FANCcore nuclear complex,which has E3 ubiquitin-ligase activity and monoubiquitinates FANCD2 and FANCI inresponse to replication stress.In this thesis, I used mass spectrometry to compare cellular extracts from FANC Corecomplex deficient FA-A and FA-C cells to their ectopically corrected counterparts after agenotoxic stress.FANCD2 and FANCI appear to be the only true direct targets of the FANCcore complex.However, I also identified other proteins that undergo post-translational modifications throughFANCA- or FANCC-specific direct or indirect mechanisms that are independent of theFANCcore complex. The majority of these potential FANCA or FANCC target proteinslocalize to the cell membrane.Finally, I demonstrated that (a) the chemokine receptor CXCR5 is a neddylated protein; (b)FANCA, surprisingly, appears to modulate CXCR5 neddylation through a currently unknownmechanism; (c) CXCR5 neddylation is involved in the targeting of this receptor to the cellmembrane; and (d) CXCR5 neddylation stimulates cell migration/motility.I also confirmed that the role of FANCA in neddylation is not restrict to CXCR5 but also to,at least, one other protein, APLP2.My work has uncovered a new signaling pathway that is potentially involved in the rarehuman syndrome Fanconi Anemia and in cell motility and has highlighted a potential newfunction for the FANCA protein independant of the FANC Core complex and of a genotoxicstress. Anémie de Fanconi Neddylation Ubiquitination Récepteurs aux chimiokines Mobilité cellulaire Leucémie Fanconi Anemia Neddylation Ubiquitylation Chemokines receptors Cell motility Leukemia
34	Characterizing the Role of DNA Repair Proteins in Telomere Length Regulation and Maintenance: Fanconi Anemia Complementation Group C Protein and 8-Oxoguanine DNA Glycosylase Rhee, David Beomjin 01 August 2010 (has links) Telomeres are the chromosome end structures consisting of telomere-associated proteins and short tandem repeat sequences, TTAGGG, in humans and mice. Telomeres prevent chromosome termini from being recognized as broken DNA ends. The structural integrity of DNA including telomeres is constantly threatened by a variety of DNA damaging agents on a daily basis. To counteract the constant threats from DNA damage, organisms have developed a number of DNA repair pathways to ensure that the integrity of genome remains intact. A number of DNA repair proteins localize to telomeres and contribute to telomere maintenance; however, it is still unclear as to what extent. Telomere shortening has been linked to rare human disorders that present with bone marrow failure including Fanconi anemia (FA). FANCC is one of the most commonly mutated FA genes in FA patients and the FANCC subtype tends to have a relatively early onset of bone marrow failure and hematologic malignancies. Here, we studied the role of Fancc in telomere length regulation in mice. We demonstrated that deletion of Fancc did not affect telomerase activity, telomere length or telomeric end-capping in mice with long telomeres. We also showed that Fancc deficiency accelerates telomere shortening during high turnover of hematopoietic cells and promotes telomere recombination initiated by short telomeres. Telomere shortening has also been linked to human aging and cancer development, with oxidative stress as a major contributing factor. 8-oxo-7, 8-dihydroguanine is among the most common oxidative DNA lesions, and is substrates for OGG1-initiated DNA base excision repair. Mammalian telomeres consist of triple guanine repeats and are subject to oxidative guanine damage. Here, we investigated the impact of oxidative guanine damage and its repair by OGG1 on telomere integrity. We demonstrated that oxidative guanine damage can arise in telomeres where it affects length homeostasis, recombination, DNA replication, and DNA breakage repair. We also examined if telomeric DNA is particularly susceptible to oxidative guanine damage and if telomere specific factors affect the incision of oxidized guanines by OGG1. We showed that the GGG sequence context of telomere repeats and certain telomere configurations may contribute to telomere vulnerability to oxidative DNA damage processing. Telomere DNA repair Fanconi Anemia BER ALT Cancer Biology, general Cancer Biology Genetics Life Sciences Molecular Biology
35	Estudo molecular do gene FANCA em pacientes com quadro clínico de Anemia de Fanconi / Molecular study of the gene FANCA in patients with compatible clinical of Fanconi Anemia Gonçalves, Claudia Estela, 1970- 27 August 2018 (has links) Orientador: Carmen Sílvia Bertuzzo / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-27T12:57:33Z (GMT). No. of bitstreams: 1 Goncalves_ClaudiaEstela_D.pdf: 2258187 bytes, checksum: 7cac2852cc031e31eba1a31c62d9dda2 (MD5) Previous issue date: 2014 / Resumo: A Anemia de Fanconi (AF) é uma alteração genética caracterizada por múltiplas anomalias congênitas, anormalidades hematológicas e predisposição a uma variedade de tumores. A incidência mundial da AF em todo o mundo é de aproximadamente três por milhão e a frequência de heterozigotos é estimada em um para 300 na Europa e Estados Unidos. É uma doença causada por mutações em genes relacionados ao sistema de reparo. Até o momento foram descritos 16 genes que podem estar multados. São eles: FANCA, FANCB, FANCC, FNCD1, FANCD2, FANCE, FANCF, FANCG, FANCI, FANCJ, FANCL, FANCM, FANCN, FANCO, FANCP E PANCQ. Os grupos mais frequentes são o FANCA e FANCC. De qualquer modo devido a essa heterogeneidade gênica, o diagnóstico molecular dessa alteração é complexo. Com o intuito de testar uma estratégia diagnóstica, o presente trabalho se propôs a identificar as mutações mais frequentes no gene FANC por PCR e digestão enzimática e investigar mutações no gene FANCA, por meio da Reação em Cadeia da Polimerase seguida de digestão enzimática da mutação Brasileira e posterior sequenciamento dos 43 éxons em 60 pacientes portadores de Anemia de Fanconi DEB positivos. Foram detectados 19 pacientes (27,94%), como sendo do grupo C e 16 pacientes como grupo A (23,53%). A mutação ?3788-3790 do gene FANCA teve uma frequência alélica de 15,4%. Foram encontradas 3 mutações intrônicas, 1 mutação sinônima e 1 mutação de sentido trocado no gene FANCA. Não foram encontradas correlações com as manifestações hematológicas, renais, baixo peso, malformações congênitas de membros, machas e pigmentação de pele, sexo e idade / Abstract: The Fanconi Anemia (FA) is a genetic disorder characterized by multiple congenital and hematological abnormalities and predisposition to a variety of tumors. The worldwide incidence of AF is approximately three per million and the frequency of heterozygotes is estimated at one in 300 in Europe and the United States. It is a disease caused by mutations in genes involved in the repair system. So far have been described 16 genes that may be mutated. They are: FANCA , FANCB , FANCC , FNCD1 , FANCD2 , FANCE , FANCF , FANCG , FANCI , FANCJ , FANCL , FANCM , FANCN , FANCO , FANCP And PANCQ . The most common groups are the FANCA and FANCC. However due to this genetic heterogeneity, molecular diagnosis of this change is complex. In order to test a diagnostic strategy, the present study aimed to identify the most frequent mutations in the FANC gene by PCR and restriction enzyme digestion and investigate mutations in the FANCA gene, using the polymerase chain reaction followed by enzymatic digestion of the mutation Brazilian and subsequent sequencing of the 43 exons in 60 patients with Fanconi Anemia positive DEB. 19 patients (27.94%) were detected as group C and 16 patients as group A (23.53%). The ?3788 - 3790 mutation in the FANCA gene had an allelic frequency of 15.4%. Three intronic mutations, one synonymous mutation and one mutation changed direction in FANCA gene were found. No correlation with hematologic, renal, low weight manifestations of congenital malformations members, butches and skin pigmentation, age and sex were found / Doutorado / Clinica Medica / Doutora em Clínica Médica Anemia de Fanconi Neoplasias Genótipo Síndromes mielodisplásicas Mutação Instabilidade cromossomica Fanconi anemia Neoplasms Genotype Myelodysplastic syndromes Mutation Chromosomal instability
36	DNA damage response gene mutations and inherited susceptibility to breast cancer Mantere, T. (Tuomo) 26 September 2017 (has links) Abstract Breast cancer is the most common malignancy in women and it is strongly influenced by hereditary risk factors. So far, most of the breast cancer-associated genes, including BRCA1/2, have been identified among those that encode proteins involved in DNA damage response (DDR) pathways. However, known genetic risk factors explain less than half of the familial risk of breast cancer. Identification of novel genes and mutations that predispose to breast cancer is important for the understanding of the mechanisms that contribute to the disease development and also for the identification of those individuals who are at high risk. The first aim of this study was to resolve the complementation groups of Finnish patients with Fanconi anemia (FA), which is a rare genetic disease caused by defects in a specific DDR pathway, and to study the role of the causative gene mutations in breast cancer predisposition. The second aim of this study was to identify novel breast cancer susceptibility genes and alleles by targeted next-generation sequencing (NGS) of multiple (~800) DDR related genes. In both approaches, the identified gene mutations were subjected to case-control association analysis utilizing DNA samples of over 1,000 breast cancer cases and 1,000 healthy controls. Investigation of the Finnish FA patients revealed six different disease-causing mutations in three different genes (FANCA, FANCG and FANCI). All of the studied mutations were recurrent in the Finnish population but did not associate with breast cancer. Targeted NGS identified three novel potential breast cancer susceptibility genes. A significant enrichment of TEX15 c.7253dupT and FANCD2 c.2715+1G>A mutations was observed among the hereditary breast cancer cases (P = 0.018 and P = 0.036, respectively). The strongest evidence was found for a Finnish founder mutation in MCPH1 (c.904_916del), which associated with breast cancer susceptibility both in familial (P = 0.003, OR 8.3) and unselected (P = 0.016, OR 3.3) patient cohorts. The tumor suppressive function of MCPH1 was indicated by the loss of the wild-type allele of MCPH1 in 40% of the studied carrier tumors. Furthermore, carriers exhibited a significant increase in genomic instability measured by spontaneous chromosomal rearrangements in peripheral blood lymphocytes. / Tiivistelmä Rintasyöpä on naisten yleisin syöpä. Sairastumisriskiin vaikuttavat voimakkaasti perinnölliset alttiustekijät, ja suurin osa tähän asti tunnistetuista rintasyöpäalttiusgeeneistä, kuten BRCA1/2, koodaa DNA-vauriovasteessa (DDR) toimivia proteiineja. Tunnistetut tekijät selittävät yhä kuitenkin vain alle puolet rintasyövän perinnöllisestä alttiudesta. Uusien alttiusgeenien tunnistaminen on tärkeää rintasyövän patomekanismien ymmärtämiseksi sekä korkean rintasyöpäriskin omaavien henkilöiden tunnistamiseksi. Tämän tutkimuksen tarkoituksena oli määrittää viallisesta DDR-signaalinsiirtoreitistä johtuvan Fanconin anemian (FA) komplementaatioryhmät suomalaisilta FA-potilailta sekä tutkia sairauden taustalla olevien geenimutaatioden yhteyttä rintasyöpäriskiin. Uusia alttiusgeenejä etsittiin myös kohdennetulla uuden sukupolven sekvensointimenetelmällä, jonka avulla tutkittiin yhtäaikaisesti n. 800 DDR-geeniä. Molemmilla lähestymistavoilla tunnistettujen geenimuutosten yhteyttä rintasyöpään selvitettiin tapaus-verrokkitutkimuksen avulla, jossa tutkittiin DNA-näytteitä yli tuhannelta rintasyöpäpotilaalta sekä yli tuhannelta terveeltä henkilöltä. Suomalaisten FA-potilaiden geenimuutoksia selvittävässä tutkimuksessa tunnistettiin yhteensä kuusi mutaatiota kolmessa eri geenissä (FANCA, FANCG ja FANCI). Kaikki tutkimuksessa tunnistetut mutaatiot olivat toistuvia suomalaisessa väestössä, mutta merkitsevää assosiaatiota näiden mutaatioiden ja rintasyöpäalttiuden välillä ei havaittu. DDR-geenien sekvensoinnin avulla tunnistettiin kolme uutta mahdollista rintasyöpäalttiusgeeniä. Tutkimuksessa havaittiin TEX15 c.7253dupT ja FANCD2 c.2715+1G>A mutaatioiden rikastuminen perinnöllisessä rintasyöpäaineistossa (P = 0.018 ja P = 0.036). Merkittävin yhteys rintasyöpäalttiuden kanssa todettiin MCPH1-geenin perustajamutaatiolle (c.904_916del). Tämä mutaatio assosioitui rintasyöpäalttiuden kanssa sekä perinnöllisessä (P = 0.003, OR 8.3) että valikoimattomassa potilasaineistossa (P = 0.016, OR 3.3). Useissa mutaatiokantajien tuumoreissa (40 %) normaali MCPH1 vastinalleeli oli hävinnyt, mikä viittaisi siihen, että MCPH1 toimii tuumorisuppressorina. Mutaatiokantajilla todettiin myös kohonnut määrä kromosomaalisia muutoksia veren periferaalisissa lymfosyyteissä, mahdollisesti kohonneeseen genomiseen epävakauteen liittyen. DNA damage response Fanconi anemia hereditary breast cancer predisposition next-generation sequencing DNA-vauriovaste Fanconin anemia perinnöllinen rintasyöpäalttius uuden-sukupolven sekvensointimenetelmät FANCD2 MCPH1 TEX15
37	BRCA/Fanconi anemia pathway genes in hereditary predisposition to breast cancer Solyom, S. (Szilvia) 19 April 2011 (has links) Abstract Two major genes are involved in hereditary predisposition to breast and ovarian cancer – BRCA1 and BRCA2. However, germline mutations in these tumor suppressors account for a maximum 20% of the familial breast cancer cases. A significant portion of the genes predisposing to this disease is unknown and therefore needs to be discovered. The aim of this study was to identify novel breast cancer susceptibility genes from the interweaving BRCA/Fanconi anemia (FA) pathway. Five candidate genes – MERIT40, ABRAXAS, BRIP1, CHK1, and FANCA – were screened for mutations by utilizing conformation-sensitive gel electrophoresis and sequencing, or with multiplex ligation-dependent probe amplification in blood DNA samples of Finnish familial breast cancer patients. Investigation of the MERIT40 gene revealed novel nucleotide changes, being the first report on mutation screening of this gene. None of the observed alterations, however, appeared to be disease related, suggesting that germline mutations in MERIT40 are rare or absent in breast cancer patients. A missense alteration (c.1082G>A, leading to Arg361Gln) was identified in ABRAXAS in 3 out of 125 Northern Finnish breast cancer families (2.4%), but not in any of the 867 healthy controls. The prevalence of the mutation between familial and control cases was statistically significantly different (p=0.002). ABRAXAS c.1082G>A appears to have pathological significance based on its exclusive occurrence in cancer cases, evolutionary conservation, disruption of a putative nuclear localization signal, reduced nuclear localization of the protein, and defective accumulation at DNA damage sites. The BRIP1 (FANCJ) and CHK1 genes were screened for large genomic rearrangements, but no abnormalities were detected, ruling out a significant contribution to breast cancer susceptibility in the Northern Finnish population. A novel large heterozygous deletion was identified in the FANCA gene in one out of 100 breast cancer families, removing the promoter and the first 12 exons. The deletion allele was not present in the tested controls, suggesting that it might contribute to breast cancer susceptibility. This is the first report on the association of a large-size germline deletion in a gene acting in the upstream part of the FA signaling pathway with familial breast cancer. / Tiivistelmä BRCA1 ja BRCA2 ovat kaksi tärkeintä perinnöllisen rinta- ja munasarjasyövän alttiusgeeniä. Niissä esiintyvät ituradan muutokset selittävät kuitenkin vain noin 20 % familiaalisista rintasyöpätapauksista. Suurin osa alttiusgeeneistä on edelleen tunnistamatta ja näitä tekijöitä etsitään aktiivisesti. Tämän tutkimuksen tarkoituksena on ollut tunnistaa uusia alttiustekijöitä toisiinsa läheisesti liittyviltä BRCA/Fanconin anemia (FA) signaalinsiirtoreiteiltä. Viisi kandidaattigeeniä - MERIT40, ABRAXAS, BRIP1, CHK1 ja FANCA – kartoitettiin mutaatioiden suhteen suomalaisissa rintasyöpäperheissä käyttämällä konformaatiosensitiivistä geelielektroforeesia ja sekvensointia, tai multiplex ligation-dependent probe amplification- menetelmää. MERIT40-geenissä havaittiin useita aikaisemmin raportoimattomia nukleotidimuutoksia, mutta yhdenkään niistä ei havaittu liittyvän rintasyöpäalttiuteen. MERIT40-geenimuutosten mahdollista yhteyttä rintasyöpäalttiuteen ei ole tutkittu aikaisemmin. ABRAXAS-geenissä havaittiin missense-mutaatio (c.1082G>A, joka johtaa Arg361Gln aminohappokorvautumiseen) kolmessa pohjoissuomalaisessa rintasyöpäperheessä (3/125, 2.4 %). Muutosta ei havaittu terveissä kontrolleissa (N=867), ja ero mutaation esiintyvyydessä familiaalisten rintasyöpätapausten ja terveiden kontrollien välillä oli tilastollisesti merkitsevä (p=0.002). ABRAXAS c.1082G>A-muutos on todennäköisesti patogeeninen, sillä kyseinen aminohappopaikka on evolutiivisesti konservoitunut ja sijaitsee todennäköisellä tumaanohjaussignaalialueella. Funktionaaliset kokeet osoittivat, että mutatoitunut proteiinituote lokalisoitui villityypin proteiinia heikommin tumaan ja sen ohjautuminen DNA-vaurioalueille oli puutteellista. BRIP1- (FANCJ) ja CHK1-geeneistä etsittiin laajoja genomisia uudelleenjärjestelyjä, mutta niitä ei havaittu. Näin ollen kyseisillä muutoksilla ei ole merkittävää roolia perinnöllisessä rintasyöpäalttiudessa suomalaisessa väestössä. FANCA-geenissä havaittiin laaja heterotsygoottinen deleetio yhdessä tutkitusta 100 rintasyöpäperheestä. Deleetio poistaa geenin promoottorialueen lisäksi sen 12 ensimmäistä eksonia. Deleetioalleelia ei havaittu terveissä kontrolleissa, joten se mahdollisesti liittyy perinnölliseen rintasyöpäalttiuteen. Tutkimus on ensimmäinen, jossa raportoidaan laaja genominen deleetio FA-signaalinsiirtoreitin ylävirran geenissä familiaalisessa rintasyövässä. Fanconi anemia breast cancer genetic predisposition to disease germline mutation Fanconin anemia ituradan muutos perinnöllinen alttius rintasyöpä ABRAXAS BRIP1 CHK1 FANCA FANCJ MERIT40
38	Role for Fanconi anemia pathway in immunoglobulin diversification / Rôle de la voie FANC dans les processus de diversifications des immunoglobuline Nguyen, Thuy Vy 21 November 2013 (has links) Dans le but de reconnaitre et répondre de manière efficace à une très grande variétés d’agents pathogènes, les cellules B ont développé au cours des mécanismes de diversifications des immunoglobulines contrôlés par des processus génétiques complexes comme la recombinaison V(D)J, l’hypermutation somatiques (SHM), et le changement de classe par recombinaison (CSR). L’ensemble de ces processus est contrôlé par différentes voies de réparations de l’ADN. L’anémie de Fanconi est une maladie génétique rare caractérisée par une défaillance progressive de la moelle osseuse, des anomalies de développement et un risque accru de développer des leucémies et des cancers oesopharyngés. La voie FANC est impliquée dans la réparation des pontages de l’ADN et dans le maintien de la fourche de réplication en cas de stress génotoxique. Il est également bien décrit que la voie FANC joue un rôle important dans la coordination des voies de réponses aux dommages à l’ADN. Dans ce travail de thèse, nous nous sommes intéressés au rôle de la voie FANC dans les processus de diversifications des immunoglobulines.En utilisant des souris déficientes pour le gène Fanca, nous montrons que la voie FANC (ou FANCA) participe à la recombinaison V(D)J en contrôlant, dans la moelle osseuse, la transition des cellules B, du stade pre-B au stade de cellules B immatures. Ceci se ferait probablement par le contrôle de la transcription des gènes codant les chaines légères κ des immunoglobulines. Nous montrons également que Fanca pourrait avoir un rôle dans l’addition de nucleotides aux extrémités codantes, en régulant d’une manière indéterminée l’activité et/ou l’activation de l’enzyme TdT ou de la polymérase Polµ. Par ailleurs, nous avons montré que Fanca est nécessaire pour l’induction des mutations de type transitions A/T pendant le processus de SHM en régulant l’expression ou la stabilisation de Polη. Enfin, Fanca (ou la voie FANC) participe à l’inhibition de la recombinaison non homologue (NHEJ) et est requis durant le CSR pour stabiliser les duplexes entre 2 régions de microhomologies qui facilitent le recrutement d’endonucléases et réguler l’accès des DNA polymérases aux cassures de l’ADN. / To recognize and respond dynamically to an enormous variety of different pathogens, B lymphocytes of the immune system have evolved controlled genetic processes at their immunoglobulin (Ig) loci that are known as Ig diversification including V(D)J recombination, somatic hypermutation (SHM), and class switch recombination (CSR). These complex and vulnerable processes are orchestrated by multiple DNA repair pathways. Fanconi anemia (FA) is a rare genetic disorder that can lead to bone marrow failure, congenital abnormalities, and an increased risk of leukemia and cancer. FANC pathway has been implicated in DNA interstrands crosslinks (ICL) repair and in the rescue of stalled replication forks. The FANC pathway also plays a fundamental role in coordinating the DNA repair pathways. Several lines of evidence suggest a possible involvement of the FANC pathway in Ig diversification processes, thus we are particularly interested in revealing function of FANC pathway during these processes. By using Fanca-/- mice, our results first show that during V(D)J recombination, Fanca (or FANC pathway) participates to the control of the transition from pre-B to immature B cells in bone marrow (BM), probably through transcriptional activation of post-rearranged κ light chain. In addition, Fanca might play a role in nucleotide addition at coding end, possibly by regulating either TdT or Polµ activity/activation. Secondly, we found that Fanca is required for the induction of transition mutations at A/T during SHM via regulation of Polη expression/stabilization. Finally, Fanca (or FANC pathway) inhibits short-range recombination and is required during CSR to stabilize duplexes between 2 short microhomology regions that facilitate the recruitment of endonucleases to trim overhangs and avoid unscheduled access of polymerases to DNA ends. Voie Anémie de Fanconi Diversifications des immunoglobulines Recombinaison V(D)J Hypermutation somatiques (SHM) Fanconi anemia pathway Immunoglobulin diversification V(D)J recombination Somatic hypermutation (SHM) Class switch recombination (CSR)
39	Characterization of the BACH1 Helicase in the DNA Damage Response Pathway: a Dissertation Litman, Rachel 15 February 2007 (has links) DNA damage response pathways are a complicated network of proteins that function to remove and/or reverse DNA damage. Following genetic insult, a signal cascade is generated, which alerts the cell to the presence of damaged DNA. Once recognized, the damage is either removed or the damaged region is excised, and the original genetic sequence is restored. However, when these pathways are defective the cell is unable to effectively mediate the DNA damage response and the damage persists unrepaired. Thus, the proteins that maintain the DNA damage response pathway are critical in preserving genomic stability. One essential DNA repair protein is the Breast Cancer Associated gene, BRCA1. BRCA1 is essential for mediating the DNA damage response, facilitating DNA damage repair, and activating key cell cycle checkpoints. Moreover, mutations in BRCA1 lead to a higher incidence of breast and ovarian cancer, highlighting the importance of BRCA1 as a tumor suppressor. In an effort to better understand how BRCA1 carried out these functions, researchers sought to identify additional BRCA1 interacting proteins. This led to the identification of several proteins including the BRCA1 Associated C-terminal Helicase, BACH1. Due to the direct interaction of BACH1 with a region of BRCA1 essential for DNA repair and tumor suppression, it was speculated that BACH1 may help support these BRCA1 function(s). In fact, initial genetic screenings confirmed that mutations in BACH1 correlated not only with hereditary breast cancer, but also with defects in DNA damage repair processes. The initial correlation between BACH1 and cancer predisposition was further confirmed when mutations in BACH1 were identified in the cancer syndrome Fanconi anemia (FA) (complementation group FA-J), thus giving BACH1 its new name FANCJ. These findings supported a previously established link between the FA and BRCA pathways and between FA and DNA repair. In particular, we demonstrated that similar to other FA/BRCA proteins, suppression of FANCJ lead to a substantial decrease in homologous recombination and enhanced both the cellular sensitivity to DNA interstrand cross-linking agents and chromosomal instability. What remained unknown was specifically how FANCJ functioned and whether these functions were dependent on its interaction with BRCA1 or other associated partners. In fact, we identified that FANCJ interacted directly with the MMR protein MLH1. Moreover, we found that the FANCJ/BRCA1 interaction was not required to correct the cellular defects in FA-J cells, but rather that the FANCJ/MLH1 interaction was required. Although both the FA/BRCA and MMR pathways undoubtedly mediate the DNA damage response, there was no evidence to suggest that these pathways were linked, until recently. Our findings not only indicate a physical link between these pathways by protein-protein interaction, but also demonstrated a functional link. DNA Damage DNA Repair Genes BRCA1 BRCA Protein Amino Acids, Peptides, and Proteins Genetic Phenomena Hemic and Lymphatic Diseases Nutritional and Metabolic Diseases
40	Role of Mammalian RAD51 Paralogs in Genome Maintenance and Tumor Suppression Somyajit, Kumar January 2014 (has links) (PDF) My research was focused on understanding the importance of mammalian RAD51 paralogs in genome maintenance and suppression of tumorigenesis. The investigation carried out during this study has been addressed toward gaining more insights into the involvement of RAD51 paralogs in DNA damage signalling, repair of various types of lesions including double stranded breaks (DSBs), daughter strand gaps (DSGs), interstrand crosslinks (ICLs), and in the protection of stalled replication forks. My study highlights the molecular functions of RAD51 paralogs in Fanconi anemia (FA) pathway of ICL repair, in the ATM and ATR mediated DNA damage responses, in homologous recombination (HR), and in the recovery from replication associated lesions. My research also focused on the development of a novel photoinducible ICL agent for targeted cancer therapy. The thesis has been divided into following sections as follows: Chapter I: General introduction that describes about DNA damage responses and the known functions of RAD51 paralogs across species in DNA repair and checkpoint The genome of every living organism is susceptible to various types of DNA damage and mammalian cells are evolved with various DNA damage surveillance mechanisms in response to DNA damages. In response to DNA damage, activated checkpoints arrest the cell cycle progression transiently and allow the repair of damaged DNA. Upon completion of DNA repair, checkpoints are deactivated to resume the normal cell cycle progression. Defective DNA damage responses may lead to chromosome instability and tumorigenesis. Indeed, genome instability is associated with several genetic disorders, premature ageing and various types of cancer in humans. The major cause of chromosome instability is the formation of DSBs and DSGs. Both DSBs and DSGs are the most dangerous type of DNA lesions that arise endogenously as well as through exogenous sources such as radiations and chemicals. Spontaneous DNA damage is due to generation of reactive oxygen species (ROS) through normal cellular metabolism. Replication across ROS induced modified bases and single strand breaks (SSBs) leads to DSGs and DSBs, respectively. Such DNA lesions need to be accurately repaired to maintain the integrity of the genome. To understand the various cellular responses that are triggered after different types of DNA damage and the possible roles of RAD51 paralogs in these processes, chapter I of the thesis has been distributed in to multiple sections as follows: Briefly, the initial portion of the chapter provides a glimpse of various types of DNA damage responses and repair pathways to deal with the lesions arising from both endogenous as well as exogenous sources. Owing to the vast range of cellular responses and pathways, the following section provides the detailed description and mechanisms of various pathways involved in taking care of wide range of DNA lesions from SSBs to DSBs. Subsequent section of chapter I provides a comprehensive description of maintenance of genome stability at the replication fork and telomeres. Germline mutations in the genes that regulate genome integrity cause various genetic disorders and cancer. Mutations in ATM, ATR, MRE11, NBS1, BLM and FANC (1-16), BRCA1 and BRCA2 that are known to regulate DNA damage signaling, DNA repair and genome integrity lead to chromosome instability disorders such as ataxia-telangiectasia, ATR-Seckel syndrome, AT-like disorder, Nijmegen breakage syndrome, Bloom syndrome, FA, and breast and ovarian cancers respectively. Interestingly, RAD51 paralog mutations are reported in patients with FA-like disorder and various types of cancers including breast and ovarian cancers. Mono-allelic germline mutations in all RAD51 paralogs are reported to cause cancer in addition to the reported cases of FA-like disorder with bi-allelic germline mutations in RAD51C and XRCC2. In accordance, the last section of the chapter has been dedicated to describe the genetics of breast and ovarian cancers and the known functions of tumor suppressors such as BRCA1, BRCA2 and RAD51 paralogs in the protection of genome. Despite the identification of five RAD51 paralogs nearly two decades ago, the molecular mechanism(s) by which RAD51 paralogs regulate HR and genome maintenance remain obscure. To gain insights into the molecular mechanisms of RAD51 paralogs in DNA damage responses and their link with genetic diseases and cancer, the following objectives were laid for my PhD thesis: 1) To understand the functional role of RAD51 paralog RAD51C in FA pathway of ICL repair and DNA damage signalling. 2) To dissect the ATM/ATR mediated targeting of RAD51 paralog XRCC3 in the repair of DSBs and intra S-phase checkpoint. 3) To uncover the replication restart pathway after transient replication pause and the involvement of distinct complexes of RAD51 paralogs in the protection of replication forks. 4) To design photoinducible ICL agent that can be activated by visible light for targeted cancer therapy. Chapter II: Distinct roles of FANCO/RAD51C protein in DNA damage signaling and repair: Implications for Fanconi anemia and breast cancer susceptibility RAD51C, a RAD51 paralog has been implicated in HR. However, the underlying mechanism by which RAD51C regulates HR mediated DNA repair is elusive. In 2010, a study identified biallelic mutation in RAD51C leading to FA-like disorder, whereas a second study reported monoallelic mutations in RAD51C associated with increased risk of breast and ovarian cancers. However, the role of RAD51C in the FA pathway of DNA cross-link repair and as a tumor suppressor remained obscure. To understand the role of RAD51C in FA pathway of ICL repair and DNA damage response, we employed genetic, biochemical and cell biological approaches to dissect out the functions of RAD51C in genome maintenance. In our study, we observed that RAD51C deficiency leads to ICL sensitivity, chromatid-type errors, and G2/M accumulation, which are hallmarks of the FA phenotype. We found that RAD51C is dispensable for ICL unhooking and FANCD2 monoubiquitination but is essential for HR, confirming the downstream role of RAD51C in ICL repair. Furthermore, we demonstrated that RAD51C plays a vital role in the HR-mediated repair of DSBs associated with replication. Finally, we showed that RAD51C participates in ICL and DSB induced DNA damage signaling and controls intra-S-phase checkpoint through CHK2 activation. Our analyses with pathological mutants of RAD51C displayed that RAD51C regulates HR and DNA damage signaling distinctly. Together, these results unravel the critical role of RAD51C in the FA pathway of ICL repair and as a tumor suppressor. Chapter III: ATM-and ATR-mediated phosphorylation of XRCC3 regulates DNA double-strand break-induced checkpoint activation and repair The RAD51 paralogs XRCC3 and RAD51C have been implicated in HR and DNA damage responses, but the molecular mechanism of their participation in these pathways remained obscured. In our study, we showed that an SQ motif serine 225 in XRCC3 is phosphorylated by ATR kinase in an ATM signaling pathway. We found that RAD51C in CX3 complex but not in BCDX2 complex is essential for XRCC3 phosphorylation, and this modification follows end resection and is specific to S and G2 phases. XRCC3 phosphorylation was found to be required for chromatin loading and stabilization of RAD51 and HR-mediated repair of DSBs. Notably, in response to DSBs, XRCC3 participates in the intra-S-phase checkpoint following its phosphorylation and in the G2/M checkpoint independently of its phosphorylation. Strikingly, we found that XRCC3 distinctly regulates recovery of stalled and collapsed replication forks such that phosphorylation was required for the HR-mediated recovery of collapsed replication forks but is dispensable for the recovery of stalled replication forks. Together, our findings suggest that XRCC3 is a new player in the ATM/ATR-induced DNA damage responses to control checkpoint and HR-mediated repair. Chapter IV: RAD51 paralogs protect stalled forks and mediate replication restart in an FA-BRCA independent manner Mammalian RAD51 paralogs RAD51 B, C, D, XRCC2 and XRCC3 are critical for genome maintenance. To understand the crucial roles of RAD51 paralogs during spontaneously arising DNA damage, we have studied the RAD51 paralogs assembly during replication and examined the replication fork stability and its restart. We found that RAD51 paralogs are enriched onto the S-phase chromatin spontaneously. Interestingly, the number of 53BP1 nuclear bodies in G1-phase and micro-nucleation which serve as markers for under replicated lesions increases after genetic ablation of RAD51C, XRCC2 and XRCC3. Furthermore, we showed that RAD51 paralogs are specifically enriched at two major fragile sites FRA3B and FRA16D after replication fork stalling. We found that all five RAD51 paralogs bind to nascent DNA strands after replication fork stalling and protect the fork. Nascent replication tracts created before fork stalling with hydroxyurea degrade in the absence of RAD51 paralogs but remain stable in wild-type cells. This function was dependent on ATP binding at the walker A motif of RAD51 paralogs. Our results also suggested that RAD51 paralogs assemble into BCDX2 complex to prevent generation of DSBs at stalled replication forks, thereby safeguarding the pre-assembled replisome from the action of nucleases. Strikingly, we showed that RAD51C and XRCC3 in complex with FANCM promote the restart of stalled replication forks in an ATP hydrolysis dependent manner. Moreover, RAD51C R258H mutation that was identified in FA-like disorder abrogates the interaction of RAD51C with FANCM and XRCC3, and prevents fork restart. Thus, assembly of RAD51 paralogs in different complexes prevents nucleolytic degradation of stalled replication forks and promotes restart to maintain genomic integrity. Chapter V: Trans-dichlorooxovandium(IV) complex as a potent photoinducible DNA interstrand crosslinker for targeted cancer therapy Although DNA ICL agents such as MMC, cisplatin and psoralen are known to serve as anticancer drugs, these agents affect normal cells as well. Moreover, tumor resistance to these agents has been reported. We have designed and synthesized a novel photoinducible DNA crosslinking agent (ICL-2) which is a derivative of oxovanadiumterpyridine complex with two chlorides in trans position. We found that ICL-2 can be activated by UV-A and visible light to enable DNA ICLs. ICL-2 efficiently activated FA pathway of ICL repair. Strikingly, photoinduction of ICL-2 induces prolonged activation of cell cycle checkpoint and high degree of cell death in FA pathway defective cells. Moreover, we showed that ICL-2 specifically targets cells that express pathological RAD51C mutants. Our findings suggest that ICL-2 can be potentially used for targeted cancer therapy in patients with gene mutations in FA and HR pathway. Tumour Suppression Targeted Cancer Therapy DNA Repair RAD51 Paralogs DNA Damage Signallling DNA Lesions Genome Stability Fanconi Anemia Tumorigenesis Breast Cancer Cancer Susceptibility Genes Genomes Carcinogenesis Trans-dichlorooxovandium (IV) Complex RAD51C Oxovanadium(IV) Complexes Biochemistry

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