Temperature-Dependent Regulation of Proteostasis and Longevity

✅ 全文

温度依赖的蛋白质稳态调控与长寿

作者 Kavya Leo Vakkayil; Thorsten Hoppe 期刊 Frontiers in Aging 发表日期 2022 ISSN 2673-6217 DOI 10.3389/fragi.2022.853588 类型 原创研究 (Original Research)

📄 英文摘要 English Abstract

EN

Temperature is an important environmental condition that determines the physiology and behavior of all organisms. Animals use different response strategies to adapt and survive fluctuations in ambient temperature. The hermaphrodite Caenorhabditis elegans has a well-studied neuronal network consisting of 302 neurons. The bilateral AFD neurons are the primary thermosensory neurons in the nematode. In addition to regulating thermosensitivity, AFD neurons also coordinate cellular stress responses through systemic mechanisms involving neuroendocrine signaling. Recent studies have examined the effects of temperature on altering various signaling pathways through specific gene expression programs that promote stress resistance and longevity. These studies challenge the proposed theories of temperature-dependent regulation of aging as a passive thermodynamic process. Instead, they provide evidence that aging is a well-defined genetic program. Loss of protein homeostasis (proteostasis) is one of the key hallmarks of aging. Indeed, proteostasis pathways, such as the heat shock response and aggregation of metastable proteins, are also controlled by thermosensory neurons in C. elegans . Prolonged heat stress is thought to play a critical role in the development of neurodegenerative protein misfolding diseases in humans. This review presents the latest evidence on how temperature coordinates proteostasis and aging. It also discusses how studies of poikilothermic organisms can be applied to vertebrates and provides new therapeutic strategies for human disease.

📄 中文摘要 Chinese Abstract

中文
温度是影响所有生物体生理和行为的关键环境因素。像秀丽隐杆线虫(*Caenorhabditis elegans*)这样的变温动物缺乏内在的体温调节机制,因此其核心体温会随环境温度波动。这些生物依赖感觉神经元——特别是双侧AFD神经元——来检测温度变化并协调系统性反应。最新研究挑战了温度依赖性衰老是被动热力学过程的传统观点,转而支持衰老受特定遗传程序调控的观点。衰老的一个关键标志是蛋白质稳态(proteostasis)的衰退,涉及分子伴侣、泛素-蛋白酶体系统(UPS)和自噬。在*C. elegans*中,温度感觉神经元调控热休克反应(HSR)和蛋白质聚集等蛋白质稳态通路,将环境感知直接与细胞应激抗性和寿命联系起来。

📋 英文结构化总结 English Structured Summary

全文整理

EN

Background:

Temperature is a critical environmental factor influencing the physiology and behavior of all organisms. Poikilothermic animals like *Caenorhabditis elegans* lack internal thermoregulation, so their core body temperature fluctuates with ambient conditions. These organisms rely on sensory neurons—particularly the bilateral AFD neurons—to detect temperature changes and coordinate systemic responses. Recent research challenges the traditional view that temperature-dependent aging is a passive thermodynamic process, instead supporting the idea that aging is governed by defined genetic programs. A key hallmark of aging is the decline in protein homeostasis (proteostasis), which involves molecular chaperones, the ubiquitin–proteasome system (UPS), and autophagy. In *C. elegans*, thermosensory neurons regulate proteostasis pathways such as the heat shock response (HSR) and protein aggregation, linking environmental sensing directly to cellular stress resistance and longevity.

Methods:

N/A – Review article

Results:

Studies in *C. elegans* demonstrate that temperature modulates proteostasis and longevity through neuroendocrine signaling initiated by thermosensory neurons. At 25°C, late larval transfer from 20°C activates the unfolded protein response in the endoplasmic reticulum (UPRER), transiently increases HSR, and enhances UPS activity in the intestine—but not in muscle—indicating tissue-specific regulation. The eIF4E family protein IFE-2 boosts translational efficiency of specific mRNAs at 25°C. Hormetic heat shock (36°C for 1 hour) induces autophagy and selective HSR, reducing protein aggregation. Low temperatures extend lifespan via TRPA-1–mediated cold sensing in neurons and intestine, activating DAF-16 through PKC-2 and SGK-1. Fatty acid signaling involving PAQR-2, FAT-7, and MDT-15 regulates autophagy and chaperone expression at 15°C. AFD neurons control longevity at warm temperatures via DAF-9/DAF-12 steroid signaling, while ASJ neurons shorten lifespan via INS-6/DAF-28 neuropeptides. Overexpression of *hsf-1* in neurons or the proteasomal subunit *rpn-6.1* extends lifespan at 25°C via distinct pathways.

Data Summary:

*C. elegans* mean lifespan is 15.2 ± 0.5 days at 25°C and 26.1 ± 0.6 days at 15°C. Transient heat stress during early development increases adult lifespan via CBP-1 and SWI/SNF chromatin remodeling. Loss of AFD neuron function reduces lifespan at 25°C but not 15°C. *daf-41* mutants live longer at high temperatures but are short-lived at cold temperatures. TRPA-1 expression in neurons or intestine promotes longevity at low temperatures. Overexpression of *rpn-6.1* extends lifespan independently of HSF-1 but dependent on DAF-16.

Conclusions:

Temperature-dependent regulation of proteostasis and longevity is an active, genetically controlled process mediated by thermosensory neurons and systemic signaling in *C. elegans*. Key pathways include HSR, UPRER, UPS, autophagy, and lipid metabolism, all modulated by neuronal circuits and neuroendocrine factors. These findings refute the notion that thermal effects on aging are purely passive and highlight the role of sensory perception in coordinating organismal stress responses and lifespan.

Practical Significance:

Insights from *C. elegans* offer potential therapeutic strategies for human aging and neurodegenerative diseases. Mild hypothermia or heat therapy (e.g., sauna bathing) may enhance proteostasis and reduce cardiovascular risk. Cold-shock proteins like RBM3 show neuroprotective effects in mouse models, suggesting avenues for treating protein-misfolding disorders. Understanding how temperature sensing regulates proteostasis could inform interventions to promote healthy aging in homeotherms, including humans.

📋 中文结构化总结 Chinese Structured Summary

中文

背景:

温度是影响所有生物体生理和行为的关键环境因素。像秀丽隐杆线虫(*Caenorhabditis elegans*)这样的变温动物缺乏内在的体温调节机制,因此其核心体温会随环境温度波动。这些生物依赖感觉神经元——特别是双侧AFD神经元——来检测温度变化并协调系统性反应。最新研究挑战了温度依赖性衰老是被动热力学过程的传统观点,转而支持衰老受特定遗传程序调控的观点。衰老的一个关键标志是蛋白质稳态(proteostasis)的衰退,涉及分子伴侣、泛素-蛋白酶体系统(UPS)和自噬。在*C. elegans*中,温度感觉神经元调控热休克反应(HSR)和蛋白质聚集等蛋白质稳态通路,将环境感知直接与细胞应激抗性和寿命联系起来。

方法:

不适用——综述文章

结果:

*C. elegans*的研究表明,温度通过温度感觉神经元启动的神经内分泌信号调节蛋白质稳态和寿命。在25°C下,从20°C转移至晚期幼虫阶段会激活内质网中的未折叠蛋白反应(UPRER),短暂增强HSR,并提高肠道(而非肌肉)中的UPS活性,表明存在组织特异性调控。eIF4E家族蛋白IFE-2在25°C下增强特定mRNA的翻译效率。低剂量热激(36°C,1小时)诱导自噬和选择性HSR,减少蛋白质聚集。低温通过TRPA-1介导的神经元和肠道冷感觉延长寿命,经PKC-2和SGK-1激活DAF-16。涉及PAQR-2、FAT-7和MDT-15的脂肪酸信号在15°C下调控自噬和伴侣蛋白表达。AFD神经元通过DAF-9/DAF-12类固醇信号控制高温下的寿命,而ASJ神经元通过INS-6/DAF-28神经肽缩短寿命。在神经元中过表达*hsf-1*或蛋白酶体亚基*rpn-6.1*通过不同通路在25°C下延长寿命。

数据摘要:

*C. elegans*在25°C下的平均寿命为15.2 ± 0.5天,在15°C下为26.1 ± 0.6天。早期发育期间的短暂热应激通过CBP-1和SWI/SNF染色质重塑增加成年寿命。AFD神经元功能丧失会缩短25°C下的寿命,但不影响15°C下的寿命。*daf-41*突变体在高温下寿命延长,但在低温下寿命缩短。TRPA-1在神经元或肠道中的表达促进低温下的长寿。*rpn-6.1*的过表达独立于HSF-1但依赖DAF-16来延长寿命。

结论:

温度依赖性蛋白质稳态和寿命调控是一个由温度感觉神经元和系统性信号介导的、主动的遗传控制过程。关键通路包括HSR、UPRER、UPS、自噬和脂质代谢,均由神经回路和神经内分泌因子调控。这些发现驳斥了温度对衰老的影响纯粹是被动的观点,并强调了感觉感知在协调生物体应激反应和寿命中的作用。

实际意义:

来自*C. elegans*的见解为人类衰老和神经退行性疾病提供了潜在的治疗策略。轻度低体温或热疗(如桑拿浴)可能增强蛋白质稳态并降低心血管风险。冷休克蛋白如RBM3在小鼠模型中显示出神经保护作用,为治疗蛋白质错误折叠疾病提供了新途径。理解温度感知如何调控蛋白质稳态可能有助于促进恒温动物(包括人类)的健康衰老干预。

📖 英文全文 English Full Text

EN

MINI REVIEW published: 24 March 2022 doi: 10.3389/fragi.2022.853588

Temperature-Dependent Regulation of Proteostasis and Longevity Kavya Leo Vakkayil 1 and Thorsten Hoppe 1,2* 1 Institute for Genetics and Cologne Excellence Cluster on Cellular Stress Responses in Aging-Associated Diseases (CECAD), University of Cologne, Cologne, Germany, 2Center for Molecular Medicine Cologne (CMMC), University of Cologne, Cologne, Germany

Edited by: Cindy Voisine, Northeastern Illinois University, United States Reviewed by: Mark A. McCormick, University of New Mexico, United States Matthias Peter Mayer, Heidelberg University, Germany *Correspondence: Thorsten Hoppe thorsten.hoppe@uni-koeln.de Specialty section: This article was submitted to Aging, Metabolism and Redox Biology, a section of the journal Frontiers in Aging Received: 12 January 2022 Accepted: 11 February 2022 Published: 24 March 2022 Citation: Vakkayil KL and Hoppe T (2022) Temperature-Dependent Regulation of Proteostasis and Longevity. Front. Aging 3:853588. doi: 10.3389/fragi.2022.853588

Temperature is an important environmental condition that determines the physiology and behavior of all organisms. Animals use different response strategies to adapt and survive fluctuations in ambient temperature. The hermaphrodite Caenorhabditis elegans has a well-studied neuronal network consisting of 302 neurons. The bilateral AFD neurons are the primary thermosensory neurons in the nematode. In addition to regulating thermosensitivity, AFD neurons also coordinate cellular stress responses through systemic mechanisms involving neuroendocrine signaling. Recent studies have examined the effects of temperature on altering various signaling pathways through specific gene expression programs that promote stress resistance and longevity. These studies challenge the proposed theories of temperature-dependent regulation of aging as a passive thermodynamic process. Instead, they provide evidence that aging is a well-defined genetic program. Loss of protein homeostasis (proteostasis) is one of the key hallmarks of aging. Indeed, proteostasis pathways, such as the heat shock response and aggregation of metastable proteins, are also controlled by thermosensory neurons in C. elegans. Prolonged heat stress is thought to play a critical role in the development of neurodegenerative protein misfolding diseases in humans. This review presents the latest evidence on how temperature coordinates proteostasis and aging. It also discusses how studies of poikilothermic organisms can be applied to vertebrates and provides new therapeutic strategies for human disease. Keywords: temperature, proteostasis, protein aggregation, longevity, Caenorhabditis elegans, thermosensation, AFD neuron, cell non-autonomous signaling

INTRODUCTION “Homeostasis”—a term coined by Walter Cannon—is the self-regulating dynamic process by which an organism maintains internal stability in response to external conditions (Billman, 2020). Regulation of core body temperature (thermoregulation) is one of the ways to maintain this balance. Homeotherms (warm-blooded animals) such as mammals and birds keep a constant core temperature via hypothalamic regulation of heat production and dissipation. In contrast, poikilotherms (cold-blooded animals) such as flies, nematodes, amphibians, and reptiles lack this thermoregulatory ability. As a result, the core temperature of poikilothermic organisms fluctuates with ambient temperature changes (Tabarean et al., 2010). Another necessary means of maintaining a constant internal milieu is to preserve the integrity of cellular macromolecules such as proteins and maintain a balanced cellular proteome. Protein homeostasis (proteostasis) is promoted by a network of cellular quality control pathways (Kaushik and Cuervo, 2015), including molecular chaperones, 1

the ubiquitin–proteasome system (UPS), and the autophagy machinery (Chen et al., 2011). Regulated synthesis of polypeptides involves proper protein folding by molecular chaperones, whereas the selective degradation of damaged proteins is mediated by the UPS and the autophagy machinery (Hoppe and Cohen, 2020). Endogenous and exogenous challenges constantly threaten the integrity of the organismal proteome and affect longevity (Gumeni et al., 2017). Cells cope with cellular stress by adopting sophisticated protective measures. For example, to combat heat stress, organisms have an ancient, highly conserved genetic program termed the heat shock response (HSR) (Morimoto, 1998). An abnormal rise in temperature that triggers protein misfolding and aggregation activates the heat shock transcription factor-1 (HSF-1) in the cytoplasm. Subsequently, HSF-1 converts from an inactive monomer to an active trimeric form and activates expression of heat shock proteins (HSPs), including molecular chaperones (Anckar and Sistonen, 2011). The suppression of HSR in early adulthood renders organisms susceptible to various environmental stressors and eventually leads to breakdown of proteostasis (Ben-Zvi et al., 2009; Labbadia and Morimoto, 2015). The capacity of the proteostasis network (PN) decreases with age, leading to the accumulation of damaged proteins and chronic age-related diseases (Balchin et al., 2016). This review summarizes how proteostasis and longevity are modulated by changes in environmental temperature, focusing on studies in Caenorhabditis elegans.

FIGURE 1 | Temperature-dependent regulation of proteostasis. Autophagy and chaperone levels are affected at low temperatures via fatty acid signaling (1), (2). A wild-type thermosensory circuit attenuates protein folding during chronic stress; small dark green structures inside the worm indicate protein aggregates (3). A 1-day transfer of late larval staged C. elegans from 20 to 25°C increases the heat shock response [HSR (mildly, small arrow)], the unfolded protein response in the endoplasmic reticulum (UPRER), and the activity of the ubiquitin/proteasome-system (UPS) in the intestine (4). The translational efficiency of selective mRNAs (msh-4/him-14, msh-5) increases at 25°C via an eIF4E family protein, IFE-2 (5). AFD thermosensory neuron cells non-autonomously regulate the heat shock response [acute heat shock (HS) of 30°C for 15 min] (6). Hormetic heat shock of 1 h at 36°C induces autophagy and selective HSR (7).

However, the data prove otherwise. At physiological temperatures (20°C), thermosensory mutants suppress protein aggregation and toxicity in multiple tissues. This counterintuitive result shows that the neuronal circuitry based on the thermosensory AFD neurons differentiates between acute heat stress and chronic protein misfolding stress (Prahlad and Morimoto, 2011). Several interesting observations have been made in recent years despite the lack of mechanistic insight into the effects of temperature on proteostasis. For example, when late larval stages of C. elegans grown at 20°C are exposed to 25°C for 1 day, several stress responses are regulated. The unfolded protein response in the endoplasmic reticulum (UPRER) is strongly activated, whereas HSR increases only transiently after a 1-day exposure to 25°C. Surprisingly, a change in ambient temperature from 20 to 25°C can affect selective protein degradation via the UPS. UPS activity increases in the intestine but not in muscle cells, suggesting tissue-specific regulation of protein degradation (Pispa et al., 2020). Increasing temperature conditions also modulates mRNA translation. One of the five eukaryotic initiation factor (eIF)-4E proteins in C. elegans, IFE-2, increases the translational efficiency of certain mRNAs at 25°C (Song et al., 2010). Furthermore, hormetic heat shock of 1 h at 36°C induces autophagy and selective HSR in adult worms, associated with decreased protein aggregation (Kumsta et al., 2017). These studies suggest that C. elegans respond to elevated temperature conditions not only by triggering HSR but also other branches of the PN, including translation, protein degradation, and UPR.

The soil-dwelling nematode C. elegans is a poikilothermic organism that must constantly adapt its physiology to the changing temperature conditions in its natural habitat (Mendenhall et al., 2017). The worm perceives environmental temperature by the thermosensory neurons named AFD, AWC, ASI, and ASJ (Ohta et al., 2014). The interneurons AIY and AIZ receive thermal inputs from upstream thermosensory neurons, which are further integrated by the RIA interneurons (Kimata et al., 2012). The bilateral AFD neuron is the primary thermosensory neuron that senses ambient temperatures to regulate animal behavior (Goodman and Sengupta, 2018). Thermosensation by AFD and AIY neurons has been associated with organismal proteostasis, particularly in the regulation of the HSR. The heat shock response has always been considered a cell-autonomous response triggered by accumulation of damaged proteins. Surprisingly, a pioneering study by the Morimoto laboratory shows that thermosensory neurons control the heat shock response of somatic tissues. Consequently, worms lacking these neurons exhibit reduced thermotolerance when exposed to increased temperature (Prahlad et al., 2008). The temperature-dependent activation of AFD neurons triggers the HSR in distal tissues by serotonin signaling (Tatum et al., 2015). Reduced HSR in thermosensory mutants suggests a potential increase in protein misfolding.

25°C (He et al., 2009). The cyclic AMP (cAMP)-responsive element binding protein, CRH-1/CREB, increases expression of the FMRFamide-like neuropeptide FLP-6 in AFD neurons, promoting adult lifespan. Increased expression of FLP-6 increases DAF-9/sterol signaling in AIY neurons and downregulates insulin signaling in the gut to regulate longevity (Chen et al., 2016). Heat-sensitive ASJ neurons, when ablated, extend lifespan at 25°C. ASJ neurons act via UNC-31-dependent release of two neuropeptides, INS-6 and DAF-28, to inhibit the FOXO transcription factor DAF-16 in the gut (Zhang et al., 2018). STR-2, a G-protein-coupled receptor expressed in AWCON and ASI neurons, controls lifespan at 20°C and higher temperatures. STR-2 fine-tunes neutral lipid levels in nonneuronal tissues to adapt to higher temperatures to maintain lifespan (Dixit et al., 2020). Systemic temperature signaling at culture temperatures (17–23°C) occurs via HSF-1 activity in nonneuronal cells such as the gut or muscle. Downstream signaling modifies the thermotaxis circuit via the nuclear hormone receptor NHR-69-mediated estrogen signaling (Sugi et al., 2011). HSF-1 not only regulates thermotaxic behavioral performance but also contributes to extending animal lifespan at warm temperatures. Pioneering work by Lee and Kenyon showed that a reduction in HSF-1 function further shortened lifespan at 22.5°C. Consistent with this, recent data show that overexpression of hsf-1 in neurons protects animals at 25°C and extends their lifespan (Chauve et al., 2021). Overexpression of the proteasomal subunit rpn-6.1 extends lifespan independently of HSF-1 in a DAF-16-dependent manner at 25°C (Vilchez et al., 2012). Temperature experiences under different growth conditions can lead to different outcomes via the same central player. For example, the co-chaperone DAF-41/p23 modulates lifespan in different ways at warm and cold temperatures, as daf-41 mutants live longer at higher temperatures but are short-lived at cold temperatures (Horikawa et al., 2015). Temperature sensing across different tissues and lipid signaling interact to regulate lifespan at cold temperatures. Low temperatures significantly extend C. elegans lifespan via the cold-sensitive transient receptor potential (TRP) channel, TRPA-1. TRPA-1 is a non-selective cation channel that is also permeable to calcium. Expression of TRPA-1 in neurons or intestine promotes DAF-16 activity via a genetic program involving a calcium-sensitive kinase, PKC-2, and a DAF-16 kinase, SGK-1. Intriguingly, this study shows that the intestine, which is a non-excitable tissue in worms, functions as a cold receptor (Xiao et al., 2013). TRPA-1 acts in the coldsensitive IL1 sensory neurons. Glutamatergic and serotoninergic signals from IL1 and NSM neurons, respectively, activate a prolongevity cascade. This neuroendocrine signaling regulates DAF16 function in intestinal cells (Zhang et al., 2018). Moreover, temperature signaling from IL1 and AFD neurons maintains germline proliferation and delays germline stem cell (GSC) exhaustion. Prostaglandin E2 (PGE2) signals from adult GSCs communicate with the gut to produce hydrogen sulfide (H2S). Thus, germline and somatic tissues contribute to cold-induced longevity (Hyun Ju Lee et al., 2019). PAQR-2, MDT-15, and azelaic acid (AzA) support longevity at low temperatures through fatty acid–mediated signaling (Chen et al., 2019; Dongyeop Lee

Low temperatures regulate proteostasis pathways via modulation of lipid homeostasis. Culturing worms at 15°C promotes autophagy through signaling mediated by the adiponectin receptor PAQR-2. PAQR-2 increases fatty acid desaturase FAT-7, which triggers the biosynthesis of polyunsaturated fatty acids, namely γ-linolenic acid and arachidonic acid, to induce autophagy (Chen et al., 2019). Mediator complex subunit—mediator 15 (MDT-15/MED15) regulates the expression of fat-7 at lower temperatures. Decreasing MDT-15 levels at 15°C increases protein aggregates and cytosolic chaperone expression via HSF-1 as an adaptive response (Dongyeop Lee et al., 2019). Alternatively, gene ontology analysis shows that genes regulated by cold warming—exposure to cold shock (4°C) followed by recovery at normal temperatures (20°C)—are involved in biological processes such as autophagy and proteostasis (Jiang et al., 2018). These studies highlight the importance of different temperature conditions in regulating proteome dynamics (Figure 1). The maintenance of proteostasis is essential for healthy aging, and its impairment is considered one of the critical hallmarks of aging (López-Otín et al., 2013). In the following section, studies on the influence of temperature on longevity are described in detail.

MODULATION OF ORGANISMAL LONGEVITY BY TEMPERATURE Poikilothermic animals have shorter lifespans at higher temperatures than at lower temperatures (Lamb, 1968). C. elegans, for example, has a mean lifespan of 15.2 ± 0.5 (mean lifespan ± SEM provided) and 26.1 ± 0.6 days at 25 and 15°C, respectively (Lee and Kenyon, 2009). Pioneering studies led to the postulation of two theories, rate-of-living theory and threshold theory, to explain the effects of temperature on lifespan. Pearl’s rate-of-living theory attempts to determine lifespan as a simple rate-limiting response and proposes that the rate of aging increases at higher temperatures (Shaw and Bercaw, 1962). Alternatively, the threshold theory introduces two phases that determine lifespan—aging and dying. It states that the rate of aging is independent of temperature, while the rate of dying depends on temperature (Smith, 1963). Interestingly, the effect of temperature on lifespan has been considered mainly as a passive thermodynamic process in the aforementioned scenarios. However, several studies on poikilothermic organisms, including C. elegans, provide considerable evidence to the contrary. Sensory perception of thermal signals via thermosensory neurons plays a critical role in regulating C. elegans lifespan. AFD thermosensory neurons control lifespan at warm temperatures via a steroid signaling pathway. If AFD neuron function is knocked down from early development by genetic mutation or laser ablation, lifespan shortens at 25°C but not at 15°C. Thermosensation via these neurons contributes to inhibition of the nuclear hormone receptor (NHR) DAF-12 via DAF-9/Cytochrome P450 (Lee and Kenyon, 2009). Neuronal synaptic transmission may also affect longevity at

FIGURE 2 | Temperature-dependent regulation of longevity. Increased lifespan at low temperatures is regulated by signals involving germline stem cells (1), AFD and IL1 neurons (1 and 2), TRPA-1 (3), the co-chaperone DAF-41 (4), and fatty acids (5). AFD, AWC, and ASI neurons, and HSF-1 maintain lifespan at higher temperatures (6), overexpression of rpn-6.1 prolongs it (7), and ASJ neurons and DAF-41 shorten lifespan at higher temperatures (8).

et al., 2019; Bai et al., 2021). Although these different factors regulating life expectancy in warm and cold temperatures have been identified, it remains unclear how they communicate with each other and coordinate their functions. Extensive studies have helped to identify the main players that regulate longevity at cold and warm temperatures. Cultivation at low temperatures is beneficial, while warm temperatures affect longevity. However, this relationship does not always hold. When C. elegans is exposed to high temperatures during early developmental stages, adult lifespan increases (Zhang et al., 2015). This transient heat stress during early life activates long-lasting defense responses via histone acetyltransferase CBP-1 and the chromatin remodeling complex SWI/SNF, which promote longevity (Zhou et al., 2019). These studies show that the temperature-dependent effects on aging are a well-regulated event controlled by genetic and epigenetic factors (Figure 2).

distal tissues. Insulin-like peptides, FMRFamide-like peptides, biogenic amines, and neurotransmitters are critical for triggering downstream responses. Studies in poikilothermic animals have undoubtedly improved our understanding of temperature-dependent effects on organismal survival. However, many questions remain unanswered, particularly regarding the regulation of proteostasis. AFD thermosensory neurons and associated neuroendocrine signaling are well studied with respect to HSR. Surprisingly, there is little evidence of molecular players controlling other proteostasis pathways in response to temperature. In particular, it is unclear how temperature affects the UPS, the autophagy machinery, the unfolded protein response, and the genetic components involved. In addition to AFD, AWC, ASI, and ASJ neurons, the intestine act as temperature sensors in C. elegans. How thermosensation mediates proteostasis via these neurons and the gut remains to be elucidated. A crucial step would be to analyze how cellspecific thermosensory receptors and circuits control organismal proteostasis. C. elegans adapts to different environmental temperatures by calibrating unsaturated fatty acid levels to maintain optimal membrane fluidity (Ma et al., 2015). The role of fatty acids in regulating distinct proteostasis pathways under different temperature conditions is still unexplored. Further studies are needed to clarify these crucial issues.

DISCUSSION The evidence discussed thus far reveals a common theme in the temperature-dependent regulation of proteostasis and longevity. Environmental signals such as temperature influence organismal physiology via non-autonomous cell signaling mechanisms. Neurons act as receptors for thermal information and send signals mediated by small molecules to

Frontiers in Aging | www.frontiersin.org 4 March 2022 | Volume 3 | Article 853588 Vakkayil and Hoppe Temperature-Dependent Proteostasis Regulation TEMPERATURE—A POTENTIAL THERAPEUTIC INTERVENTION?

neurodegenerative diseases. These results suggest a potential role for therapeutic human hypothermia in achieving neuroprotective effects (Peretti et al., 2015). In-depth analyses in higher-order animals may help to exploit the benefits of temperature in improving organismal health. On a positive note, previous results from a poikilothermic animal may serve as a springboard for exploring this potential therapeutic area.

There are few studies demonstrating the effects of temperature on proteostasis and homeotherm longevity. However, some basic principles remain. Temperature determines, in part, the effects of birth time on human fetal development and longevity. In particular, an increase in ambient temperature at birth has detrimental effects (Flouris et al., 2009). The central thermostat in the preoptic area controls core body temperature (CBT) in homeotherms. Transgenic mice overexpressing the mitochondrial membrane protein uncoupling protein 2 (UCP2) in hypocretin neurons (HcrtUCP2 mice) exhibit increased hypothalamic temperature and reduced CBT. A modest but sustained reduction in CBT increases the life expectancy of Hcrt-UCP2 mice (Conti et al., 2006). Further studies have also shown that gonad-dependent differences in CBT affect life expectancy in a sex-specific manner (Sanchez-Alavez et al., 2011). In addition, selective temperature conditions may alter the pathophysiology of agerelated diseases. Aggregation of damaged proteins contributes to neurodegenerative diseases. A recent review suggested heat therapy that promotes chaperone expression as a potential treatment strategy (Hunt et al., 2020). Further evidence suggests that sauna bathing—a passive heat therapy—reduces the risk of death from cardiovascular disease (Laukkanen et al., 2018). Swimming in cold water (temperature <5°C) is also beneficial for experienced healthy individuals when practiced with caution (Knechtle et al., 2020). Cold-shock proteins such as RNA-binding motif protein 3, RBM3, are essential for maintaining synapses in laboratory mouse models of

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# 温度依赖的蛋白质稳态与寿命调控

**迷你综述** 发表日期:2022年3月24日 DOI:10.3389/fragi.2022.853588

**温度依赖的蛋白质稳态与寿命调控**

Kavya Leo Vakkayil¹ 与 Thorsten Hoppe¹,²*

¹ 科隆大学遗传学系及衰老相关疾病细胞应激反应科隆卓越集群(CECAD),德国科隆 ² 科隆大学分子医学中心(CMMC),德国科隆

**编辑:** Cindy Voisine,美国东北伊利诺伊大学

**审稿人:** Mark A. McCormick,美国新墨西哥大学 Matthias Peter Mayer,德国海德堡大学

**通讯作者:** Thorsten Hoppe thorsten.hoppe@uni-koeln.de

**专刊栏目:** 本文投稿于《衰老前沿》期刊"衰老、代谢与氧化还原生物学"栏目

**收稿日期:** 2022年1月12日 **接受日期:** 2022年2月11日 **发表日期:** 2022年3月24日

**引用格式:** Vakkayil KL 与 Hoppe T (2022) 温度依赖的蛋白质稳态与寿命调控。 Front. Aging 3:853588. doi: 10.3389/fragi.2022.853588

**摘要:** 温度是一种重要的环境条件,决定了所有生物的生理和行为。动物采用不同的响应策略来适应和应对环境温度的波动。雌雄同体的秀丽隐杆线虫(*Caenorhabditis elegans*)拥有由302个神经元组成的已被深入研究的神经网络。双侧AFD神经元是该线虫的主要温度感受神经元。除调控温度敏感性外,AFD神经元还通过涉及神经内分泌信号的系统性机制协调细胞应激反应。近期研究探讨了温度如何通过特定的基因表达程序改变多种信号通路,从而促进应激抗性和寿命延长。这些研究挑战了此前将温度依赖性衰老调控视为被动热力学过程的理论,转而提供了衰老是一个明确的遗传程序的证据。蛋白质稳态(proteostasis)的丧失是衰老的关键标志之一。事实上,蛋白质稳态通路——如热休克反应和亚稳态蛋白的聚集——同样受到线虫中温度感受神经元的调控。长时间的热应激被认为在人类神经退行性蛋白错误折叠疾病的发展中发挥关键作用。本综述呈现了温度如何协调蛋白质稳态与衰老的最新证据,并讨论了变温动物研究如何应用于脊椎动物,以及为人类疾病提供新的治疗策略。

**关键词:** 温度、蛋白质稳态、蛋白质聚集、寿命、秀丽隐杆线虫、温度感觉、AFD神经元、细胞非自主性信号传导

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## 引言

"稳态"(Homeostasis)——由Walter Cannon创造的术语——是生物体为应对外部条件而维持内部稳定的自我调节动态过程(Billman, 2020)。核心体温的调节(体温调节)是维持这种平衡的方式之一。恒温动物(温血动物),如哺乳动物和鸟类,通过下丘脑对产热和散热的调节来维持恒定的核心体温。相比之下,变温动物(冷血动物),如蝇类、线虫、两栖动物和爬行动物,缺乏这种体温调节能力。因此,变温生物的核心体温随环境温度变化而波动(Tabarean et al., 2010)。维持恒定内部环境的另一种必要方式是保持蛋白质等细胞大分子的完整性,维持平衡的细胞蛋白质组。蛋白质稳态(proteostasis)由细胞质量控制通路网络促进(Kaushik and Cuervo, 2015),包括分子伴侣、泛素-蛋白酶体系统(UPS)和自噬机器(Chen et al., 2011)。受调控的多肽合成涉及分子伴侣介导的蛋白质正确折叠,而受损蛋白质的选择性降解则由UPS和自噬机器介导(Hoppe and Cohen, 2020)。

内源性和外源性挑战不断威胁生物体蛋白质组的完整性并影响寿命(Gumeni et al., 2017)。细胞通过采取精密的保护措施来应对细胞应激。例如,为对抗热应激,生物体拥有一项古老且高度保守的遗传程序,称为热休克反应(HSR)(Morimoto, 1998)。触发蛋白质错误折叠和聚集的异常温度升高会激活细胞质中的热休克转录因子-1(HSF-1)。随后,HSF-1从无活性单体转化为活性三聚体形式,并激活热休克蛋白(HSPs)的表达,包括分子伴侣(Anckar and Sistonen, 2011)。成年早期HSR的抑制使生物体易受各种环境应激源的影响,并最终导致蛋白质稳态的崩溃(Ben-Zvi et al., 2009; Labbadia and Morimoto, 2015)。蛋白质稳态网络(PN)的能力随年龄增长而下降,导致受损蛋白质的积累和慢性年龄相关疾病(Balchin et al., 2016)。本综述总结了环境温度变化如何调控蛋白质稳态与寿命,重点关注秀丽隐杆线虫中的研究。

**图1 | 温度依赖的蛋白质稳态调控。** 低温通过脂肪酸信号传导影响自噬和伴侣蛋白水平(1)、(2)。野生型温度感觉回路在慢性应激期间减弱蛋白质折叠;线虫体内深绿色小结构表示蛋白质聚集体(3)。将晚期幼虫阶段的线虫从20°C转移至25°C持续1天,可增强热休克反应[HSR(轻度,小箭头)]、内质网未折叠蛋白反应(UPRER)以及肠道中泛素/蛋白酶体系统(UPS)的活性(4)。通过eIF4E家族蛋白IFE-2,选择性mRNA(msh-4/him-14、msh-5)在25°C下的翻译效率提高(5)。AFD温度感受神经元细胞非自主性地调控热休克反应[急性热休克(HS),30°C持续15分钟](6)。36°C持续1小时的激效热休克诱导自噬和选择性HSR(7)。

然而,数据证明事实并非如此。在生理温度(20°C)下,温度感觉突变体在多种组织中抑制蛋白质聚集和毒性。这一反直觉的结果表明,基于温度感受AFD神经元的神经回路能够区分急性热应激和慢性蛋白质错误折叠应激(Prahlad and Morimoto, 2011)。

尽管对温度影响蛋白质稳态的机制性理解仍然有限,但近年来已有若干有趣的发现。例如,当在20°C下培养的线虫晚期幼虫阶段暴露于25°C持续1天时,多种应激反应受到调控。内质网未折叠蛋白反应(UPRER)被强烈激活,而HSR在暴露于25°C 1天后仅短暂升高。令人惊讶的是,环境温度从20°C到25°C的变化可以通过UPS影响选择性蛋白质降解。UPS活性在肠道中增加,但在肌肉细胞中不增加,表明蛋白质降解受到组织特异性调控(Pispa et al., 2020)。温度升高条件还调控mRNA翻译。线虫中五种真核起始因子(eIF)-4E蛋白之一的IFE-2在25°C下提高了某些mRNA的翻译效率(Song et al., 2010)。此外,36°C持续1小时的激效热休克在成年线虫中诱导自噬和选择性HSR,与蛋白质聚集减少相关(Kumsta et al., 2017)。这些研究表明,线虫不仅通过触发HSR来响应温度升高条件,还通过蛋白质稳态网络的其他分支,包括翻译、蛋白质降解和UPR来响应。

土壤栖息的线虫秀丽隐杆线虫是一种变温生物,必须不断调整其生理以适应自然栖息地中变化的温度条件(Mendenhall et al., 2017)。线虫通过名为AFD、AWC、ASI和ASJ的温度感受神经元感知环境温度(Ohta et al., 2014)。中间神经元AIY和AIZ接收来自上游温度感受神经元的热输入,这些信号进一步由RIA中间神经元整合(Kimata et al., 2012)。双侧AFD神经元是感知环境温度以调控动物行为的主要温度感受神经元(Goodman and Sengupta, 2018)。AFD和AIY神经元的温度感觉与生物体蛋白质稳态相关,特别是在HSR的调控中。热休克反应一直被认为是由受损蛋白质积累触发的细胞自主性反应。令人惊讶的是,Morimoto实验室的一项开创性研究表明,温度感受神经元控制体细胞组织的热休克反应。因此,缺乏这些神经元的线虫在暴露于升高温度时表现出降低的热耐受性(Prahlad et al., 2008)。AFD神经元的温度依赖性激活通过血清素信号传导触发远端组织的HSR(Tatum et al., 2015)。温度感觉突变体中HSR的降低表明蛋白质错误折叠可能增加。

25°C(He et al., 2009)。环磷酸腺苷(cAMP)反应元件结合蛋白CRH-1/CREB增加AFD神经元中FMRF酰胺样神经肽FLP-6的表达,促进成年寿命。FLP-6表达增加提升AIY神经元中DAF-9/固醇信号传导,并下调肠道中的胰岛素信号传导以调控寿命(Chen et al., 2016)。热敏感的ASJ神经元被切除后在25°C下延长寿命。ASJ神经元通过UNC-31依赖性释放两种神经肽INS-6和DAF-28,抑制肠道中的FOXO转录因子DAF-16(Zhang et al., 2018)。STR-2是一种在AWCON和ASI神经元中表达的G蛋白偶联受体,在20°C及更高温度下控制寿命。STR-2微调非神经元组织中的中性脂质水平,以适应更高温度从而维持寿命(Dixit et al., 2020)。培养温度(17–23°C)下的系统性温度信号传导通过非神经元细胞(如肠道或肌肉)中的HSF-1活性发生。下游信号通过核激素受体NHR-69介导的雌激素信号传导改变趋温回路(Sugi et al., 2011)。HSF-1不仅调控趋温行为表现,还有助于在温暖温度下延长动物寿命。Lee和Kenyon的开创性工作表明,HSF-1功能的降低在22.5°C下进一步缩短了寿命。与此一致,近期数据显示,神经元中hsf-1的过表达在25°C下保护动物并延长其寿命(Chauve et al., 2021)。蛋白酶体亚基rpn-6.1的过表达以DAF-16依赖性方式在25°C下独立于HSF-1延长寿命(Vilchez et al., 2012)。不同生长条件下的温度经历可通过同一核心因子导致不同结果。例如,共伴侣蛋白DAF-41/p23在温暖和冷温度下以不同方式调控寿命,因为daf-41突变体在较高温度下寿命更长,但在冷温度下寿命较短(Horikawa et al., 2015)。

不同组织间的温度感知与脂质信号传导相互作用,调控冷温度下的寿命。低温通过冷敏感瞬时受体电位(TRP)通道TRPA-1显著延长线虫寿命。TRPA-1是一种非选择性阳离子通道,对钙离子也具有通透性。TRPA-1在神经元或肠道中的表达通过涉及钙敏感激酶PKC-2和DAF-16激酶SGK-1的遗传程序促进DAF-16活性。有趣的是,该研究表明,肠道作为线虫中的非兴奋性组织,发挥冷感受器的功能(Xiao et al., 2013)。TRPA-1在冷敏感的IL1感觉神经元中发挥作用。来自IL1和NSM神经元的谷氨酸能和血清素能信号激活促长寿级联反应。这种神经内分泌信号传导调控肠道细胞中DAF-16的功能(Zhang et al., 2018)。此外,来自IL1和AFD神经元的温度信号维持生殖系增殖并延迟生殖系干细胞(GSC)耗竭。来自成年GSCs的前列腺素E2(PGE2)信号与肠道通讯以产生硫化氢(H₂S)。因此,生殖系和体组织对冷诱导的长寿均有贡献(Hyun Ju Lee et al., 2019)。PAQR-2、MDT-15和壬二酸(AzA)通过脂肪酸介导的信号传导支持低温下的长寿(Chen et al., 2019; Dongyeop Lee et al., 2019; Bai et al., 2021)。

低温通过调节脂质稳态来调控蛋白质稳态通路。在15°C下培养线虫通过脂联素受体PAQR-2介导的信号传导促进自噬。PAQR-2增加脂肪酸去饱和酶FAT-7,触发多不饱和脂肪酸(即γ-亚麻酸和花生四烯酸)的生物合成以诱导自噬(Chen et al., 2019)。中介体复合物亚基——中介体15(MDT-15/MED15)在较低温度下调控fat-7的表达。在15°C下降低MDT-15水平通过HSF-1作为适应性反应增加蛋白质聚集和细胞质伴侣蛋白表达(Dongyeop Lee et al., 2019)。或者,基因本体分析显示,由冷变暖——暴露于冷休克(4°C)后恢复至正常温度(20°C)——调控的基因参与自噬和蛋白质稳态等生物学过程(Jiang et al., 2018)。这些研究强调了不同温度条件在调控蛋白质组动力学中的重要性(图1)。蛋白质稳态的维持对健康衰老至关重要,其损害被认为是衰老的关键标志之一(López-Otín et al., 2013)。以下部分详细描述了温度对寿命影响的研究。

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## 温度对生物体寿命的调控

变温动物在较高温度下的寿命短于较低温度下的寿命(Lamb, 1968)。例如,线虫在25°C和15°C下的平均寿命分别为15.2 ± 0.5天(提供平均寿命±标准误)和26.1 ± 0.6天(Lee and Kenyon, 2009)。开创性研究提出了两种理论——代谢速率理论和阈值理论——来解释温度对寿命的影响。Pearl的代谢速率理论试图将寿命确定为简单的限速反应,并提出衰老速率在较高温度下增加(Shaw and Bercaw, 1962)。或者,阈值理论引入两个决定寿命的阶段——衰老和死亡。它指出衰老速率与温度无关,而死亡速率取决于温度(Smith, 1963)。有趣的是,在上述情形中,温度对寿命的影响主要被视为一个被动的热力学过程。然而,包括线虫在内的变温生物的多项研究提供了大量相反的证据。

通过温度感受神经元对热信号的感觉感知在调控线虫寿命中发挥关键作用。AFD温度感受神经元通过固醇信号通路在温暖温度下控制寿命。如果通过基因突变或激光消融从早期发育开始敲除AFD神经元功能,寿命在25°C下缩短,但在15°C下不缩短。通过这些神经元的温度感觉有助于抑制核激素受体(NHR)DAF-12(通过DAF-9/细胞色素P450)(Lee and Kenyon, 2009)。神经元突触传递也可能影响

**图2 | 温度依赖的寿命调控。** 低温下寿命延长涉及生殖系干细胞(1)、AFD和IL1神经元(1和2)、TRPA-1(3)、共伴侣蛋白DAF-41(4)和脂肪酸(5)的信号传导。AFD、AWC和ASI神经元以及HSF-1在较高温度下维持寿命(6),rpn-6.1的过表达延长寿命(7),ASJ神经元和DAF-41在较高温度下缩短寿命(8)。

温暖温度下的寿命。尽管已鉴定出这些调控温暖和冷温度下预期寿命的不同因素,但它们如何相互通讯和协调功能仍不清楚。广泛的研究有助于鉴定调控冷温和温暖温度下长寿的主要因子。低温培养是有益的,而温暖温度影响寿命。然而,这种关系并不总是成立。当线虫在早期发育阶段暴露于高温时,成年寿命增加(Zhang et al., 2015)。这种早期生活中的短暂热应激通过组蛋白乙酰转移酶CBP-1和染色质重塑复合物SWI/SNF激活持久的防御反应,从而促进长寿(Zhou et al., 2019)。这些研究表明,温度对衰老的影响是由遗传和表观遗传因素调控的受控事件(图2)。

远端组织。胰岛素样肽、FMRF酰胺样肽、生物胺和神经递质对触发下游反应至关重要。

变温动物的研究无疑增进了我们对温度依赖性效应如何影响生物体存活的理解。然而,许多问题仍未得到解答,特别是在蛋白质稳态的调控方面。AFD温度感受神经元及相关神经内分泌信号传导在HSR方面已被充分研究。令人惊讶的是,很少有证据表明有其他分子因子响应温度控制其他蛋白质稳态通路。特别不清楚的是,温度如何影响UPS、自噬机器、未折叠蛋白反应及其所涉及的遗传组分。除AFD、AWC、ASI和ASJ神经元外,肠道在线虫中也充当温度感受器。温度感觉如何通过这些神经元和肠道介导蛋白质稳态仍有待阐明。一个关键步骤将是分析细胞特异性温度感觉受体和回路如何调控生物体蛋白质稳态。线虫通过校准不饱和脂肪酸水平来适应不同的环境温度,以维持最佳的膜流动性(Ma et al., 2015)。脂肪酸在不同温度条件下调控不同蛋白质稳态通路的作用仍有待探索。需要进一步研究来阐明这些关键问题。

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## 讨论

迄今为止讨论的证据揭示了温度依赖的蛋白质稳态和寿命调控中的一个共同主题。温度等环境信号通过非自主性细胞信号传导机制影响生物体生理。神经元充当热信息的受体,并通过小分子介导的信号向

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## 温度——一种潜在的治疗干预手段?

很少有研究证明温度对蛋白质稳态和恒温动物寿命的影响。然而,一些基本原则仍然存在。温度在一定程度上决定了出生时间对人类胎儿发育和寿命的影响。特别是,出生时环境温度升高具有有害影响(Flouris et al., 2009)。视前区的中枢恒温器调控恒温动物的核心体温(CBT)。在食欲素神经元中过表达线粒体膜蛋白解偶联蛋白2(UCP2)的转基因小鼠(Hcrt-UCP2小鼠)表现出下丘脑温度升高和CBT降低。CBT适度但持续的降低增加了Hcrt-UCP2小鼠的预期寿命(Conti et al., 2006)。进一步研究还表明,CBT的性腺依赖性差异以性别特异性方式影响预期寿命(Sanchez-Alavez et al., 2011)。此外,特定的温度条件可能改变年龄相关疾病的病理生理学。受损蛋白质的聚集导致神经退行性疾病。最近的一篇综述提出,促进伴侣蛋白表达的热疗可能是一种潜在的治疗策略(Hunt et al., 2020)。进一步证据表明,桑拿浴——一种被动热疗——降低心血管疾病死亡风险(Laukkanen et al., 2018)。在冷水中游泳(温度<5°C)对有经验的健康个体也是有益的,但需谨慎进行(Knechtle et al., 2020)。冷休克蛋白,如RNA结合基序蛋白3(RBM3),对维持实验室小鼠模型中的突触至关重要。这些结果暗示了治疗性人体低温在实现神经保护作用方面的潜在作用(Peretti et al., 2015)。在高等动物中的深入分析可能有助于利用温度在改善生物体健康方面的益处。积极的一面是,此前来自变温动物的结果可以作为探索这一潜在治疗领域的跳板。