Your search keyword '"Elinati E"' showing total 19 results

1. Mammalian meiotic silencing exhibits sexually dimorphic features

Author

Cloutier, J. M., Mahadevaiah, S. K., ElInati, E., Tóth, A., and Turner, James

Published

2016

2. Assisted oocyte activation overcomes fertilization failure in globozoospermic patients regardless of the DPY19L2 status

Author

Kuentz, P., Vanden Meerschaut, F., ElInati, E., Nasr-Esfahani, M.H., Gurgan, T., Iqbal, N., Carré-Pigeon, F., Brugnon, F., Gitlin, S.A., Velez de la Calle, J., Kilani, Z., De Sutter, P., and Viville, S.

Published

2013

3. Genetic aspects and clinical outcomes of globozoospermia: O-272

Author

ElInati, E., Kuentz, P., Redin, C., Meerschaut, F. Vanden, Nasr-Esfahani, M., Gurgan, T., Louanjli, N., Iqbal, N., Pigeon, F. Carré, Gourabi, H., Brugnon, F., Gitlin, S., De Sutter, P., Muller, J., and Viville, S.

Published

2012

4. SETDB1 Links the Meiotic DNA Damage Response to Sex Chromosome Silencing in Mice

Author

Hirota, Takayuki, Blakeley, P., Sangrithi, M.N., Mahadevaiah, S.K., Encheva, V., Snijders, A.P., ElInati, E., Ojarikre, O.A., de Rooij, D.G., Niakan, K.K., Turner, J.M.A., Hirota, Takayuki, Blakeley, P., Sangrithi, M.N., Mahadevaiah, S.K., Encheva, V., Snijders, A.P., ElInati, E., Ojarikre, O.A., de Rooij, D.G., Niakan, K.K., and Turner, J.M.A.

Abstract

Meiotic synapsis and recombination ensure correct homologous segregation and genetic diversity. Asynapsed homologs are transcriptionally inactivated by meiotic silencing, which serves a surveillance function and in males drives meiotic sex chromosome inactivation. Silencing depends on the DNA damage response (DDR) network, but how DDR proteins engage repressive chromatin marks is unknown. We identify the histone H3-lysine-9 methyltransferase SETDB1 as the bridge linking the DDR to silencing in male mice. At the onset of silencing, X chromosome H3K9 trimethylation (H3K9me3) enrichment is downstream of DDR factors. Without Setdb1, the X chromosome accrues DDR proteins but not H3K9me3. Consequently, sex chromosome remodeling and silencing fail, causing germ cell apoptosis. Our data implicate TRIM28 in linking the DDR to SETDB1 and uncover additional factors with putative meiotic XY-silencing functions. Furthermore, we show that SETDB1 imposes timely expression of meiotic and post-meiotic genes. Setdb1 thus unites the DDR network, asynapsis, and meiotic chromosome silencing.

Published

2018

5. Mammalian meiotic silencing exhibits sexually dimorphic features

Author

Cloutier, J. M., primary, Mahadevaiah, S. K., additional, ElInati, E., additional, Tóth, A., additional, and Turner, James, additional

Published

2015

6. SESSION 70: GENETICS: WHAT GENOMES GONE WRONG CAN TELL US

Author

ElInati, E., primary, Kuentz, P., additional, Redin, C., additional, Vanden Meerschaut, F., additional, Nasr-Esfahani, M., additional, Gurgan, T., additional, Louanjli, N., additional, Iqbal, N., additional, Carre Pigeon, F., additional, Gourabi, H., additional, Brugnon, F., additional, Gitlin, S., additional, De Sutter, P., additional, Muller, J., additional, Viville, S., additional, Dul, E. C., additional, van Echten-Arends, J., additional, Groen, H., additional, Kastrop, P. M. M., additional, Amory-van Wissen, L. C. P., additional, Engelen, J. J. M., additional, Land, J. A., additional, Coonen, E., additional, van de Werken, C., additional, van der Heijden, G. W., additional, van Veen-Buurman, C. J. H., additional, Laven, J. S. E., additional, Peters, A. H. F. M., additional, Baart, E. B., additional, Rabinowitz, M., additional, Gemelos, G., additional, Banjevic, M., additional, Zimmermann, B., additional, Baner, J., additional, Levy, B., additional, Hill, M., additional, Mertzanidou, A., additional, Spits, C., additional, Van de Velde, H., additional, Sermon, K., additional, Wells, D., additional, Alfarawati, S., additional, Konstantinidis, M., additional, Jaroudi, S., additional, Fragouli, E., additional, Minasi, M. G., additional, Ruberti, A., additional, Rubino, P., additional, Iammarrone, E., additional, Biricick, A., additional, Zavaglia, D., additional, Nuccitelli, A., additional, Colasante, A., additional, Fiorentino, F., additional, and Greco, E., additional

Published

2012

7. POSTER VIEWING SESSION - REPRODUCTIVE (EPI) GENETICS

Author

Acar-Perk, B., primary, Weimer, J., additional, Koch, K., additional, Salmassi, A., additional, Arnold, N., additional, Mettler, L., additional, Schmutzler, A. G., additional, Ottolini, C. S., additional, Griffin, D. K., additional, Handyside, A. H., additional, Summers, M. C., additional, Thornhill, A. R., additional, Montjean, D., additional, Benkhalifa, M., additional, Cohen-Bacrie, P., additional, Siffroi, J. P., additional, Mandelbaum, J., additional, Berthaut, I., additional, Bashamboo, A., additional, Ravel, C., additional, McElreavey, K., additional, Ao, A., additional, Zhang, X. Y., additional, Yilmaz, A., additional, Chung, J. T., additional, Demirtas, E., additional, Son, W. Y., additional, Dahan, M., additional, Buckett, W., additional, Holzer, H., additional, Tan, S. L., additional, Perheentupa, A., additional, Vierula, M., additional, Jorgensen, N., additional, Skakkebaek, N. E., additional, Chantot-Bastaraud, S., additional, Toppari, J., additional, Muzii, L., additional, Magli, M. C., additional, Gioia, L., additional, Mattioli, M., additional, Ferraretti, A. P., additional, Gianaroli, L., additional, Koscinski, I., additional, Elinati, E., additional, Fossard, C., additional, Kuentz, P., additional, Kilani, Z., additional, Demirol, A., additional, Gurgan, T., additional, Schmitt, F., additional, Velez de la Calle, J., additional, Iqbal, N., additional, Louanjli, N., additional, Pasquier, M., additional, Carre-Pigeon, F., additional, Muller, J., additional, Barratt, C., additional, Viville, S., additional, Magli, C., additional, Grugnetti, C., additional, Castelletti, E., additional, Paviglianiti, B., additional, Pepas, L., additional, Braude, P., additional, Grace, J., additional, Bolton, V., additional, Khalaf, Y., additional, El-Toukhy, T., additional, Galeraud-Denis, I., additional, Bouraima, H., additional, Sibert, L., additional, Rives, N., additional, Carreau, S., additional, Janse, F., additional, de With, L. M., additional, Fauser, B. C. J. M., additional, Lambalk, C. B., additional, Laven, J. S. E., additional, Goverde, A. J., additional, Giltay, J. C., additional, De Leo, V., additional, Governini, L., additional, Quagliariello, A., additional, Margollicci, M. A., additional, Piomboni, P., additional, Luddi, A., additional, Miyamura, H., additional, Nishizawa, H., additional, Ota, S., additional, Suzuki, M., additional, Inagaki, A., additional, Egusa, H., additional, Nishiyama, S., additional, Kato, T., additional, Nakanishi, I., additional, Fujita, T., additional, Imayoshi, Y., additional, Markoff, A., additional, Yanagihara, I., additional, Udagawa, Y., additional, Kurahashi, H., additional, Alvaro Mercadal, B., additional, Imbert, R., additional, Demeestere, I., additional, De Leener, A., additional, Englert, Y., additional, Costagliola, S., additional, Delbaere, A., additional, Velilla, E., additional, Colomar, A., additional, Toro, E., additional, Chamosa, S., additional, Alvarez, J., additional, Lopez-Teijon, M., additional, Fernandez, S., additional, Hosoda, Y., additional, Hasegawa, A., additional, Morimoto, N., additional, Wakimoto, Y., additional, Ito, Y., additional, Komori, S., additional, Sati, L., additional, Zeiss, C., additional, Demir, R., additional, McGrath, J., additional, Ku, S. Y., additional, Kim, Y. J., additional, Kim, Y. Y., additional, Kim, H. J., additional, Park, K. E., additional, Kim, S. H., additional, Choi, Y. M., additional, Moon, S. Y., additional, Minor, A., additional, Chow, V., additional, Ma, S., additional, Martinez Mendez, E., additional, Gaytan, M., additional, Linan, A., additional, Pacheco, A., additional, San Celestino, M., additional, Nogales, C., additional, Ariza, M., additional, Cernuda, D., additional, Bronet, F., additional, Lendinez Ramirez, A. M., additional, Palomares, A. R., additional, Perez-Nevot, B., additional, Urraca, V., additional, Ruiz Martin, A., additional, Reche, A., additional, Ruiz Galdon, M., additional, Reyes-Engel, A., additional, Treff, N. R., additional, Tao, X., additional, Taylor, D., additional, Levy, B., additional, Ferry, K. M., additional, Scott Jr., R. T., additional, Vasan, S., additional, Acharya, K. K., additional, Vasan, B., additional, Yalaburgi, R., additional, Ganesan, K. K., additional, Darshan, S. C., additional, Neelima, C. H., additional, Deepa, P., additional, Akhilesh, B., additional, Sravanthi, D., additional, Sreelakshmi, K. S., additional, Deepti, H., additional, van Doorninck, J. H., additional, Eleveld, C., additional, van der Hoeven, M., additional, Birnie, E., additional, Steegers, E. A. P., additional, Galjaard, R. J., additional, van den Berg, I. M., additional, Fiorentino, F., additional, Spizzichino, L., additional, Bono, S., additional, Biricik, A., additional, Kokkali, G., additional, Rienzi, L., additional, Ubaldi, F. M., additional, Iammarrone, E., additional, Gordon, A., additional, Pantos, K., additional, Oitmaa, E., additional, Tammiste, A., additional, Suvi, S., additional, Punab, M., additional, Remm, M., additional, Metspalu, A., additional, Salumets, A., additional, Rodrigo, L., additional, Mir, P., additional, Cervero, A., additional, Mateu, E., additional, Mercader, A., additional, Vidal, C., additional, Giles, J., additional, Remohi, J., additional, Pellicer, A., additional, Martin, J., additional, Rubio, C., additional, Mozdarani, H., additional, Moghbeli Nejad, S., additional, Behmanesh, M., additional, Alleyasin, A., additional, Ghedir, H., additional, Ibala-Romdhane, S., additional, Mamai, O., additional, Brahem, S., additional, Elghezal, H., additional, Ajina, M., additional, Gribaa, M., additional, Saad, A., additional, Martinez, M. C., additional, Peinado, V., additional, Milan, M., additional, Al-Asmar, N., additional, Buendia, P., additional, Delgado, A., additional, Escrich, L., additional, Amorocho, B., additional, Simon, C., additional, Petrussa, L., additional, Van de Velde, H., additional, De Munck, N., additional, De Rycke, M., additional, Altmae, S., additional, Martinez-Conejero, J. A., additional, Esteban, F. J., additional, Ruiz-Alonso, M., additional, Stavreus-Evers, A., additional, Horcajadas, J. A., additional, Bug, B., additional, Raabe-Meyer, G., additional, Bender, U., additional, Zimmer, J., additional, Schulze, B., additional, Vogt, P. H., additional, Laisk, T., additional, Peters, M., additional, Grabar, V., additional, Feskov, A., additional, Zhilkova, E., additional, Sugawara, N., additional, Maeda, M., additional, Seki, T., additional, Manome, T., additional, Nagai, R., additional, Araki, Y., additional, Georgiou, I., additional, Lazaros, L., additional, Xita, N., additional, Chatzikyriakidou, A., additional, Kaponis, A., additional, Grigoriadis, N., additional, Hatzi, E., additional, Grigoriadis, I., additional, Sofikitis, N., additional, Zikopoulos, K., additional, Gunn, M., additional, Brezina, P. R., additional, Benner, A., additional, Du, L., additional, Kearns, W. G., additional, Shen, X., additional, Zhou, C., additional, Xu, Y., additional, Zhong, Y., additional, Zeng, Y., additional, Zhuang, G., additional, Gunn, M. C., additional, Richter, K., additional, Andreeva, P., additional, Dimitrov, I., additional, Konovalova, M., additional, Kyurkchiev, S., additional, Shterev, A., additional, Daser, A., additional, Day, E., additional, Turley, H., additional, Immesberger, A., additional, Haaf, T., additional, Hahn, T., additional, Dear, P. H., additional, Schorsch, M., additional, Don, J., additional, Golan, N., additional, Eldar, T., additional, and Yaverboim, R., additional

Published

2011

8. Ataxia-Telangiectasia Mutated Loss-of-Function Displays Variant and Tissue-Specific Differences across Tumor Types.

Author

Pilié PG, Giuliani V, Wang WL, McGrail DJ, Bristow CA, Ngoi NYL, Kyewalabye K, Wani KM, Le H, Campbell E, Sanchez NS, Yang D, Gheeya JS, Goswamy RV, Holla V, Shaw KR, Meric-Bernstam F, Liu CY, Ma X, Feng N, Machado AA, Bardenhagen JP, Vellano CP, Marszalek JR, Rajendra E, Piscitello D, Johnson TI, Likhatcheva M, Elinati E, Majithiya J, Neves J, Grinkevich V, Ranzani M, Luzarraga MR, Boursier M, Armstrong L, Geo L, Lillo G, Tse WY, Lazar AJ, Kopetz SE, Geck Do MK, Lively S, Johnson MG, Robinson HMR, Smith GCM, Carroll CL, Di Francesco ME, Jones P, Heffernan TP, and Yap TA

Subjects

Animals, Humans, Mice, Antineoplastic Agents therapeutic use, Antineoplastic Agents pharmacology, Biomarkers, Tumor genetics, Cell Line, Tumor, Loss of Function Mutation, Xenograft Model Antitumor Assays, Ataxia Telangiectasia Mutated Proteins genetics, Ataxia Telangiectasia Mutated Proteins antagonists & inhibitors, Neoplasms genetics, Neoplasms drug therapy, Neoplasms pathology

Abstract

Purpose: Mutations in the ATM gene are common in multiple cancers, but clinical studies of therapies targeting ATM-aberrant cancers have yielded mixed results. Refinement of ATM loss of function (LOF) as a predictive biomarker of response is urgently needed., Experimental Design: We present the first disclosure and preclinical development of a novel, selective ATR inhibitor, ART0380, and test its antitumor activity in multiple preclinical cancer models. To refine ATM LOF as a predictive biomarker, we performed a comprehensive pan-cancer analysis of ATM variants in patient tumors and then assessed the ATM variant-to-protein relationship. Finally, we assessed a novel ATM LOF biomarker approach in retrospective clinical data sets of patients treated with platinum-based chemotherapy or ATR inhibition., Results: ART0380 had potent, selective antitumor activity in a range of preclinical cancer models with differing degrees of ATM LOF. Pan-cancer analysis identified 10,609 ATM variants in 8,587 patient tumors. Cancer lineage-specific differences were seen in the prevalence of deleterious (Tier 1) versus unknown/benign (Tier 2) variants, selective pressure for loss of heterozygosity, and concordance between a deleterious variant and ATM loss of protein (LOP). A novel ATM LOF biomarker approach that accounts for variant classification, relationship to ATM LOP, and tissue-specific penetrance significantly enriched for patients who benefited from platinum-based chemotherapy or ATR inhibition., Conclusions: These data help to better define ATM LOF across tumor types in order to optimize patient selection and improve molecularly targeted therapeutic approaches for patients with ATM LOF cancers., (©2024 The Authors; Published by the American Association for Cancer Research.)

Published

2024

9. Quantitative, titratable and high-throughput reporter assays to measure DNA double strand break repair activity in cells.

Author

Rajendra E, Grande D, Mason B, Di Marcantonio D, Armstrong L, Hewitt G, Elinati E, Galbiati A, Boulton SJ, Heald RA, Smith GCM, and Robinson HMR

Subjects

DNA metabolism, DNA Breaks, Double-Stranded, DNA End-Joining Repair, Homologous Recombination, Recombinational DNA Repair, Humans, Cell Line, DNA Repair genetics, High-Throughput Screening Assays

Abstract

Repair of DNA damage is essential for the maintenance of genome stability and cell viability. DNA double strand breaks (DSBs) constitute a toxic class of DNA lesion and multiple cellular pathways exist to mediate their repair. Robust and titratable assays of cellular DSB repair (DSBR) are important to functionally interrogate the integrity and efficiency of these mechanisms in disease models as well as in response to genetic or pharmacological perturbations. Several variants of DSBR reporters are available, however these are often limited by throughput or restricted to specific cellular models. Here, we describe the generation and validation of a suite of extrachromosomal reporter assays that can efficiently measure the major DSBR pathways of homologous recombination (HR), classical nonhomologous end joining (cNHEJ), microhomology-mediated end joining (MMEJ) and single strand annealing (SSA). We demonstrate that these assays can be adapted to a high-throughput screening format and that they are sensitive to pharmacological modulation, thus providing mechanistic and quantitative insights into compound potency, selectivity, and on-target specificity. We propose that these reporter assays can serve as tools to dissect the interplay of DSBR pathway networks in cells and will have broad implications for studies of DSBR mechanisms in basic research and drug discovery., (© The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2024

10. The BCL-2 pathway preserves mammalian genome integrity by eliminating recombination-defective oocytes.

Author

ElInati E, Zielinska AP, McCarthy A, Kubikova N, Maciulyte V, Mahadevaiah S, Sangrithi MN, Ojarikre O, Wells D, Niakan KK, Schuh M, and Turner JMA

Subjects

Aneuploidy, Animals, Apoptosis, Apoptosis Regulatory Proteins deficiency, Apoptosis Regulatory Proteins genetics, Apoptosis Regulatory Proteins metabolism, Cell Cycle Proteins deficiency, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Chromosome Segregation, DNA Breaks, Double-Stranded, DNA-Binding Proteins deficiency, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Endodeoxyribonucleases deficiency, Endodeoxyribonucleases genetics, Endodeoxyribonucleases metabolism, Female, Fertilization, Genes, bcl-2, Meiosis genetics, Mice, Mice, Inbred C57BL, Mice, Knockout, Oocytes cytology, Phosphate-Binding Proteins deficiency, Phosphate-Binding Proteins genetics, Phosphate-Binding Proteins metabolism, Proto-Oncogene Proteins c-bcl-2 deficiency, Proto-Oncogene Proteins c-bcl-2 genetics, Signal Transduction, Tumor Suppressor Proteins deficiency, Tumor Suppressor Proteins genetics, Tumor Suppressor Proteins metabolism, bcl-2-Associated X Protein deficiency, bcl-2-Associated X Protein genetics, bcl-2-Associated X Protein metabolism, Mutation, Oocytes metabolism, Proto-Oncogene Proteins c-bcl-2 metabolism, Recombinational DNA Repair genetics

Abstract

DNA double-strand breaks (DSBs) are toxic to mammalian cells. However, during meiosis, more than 200 DSBs are generated deliberately, to ensure reciprocal recombination and orderly segregation of homologous chromosomes. If left unrepaired, meiotic DSBs can cause aneuploidy in gametes and compromise viability in offspring. Oocytes in which DSBs persist are therefore eliminated by the DNA-damage checkpoint. Here we show that the DNA-damage checkpoint eliminates oocytes via the pro-apoptotic BCL-2 pathway members Puma, Noxa and Bax. Deletion of these factors prevents oocyte elimination in recombination-repair mutants, even when the abundance of unresolved DSBs is high. Remarkably, surviving oocytes can extrude a polar body and be fertilised, despite chaotic chromosome segregation at the first meiotic division. Our findings raise the possibility that allelic variants of the BCL-2 pathway could influence the risk of embryonic aneuploidy.

Published

2020

11. SETDB1 Links the Meiotic DNA Damage Response to Sex Chromosome Silencing in Mice.

Author

Hirota T, Blakeley P, Sangrithi MN, Mahadevaiah SK, Encheva V, Snijders AP, ElInati E, Ojarikre OA, de Rooij DG, Niakan KK, and Turner JMA

Subjects

Animals, Apoptosis, DNA Repair, Histone-Lysine N-Methyltransferase genetics, Histones metabolism, Male, Mice, Mice, Inbred C57BL, Tripartite Motif-Containing Protein 28 genetics, Tripartite Motif-Containing Protein 28 metabolism, Chromosome Pairing, DNA Damage, Gene Silencing, Histone Code, Histone-Lysine N-Methyltransferase metabolism

Abstract

Meiotic synapsis and recombination ensure correct homologous segregation and genetic diversity. Asynapsed homologs are transcriptionally inactivated by meiotic silencing, which serves a surveillance function and in males drives meiotic sex chromosome inactivation. Silencing depends on the DNA damage response (DDR) network, but how DDR proteins engage repressive chromatin marks is unknown. We identify the histone H3-lysine-9 methyltransferase SETDB1 as the bridge linking the DDR to silencing in male mice. At the onset of silencing, X chromosome H3K9 trimethylation (H3K9me3) enrichment is downstream of DDR factors. Without Setdb1, the X chromosome accrues DDR proteins but not H3K9me3. Consequently, sex chromosome remodeling and silencing fail, causing germ cell apoptosis. Our data implicate TRIM28 in linking the DDR to SETDB1 and uncover additional factors with putative meiotic XY-silencing functions. Furthermore, we show that SETDB1 imposes timely expression of meiotic and post-meiotic genes. Setdb1 thus unites the DDR network, asynapsis, and meiotic chromosome silencing., (Copyright © 2018 Francis Crick Institute. Published by Elsevier Inc. All rights reserved.)

Published

2018

12. ATR is a multifunctional regulator of male mouse meiosis.

Author

Widger A, Mahadevaiah SK, Lange J, ElInati E, Zohren J, Hirota T, Pacheco S, Maldonado-Linares A, Stanzione M, Ojarikre O, Maciulyte V, de Rooij DG, Tóth A, Roig I, Keeney S, and Turner JMA

Subjects

Animals, Ataxia Telangiectasia Mutated Proteins genetics, Ataxia Telangiectasia Mutated Proteins metabolism, Cell Cycle Proteins genetics, Cell Cycle Proteins metabolism, Chromosome Pairing genetics, Chromosomes, Mammalian metabolism, In Situ Hybridization, Fluorescence, Male, Meiotic Prophase I genetics, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Nuclear Proteins genetics, Nuclear Proteins metabolism, Phosphate-Binding Proteins, Rad51 Recombinase genetics, Rad51 Recombinase metabolism, Chromosomes, Mammalian genetics, DNA Breaks, Double-Stranded, Meiosis genetics, Spermatocytes metabolism

Abstract

Meiotic cells undergo genetic exchange between homologs through programmed DNA double-strand break (DSB) formation, recombination and synapsis. In mice, the DNA damage-regulated phosphatidylinositol-3-kinase-like kinase (PIKK) ATM regulates all of these processes. However, the meiotic functions of the PIKK ATR have remained elusive, because germline-specific depletion of this kinase is challenging. Here we uncover roles for ATR in male mouse prophase I progression. ATR deletion causes chromosome axis fragmentation and germ cell elimination at mid pachynema. This elimination cannot be rescued by deletion of ATM and the third DNA damage-regulated PIKK, PRKDC, consistent with the existence of a PIKK-independent surveillance mechanism in the mammalian germline. ATR is required for synapsis, in a manner genetically dissociable from DSB formation. ATR also regulates loading of recombinases RAD51 and DMC1 to DSBs and recombination focus dynamics on synapsed and asynapsed chromosomes. Our studies reveal ATR as a critical regulator of mouse meiosis.

Published

2018

13. DNA damage response protein TOPBP1 regulates X chromosome silencing in the mammalian germ line.

Author

ElInati E, Russell HR, Ojarikre OA, Sangrithi M, Hirota T, de Rooij DG, McKinnon PJ, and Turner JMA

Subjects

Animals, Ataxia Telangiectasia Mutated Proteins genetics, Ataxia Telangiectasia Mutated Proteins metabolism, BRCA1 Protein, Carrier Proteins metabolism, Chromosome Pairing, Histones genetics, Histones metabolism, Male, Mice, Mice, Knockout, Sex Chromosomes metabolism, Spermatids cytology, Spermatids growth & development, Spermatids metabolism, Spermatocytes cytology, Spermatocytes growth & development, Spermatocytes metabolism, Spermatogonia cytology, Spermatogonia growth & development, Spermatogonia metabolism, Spermatozoa cytology, Spermatozoa growth & development, Spermatozoa metabolism, Tumor Suppressor Proteins genetics, Tumor Suppressor Proteins metabolism, Carrier Proteins genetics, DNA Breaks, Double-Stranded, Sex Chromosomes chemistry, Spermatogenesis genetics, X Chromosome Inactivation

Abstract

Meiotic synapsis and recombination between homologs permits the formation of cross-overs that are essential for generating chromosomally balanced sperm and eggs. In mammals, surveillance mechanisms eliminate meiotic cells with defective synapsis, thereby minimizing transmission of aneuploidy. One such surveillance mechanism is meiotic silencing, the inactivation of genes located on asynapsed chromosomes, via ATR-dependent serine-139 phosphorylation of histone H2AFX (γH2AFX). Stimulation of ATR activity requires direct interaction with an ATR activation domain (AAD)-containing partner. However, which partner facilitates the meiotic silencing properties of ATR is unknown. Focusing on the best-characterized example of meiotic silencing, meiotic sex chromosome inactivation, we reveal this AAD-containing partner to be the DNA damage and checkpoint protein TOPBP1. Conditional TOPBP1 deletion during pachynema causes germ cell elimination associated with defective X chromosome gene silencing and sex chromosome condensation. TOPBP1 is essential for localization to the X chromosome of silencing "sensors," including BRCA1, and effectors, including ATR, γH2AFX, and canonical repressive histone marks. We present evidence that persistent DNA double-strand breaks act as silencing initiation sites. Our study identifies TOPBP1 as a critical factor in meiotic sex chromosome silencing., Competing Interests: The authors declare no conflict of interest.

Published

2017

14. DNA damage induces a kinetochore-based ATM/ATR-independent SAC arrest unique to the first meiotic division in mouse oocytes.

Author

Lane SIR, Morgan SL, Wu T, Collins JK, Merriman JA, ElInati E, Turner JM, and Jones KT

Subjects

Anaphase-Promoting Complex-Cyclosome metabolism, Animals, Aurora Kinases metabolism, Centromere drug effects, Centromere metabolism, Intracellular Signaling Peptides and Proteins metabolism, Kinetochores drug effects, Mice, Models, Biological, Oocytes drug effects, Protein Kinase Inhibitors pharmacology, Protein Serine-Threonine Kinases metabolism, Ataxia Telangiectasia Mutated Proteins metabolism, DNA Damage, Kinetochores metabolism, M Phase Cell Cycle Checkpoints drug effects, Meiosis drug effects, Oocytes cytology, Oocytes metabolism

Abstract

Mouse oocytes carrying DNA damage arrest in meiosis I, thereby preventing creation of embryos with deleterious mutations. The arrest is dependent on activation of the spindle assembly checkpoint, which results in anaphase-promoting complex (APC) inhibition. However, little is understood about how this checkpoint is engaged following DNA damage. Here, we find that within minutes of DNA damage checkpoint proteins are assembled at the kinetochore, not at damage sites along chromosome arms, such that the APC is fully inhibited within 30 min. Despite this robust response, there is no measurable loss in k-fibres, or tension across the bivalent. Through pharmacological inhibition we observed that the response is dependent on Mps1 kinase, aurora kinase and Haspin. Using oocyte-specific knockouts we find the response does not require the DNA damage response kinases ATM or ATR. Furthermore, checkpoint activation does not occur in response to DNA damage in fully mature eggs during meiosis II, despite the divisions being separated by just a few hours. Therefore, mouse oocytes have a unique ability to sense DNA damage rapidly by activating the checkpoint at their kinetochores., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

15. A new mutation identified in SPATA16 in two globozoospermic patients.

Author

ElInati E, Fossard C, Okutman O, Ghédir H, Ibala-Romdhane S, Ray PF, Saad A, Hennebicq S, and Viville S

Subjects

DNA Mutational Analysis, Founder Effect, Genotype, Haplotypes, Humans, Male, Polymorphism, Single Nucleotide, Sequence Deletion, Vesicular Transport Proteins, Homeodomain Proteins genetics, Mutation, Teratozoospermia genetics

Abstract

Purpose: The aim of this study is to identify potential genes involved in human globozoopsermia., Methods: Nineteen globozoospermic patients (previously screened for DPY19L2 mutations with no causative mutation) were recruited in this study and screened for mutations in genes implicated in human globozoospermia SPATA16 and PICK1. Using the candidate gene approach and the determination of Spata16 partners by Glutathione S-transferase (GST) pull-down four genes were also selected and screened for mutations., Results: We identified a novel mutation of SPATA16: deletion of 22.6 Kb encompassing the first coding exon in two unrelated Tunisian patients who presented the same deletion breakpoints. The two patients shared the same haplotype, suggesting a possible ancestral founder effect for this new deletion. Four genes were selected using the candidate gene approach and the GST pull-down (GOPC, PICK1, AGFG1 and IRGC) and were screened for mutation, but no variation was identified., Conclusions: The present study confirms the pathogenicity of the SPATA16 mutations. The fact that no variation was detected in the coding sequence of AFGF1, GOPC, PICK1 and IRGC does not mean that they are not involved in human globozoospermia. A larger globozoospermic cohort must be studied in order to accelerate the process of identifying new genes involved in such phenotypes. Until sufficient numbers of patients have been screened, AFGF1, GOPC, PICK1 and IRGC should still be considered as candidate genes.

Published

2016

16. Silencing of X-Linked MicroRNAs by Meiotic Sex Chromosome Inactivation.

Author

Royo H, Seitz H, ElInati E, Peters AH, Stadler MB, and Turner JM

Subjects

Animals, Gene Expression Regulation, Developmental, Gene Silencing, Genes, X-Linked, Humans, Male, Meiosis genetics, Mice, MicroRNAs genetics, Pachytene Stage, Spermatocytes metabolism, Y Chromosome genetics, MicroRNAs biosynthesis, Spermatogenesis, X Chromosome genetics, X Chromosome Inactivation genetics

Abstract

During the pachytene stage of meiosis in male mammals, the X and Y chromosomes are transcriptionally silenced by Meiotic Sex Chromosome Inactivation (MSCI). MSCI is conserved in therian mammals and is essential for normal male fertility. Transcriptomics approaches have demonstrated that in mice, most or all protein-coding genes on the X chromosome are subject to MSCI. However, it is unclear whether X-linked non-coding RNAs behave in a similar manner. The X chromosome is enriched in microRNA (miRNA) genes, with many exhibiting testis-biased expression. Importantly, high expression levels of X-linked miRNAs (X-miRNAs) have been reported in pachytene spermatocytes, indicating that these genes may escape MSCI, and perhaps play a role in the XY-silencing process. Here we use RNA FISH to examine X-miRNA expression in the male germ line. We find that, like protein-coding X-genes, X-miRNAs are expressed prior to prophase I and are thereafter silenced during pachynema. X-miRNA silencing does not occur in mouse models with defective MSCI. Furthermore, X-miRNAs are expressed at pachynema when present as autosomally integrated transgenes. Thus, we conclude that silencing of X-miRNAs during pachynema in wild type males is MSCI-dependent. Importantly, misexpression of X-miRNAs during pachynema causes spermatogenic defects. We propose that MSCI represents a chromosomal mechanism by which X-miRNAs, and other potential X-encoded repressors, can be silenced, thereby regulating genes with critical late spermatogenic functions.

Published

2015

17. Histone H2AFX Links Meiotic Chromosome Asynapsis to Prophase I Oocyte Loss in Mammals.

Author

Cloutier JM, Mahadevaiah SK, ElInati E, Nussenzweig A, Tóth A, and Turner JM

Subjects

Animals, Chromosome Aberrations, Chromosome Disorders genetics, DNA Breaks, Double-Stranded, DNA Damage genetics, Female, Histones metabolism, Humans, Male, Meiotic Prophase I genetics, Mice, Oocytes metabolism, Ovary metabolism, Prophase genetics, X Chromosome genetics, Chromosome Pairing genetics, Histones genetics, Oocytes growth & development, Ovary growth & development

Abstract

Chromosome abnormalities are common in the human population, causing germ cell loss at meiotic prophase I and infertility. The mechanisms driving this loss are unknown, but persistent meiotic DNA damage and asynapsis may be triggers. Here we investigate the contribution of these lesions to oocyte elimination in mice with chromosome abnormalities, e.g. Turner syndrome (XO) and translocations. We show that asynapsed chromosomes trigger oocyte elimination at diplonema, which is linked to the presence of phosphorylated H2AFX (γH2AFX). We find that DNA double-strand break (DSB) foci disappear on asynapsed chromosomes during pachynema, excluding persistent DNA damage as a likely cause, and demonstrating the existence in mammalian oocytes of a repair pathway for asynapsis-associated DNA DSBs. Importantly, deletion or point mutation of H2afx restores oocyte numbers in XO females to wild type (XX) levels. Unexpectedly, we find that asynapsed supernumerary chromosomes do not elicit prophase I loss, despite being enriched for γH2AFX and other checkpoint proteins. These results suggest that oocyte loss cannot be explained simply by asynapsis checkpoint models, but is related to the gene content of asynapsed chromosomes. A similar mechanistic basis for oocyte loss may operate in humans with chromosome abnormalities.

Published

2015

18. Globozoospermia is mainly due to DPY19L2 deletion via non-allelic homologous recombination involving two recombination hotspots.

Author

Elinati E, Kuentz P, Redin C, Jaber S, Vanden Meerschaut F, Makarian J, Koscinski I, Nasr-Esfahani MH, Demirol A, Gurgan T, Louanjli N, Iqbal N, Bisharah M, Pigeon FC, Gourabi H, De Briel D, Brugnon F, Gitlin SA, Grillo JM, Ghaedi K, Deemeh MR, Tanhaei S, Modarres P, Heindryckx B, Benkhalifa M, Nikiforaki D, Oehninger SC, De Sutter P, Muller J, and Viville S

Subjects

Homozygote, Humans, Linkage Disequilibrium, Male, Point Mutation, Repetitive Sequences, Nucleic Acid, Gene Deletion, Homologous Recombination, Infertility, Male genetics, Membrane Proteins genetics

Abstract

To date, mutations in two genes, SPATA16 and DPY19L2, have been identified as responsible for a severe teratozoospermia, namely globozoospermia. The two initial descriptions of the DPY19L2 deletion lead to a very different rate of occurrence of this mutation among globospermic patients. In order to better estimate the contribution of DPY19L2 in globozoospermia, we screened a larger cohort including 64 globozoospermic patients. Twenty of the new patients were homozygous for the DPY19L2 deletion, and 7 were compound heterozygous for both this deletion and a point mutation. We also identified four additional mutated patients. The final mutation load in our cohort is 66.7% (36 out of 54). Out of 36 mutated patients, 69.4% are homozygous deleted, 19.4% heterozygous composite and 11.1% showed a homozygous point mutation. The mechanism underlying the deletion is a non-allelic homologous recombination (NAHR) between the flanking low-copy repeats. Here, we characterized a total of nine breakpoints for the DPY19L2 NAHR-driven deletion that clustered in two recombination hotspots, both containing direct repeat elements (AluSq2 in hotspot 1, THE1B in hotspot 2). Globozoospermia can be considered as a new genomic disorder. This study confirms that DPY19L2 is the major gene responsible for globozoospermia and enlarges the spectrum of possible mutations in the gene. This is a major finding and should contribute to the development of an efficient molecular diagnosis strategy for globozoospermia.

Published

2012

19. DPY19L2 deletion as a major cause of globozoospermia.

Author

Koscinski I, Elinati E, Fossard C, Redin C, Muller J, Velez de la Calle J, Schmitt F, Ben Khelifa M, Ray PF, Kilani Z, Barratt CL, and Viville S

Subjects

Acrosome metabolism, Acrosome pathology, Female, Humans, Male, Sperm Head metabolism, Sperm Head pathology, Gene Deletion, Infertility, Male genetics, Membrane Proteins genetics

Abstract

Globozoospermia, characterized by round-headed spermatozoa, is a rare (< 0.1% in male infertile patients) and severe teratozoospermia consisting primarily of spermatozoa lacking an acrosome. Studying a Jordanian consanguineous family in which five brothers were diagnosed with complete globozoospermia, we showed that the four out of five analyzed infertile brothers carried a homozygous deletion of 200 kb on chromosome 12 encompassing only DPY19L2. Very similar deletions were found in three additional unrelated patients, suggesting that DPY19L2 deletion is a major cause of globozoospermia, given that 19% (4 of 21) of the analyzed patients had such deletion. The deletion is most probably due to a nonallelic homologous recombination (NAHR), because the gene is surrounded by two low copy repeats (LCRs). We found DPY19L2 deletion in patients from three different origins and two different breakpoints, strongly suggesting that the deletion results from recurrent events linked to the specific architectural feature of this locus rather than from a founder effect, without fully excluding a recent founder effect. DPY19L2 is associated with a complete form of globozoospermia, as is the case for the first two genes found to be associated with globozoospermia, SPATA16 or PICK1. However, in contrast to SPATA16, for which no pregnancy was reported, pregnancies were achieved, via intracytoplasmic sperm injection, for two patients with DPY19L2 deletion, who then fathered three children., (Copyright © 2011 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2011