Collaborative Research: Insults for free: the roles of metamorphosis and dormancy in aging dynamics

合作研究：免费侮辱：变态和休眠在衰老动态中的作用

• 批准号: 2311953
• 负责人: Michael Dillon
• 金额: $ 39.83万
• 依托单位: University of Wyoming
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2023
• 资助国家: 美国
• 起止时间: 2023-08-01 至 2026-07-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2311953&HistoricalAwards=false
• 关键词: Collaborative; Research; Insults; free; roles

Biological age does not always correlate with chronological age, and it is unclear how physiology contributes to aging or protects from it. Some hypotheses predict that organisms will repair tissues necessary for reproduction, while allowing other tissues to age. Other hypotheses predict the opposite: tissues related to reproduction will age faster because of selection for early life fitness. This research will examine aging dynamics across life stages and tissues, and in response to stress. Bees are an ideal system to probe the mechanistic underpinnings of extreme differences in lifespan, yielding general insight into regulators of aging. Bee life-cycles are short compared to vertebrates and its possible to examine lifetime patterns of senescence. And, many aspects of cellular senescence are conserved across insects and vertebrates. Investigating how aging dynamics differ among species may lead to new ways of disrupting negative effects of aging. Understanding aging is particularly pressing in a world in which organisms are increasingly exposed to stress and many bee species are in decline. The proposed research will support the training of six graduate students and six undergraduate students. A K-12 learning module on bumble bee spring emergence will be developed as a hands-on lesson to engage Native American high school students in STEM. As part of an ongoing collaboration, informational exhibits and outreach events about pollinators will be developed with the Red River Valley Zoo (Fargo, ND) and Science Kids and Wyoming PBS (Laramie, WY). The objective of the proposed research is to integrate physiology with life history theory to mechanistically explain patterns of aging. Insect metamorphosis may be an extreme version of the disposable soma hypothesis. During metamorphosis, larval tissues are recycled and replaced by imaginal cells with stem cell-like properties, which have the potential to be cellularly “younger” than the tissues they replace. Insect metamorphosis may provide an opportunity to dispose of damaged somatic tissues, mitigating the effects of juvenile exposure to stress. Insect overwintering, also known as diapause, also has important implications for aging. Diapause increases lifespans by six times compared to non-diapausing individuals. This research will determine how metamorphosis and diapause contribute to aging dynamics by examining cellular damage and organismal performance by: 1) determining the relationship between senescence and cellular markers of aging, 2) examining how the disposable soma during metamorphosis influences aging by comparing cellular aging in tissues formed during metamorphosis to those carried over from the larval stage, and 3) assessing whether overwintering dormancy is a slowing down of aging or is regenerative. The proposed research will investigate these dynamics in solitary bees and bumble bees, and will strengthen an already productive collaboration between NDSU, UW, and the USDA-ARS, and greatly extend what is known about the mechanisms that contribute to variation in senescence.This project is jointly funded by the Integrative Ecological Physiology program and the Established Program to Stimulate Competitive Research (EPSCoR).This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

生物学年龄并不总是与实际年龄相关，目前还不清楚生理学如何促进衰老或防止衰老。一些假设预测，生物体将修复生殖所需的组织，同时允许其他组织老化。其他假说则预测相反的情况：与生殖有关的组织会因为早期生命健康的选择而老化得更快。这项研究将检查整个生命阶段和组织的衰老动力学，以及对压力的反应。蜜蜂是一个理想的系统，可以探索寿命极端差异的机械基础，从而对衰老的调节因子产生普遍的洞察力。与脊椎动物相比，蜜蜂的生命周期很短，因此有可能检查衰老的生命模式。而且，细胞衰老的许多方面在昆虫和脊椎动物中是保守的。研究不同物种之间衰老动力学的差异可能会导致破坏衰老负面影响的新方法。在生物体日益面临压力且许多蜜蜂物种数量正在减少的世界中，了解衰老尤其紧迫。拟议的研究将支持六名研究生和六名本科生的培训。一个关于大黄蜂春季出现的K-12学习模块将被开发为一个动手课程，以吸引美国土著高中学生参与STEM。作为正在进行的合作的一部分，将与红河山谷动物园（法戈，ND）和科学儿童和怀俄明州PBS（拉勒米，WY）一起开发关于传粉者的信息展览和推广活动。这项研究的目的是将生理学与生活史理论结合起来，从机制上解释衰老的模式。昆虫变态可能是一次性索马假说的极端版本。在变态过程中，幼虫组织被回收并被具有干细胞样特性的成虫细胞所取代，这些细胞具有比它们所取代的组织更“年轻”的潜力。昆虫变态可能提供了一个机会，以处理受损的体细胞组织，减轻青少年暴露于压力的影响。昆虫越冬，也被称为滞育，对衰老也有重要影响。与非滞育个体相比，滞育使寿命延长六倍。这项研究将通过检查细胞损伤和生物体性能来确定变态和滞育如何对衰老动力学做出贡献：1）确定衰老和衰老的细胞标志物之间的关系，2）通过比较变态期间形成的组织中的细胞衰老和从幼虫阶段延续的细胞衰老来检查变态期间的一次性索马如何影响衰老，以及3）评估越冬休眠是老化的减缓还是再生。拟议的研究将调查这些动态在孤独的蜜蜂和熊蜂，并将加强之间已经富有成效的合作NDSU，华盛顿大学和USDA-ARS，并极大地扩展了对衰老变化机制的了解。该项目由综合生态生理学计划和刺激竞争研究的既定计划（EPSCoR）共同资助。该奖项反映了NSF的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。