Cer1p Functions as a Molecular Chaperone in the Endoplasmic Reticulum of Saccharomyces cerevisiae

Cer1p/Lhs1p/Ssi1p is a novel Hsp70-related protein that is important for the translocation of a subset of proteins into the yeast Saccharomyces cerevisiae endoplasmic reticulum. Cer1p has very limited amino acid identity to the hsp70 chaperone family in the N-terminal ATPase domain but lacks homology to the highly conserved hsp70 peptide binding domain. The role of Cer1p in protein folding and translocation was assessed. Deletion of CER1 slowed the folding of reduced pro-carboxypeptidase Y (pro-CPY) approximately twofold in yeast. In wild-type yeast under reducing conditions, pro-CPY can be found in a complex with Cer1p, while partially purified Cer1p is able to bind directly to peptides. Together, this suggests that Cer1p has a chaperoning activity required for proper refolding of denatured pro-CPY which is mediated by direct interaction with the unfolded polypeptide. Cer1p peptide binding and oligomerization could be disrupted by addition of ATP, confirming that Cer1p possesses a functional ATP binding site, much like Kar2p and other members of the hsp70 family. Interestingly, replacing the signal sequence of a CER1-dependent protein with that of a CER1-independent protein did not relieve the requirement of CER1 for import. This result suggests that an interaction with the mature portion of the protein also is important for the translocation role of Cer1p. The CER1 RNA levels increase at lower temperatures. In addition, the effects of deletion on folding and translocation are more severe at lower temperatures. Therefore, these results suggest that Cer1p provides an additional chaperoning activity in processes known to require Kar2p. However, there appears to be a greater requirement for Cer1p chaperone activity at lower temperatures.     

A new set of vesicles in Giardia lamblia

In the present study it was demonstrated the existence of a new set of membrane-bounded vesicles in Giardia lamblia. They were found in dividing and non-dividing trophozoites studied by routine transmission electron microscopy, freeze-fracture and Thiéry's technique. Encysting cells were not studied. These vesicles appear different to the previously reported components of the Giardia endomembranous system, such as the endoplasmic reticulum (ER), lysosome-like peripheral vesicles (PV), and the encystation-specific vesicles (ESV) that appear during trophozoite differentiation into cysts. They measure 100-150 nm in diameter, and thus are smaller than the peripheral vesicles, and the encystation-specific vesicles (ESV). They were found in clusters, scattered throughout the cytoplasm, but preferentially located close to the nuclei, axonemes, median bodies, and ER profiles. These internal vesicles are roughly spherical, and their contents present different electron densities and are more electrondense than those of the peripheral vesicles. They appeared to be budding from the outer nuclear membrane envelope. These cytoplasmic vesicles were found only in cells with very good fixation. Only few cells in the same preparation exhibited these vesicles.     

The Endoplasmic Reticulum Chaperone BiP/GRP78 Is Important in the Structure and Function of the Human Cytomegalovirus Assembly Compartment

We previously demonstrated that the endoplasmic reticulum (ER) chaperone BiP functions in human cytomegalovirus (HCMV) assembly and egress. Here, we show that BiP localizes in two cytoplasmic structures in infected cells. Antibodies to the extreme C terminus, which includes BiP''s KDEL ER localization sequence, detect BiP in regions of condensed ER near the periphery of the cell. Antibodies to the full length, N terminus, or larger portion of the C terminus detect BiP in the assembly compartment. This inability of C-terminal antibodies to detect BiP in the assembly compartment suggests that BiP''s KDEL sequence is occluded in the assembly compartment. Depletion of BiP causes the condensed ER and assembly compartments to dissociate, indicating that BiP is important for their integrity. BiP and pp28 are in association in the assembly compartment, since antibodies that detect BiP in the assembly compartment coimmunoprecipitate pp28 and vice versa. In addition, BiP and pp28 copurify with other assembly compartment components on sucrose gradients. BiP also coimmunoprecipitates TRS1. Previous data show that cells infected with a TRS1-deficient virus have cytoplasmic and assembly compartment defects like those seen when BiP is depleted. We show that a fraction of TRS1 purifies with the assembly compartment. These findings suggest that BiP and TRS1 share a function in assembly compartment maintenance. In summary, BiP is diverted from the ER to associate with pp28 and TRS1, contributing to the integrity and function of the assembly compartment.Human cytomegalovirus (HCMV), the largest of the human herpesviruses, is capable of encoding over 200 proteins, which are expressed in temporal fashion as immediate-early, early, delayed-early, and late genes. Despite the extensive coding capacity of HCMV, its replication cycle is slow. During this protracted period, the virus must maintain optimal replication conditions in the host cell. However, the increasing strain of the infection induces cellular stress responses with consequences that may be deleterious to the progress of the infection. We and others have previously shown that HCMV has multiple mechanisms to deal with the deleterious aspects of cellular stress responses while maintaining beneficial ones (2, 8-10, 14, 17, 18, 22-24, 26, 27, 50, 51).An example of these mechanisms is the viral control of endoplasmic reticulum (ER) stress and the unfolded protein response (UPR). Due to the number of HCMV proteins that are glycosylated, or receive other ER-dependent posttranslational modifications, the load of proteins in the ER can exceed its capacity, resulting in ER stress and the activation of the UPR (18, 47, 51). However, we and others have shown that HCMV controls and modulates the UPR, maintaining aspects that may benefit the viral infection while inhibiting aspects that would be detrimental (18, 51).The UPR is normally controlled by transmembrane sensors which initiate the complex UPR signaling cascade when activated by ER stress (reviewed in references 20, 35, 38, and 52). The ER molecular chaperone BiP (immunoglobulin heavy chain-binding protein), also called glucose-regulated protein 78 (GRP78), is believed to bind these sensors and keep them inactive during unstressed conditions. However, when unfolded or misfolded proteins accumulate in the ER, BiP leaves these sensors to perform its chaperone function, thus allowing the sensors to activate UPR signaling. We have previously shown that during HCMV infection, BiP is vastly overproduced (8), suggesting that BiP may have other functions in the viral infection. Indeed, it has been shown that BiP binds to the viral proteins US2 and US11; this interaction is necessary for the virus-mediated degradation of major histocompatibility complex class I and II (15, 47). Further, we have shown that depletion of BiP, using either the BiP-specific subtilase cytotoxin SubAB (32) or short hairpin RNAs, caused infectious virion formation in the cytoplasm to cease and nucleocapsids to accumulate just outside the outer nuclear membrane (8). This result suggested that BiP has a significant role in virion formation and cytoplasmic egress.Although the exact mechanism of virion formation in the cytoplasm is not well understood, studies have identified a perinuclear structure, referred to as the cytoplasmic assembly compartment, that is involved in the process. Several viral proteins, for example, tegument proteins (pp28, pp65) (36) and viral glycoproteins (gB, gH, gL, gO, gp65) (36, 46), have been identified as part of this structure. Defining the exact origin of this compartment has been complicated by the observation of specific organellar markers in and around the compartment, while other markers of the same organelles are not detected. For example, immunofluorescence examination suggests that the early endosomal marker early endosome antigen 1 (EEA1) has been observed in the center of the assembly compartment (12, 13); however, Rab4 and Rab5, other early endosomal markers, were not detected (16). Such observations suggest that the virus directs specific viral and cellular proteins to the assembly compartment as needed for assembly compartment function.In the present study, we further examine the role of BiP during an HCMV infection, including its localization and interactions with other proteins. We show here that in infected cells, BiP localizes in two distinct structures, regions of condensed ER near the periphery of the cell and the assembly compartment. The data suggest that BiP diversion from the ER to the assembly compartment is due to occlusion of its ER localization signal. Depletion of BiP causes both condensed ER and assembly compartments to disperse, indicating that BiP is important for their formation or maintenance. BiP and pp28 appear to associate in the assembly compartment, since BiP from the assembly compartment coimmunoprecipitates pp28 and vice versa. In addition, both BiP and pp28 copurify with the assembly compartment on sucrose gradients. BiP also coimmunoprecipitates TRS1. Previous studies (1, 4) have shown that cells infected with HCMV with a mutation in the TRS1 gene show cytoplasmic and assembly compartment defects like those seen when BiP is depleted (reference 8 and the studies presented below). We show that a fraction of TRS1 purifies with the assembly compartment, indicating a shared assembly compartment function with BiP. In summary, our data suggest that BiP is diverted from the ER to associate with pp28 and TRS1, contributing to the integrity and function of the assembly compartment.     

MAIGO5 Functions in Protein Export from Golgi-Associated Endoplasmic Reticulum Exit Sites in Arabidopsis

Plant cells face unique challenges to efficiently export cargo from the endoplasmic reticulum (ER) to mobile Golgi stacks. Coat protein complex II (COPII) components, which include two heterodimers of Secretory23/24 (Sec23/24) and Sec13/31, facilitate selective cargo export from the ER; however, little is known about the mechanisms that regulate their recruitment to the ER membrane, especially in plants. Here, we report a protein transport mutant of Arabidopsis thaliana, named maigo5 (mag5), which abnormally accumulates precursor forms of storage proteins in seeds. mag5-1 has a deletion in the putative ortholog of the Saccharomyces cerevisiae and Homo sapiens Sec16, which encodes a critical component of ER exit sites (ERESs). mag mutants developed abnormal structures (MAG bodies) within the ER and exhibited compromised ER export. A functional MAG5/SEC16A–green fluorescent protein fusion localized at Golgi-associated cup-shaped ERESs and cycled on and off these sites at a slower rate than the COPII coat. MAG5/SEC16A interacted with SEC13 and SEC31; however, in the absence of MAG5/SEC16A, recruitment of the COPII coat to ERESs was accelerated. Our results identify a key component of ER export in plants by demonstrating that MAG5/SEC16A is required for protein export at ERESs that are associated with mobile Golgi stacks, where it regulates COPII coat turnover.     

A single-stranded RNA copy of the Giardia lamblia virus double-stranded RNA genome is present in the infected Giardia lamblia.

An isolate of Giardia lamblia infected with the double-stranded RNA virus (GLV) has two major species of RNA that are not present in an uninfected isolate. One of these species is the previously characterized double-stranded RNA genome of GLV (1). The second species of RNA appears to be a full length copy of one strand of the double-stranded RNA genome. This full length single-stranded RNA is not present in viral particles isolated from the growth medium. The cellular concentration of the single-stranded RNA changes during exponential and stationary phases of cell growth in a fashion consistent with a viral replicative intermediate or mRNA. The single-stranded species does not appear to be polyadenylated.     

内质网区蓖麻毒素的逆向转运

蓖麻毒素是植物来源的核糖体失活蛋白。蓖麻毒素必须通过细胞的内膜系统到达内质网,然后转位至胞质,才能作用于胞质内的核糖体。在内质网中毒素的两条链分离,具有催化活性的A链被内质网上的蛋白质识别,并被转位到胞质内催化核糖体失活。现对内质网在参与蓖麻毒素胞内转运过程中的作用进行综述。     

Localization of acid phosphatase activity in Giardia lamblia and Giardia muris trophozoites

Numerous membrane-bounded vacuoles are found adjacent to the plasma membrane of the pathogenic protozoan Giardia lamblia. The function of these vacuoles has been discussed by several authors. Approximately 100-400 nm in diameter with a core of low electron density, they have been suggested to be mitochondria, mucocysts, lysosomes, and endocytotic vacuoles. Enzyme cytochemical localization for acid phosphatase activity using cerium as a capturing agent demonstrates reaction product in these vacuoles as well as in the endoplasmic reticulum and nuclear envelope cisternae. The distribution of reaction product suggests the vacuoles are lysosome-like; however, their function and development remain in question.     

Activity of intracellular phospholipase A1 and A2 in Giardia lamblia

Neither phospholipase A1 (PLA A1) nor phospholipase A2 (PLA A2), nor their respective genes, have been identified in Giardia lamblia, even though they are essential for lipid metabolism in this parasite. A method to identify, isolate, and characterize these enzymes is needed. The activities of PLA A1 and PLA A2 were analyzed in a total extract (TE) and in vesicular (P30) and soluble (S30) subcellular fractions of G. lamblia trophozoites; the effects of several chemical and physicochemical factors on their activities were investigated. The assays were performed using substrate labeled with 14C, and the mass of the 14C-product was quantified. PLA A1 and PLA A2 activity was present in the TE and the P30 and S30 fractions, and it was dependent on pH and the concentrations of protein and Ca2+. In all trophozoite preparations, PLA A1 and PLA A2 activities were inhibited by ethylenediaminetetraacetic acid and Rosenthal's inhibitor. These results suggest that G. lamblia possesses several PLA A1 and PLA A2 isoforms that may be soluble or associated with membranes. In addition to participating in G. lamblia phospholipid metabolism, PLA A1 and PLA A2 could play important roles in the cytopathogenicity of this parasite.     

Surface antigen variability and variation in Giardia lamblia

Recent studies show that Giardia isolates are heterogeneous but fall into at least three groups as determined by a number of complementary techniques. Giardia undergoes surface antigenic variation, both in vitro, and in humans and other animal model infections. Many of the characteristics of antigenic variation and the proteins involved, called variant-specific surface proteins (VSPs), are unique. The sequences of five VSPs reveal a family of cysteine-rich proteins. Here Theodore Nash reviews the relationship between antigenic variation and Giardia heterogeneity.     

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.     

The Endoplasmic Reticulum: A Social Network in Plant Cells

The endoplasmic reticulum (ER) is an interconnected network comprised of ribosome-studded sheets and smooth tubules. The ER plays crucial roles in the biosynthesis and transport of proteins and lipids, and in calcium (Ca²⁺) regulation in compartmentalized eukaryotic cells including plant cells. To support its well-segregated functions, the shape of the ER undergoes notable changes in response to both developmental cues and outside influences. In this review, we will discuss recent findings on molecular mechanisms underlying the unique morphology and dynamics of the ER, and the importance of the interconnected ER network in cell polarity. In animal and yeast cells, two family proteins, the reticulons and DP1/Yop1, are required for shaping high-curvature ER tubules, while members of the atlastin family of dynamin-like GTPases are involved in the fusion of ER tubules to make an interconnected ER network. In plant cells, recent data also indicate that the reticulons are involved in shaping ER tubules, while RHD3, a plant member of the atlastin GTPases, is required for the generation of an interconnected ER network. We will also summarize the current knowledge on how the ER interacts with other membrane-bound organelles, with a focus on how the ER and Golgi interplay in plant cells.     

Localization of Acid Phosphatase Activity in Giardia lamblia and Giardia muris Trophozoites1

Numerous membrane-bounded vacuoles are found adjacent to the plasma membrane of the pathogenic protozoan Giardia lamblia. The function of these vacuoles has been discussed by several authors. Approximately 100–400 nm in diameter with a core of low electron density, they have been suggested to be mitochondria, mucocysts, lysosomes, and endocytotic vacuoles. Enzyme cytochemical localization for acid phosphatase activity using cerium as a capturing agent demonstrates reaction product in these vacuoles as well as in the endoplasmic reticulum and nuclear envelope cisternae. The distribution of reaction product suggests the vacuoles are lysosome-like; however, their function and development remain in question.     

Role of Sarco/Endoplasmic Reticulum Ca2+-ATPase in Thermogenesis

Enzymes are able to handle the energy derived from the hydrolysis of phosphate compounds in such a way as to determine the parcel that is used for work and the fraction that is converted into heat. The sarco/endoplasmic reticulum Ca²⁺-ATPases (SERCA) is a family of membrane-bound ATPases that are able to transport Ca²⁺ ion across the membrane using the chemical energy derived from ATP hydrolysis. The heat released during ATP hydrolysis by SERCA may vary from 10 up to 30 kcal/mol depending on the SERCA isoform used and on whether or not a Ca²⁺ gradient is formed across the membrane. Drugs such as heparin, dimethyl sulfoxide and the platelet-activating factor (PAF) are able to modify the fraction of the chemical energy released during ATP hydrolysis that is used for Ca²⁺ transport and the fraction that is dissipated in the surrounding medium as heat. The thyroid hormone 3,5,3′-triiodo L-thyronine (T₃) regulates the expression and function of the thermogenic SERCA isoforms. Modulation of heat production by SERCA might be one of the mechanisms involved in the increased thermogenesis found in hyperthyroidism.     

冠状病毒感染与内质网应激研究进展

内质网（Endoplasmic reticulum,ER）是真核细胞细胞器的重要组成部分,主要负责蛋白质合成和翻译后修饰等过程,还参与调控了钙离子储存和脂类合成,具有重要生理功能。冠状病毒感染细胞后,在复制其遗传信息的同时也在合成大量病毒蛋白,造成未折叠/错误折叠蛋白堆积,进而增加内质网工作负担,诱发内质网应激（Endoplasmic reticulum stress,ERS）,激活未折叠蛋白反应（Unfolded protein response,UPR）,引起一系列信号级联反应,如诱导细胞凋亡等,进而影响病毒复制。本文就冠状病毒感染与ERS及UPR信号通路的研究进展做一综述,为新型抗冠状病毒药物的研发提供新视角。     

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.     

酿酒酵母细胞中内质网应激与未折叠蛋白反应的研究进展

内质网应激激活的未折叠蛋白反应(Unfolded protein response,UPR)途径在酿酒酵母和哺乳动物细胞中是非常保守的。内质网(Endoplasmic reticulum,ER)是蛋白质合成、折叠和修饰的细胞器,也是贮存钙的主要场所之一。酵母细胞内质网钙平衡与UPR的作用是相互的;两个MAPK途径——HOG途径和CWI途径都是细胞应答内质网应激压力时生存所必需的;重金属镉离子能够激活UPR途径,它通过激活钙离子通道Cch1/Mid1进入细胞影响钙离子的功能。本文结合最新研究进展对酿酒酵母细胞中的两个MAPK途径、镉离子和钙离子稳态与内质网应激激活的UPR途径之间相互关系进行综述。