Navigating the ERAD interaction network

The endoplasmic reticulum (ER)-associated protein degradation (ERAD) pathway, which orchestrates the degradation of ER proteins by the proteasome, involves a plethora of proteins with diverse functions. Using a combination of proteomic and genetic approaches, a recent study provides fresh insights into the organization of the mammalian ERAD interaction network and the functions of its components.     

How Positive-Strand RNA Viruses Benefit from Autophagosome Maturation

The autophagic degradation pathway is a powerful tool in the host cell arsenal against cytosolic pathogens. Contents trapped inside cytosolic vesicles, termed autophagosomes, are delivered to the lysosome for degradation. In spite of the degradative nature of the pathway, some pathogens are able to subvert autophagy for their benefit. In many cases, these pathogens have developed strategies to induce the autophagic signaling pathway while inhibiting the associated degradation activity. One surprising finding from recent literature is that some viruses do not impede degradation but instead promote the generation of degradative autolysosomes, which are the endpoint compartments of autophagy. Dengue virus, poliovirus, and hepatitis C virus, all positive-strand RNA viruses, utilize the maturation of autophagosomes into acidic and ultimately degradative compartments to promote their replication. While the benefits that each virus reaps from autophagosome maturation are unique, the parallels between the viruses indicate a complex relationship between cytosolic viruses and host cell degradation vesicles.     

Defining the ERAD connection: Assembly required

Comment on: Anti-malaria drug blocks proteotoxic stress response: Anti-cancer implications. Neznanov N, et al. Cell Cycle 2009; 8:In press.     

ERAD: the long road to destruction

Endoplasmic reticulum (ER)-associated protein degradation (ERAD) eliminates misfolded or unassembled proteins from the ER. ERAD targets are selected by a quality control system within the ER lumen and are ultimately destroyed by the cytoplasmic ubiquitin-proteasome system (UPS). The spatial separation between substrate selection and degradation in ERAD requires substrate transport from the ER to the cytoplasm by a process termed dislocation. In this review, we will summarize advances in various aspects of ERAD and discuss new findings on how substrate dislocation is achieved.     

How Viruses Use the Endoplasmic Reticulum for Entry,Replication, and Assembly

To cause infection, a virus enters a host cell, replicates, and assembles, with the resulting new viral progeny typically released into the extracellular environment to initiate a new infection round. Virus entry, replication, and assembly are dynamic and coordinated processes that require precise interactions with host components, often within and surrounding a defined subcellular compartment. Accumulating evidence pinpoints the endoplasmic reticulum (ER) as a crucial organelle supporting viral entry, replication, and assembly. This review focuses on the molecular mechanism by which different viruses co-opt the ER to accomplish these crucial infection steps. Certain bacterial toxins also hijack the ER for entry. An interdisciplinary approach, using rigorous biochemical and cell biological assays coupled with advanced microscopy strategies, will push to the next level our understanding of the virus-ER interaction during infection.To trigger infection, a virus binds to receptors on a host cell’s plasma membrane. This interaction induces virus internalization, and initiates a complex journey of the viral particle into the host’s interior that leads to either nonproductive or productive infection (Mercer et al. 2010). In nonproductive infection, the virus may be targeted to and trapped in organelles unsupportive of viral membrane fusion or penetration, events which normally enable the viral nucleic acid access to the host cytosol or nucleus. Alternatively, the virus could be transported to a degradative intracellular compartment in which it is destroyed. In contrast, for productive infection, a viral particle must avoid these nonproductive routes and traffic along a pathway that allows it to reach the appropriate replication and assembly site. Successful infection is usually completed when the newly assembled particle is released into the extracellular milieu, in which it can promote another infection round. Thus, the ability to co-opt a host cell entry pathway leading to efficient replication and assembly ultimately dictates the fate of an incoming virus.For proper entry, replication, and assembly, viruses often rely on the complex membranous network surrounding and residing within the host cell, such as the plasma, endolysosomal, and endoplasmic reticulum (ER) membranes. Selecting the suitable membrane system requires several considerations. To support entry, the membranous system must possess triggers capable of inducing the necessary conformational changes that facilitate viral membrane fusion or penetration (Inoue et al. 2011). Examples of cellular triggers include receptors, low pH, proteases, chaperones, and reductases. Additionally, because viral replication and assembly often occur in the context of virus-induced membranous structures derived from host membranes, the membranous network of choice should accommodate these remodeling reactions (Miller and Krijnse-Locker 2008). Moreover, as a virus commonly manipulates the host immune system to sustain infection, a membrane’s ability to provide the virus with such an opportunity would offer tremendous advantages during the infection course (Takeuchi and Akira 2009).A wealth of data implicates the endoplasmic reticulum (ER), one of the most elaborate membranous networks in a cell (Shibata et al. 2009), as the organelle many viruses exploit during infection. This review focuses on how viruses co-opt the ER to enter, replicate, and assemble in the target cell. We will also draw parallels from the mechanisms by which bacterial toxins use the ER for entry. Together, these insights should unveil clues regarding why many viruses select the ER during infection.     

A novel role for N-glycans in the ERAD system

The endoplasmic reticulum (ER) provides a quality-control system for newly synthesized secretory and membrane proteins. Any improperly folded or incompletely assembled oligomers are retained in the ER, and they are retro-translocated into the cytosol when misfolding persists, where they are destroyed by the proteasome through ubiquitylation. This disposal process is called ER-associated degradation (ERAD). Although much is known about the fate of ERAD substrates near the point of degradation, little information is available about how these proteins are recognized, retained, and targeted for translocation and ubiquitylation machinery. Recent studies indicate that N-linked oligosaccharides attached to nascent proteins function as tags for several processes of a quality-control system, such as individual steps of ER-retention, selection for ERAD substrates, and ubiquitylation. In this review, I describe recent advances in the molecular basis of the ERAD system, particularly those mediated by N-glycan recognition molecules.     

Quality control: another player joins the ERAD cast

The quality control system known as ERAD removes misfolded proteins from the ER to the cytosol for degradation. The AAA ATPase Cdc48p and ubiquitin ligases play crucial roles; their relationship has been unclear, but recent work has shown that the membrane protein Ubx2p links their functions in yeast.     

Finding the will and the way of ERAD substrate retrotranslocation

ER-associated degradation (ERAD) is a mechanism by which numerous ER-localized proteins are targeted for cytosolic degradation by the ubiquitin-proteasome system. A surprising and still-cryptic requirement of this process is the energy dependent retrotranslocation of both lumenal and membrane-embedded ER proteins into the cytosol for ongoing ubiquitination and proteasomal destruction. The current understanding, results, and open questions are discussed below for this intriguing and critical process of ERAD.     

Chlamydiae Assemble a Pathogen Synapse to Hijack the Host Endoplasmic Reticulum

Chlamydiae are obligate intracellular bacterial pathogens that replicate within a specialized membrane‐bound compartment, termed an ‘inclusion’. The inclusion membrane is a critical host–pathogen interface, yet the extent of its interaction with cellular organelles and the origin of this membrane remain poorly defined. Here we show that the host endoplasmic reticulum (ER) is specifically recruited to the inclusion, and that key rough ER (rER) proteins are enriched on and translocated into the inclusion. rER recruitment is a Chlamydia‐orchestrated process that occurs independently of host trafficking. Generation of infectious progeny requires an intact ER, since ER vacuolation early during infection stalls inclusion development, whereas disruption post ER recruitment bursts the inclusion. Electron tomography and immunolabelling of Chlamydia‐infected cells reveal ‘pathogen synapses’ at which ordered arrays of chlamydial type III secretion complexes connect to the inclusion membrane only at rER contact sites. Our data show a supramolecular assembly involved in pathogen hijack of a key host organelle.     

Pkc1p modifies CPY* degradation in the ERAD pathway

The process of endoplasmic reticulum-associated degradation (ERAD) involved in the degradation of misfolded N-linked glycoproteins utilizes Cdc48p which extracts misfolded glycoproteins from the lumen to the cytosol to present them for deglycosylation and degradation. Pkc1p has been identified as a component of the ERAD pathway, because deletion of the pkc1 gene impairs ERAD and causes accumulation of CPY* in the lumen of the ER, most probably because of the mislocalization of Cdc48p. In addition, we show that Cdc48p interacts in the cytosol with the deglycosylation enzyme, PNGase, only when Cdc48p is associated with a misfolded glycoprotein.     

When worlds collide: IP3 receptors and the ERAD pathway

While cell signaling devotees tend to think of the endoplasmic reticulum (ER) as a Ca²⁺ store, those who study protein synthesis tend to see it more as site for protein maturation, or even degradation when proteins do not fold properly. These two worldviews collide when inositol 1,4,5-trisphosphate (IP₃) receptors are activated, since in addition to acting as release channels for stored ER Ca²⁺, IP₃ receptors are rapidly destroyed via the ER-associated degradation (ERAD) pathway, a ubiquitination- and proteasome-dependent mechanism that clears the ER of aberrant proteins. Here we review recent studies showing that activated IP₃ receptors are ubiquitinated in an unexpectedly complex manner, and that a novel complex composed of the ER membrane proteins SPFH1 and SPFH2 (erlin 1 and 2) binds to IP₃ receptors immediately after they are activated and mediates their ERAD. Remarkably, it seems that the conformational changes that underpin channel opening make IP₃ receptors resemble aberrant proteins, which triggers their binding to the SPFH1/2 complex, their ubiquitination and extraction from the ER membrane and finally, their degradation by the proteasome. This degradation of activated IP₃ receptors by the ERAD pathway serves to reduce the sensitivity of ER Ca²⁺ stores to IP₃ and may protect cells against deleterious effects of over-activation of Ca²⁺ signaling pathways.     

Tipping the Delicate Balance: Defining How Proteasome Maturation Affects the Degradation of a Substrate for Autophagy and Endoplasmic Reticulum Associated Degradation (ERAD)

An increasing body of data links endoplasmic reticulum (ER) function to autophagy. Not surprisingly, then, some aberrant proteins in the ER can be destroyed either via ER associated degradation (ERAD), which is proteasome-mediated, or via autophagy. One such substrate is the “Z” variant of the alpha-1 protease inhibitor (A1Pi), variably known as A1Pi-Z or AT-Z (“anti-trypsin, Z variant”). The wild type protein is primarily synthesized in the liver and is secreted. In contrast, AT-Z—like other ERAD substrates—is retro-translocated from the ER and delivered to the proteasome. However, AT-Z can form high molecular weight polymers that are degraded via autophagy, and cells that accumulate AT-Z polymers ultimately succumb, which leads to liver disease. Therefore, identifying genes that have an impact AT-Z turnover represents an active area of research. To this end, a yeast expression system for AT-Z has proven valuable. For example, a recent study using this system indicates that the activity of a proteasome assembly chaperone (PAC) is critical for maximal AT-Z turnover, which suggests a new role for PACs. Because PACs are conserved, it will be critical to analyze whether these dedicated chaperones are implicated in other diseases associated with ERAD and autophagy.

Addendum to:

ADD66, a Gene Involved in the Endoplasmic Reticulum Associated Degradation of a1-Antitrypsin-Z in Yeast, Facilitates Proteasome Activity and Assembly

C.M. Scott, K.B. Kruse, B.Z. Schmidt, D.H. Perlmutter, A.A. McCracken and J.L. Brodsky

Mol Biol Cell 2007; In press     

Forcible destruction of severely misfolded mammalian glycoproteins by the non-glycoprotein ERAD pathway

Glycoproteins and non-glycoproteins possessing unfolded/misfolded parts in their luminal regions are cleared from the endoplasmic reticulum (ER) by ER-associated degradation (ERAD)-L with distinct mechanisms. Two-step mannose trimming from Man₉GlcNAc₂ is crucial in the ERAD-L of glycoproteins. We recently showed that this process is initiated by EDEM2 and completed by EDEM3/EDEM1. Here, we constructed chicken and human cells simultaneously deficient in EDEM1/2/3 and analyzed the fates of four ERAD-L substrates containing three potential N-glycosylation sites. We found that native but unstable or somewhat unfolded glycoproteins, such as ATF6α, ATF6α(C), CD3-δ–ΔTM, and EMC1, were stabilized in EDEM1/2/3 triple knockout cells. In marked contrast, degradation of severely misfolded glycoproteins, such as null Hong Kong (NHK) and deletion or insertion mutants of ATF6α(C), CD3-δ–ΔTM, and EMC1, was delayed only at early chase periods, but they were eventually degraded as in wild-type cells. Thus, higher eukaryotes are able to extract severely misfolded glycoproteins from glycoprotein ERAD and target them to the non-glycoprotein ERAD pathway to maintain the homeostasis of the ER.