A Novel Membrane Protein Complex on the Endoplasmic Reticulum and Early Golgi Compartments in the Yeast Saccharomyces cerevisiae

A novel membrane protein, Yml067c in the systematic ORF name, was discovered as a component of immunoisolated vesicles of the early Golgi compartment of the yeast Saccharomyces cerevisiae (Cho et al., FEBS Lett. 469, 151-154 (2000)). Conserved sequences having sequence similarity to Yml067c were widely distributed in the eukaryotes and one of them, Yal042w, was found in the Saccharomyces genome database. In the yeast cell, Yml067c and Yal042w were found to form a heterooligomeric complex by immunoprecipitation of their tagged derivatives from the detergent-solubilized membrane. Cell fractionation and indirect immunofluorescent staining indicated that the majority of these proteins were localized on the ER membrane. Therfore, the Yml067c-Yal042w complex should shuttle between the ER and the early Golgi compartment as well as the p24-family proteins.     

Degradation of the Endoplasmic Reticulum by Autophagy during Endoplasmic Reticulum Stress in Arabidopsis

In this article, we show that the endoplasmic reticulum (ER) in Arabidopsis thaliana undergoes morphological changes in structure during ER stress that can be attributed to autophagy. ER stress agents trigger autophagy as demonstrated by increased production of autophagosomes. In response to ER stress, a soluble ER marker localizes to autophagosomes and accumulates in the vacuole upon inhibition of vacuolar proteases. Membrane lamellae decorated with ribosomes were observed inside autophagic bodies, demonstrating that portions of the ER are delivered to the vacuole by autophagy during ER stress. In addition, an ER stress sensor, INOSITOL-REQUIRING ENZYME-1b (IRE1b), was found to be required for ER stress–induced autophagy. However, the IRE1b splicing target, bZIP60, did not seem to be involved, suggesting the existence of an undiscovered signaling pathway to regulate ER stress–induced autophagy in plants. Together, these results suggest that autophagy serves as a pathway for the turnover of ER membrane and its contents in response to ER stress in plants.     

Glycoprotein Folding in the Endoplasmic Reticulum

Our understanding of eukaryotic protein folding in the endoplasmic reticulum has increased enormously over the last 5 years. In this review, we summarize some of the major research themes that have captivated researchers in this field during the last years of the 20th century. We follow the path of a typical protein as it emerges from the ribosome and enters the reticular environment. While many of these events are shared between different polypeptide chains, we highlight some of the numerous differences between proteins, between cell types, and between the chaperones utilized by different ER glycopro-teins. Finally, we consider the likely advances in this field as the new century unfolds and we address the prospect of a unified understanding of how protein folding, degradation, and translation are coordinated within a cell.     

Sphingolipid Homeostasis in the Endoplasmic Reticulum and Beyond

Sphingolipids are a diverse group of lipids that have essential cellular roles as structural components of membranes and as potent signaling molecules. In recent years, a detailed picture has emerged of the basic biochemistry of sphingolipids—from their initial synthesis in the endoplasmic reticulum (ER), to their elaboration into complex glycosphingolipids, to their turnover and degradation. However, our understanding of how sphingolipid metabolism is regulated in response to metabolic demand and physiologic cues remains incomplete. Here I discuss new insights into the mechanisms that ensure sphingolipid homeostasis, with an emphasis on the ER as a critical regulatory site in sphingolipid metabolism. In particular, Orm family proteins have recently emerged as key ER-localized mediators of sphingolipid homeostasis. A detailed understanding of how cells sense and control sphingolipid production promises to provide key insights into membrane function in health and disease.Eukaryotic cell membranes maintain a complex and tightly regulated complement of lipids and proteins that are essential for their function. These lipids can be divided into three broad classes—sterols, glycerolipids, and sphingolipids—on the basis of their distinct chemical structures and dedicated enzymatic machineries (Fig. 1A–C). Sphingolipids typically represent ∼10%–20% of cellular lipids and have essential functions arising both from their effects on the physical properties of membranes and from their roles as signaling molecules (van Meer et al. 2008). Additionally, the activities of many transmembrane and peripheral membrane proteins are dependent on their close association with sphingolipids (Lingwood and Simons 2010). Over recent years, sphingolipids have been shown to participate in an increasingly wide range of biological processes that includes secretion, endocytosis, chemotaxis, neurotransmission, angiogenesis, and inflammation (Hannun and Obeid 2008; Lingwood and Simons 2010; Lippincott-Schwartz and Phair 2010; Blaho and Hla 2011; Lingwood 2011).Open in a separate windowFigure 1.Structures of sphingolipids and other cellular lipids. (A–C) Representative structures of (A) sphingolipids, (B) glycerolipids, and (C) sterols. (D) Formation of sphingolipids from key building blocks, long chain bases (LCBs), and coenzyme A-linked fatty acids (FA-CoAs) that often have a very long acyl chain (VLCFA-CoA). Serine palmitoyltransferase (SPT) produces the LCB intermediate 3-keto-dihydrosphingosine, which is then reduced to yield LCBs that are used by ceramide synthase (CerS) to form ceramides. Sphingolipid structural diversity arises from (a) headgroup modifications including phosphorylation, glycosylation, or phosphocholine addition, (b) LCB hydroxylation, (c) LCB desaturation, (d) variability in the length of the N-linked acyl chain, and (e) desaturation of the N-linked acyl chain.The focus of this article is the variety of regulatory mechanisms that cells use to ensure sphingolipid homeostasis. This task requires balancing sphingolipid levels in conjunction with sterols and glycerolipids and adapting sphingolipid metabolism in response to physiological cues and external stresses. A need for tight regulatory control is further highlighted by the potent signaling activities of many sphingolipid biosynthetic intermediates such as sphingosines and ceramides (Hannun and Obeid 2008; Fyrst and Saba 2010; Blaho and Hla 2011). Additionally, because most sphingolipids cannot move freely between different organelles, cells must regulate multiple intracellular pools of sphingolipids as well as lipid transport between these sites.It is noteworthy that, despite great progress in defining the enzymes that carry out sphingolipid synthesis and degradation, how cells achieve sphingolipid homeostasis remains poorly understood. In this article, I will describe recent progress in the field and highlight outstanding questions. In particular, I will discuss the emergence of the endoplasmic reticulum (ER) as a key site for sphingolipid homeostasis. Several critical enzymes in sphingolipid metabolism are found in the ER, and recent studies have identified a mechanism for matching sphingolipid production to metabolic demand that depends on the ER-localized Orm family of proteins (Breslow et al. 2010). Although many details of Orm protein function remain to be discovered, Orm proteins provide a valuable model for understanding how cells sense sphingolipids and dynamically regulate sphingolipid metabolism.     

N-Linked Protein Glycosylation in the Endoplasmic Reticulum

The attachment of glycans to asparagine residues of proteins is an abundant and highly conserved essential modification in eukaryotes. The N-glycosylation process includes two principal phases: the assembly of a lipid-linked oligosaccharide (LLO) and the transfer of the oligosaccharide to selected asparagine residues of polypeptide chains. Biosynthesis of the LLO takes place at both sides of the endoplasmic reticulum (ER) membrane and it involves a series of specific glycosyltransferases that catalyze the assembly of the branched oligosaccharide in a highly defined way. Oligosaccharyltransferase (OST) selects the Asn-X-Ser/Thr consensus sequence on polypeptide chains and generates the N-glycosidic linkage between the side-chain amide of asparagine and the oligosaccharide. This ER-localized pathway results in a systemic modification of the proteome, the basis for the Golgi-catalyzed modification of the N-linked glycans, generating the large diversity of N-glycoproteome in eukaryotic cells. This article focuses on the processes in the ER. Based on the highly conserved nature of this pathway we concentrate on the mechanisms in the eukaryotic model organism Saccharomyces cerevisiae.The presence of glycans on proteins is known to influence their stability and solubility and the glycan core can contribute to folding processes (Shental-Bechor and Levy 2008; Hanson et al. 2009; Culyba et al. 2011). N-glycans also influence the function and activity of proteins (Skropeta 2009). The terminal residues of N-glycans play a key role in the quality control of protein folding in the ER. Ultimately the glycan signals whether a protein is correctly folded and can leave the ER to continue its maturation in the Golgi or whether the protein is not correctly folded and is degraded (Helenius and Aebi 2004; Aebi et al. 2010). It is therefore of great importance that the oligosaccharide to be transferred to proteins is complete. This “quality control” of the oligosaccharide is mediated by the substrate specificity of oligosaccharyltransferase.     

Psychostimulant-Induced Endoplasmic Reticulum Stress and Neurodegeneration

The endoplasmic reticulum (ER) is a subcellular organelle that ensures proper protein folding process. The ER stress is defined as cellular conditions that disturb the ER homeostasis, resulting in accumulation of unfolded and/or misfolded proteins in the lumen of the ER. The presence of these proteins within the ER activates the ER stress response, known as unfolded protein response (UPR), to restore normal functions of the ER. However, under the severe and/or prolonged ER stress, UPR initiates apoptotic cell death. Psychostimulants such as cocaine, amphetamine, and methamphetamine cause the ER stress and/or apoptotic cell death in regions of the brain related to drug addiction. Recent studies have shown that the ER stress in response to psychostimulants is linked to behavioral sensitization and that the psychostimulant-induced ER stress signaling cascades are closely associated with the pathogenesis of the neurodegenerative diseases. Therefore, this review was conducted to improve understanding of the functional role of the ER stress in the addiction as well as neurodegenerative diseases. This would be helpful to facilitate development of new therapeutic strategies for the drug addiction and/or neurodegenerative diseases caused or exacerbated by exposure to psychostimulants.     

内质网应激与心脏疾病

内质网是细胞内蛋白质合成折叠、Ca2+储存和脂质合成的重要部位.内质网稳态的破坏将导致大量错误或者未折叠蛋白质在内质网中的聚集,通过相应的信号通路,引起一系列的细胞反应,即内质网应激.内质网应激参与心脏的发育和多种心脏疾病的发生发展,包括心肌缺血和再灌注损伤、心肌病、心力衰竭等.内质网应激可能是研究心血管疾病发病机制和防治措施的新靶点.     

内质网应激与肝脏疾病

内质网在细胞内分布广泛,是细胞内蛋白质、脂类和糖类合成的重要场所,是细胞内钙离子的储存场所,与物质运输、交换等作用密切相关。内质网稳态失衡会诱导内质网应激(Endoplasmic reticulum stress,ERS),持久应激会导致细胞凋亡。多项研究显示内质网应激与多种肝脏疾病密切相关。本文就内质网应激与肝脏疾病发病机制作一综述。     

细胞内质网应激与糖脂代谢紊乱的机制关联

在真核细胞中,内质网是蛋白质合成、折叠、加工及其质量监控的重要场所。当内质网难以承担蛋白折叠的高负荷时则引发内质网应激(ER stress),激活细胞的未折叠蛋白响应(unfoldedprotein response,UPR)。细胞通过内质网跨膜蛋白ATF6、PERK和IRE1介导的三条极为关键的UPR信号通路,调控下游相关基因的表达,以增强内质网对蛋白折叠的处理能力。因此,UPR通路在细胞的稳态平衡中具有举足轻重的作用,而这一动态过程的调控对于维持机体的正常生理功能至关重要。近来大量研究表明,在哺乳动物中内质网应激与机体的营养感应和糖脂代谢的调控过程密切相关。在肝脏、脂肪、胰岛以及下丘脑等不同的组织器官中,内质网应激均影响代谢通路的调节机制,因此在糖脂代谢紊乱的发生发展中扮演重要的角色。综上所述,进一步深入了解内质网应激引发代谢异常的生理学机制,可以为肥胖、脂肪肝及2型糖尿病等相关代谢性疾病的防治提供新的潜在药物靶点和重要的理论线索。     

Protein-Folding Homeostasis in the Endoplasmic Reticulum and Nutritional Regulation

The flux of newly synthesized proteins entering the endoplasmic reticulum (ER) is under negative regulation by the ER-localized PKR-like ER kinase (PERK). PERK is activated by unfolded protein stress in the ER lumen and inhibits new protein synthesis by the phosphorylation of translation initiation factor eIF2α. This homeostatic mechanism, shared by all animal cells, has proven to be especially important to the well-being of professional secretory cells, notably the endocrine pancreas. PERK, its downstream effectors, and the allied branches of the unfolded protein response intersect broadly with signaling pathways that regulate nutrient assimilation, and ER stress and the response to it have been implicated in the development of the metabolic syndrome accompanying obesity in mammals. Here we review our current understanding of the cell biology underlying these relationships.Insulin was among the first proteins to be sequenced, among the first to have its structure solved, and therefore among the first to provide clues to the diversity of modifications that affect secreted proteins. The β cell of the pancreas, which produces insulin, is one of the best-studied secretory cells, and the role of the secretory pathway in insulin biosynthesis has been recognized from the dawn of modern cell biology. Years later, when the stress pathways that contribute to protein-folding homeostasis in the endoplasmic reticulum (the unfolded protein response, UPR) came under scrutiny (Gardner et al. 2013; Olzmann et al. 2013), it was revealed that their integrity is important to insulin metabolism and to the function of β cells.The precursor of insulin, prepro-insulin, is recruited to the ER membrane cotranslationally through its amino-terminal signal sequence (Mandon et al. 2013). Oxidative folding and signal sequence removal yield mature pro-insulin, whose tertiary structure is stabilized by three disulfide bonds (Bulleid 2012). Folded pro-insulin clears ER quality control (Braakman and Hebert 2013) and traffics distally (Lord et al. 2013).The peptidase involved in post-ER steps of pro-insulin maturation has long been recognized as playing a key role in its secretion, but the sensitivity of insulin biosynthesis to integrity of ER steps was not recognized until later. An early clue came from study of a naturally occurring mutation in mouse Ins2. The Akita mutation results in a Cys-92→Tyr substitution, disrupting an essential disulfide bond and leading to misfolding of proinsulin 2 (Wang et al. 1999). Interestingly, a single copy of the mutation is sufficient to compromise β cells, whereas homozygosity for a null mutation in Ins2 is without an obvious phenotype in mice (because of redundancy between a rodent’s two insulin genes) (Duvillie et al. 1997). The biochemical (and phenotypic) dominance of the Akita mutation in mice (Colombo et al. 2008) fit well with retention of the mutant pro-insulin in the ER, high levels of UPR signaling, and with a progressive decline in β-cell mass and insulin stores as the mutant mice age. Thus, a perturbation to ER protein-folding homeostasis induced by the misfolding-prone mutant pro-insulin has a long-term negative effect on β-cell function.Unbiased human genetics provided an additional clue to the importance of protein-folding homeostasis in the ER; the Wolcott–Rallison syndrome is a rare recessive monogenic form of hypoinsulinaemic neonatal diabetes associated with bone dysplasia and episodic liver failure (Julier and Nicolino 2010). Positional cloning revealed that the causative mutations in EIF2AK3 severely disrupted the expression or function of PERK (Delepine et al. 2000), an ER-localized stress-activated kinase that tunes rates of new protein synthesis to the unfolded protein load in the ER (Harding et al. 1999). Although known to be enriched in β cells, PERK expression is ubiquitous (Shi et al. 1998). Therefore, the prominence of diabetes in the phenotype associated with loss-of-function mutations in a ubiquitous component of the unfolded protein response (UPR) pointed to a special role for ER homeostasis in β-cell health.More surprising has been the link between chronic ER stress and the ability of insulin target tissues to respond to the hormone; it has emerged that nutrient excess and obesity are associated with higher levels of UPR signaling in the liver and fat and that steps that mitigate ER stress in these tissues ameliorate the insulin resistance that is part of the metabolic syndrome linked to nutrient excess. Thus, ER stress and the response to it affect both the insulin-producing β cell and the insulin-responsive tissues and may therefore influence the pathophysiology of the common, type II form of diabetes mellitus by limiting both the production of insulin and the body’s sensitivity to it.     

PARM-1 Is an Endoplasmic Reticulum Molecule Involved in Endoplasmic Reticulum Stress-Induced Apoptosis in Rat Cardiac Myocytes

To identify novel transmembrane and secretory molecules expressed in cardiac myocytes, signal sequence trap screening was performed in rat neonatal cardiac myocytes. One of the molecules identified was a transmembrane protein, prostatic androgen repressed message-1 (PARM-1). While PARM-1 has been identified as a gene induced in prostate in response to castration, its function is largely unknown. Our expression analysis revealed that PARM-1 was specifically expressed in hearts and skeletal muscles, and in the heart, cardiac myocytes, but not non-myocytes expressed PARM-1. Immunofluorescent staining showed that PARM-1 was predominantly localized in endoplasmic reticulum (ER). In Dahl salt-sensitive rats, high-salt diet resulted in hypertension, cardiac hypertrophy and subsequent heart failure, and significantly stimulated PARM-1 expression in the hearts, with a concomitant increase in ER stress markers such as GRP78 and CHOP. In cultured cardiac myocytes, PARM-1 expression was stimulated by proinflammatory cytokines, but not by hypertrophic stimuli. A marked increase in PARM-1 expression was observed in response to ER stress inducers such as thapsigargin and tunicamycin, which also induced apoptotic cell death. Silencing PARM-1 expression by siRNAs enhanced apoptotic response in cardiac myocytes to ER stresses. PARM-1 silencing also repressed expression of PERK and ATF6, and augmented expression of CHOP without affecting IRE-1 expression and JNK and Caspase-12 activation. Thus, PARM-1 expression is induced by ER stress, which plays a protective role in cardiac myocytes through regulating PERK, ATF6 and CHOP expression. These results suggested that PARM-1 is a novel ER transmembrane molecule involved in cardiac remodeling in hypertensive heart disease.     

Disulfide Bond Formation in the Mammalian Endoplasmic Reticulum

The formation of disulfide bonds between cysteine residues occurs during the folding of many proteins that enter the secretory pathway. As the polypeptide chain collapses, cysteines brought into proximity can form covalent linkages during a process catalyzed by members of the protein disulfide isomerase family. There are multiple pathways in mammalian cells to ensure disulfides are introduced into proteins. Common requirements for this process include a disulfide exchange protein and a protein oxidase capable of forming disulfides de novo. In addition, any incorrect disulfides formed during the normal folding pathway are removed in a process involving disulfide exchange. The pathway for the reduction of disulfides remains poorly characterized. This work will cover the current knowledge in the field and discuss areas for future investigation.One of the characteristics of proteins that enter the secretory pathway is that they frequently contain covalent linkages called disulfide bonds within and between constituent polypeptide chains. The presence of these linkages is thought to confer stability when secreted proteins are exposed to the extracellular milieu or when membrane proteins are recycled through acidic endocytic compartments. In addition to structural disulfides it is now clear that a number of proteins use the formation and breaking of disulfides as a mechanism for regulation of activity (Schwertassek et al. 2007). Hence, it is important that we have a clear understanding of how correct disulfides are formed within proteins both during the protein folding process and to regulate protein function. The focus of this article will be on how correct disulfides are introduced into proteins within the secretory pathway, specifically within the endoplasmic reticulum (ER) during folding and assembly.The formation of disulfides within polypeptides begins as the protein is being cotranslationally translocated into the ER (Chen et al. 1995). The initial collapse of the polypeptide and formation of secondary structure brings cysteine residues into close enough proximity for them to form disulfides. Correct disulfide formation requires enzymes to both introduce disulfides between proximal cysteines and to reduce disulfides that form during folding but that are not present in the final native structure (Jansens et al. 2002). In addition, proteins that do not fold correctly are targeted for degradation and may require their disulfides to be broken before dislocation across the ER membrane into the cytosol (Ushioda et al. 2008). Hence, there must be a reduction and oxidation pathway present in the ER to ensure that native disulfides form and nonnative disulfides are broken during protein folding.Central to both reduction and oxidation pathways is the protein disulfide isomerase (PDI) family of enzymes (Ellgaard and Ruddock 2005) that are capable of exchanging disulfides with their substrate proteins (Fig. 1). Whether disulfide exchange results in the formation or breaking of a disulfide depends on the relative stability of the disulfides in the enzyme and substrate. To drive the formation of disulfides, the PDI family member must itself be oxidized. It is now clear that there are a number of ways for the disulfide exchange proteins to be oxidized by specific oxidases. Importantly, these oxidases do not introduce disulfides into nascent polypeptide chains; rather, they specifically oxidize members of the PDI family. The exception to this rule is the enzyme quiescin sulfydryl oxidase (QSOX; see below). The pathway for disulfide reduction is not as well characterized. It is known that the PDI family members can be reduced by the low molecular mass thiol glutathione (GSH) (Chakravarthi and Bulleid 2004; Jessop and Bulleid 2004; Molteni et al. 2004) but no enzymatic process for reduction has been identified. The glutathione redox balance within the ER is significantly more oxidized than in the cytosol (Hwang et al. 1992; Dixon et al. 2008), indicating that GSH is actively oxidized to glutathione disulfide either during the reduction of PDI family members or by reducing disulfides in nascent polypeptides directly. However, there is currently no clear indication as to how glutathione disulfide is itself reduced.Open in a separate windowFigure 1.PDI family of enzymes catalyzes disulfide exchange reactions in the endoplasmic reticulum. Nascent polypeptide chains are cotranslationally translocated across the ER membrane whereupon cysteines in close proximity can form disulfides. The reaction is catalyzed by members of the PDI family (depicted as PDI) by a disulfide exchange reaction resulting in the reduction of the PDI active site. If nonnative disulfides are formed these can be reduced by the reverse disulfide exchange reaction, resulting in the oxidation of the PDI active site.Both the formation and breaking of disulfides can be thought of as electron transport pathways that require suitable electron acceptors or donors to drive the flow of electrons. For the purposes of this article the two pathways will be discussed separately, but it should be appreciated that each pathway occurs within the same organelle so the possibility of crossover between them is real. Whether futile redox reactions occur between the pathways is unclear but any kinetic segregation of the pathways will be highlighted where it is known to occur.     

Protein Translocation across the Rough Endoplasmic Reticulum

The rough endoplasmic reticulum is a major site of protein biosynthesis in all eukaryotic cells, serving as the entry point for the secretory pathway and as the initial integration site for the majority of cellular integral membrane proteins. The core components of the protein translocation machinery have been identified, and high-resolution structures of the targeting components and the transport channel have been obtained. Research in this area is now focused on obtaining a better understanding of the molecular mechanism of protein translocation and membrane protein integration.Protein translocation across the rough endoplasmic reticulum (RER) is an ancient and evolutionarily conserved process that is analogous to protein export across the cytoplasmic membranes of eubacterial and archaebacterial cells both with respect to the mechanism and core components. The RER membrane of eukaryotic cells is contiguous with the nuclear envelope and is morphologically composed of interconnected cisternae and tubules. Electron microscope images of mammalian cells and tissues revealed that the cisternal regions of the cytoplasmic surface of the endoplasmic reticulum are densely studded by membrane-bound ribosomes (Palade 1955a,b), giving rise to the term “rough ER.” The RER-bound ribosomes in en face images are often arranged in spirals or hairpins (Palade 1955a; Christensen and Bourne 1999), indicative of polyribosomes that are actively engaged in protein translation.Consistent with this high density of membrane-bound ribosomes, the RER is a major site of protein biosynthesis in eukaryotic cells. The nuclear envelope, the Golgi, lysosome, peroxisome, plasma membrane, and endosomes are biosynthetically derived from the rough ER. The three major groups of proteins that are synthesized by RER-bound ribosomes include secretory proteins, integral membrane proteins destined for ER-derived membranes, and the lumenal-resident proteins of the ER, Golgi, nuclear envelope, and lysosome. For those membranes that are not physically linked to the ER (e.g., the lysosome), integral membrane and lumenal proteins are delivered to their destination by vesicular transport pathways. Bioinformatics analysis of fully sequenced eukaryotic genomes indicates that roughly 30% of open reading frames encode integral membrane proteins (Wallin and von Heijne 1998); hence, a major role of the RER is the biosynthesis of membrane proteins. An important class of membrane proteins that are integrated into the RER has single carboxy-terminal TM spans and are known as tail-anchored (TA) membrane proteins. The posttranslational integration pathway for TA proteins has been a subject of several recent reviews (Borgese and Fasana 2011; Shao and Hegde 2011), thus we will not address the TA pathway in this article.     

内质网应激与疾病

内质网是蛋白质合成与折叠、维持Ca²⁺动态平衡及合成脂类和固醇的场所。遗传或环境损伤引起内质网功能紊乱导致内质网应激,激活未折叠蛋白反应。未折叠蛋白反应是一种细胞自我保护性措施,但是内质网应激过强或持续时间过久可引起细胞凋亡。因此,内质网应激与众多人类疾病的发生发展密切相关。最近研究证明,癌症、炎症性疾病、代谢性疾病、骨质疏松症及神经退行性疾病等有内质网应激信号传递参与。然而内质网应激作为一个有效靶点参与各种疾病发挥作用的功能和机制仍然有待进一步研究。在近年来发表的文献基础上对内质网应激与疾病的关系,以及其可能的作用机制进行综述。     

Lipid Transport between the Endoplasmic Reticulum and Mitochondria

Mitochondria are partially autonomous organelles that depend on the import of certain proteins and lipids to maintain cell survival and membrane formation. Although phosphatidylglycerol, cardiolipin, and phosphatidylethanolamine are synthesized by mitochondrial enzymes, phosphatidylcholine, phosphatidylinositol, phosphatidylserine, and sterols need to be imported from other organelles. The origin of most lipids imported into mitochondria is the endoplasmic reticulum, which requires interaction of these two subcellular compartments. Recently, protein complexes that are involved in membrane contact between endoplasmic reticulum and mitochondria were identified, but their role in lipid transport is still unclear. In the present review, we describe components involved in lipid translocation between the endoplasmic reticulum and mitochondria and discuss functional as well as regulatory aspects that are important for lipid homeostasis.Biological membranes are major structural components of all cell types. They protect the cell from external influences, organize the interior in distinct compartments and allow balanced flux of components. Besides their specific proteome, organelles exhibit unique lipid compositions, which influence their shape, physical properties, and function. Major lipid classes found in biological membranes are phospholipids, sterols, and sphingolipids.The major “lipid factory” within the cell is the endoplasmic reticulum (ER). It is able to synthesize the bulk of structural phospholipids, sterols, and storage lipids such as triacylglycerols and steryl esters (van Meer et al. 2008). Furthermore, initial steps of ceramide synthesis occur in the ER providing precursors for the formation of complex sphingolipids in other organelles (Futerman 2006). Besides the export of ceramides, the ER supplies a large portion of lipids to other organelles, which cannot produce their own lipids or have a limited capacity to do so. Organelle interaction and transport of lipids require specific carrier proteins, membrane contact sites, tethering complexes, and/or vesicle flux. These processes are highly important for the maintenance of cell structure and survival but are still a matter of dispute. Most prominent organelle interaction partners are the ER and mitochondria. A subfraction of the ER named mitochondria-associated membrane (MAM) (Vance 1990) was described to be involved in lipid translocation to mitochondria. MAM is part of the ER network, which was shown to be in contact or close proximity to the outer mitochondrial membrane (OMM). Contact sites between MAM and mitochondria were assumed to facilitate exchange of components between the two compartments. Interestingly, MAM harbor a number of lipid synthesizing enzymes (Gaigg et al. 1994). Recently, molecular components governing membrane contact between the two organelles were identified (Dolman et al. 2005; Csordás et al. 2006; de Brito and Scorrano 2008; Kornmann et al. 2009; Friedman et al. 2010; Lavieu et al. 2010), although the specific role of these components in lipid translocation is not yet clear.     

Retention and Degradation of N-Glycoproteins in the Rough Endoplasmic Reticulum

Recent studies have shown that newly synthesized proteins and glycoproteins are submitted to a quality control mechanism in the rough endoplasmic reticulum (ER). In this report we present two models: One model will illustrate a transient retention in rough ER leading to a further degradation of glycoproteins in the cytosol, (soluble alkaline phosphatase expressed in Man-P-Dol deficient CHO cells lines). The second model will illustrate a strict retention of glycoproteins in rough ER without degradation nor recycling through the Golgi (E1, E2 glycoproteins of Hepatitis C virus in stably transfected UHCV-11.4 cells and in infected Hep G2 cells).In both cases, oligomannoside structures are markers of these phenomena, either as free soluble released oligomannosides in the case of degradation, or as N-linked oligomannosides for strict retention in rough ER.     

Alterations in the Function of Endoplasmic Reticulum and Neuronal Signalling

For many years, the endoplasmic reticulum (ER) was considered to be involved in rapid signalling events due to its ability to serve as a dynamic calcium store capable of accumulating large amounts of Ca²⁺ ions and of releasing them in response to physiological stimulation. Recent data significantly increased the importance of the ER as a signalling organelle, by demonstrating that the ER is associated with specific pathways regulating long-lasting adaptive processes and controlling cell survival. The ER lumen is enriched by enzymatic systems involved in protein synthesis and correcting post-translational folding of these proteins. The processes of post-translational protein processing are controlled by a class of specific enzymes known as chaperones, which in turn are regulated by the free Ca²⁺ concentration within the ER lumen ([Ca²⁺]_L). At the same time, a high [Ca²⁺]_L determines the ability of the ER to generate cytosolic Ca²⁺ signals. Thus, the ER is able to produce signals interacting within different temporal domains. Fast ER signals result from Ca²⁺ release via specific Ca²⁺-release channels and from rapid movements of Ca²⁺ ions within the ER lumen (calcium tunneling). Long-lasting signals involve Ca²⁺-dependent regulation of chaperones with subsequent changes in protein processing and synthesis. Any malfunctions in the ER Ca²⁺ homeostasis result in accumulation of unfolded proteins, which in turn activates several signalling systems aimed at appropriate compensatory responses or (in the case of severe ER dysregulation) in cellular pathology and death (ER stress responses). Thus, the Ca²⁺ ion emerges as a messenger molecule, which integrates various signals within the ER: fluctuations of the [Ca²⁺]_L induced by signals originating at the level of the plasmalemma (i.e., Ca²⁺ entry or activation of the metabotropic receptors) regulate in turn protein synthesis and processing via generating secondary signalling events between the ER and the nucleus.     

骨关节炎软骨细胞发生内质网应激

目的：研究骨关节炎软骨细胞是否发生内质网应激现象。方法：对关节置换术后的人类骨关节炎软骨标本和正常关节软骨标本切片进行内质网应激标志分子免疫球蛋白重链结合蛋白（BiP）的免疫组织化学检测;对小鼠膝关节进行半月板切断术诱发实验性骨关节炎,在术后1、3和6周取材,对组织切片进行番红花“O”染色、Mankin评分及BiP的免疫组织化学检测。结果：所有人类骨关节炎标本中软骨细胞BiP的表达明显升高。番红花“O”染色结果表明,在小鼠骨关节炎模型中,全部手术侧关节表面发生磨损,且随着术后时间延长关节表面磨损范围逐步扩大,手术侧Mankn分值显著高于对照侧;此外,手术侧的软骨细胞内BiP呈阳性表达,且表达量随术后时间延长而增加。结论：在人类骨关节炎标本和实验性小鼠骨关节炎模型中,关节软骨细胞均发生明显的内质网应激现象。