泛素连接酶和去泛素化酶在帕金森病中的作用

中脑黑质多巴胺能神经元特异性损伤和α突触核蛋白聚集的分子机制是帕金森病（Parkinson’s disease,PD）研究领域亟待解决的问题。蛋白质异常聚集很大程度上是由于泛素-蛋白酶体系统（ubiquitin-proteasome system,UPS）功能障碍引起的。蛋白质泛素化由一系列泛素化酶级联反应促进，并受去泛素化酶（deubiquitylases,DUBs）的反向调节。泛素化和去泛素化过程异常导致蛋白质异常聚集和包涵体形成，进而损伤神经元。近来研究报道，蛋白质的泛素化和去泛素化修饰在PD的发病机制中发挥重要作用。E3泛素连接酶促进蛋白质的泛素化，有利于α突触核蛋白的清除、促进多巴胺能神经元的存活、维持线粒体的功能等。DUBs可以去掉底物蛋白质的泛素化修饰，抑制α突触核蛋白的降解，调控线粒体的功能和神经元内铁的稳态。本文以E3泛素连接酶和DUBs为切入点，综述了蛋白质泛素化和去泛素化修饰参与多巴胺能神经元损伤机制的最新研究进展。     

泛素–蛋白酶体系统在铁死亡中的作用

铁死亡是一种新型的由铁积累和脂质过氧化驱动的调节性细胞死亡方式,且越来越多的证据表明铁死亡对包括肿瘤在内的多种疾病的发生发展有重要作用。因此,利用铁死亡进行疾病的治疗也成为基础研究和临床研究的一大方向。泛素–蛋白酶体系统(the ubiquitin-proteasome system, UPS)是真核生物蛋白的主要降解途径之一,是由泛素(ubiquitin, Ub)先标记要降解的蛋白质,进而由蛋白酶体识别和降解的过程。泛素–蛋白酶体途径功能失调会导致多种病理过程发生,因此,它对维持生物体机能稳定具有重要的意义。蛋白质稳定性的调节是铁死亡复杂的分子机制中至关重要的一部分,而泛素–蛋白酶体系统作为真核生物中大分子稳态的关键调节系统,它可以通过调节铁死亡相关分子或相关信号通路等多种方式直接或间接影响铁死亡,在铁死亡中发挥着重要作用。因此,该文就泛素–蛋白酶体系统参与调节铁死亡的相关分子或信号通路等方面进行综述,以期为以铁死亡为靶点的疾病治疗提供一定参考。     

快速高效检测植物体内蛋白泛素化修饰研究方法

UPS参与植物中绝大多数的信号转导通路。其中, 一些激素的受体本身就是E3泛素连接酶, 如茉莉酸(JA)受体COI1和生长素(auxin)受体TIR1都是F-box蛋白, 它们通过特异性介导相应转录抑制子的泛素化降解来传递激素信号, 但对于整个UPS体系而言, 由于技术的限制, 迄今为止仅见少量泛素连接酶与特异性底物间生化机制的报道。用大肠杆菌(Escherichia coli)表达蛋白实施泛素连接酶泛素化修饰底物的体外实验是验证泛素连接酶/底物对的常用方法, 但由于体外实验缺乏某些蛋白必需的转录后修饰, 导致实验结果有时存在假阴性。利用农杆菌注射烟草(Nicotiana benthamiana)瞬时表达蛋白的方法, 建立高效的植物体内检测蛋白泛素化系统, 可以快速检测蛋白泛素化, 包括检测泛素连接酶和底物的特异性相互作用、底物蛋白的自身泛素化、泛素连接酶对底物降解的促进作用、26S蛋白酶体抑制剂MG132对底物降解的抑制作用以及用植物内源表达蛋白进行体外泛素化反应。     

快速高效检测植物体内蛋白泛素化修饰研究方法

UPS参与植物中绝大多数的信号转导通路。其中, 一些激素的受体本身就是E3泛素连接酶, 如茉莉酸(JA)受体COI1和生长素(auxin)受体TIR1都是F-box蛋白, 它们通过特异性介导相应转录抑制子的泛素化降解来传递激素信号, 但对于整个UPS体系而言, 由于技术的限制, 迄今为止仅见少量泛素连接酶与特异性底物间生化机制的报道。用大肠杆菌(Escherichia coli)表达蛋白实施泛素连接酶泛素化修饰底物的体外实验是验证泛素连接酶/底物对的常用方法, 但由于体外实验缺乏某些蛋白必需的转录后修饰, 导致实验结果有时存在假阴性。利用农杆菌注射烟草(Nicotiana benthamiana)瞬时表达蛋白的方法, 建立高效的植物体内检测蛋白泛素化系统, 可以快速检测蛋白泛素化, 包括检测泛素连接酶和底物的特异性相互作用、底物蛋白的自身泛素化、泛素连接酶对底物降解的促进作用、26S蛋白酶体抑制剂MG132对底物降解的抑制作用以及用植物内源表达蛋白进行体外泛素化反应。     

泛素化和磷酸化协同作用调控蛋白质降解

在真核细胞中,泛素化和磷酸化是2种常见的蛋白质修饰方式。泛素在蛋白酶体降解途径中发挥重要的靶向作用,细胞外信号严格调控着目的蛋白的泛素化。在很多情况下,这种调控依赖于蛋白质的磷酸化。由磷酸化影响的调控步骤可能与E3泛素连接酶对底物的识别有关,也可能与实际的交联反应有关。这种调控是通过对底物或E3连接酶本身的磷酸化实现的。     

泛素蛋白酶体途径及其对植物生长发育的调控

泛素蛋白酶体途径主要由泛素活化酶、泛素结合酶、泛素蛋白连接酶和26S蛋白酶体组成。泛素活化酶首先激活泛素分子,然后把泛素转移到泛素结合酶上。泛素结合酶结合泛素蛋白连接酶并把泛素转移到底物蛋白上使底物泛素化,或把泛素转移到泛素蛋白连接酶再使底物泛素化。泛素化的蛋白通常通过26S蛋白酶体进行降解。初步的研究结果表明,植物生长发育的很多方面受泛素蛋白酶体介导的蛋白降解途径的调控。     

泛素蛋白酶体途径及其对植物生长发育的调控

泛素蛋白酶体途径主要由泛素活化酶、泛素结合酶、泛素蛋白连接酶和26S蛋白酶体组成。泛素活化酶首先激活泛素分子, 然后把泛素转移到泛素结合酶上。泛素结合酶结合泛素蛋白连接酶并把泛素转移到底物蛋白上使底物泛素化, 或把泛素转移到泛素蛋白连接酶再使底物泛素化。泛素化的蛋白通常通过26S蛋白酶体进行降解。初步的研究结果表明, 植物生长发育的很多方面受泛素蛋白酶体介导的蛋白降解途径的调控。     

泛素化修饰组学技术及其在疾病研究中的应用

泛素化修饰作为真核细胞内主要的蛋白质翻译后修饰之一，通过泛素-蛋白酶体系统(UPS)介导了细胞内的蛋白质特异性降解，同时广泛参与并调控细胞内基因转录、信号传导、DNA损伤与修复、细胞周期调控、应激反应甚至个体的免疫应答等几乎所有的生命活动过程。泛素-蛋白酶体系统的精确调控构成了稳定而复杂的泛素化信号网络，而其失调通常会造成癌症、神经退行性疾病、代谢性疾病等多种疾病的发生发展。近年来，基于质谱(MS)的蛋白质组学逐渐成熟，并极大促进了泛素化修饰研究的深度与广度。依托于泛素化蛋白质/肽段富集技术的发展以及高通量、高覆盖度和高灵敏度的质谱检测技术平台，蛋白质泛素化修饰组学也得以快速发展，并逐渐应用于人类生理、病理状态的泛素化蛋白质组研究和疾病发生发展的机制探索。本文主要综述了泛素化修饰组学研究中的泛素化蛋白质/肽段富集方法、质谱鉴定技术、定量标记技术和数据处理方法，同时对泛素化修饰组学技术在疾病研究中的应用也进行了系统分析，理清了当前存在的问题与挑战，为泛素化修饰蛋白质的发现与鉴定提供参考，为相关疾病治疗靶点的筛选和药物研发提供思路。     

去泛素化酶与肿瘤

泛素化修饰(ubiquitination modification)广泛存在于真核生物,通过26S蛋白酶体降解途径或信号传递等,改变蛋白质稳定性、定位和活性等功能,参与细胞的周期、转录、炎症、肿瘤和免疫等各项功能,是一类复杂的动态调控系统.泛素化调节是一个可逆过程,被泛素连接酶(ubiquitin ligase,E3)...     

E3泛素连接酶Smurf家族在骨形态发生蛋白和转化生长因子信号转导中的作用

泛素-蛋白酶体降解系统广泛存在于各种真核细胞中,参与调控细胞多种生理进程.作为该系统中行使调控降解功能的核心成员,E3泛素连接酶的重要作用已经越来越引起人们的重视.BMP和TGF-β是骨组织中调控成骨细胞和软骨细胞增殖、分化和凋亡的关键分子,通过不同的信号通路体系调控骨生理代谢,参与骨组织的多种生理进程.最近的研究表明,泛素-蛋白酶体降解系统在骨细胞和骨组织中具有十分重要的作用,E3泛素连接酶Smurf作为这一系统的核心,参与调控骨组织中BMP和TGF-β两个家族的分子信号转导过程.在前期成果的基础上,结合最新的研究进展,系统阐述了骨组织中E3泛素连接酶的发现,及其调控BMP和TGF-β信号通路的机制以及其对成骨细胞和软骨细胞增殖和分化的影响.     

Cellular degradation systems in ferroptosis

In eukaryotic cells, macromolecular homeostasis requires selective degradation of damaged units by the ubiquitin-proteasome system (UPS) and autophagy. Thus, dysfunctional degradation systems contribute to multiple pathological processes. Ferroptosis is a type of iron-dependent oxidative cell death driven by lipid peroxidation. Various antioxidant systems, especially the system xc⁻-glutathione-GPX4 axis, play a significant role in preventing lipid peroxidation-mediated ferroptosis. The endosomal sorting complex required for transport-III (ESCRT-III)–dependent membrane fission machinery counteracts ferroptosis by repairing membrane damage. Moreover, cellular degradation systems play a dual role in regulating the ferroptotic response, depending on the cargo they degrade. The key ferroptosis repressors, such as SLC7A11 and GPX4, are degraded by the UPS. In contrast, the overactivation of selective autophagy, including ferritinophagy, lipophagy, clockophagy and chaperone-mediated autophagy, promotes ferroptotic death by degrading ferritin, lipid droplets, circadian proteins, and GPX4, respectively. Autophagy modulators (e.g., BECN1, STING1/TMEM173, CTSB, HMGB1, PEBP1, MTOR, AMPK, and DUSP1) also determine the ferroptotic response in a context-dependent manner. In this review, we provide an updated overview of the signals and mechanisms of the degradation system regulating ferroptosis, opening new horizons for disease treatment strategies.Subject terms: Cell biology, Molecular biology     

Double-edge sword roles of iron in driving energy production versus instigating ferroptosis

Iron is vital for many physiological functions, including energy production, and dysregulated iron homeostasis underlies a number of pathologies. Ferroptosis is a recently recognized form of regulated cell death that is characterized by iron dependency and lipid peroxidation, and this process has been reported to be involved in multiple diseases. The mechanisms underlying ferroptosis are complex, and involve both well-described pathways (including the iron-induced Fenton reaction, impaired antioxidant capacity, and mitochondrial dysfunction) and novel interactions linked to cellular energy production. In this review, we examine the contribution of iron to diverse metabolic activities and their relationship to ferroptosis. There is an emphasis on the role of iron in driving energy production and its link to ferroptosis under both physiological and pathological conditions. In conclusion, excess reactive oxygen species production driven by disordered iron metabolism, which induces Fenton reaction and/or impairs mitochondrial function and energy metabolism, is a key inducer of ferroptosis.Subject terms: Cell biology, Biochemistry     

Lipid storage and lipophagy regulates ferroptosis

The synthesis, storage, and degradation of lipids are highly regulated processes. Impaired lipid metabolism is implicated in inflammation and cell death. Although ferroptosis is a recently described form of regulated cell death driven by lipid peroxidation, the impact of lipid droplets on ferroptosis remains unidentified. Here, we demonstrate that lipophagy, the autophagic degradation of intracellular lipid droplets, promotes RSL3-induced ferroptotic cell death in hepatocytes. Lipid droplet accumulation is increased at the early stage but decreased at the late stage of ferroptosis in mouse or human hepatocytes. Importantly, either genetically enhancing TPD52-dependent lipid storage or blocking ATG5-and RAB7A-dependent lipid degradation prevents RSL3-induced lipid peroxidation and subsequent ferroptosis in vitro and in vivo. These studies support an antioxidant role for lipid droplets in cell death and suggest novel strategies for the inhibition of ferroptosis by targeting the lipophagy pathway.     

Narrative review of ferroptosis in obesity

Obesity is widely recognized as a major global health problem caused by a chronic energy imbalance resulting from a combination of excess caloric intake and insufficient energy expenditure. Excessive energy intake and physical inactivity are traditional risk factors for obesity. Obesity is a risk factor for many diseases, including hypertension, diabetes and tumours. Recent studies have found a strong link between ferroptosis and obesity. Ferroptosis is an iron-dependent regulated cell death caused by iron overload and reactive oxygen species-dependent excessive accumulation of lipid peroxidation. Ferroptosis is involved in many biological processes, such as amino acid metabolism, iron metabolism and lipid metabolism. Some potential strategies to reduce the adverse effects of ferroptosis on obesity are suggested and future research priorities are highlighted.     

The role of ferroptosis in metabolic diseases

The annual incidence of metabolic diseases such as diabetes, non-alcoholic fatty liver disease (NAFLD), osteoporosis, and atherosclerosis (AS) is increasing, resulting in a heavy burden on human health and the social economy. Ferroptosis is a novel form of programmed cell death driven by iron-dependent lipid peroxidation, which was discovered in recent years. Emerging evidence has suggested that ferroptosis contributes to the development of metabolic diseases. Here, we summarize the mechanisms and molecular signaling pathways involved in ferroptosis. Then we discuss the role of ferroptosis in metabolic diseases. Finally, we analyze the potential of targeting ferroptosis as a promising therapeutic approach for metabolic diseases.     

Mitochondria regulation in ferroptosis

Ferroptosis is recognized as a new form of regulated cell death which is initiated by severe lipid peroxidation relying on reactive oxygen species (ROS) generation and iron overload. This iron-dependent cell death manifests evident morphological, biochemical and genetic differences from other forms of regulated cell death, such as apoptosis, autophagy, necrosis and pyroptosis. Ferroptosis was primarily characterized by condensed mitochondrial membrane densities and smaller volume than normal mitochondria, as well as the diminished or vanished of mitochondria crista and outer membrane ruptured. Mitochondria take the center role in iron metabolism, as well as substance and energy metabolism as it’s the major organelle in iron utilization, catabolic and anabolic pathways. Interference of key regulators of mitochondrial lipid metabolism (e.g., ASCF2 and CS), iron homeostasis (e.g., ferritin, mitoferrin1/2 and NEET proteins), glutamine metabolism and other signaling pathways make a difference to ferroptotic sensitivity. Targeted induction of ferroptosis was also considered as a potential therapeutic strategy to some oxidative stress diseases, including neurodegenerative disorders, ischemia-reperfusion injury, traumatic spinal cord injury. However, the pertinence between mitochondria and ferroptosis is still in dispute. Here we systematic elucidate the morphological characteristics and metabolic regulation of mitochondria in the regulation of ferroptosis.     

铁死亡发生机制的研究进展

铁死亡(ferroptosis)是近几年发现的一种新的细胞死亡方式,是在小分子物质诱导下发生的氧化性细胞死亡,具有铁离子依赖性.其发生是细胞内脂质活性氧(reactive oxygen species,ROS)生成与降解的平衡失调所致.铁死亡诱导剂通过不同的通路直接或间接作用于谷胱甘肽过氧化物酶(glutathione peroxidase,GPXs),导致细胞抗氧化能力降低、ROS堆积、最终引起细胞氧化性死亡.铁死亡与帕金森综合征、胰腺癌等多种疾病相关,并发现可以通过激活或抑制铁死亡来干预疾病的发展,因此铁死亡成为近年来的研究热点.本文就铁死亡的发现、特点、发生机制及其与疾病的关系展开论述,将近年研究成果进行总结,期望为以铁死亡为基础的疾病治疗提供参考.     

NMN recruits GSH to enhance GPX4-mediated ferroptosis defense in UV irradiation induced skin injury

Oxidative stress and lipid peroxidation are major causes of skin injury induced by ultraviolet (UV) irradiation. Ferroptosis is a form of regulated necrosis driven by iron-dependent peroxidation of phospholipids and contributes to kinds of tissue injuries. However, it remains unclear whether the accumulation of lipid peroxides in UV irradiation-induced skin injury could lead to ferroptosis. We generated UV irradiation-induced skin injury mice model to examine the accumulation of the lipid peroxides and iron. Lipid peroxides 4-HNE, the oxidative enzyme COX2, the oxidative DNA damage biomarker 8-OHdG, and the iron level were increased in UV irradiation-induced skin. The accumulation of iron and lipid peroxidation was also observed in UVB-irradiated epidermal keratinocytes without actual ongoing ferroptotic cell death. Ferroptosis was triggered in UV-irradiated keratinocytes stimulated with ferric ammonium citrate (FAC) to mimic the iron overload. Although GPX4 protected UVB-injured keratinocytes against ferroptotic cell death resulted from dysregulation of iron metabolism and the subsequent increase of lipid ROS, keratinocytes enduring constant UVB treatment were markedly sensitized to ferroptosis. Nicotinamide mononucleotide (NMN) which is a direct and potent NAD⁺ precursor supplement, rescued the imbalanced NAD⁺/NADH ratio, recruited the production of GSH and promoted resistance to lipid peroxidation in a GPX4-dependent manner. Taken together, our data suggest that NMN recruits GSH to enhance GPX4-mediated ferroptosis defense in UV irradiation-induced skin injury and inhibits oxidative skin damage. NMN or ferroptosis inhibitor might become promising therapeutic approaches for treating oxidative stress-induced skin diseases or disorders.     

Fascin enhances the vulnerability of breast cancer to erastin-induced ferroptosis

Ferroptosis, which is characterized by intracellular iron accumulation and lipid peroxidation, is a newly described form of regulated cell death that may play a key role in tumour suppression. In the present study, we investigated the expression profiles and biological effects of fascin actin-bundling protein 1 (Fascin, gene name FSCN1) in breast cancer. In addition, bioinformatics analysis of the TCGA cancer database and gain- and loss-of-function studies showed that Fascin enhances sensitivity to erastin-induced ferroptosis. Mechanistically, Fascin directly interacts with cysteine/glutamate transporter (xCT, gene name SLC7A11) and decreases its stability via the ubiquitin-mediated proteasome degradation pathway. Furthermore, we observed that Fascin is substantially upregulated in tamoxifen-resistant breast cancer cell lines, and drug-resistant cells were also more vulnerable to erastin-induced ferroptosis. Taken together, our findings reveal a previously unidentified role of Fascin in ferroptosis by regulating xCT. Thus, ferroptosis activation in breast cancer with high Fascin level may serve as a potential treatment.Subject terms: Cell death, Breast cancer     

Autophagy promotes ferroptosis by degradation of ferritin

Macroautophagy/autophagy is an evolutionarily conserved degradation pathway that maintains homeostasis. Ferroptosis, a novel form of regulated cell death, is characterized by a production of reactive oxygen species from accumulated iron and lipid peroxidation. However, the relationship between autophagy and ferroptosis at the genetic level remains unclear. Here, we demonstrated that autophagy contributes to ferroptosis by degradation of ferritin in fibroblasts and cancer cells. Knockout or knockdown of Atg5 (autophagy-related 5) and Atg7 limited erastin-induced ferroptosis with decreased intracellular ferrous iron levels, and lipid peroxidation. Remarkably, NCOA4 (nuclear receptor coactivator 4) was a selective cargo receptor for the selective autophagic turnover of ferritin (namely ferritinophagy) in ferroptosis. Consistently, genetic inhibition of NCOA4 inhibited ferritin degradation and suppressed ferroptosis. In contrast, overexpression of NCOA4 increased ferritin degradation and promoted ferroptosis. These findings provide novel insight into the interplay between autophagy and regulated cell death.