Genomic Instability and DNA Repair

基因组不稳定性和 DNA 修复

基本信息

批准号：
10608878
负责人：
TERRY L. SHEPPARD
金额：
$ 1.5万
依托单位：
KEYSTONE SYMPOSIA
依托单位国家：
美国
项目类别：
财政年份：
2023
资助国家：
美国
起止时间：
2023-03-28 至 2023-12-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/10608878
关键词：
Acceleration Affect Antineoplastic Agents Area Attention Biology COVID-19 pandemic Canada Cell division Cell physiology Chromatin Clinic Collaborations Communication DNA Repair DNA biosynthesis Development Disease Educational workshop Fertilization Genome Stability Genome engineering Genomic DNA Genomic Instability Immune signaling Inflammatory International Knowledge Learning Malignant Neoplasms Medical Methodology Molecular Nuclear Outcome Physiological Poly(ADP-ribose) Polymerase Inhibitor Process Public Health Reaction Research Research Personnel Science Scientist Signal Transduction Students Underrepresented Minority Vacuum Virus Diseases Woman Work acute stress cancer immunotherapy clinical practice disorder control human disease improved next generation novel therapeutic intervention pandemic disease posters programs single molecule small molecule inhibitor symposium targeted agent treatment strategy

项目摘要

ABSTRACT Support is requested for a Keystone Symposia conference entitled Genomic Instability and DNA Repair, organized by Drs. Katharina Schlacher, Irene Chiolo and Ralph Scully. The conference will be held in Whistler, BC, Canada from March 19-23, 2023. DNA replication and repair are critical processes that initiate, orchestrate, and affect a broad range of fundamental physiological reactions, ultimately promoting cell division, genome stability, and proper cellular physiology. The field of genome stability is rich in mechanistic understanding that directly led to development of small molecule inhibitors such as PARP inhibitors, now used standardly in the clinic as anti-cancer agents. Nuclear genome stability actors, however, do not act in a vacuum, but interact, communicate and collaborate with diverse intrinsic and extrinsic cellular processes. The field is at the cusp of the next level of understanding of how diverse cellular and physiological reactions directly work together with genome stability mechanisms on a molecular level and how to use this understanding to develop new treatment strategies against human diseases. The control and governance of inflammatory and immune signaling reactions as it relates to replication and chromatin reactions in particular is a potentially potent cutting-edge connection for the field, given the importance of these reactions during immunotherapy of cancer. This is enabled specifically by the continued development of single molecule targeting agents, which have arise from the strong molecular understanding of the field. The knowledge of how to control and direct inflammatory signaling will propel our understanding of how to control diseases beyond cancer. This includes viral infections, which are of particular relevance to public health during the recent pandemic. This Keystone Symposia conference will highlight the latest advances and emerging concepts in the field, aspiring to prompt rich discussions especially focused on implications for medical biology, disease and treatment strategies. This conference focusing on DNA replication and repair will be held jointly with a conference on Precision Genome Engineering, providing outstanding opportunities for cross-fertilization between these two complementary fields.

抽象的请求支持题为“基因组不稳定性和 DNA 修复”的 Keystone Symposia 会议，由博士组织。卡塔琳娜·施拉彻、艾琳·奇奥洛和拉尔夫·斯卡利。会议将在惠斯勒举行加拿大不列颠哥伦比亚省，2023 年 3 月 19 日至 23 日。 DNA 复制和修复是启动、协调和影响广泛范围的关键过程。基本的生理反应，最终促进细胞分裂、基因组稳定性和适当的细胞生理。基因组稳定性领域有着丰富的机制理解，直接导致了发展小分子抑制剂，如 PARP 抑制剂，目前在临床上标准用作抗癌药物代理。然而，核基因组稳定性参与者并不是在真空中行动，而是相互作用、沟通和与不同的内在和外在细胞过程协作。该领域正处于下一个水平的风口浪尖了解不同的细胞和生理反应如何与基因组稳定性直接协同作用分子水平上的机制以及如何利用这种理解来开发新的治疗策略对抗人类疾病。炎症和免疫信号反应的控制和治理与复制和染色质反应有关，特别是对于鉴于这些反应在癌症免疫治疗过程中的重要性。这是专门通过单分子靶向药物的不断发展，这些药物源于强大的分子对这个领域的了解。了解如何控制和引导炎症信号传导将推动我们了解如何控制癌症以外的疾病。这包括病毒感染，特别是与最近大流行期间的公共卫生相关。本次 Keystone 研讨会将重点介绍该领域的最新进展和新兴概念，渴望引发丰富的讨论，特别关注对医学生物学、疾病和治疗策略的影响。本次会议聚焦DNA 复制和修复将与精密基因组工程会议联合举行，提供这两个互补领域之间的交叉施肥的绝佳机会。