Proteasome-mediated protein processing by bidirectional degradation initiated from an internal site

Degradation of some polyubiquitinated proteins requires an intrinsic proteasomal binding element in the substrates

Lysine 48-linked polyubiquitin chains usually target proteins for 26 S proteasomal degradation; however, this modification is not a warrant for destruction. Here, we found that efficient degradation of a physiological substrate UbcH10 requires not only an exogenous polyubiquitin chain modification but also its unstructured N-terminal region. Interestingly, the unstructured N-terminal region of UbcH10 directly binds the 19 S regulatory complex of the 26 S proteasome, and it mediates the initiation of substrate translocation. To promote ubiquitin-dependent degradation of the folded domains of UbcH10, its N-terminal region can be displaced by exogenous proteasomal binding elements. Moreover, the unstructured N-terminal region can initiate substrate translocation even when UbcH10 is artificially cyclized without a free terminus. Polyubiquitinated circular UbcH10 is completely degraded by the 26 S proteasome. Accordingly, we propose that degradation of some polyubiquitinated proteins requires two binding interactions: a polyubiquitin chain and an intrinsic proteasomal binding element in the substrates (likely an unstructured region); moreover, the intrinsic proteasomal binding element initiates substrate translocation regardless of its location in the substrates.

Novel virus-associated proteins encoded by UL112–113 of human cytomegalovirus

Evidence suggests that the products of the human cytomegalovirus (HCMV) UL112–113 genes are involved in viral DNA replication during lytic infection. A polyclonal antibody was raised against the UL112 open reading frame (ORF) to characterize its function in detail. Immunoblots utilizing the UL112 antibody identified seven distinct protein bands (p20, p26, p28, p34, p43, p50 and p84) expressed during the HCMV infectious cycle. After screening a cDNA library constructed from cells 72 h after infection with HCMV, only four different cDNA protein-producing constructs were obtained, and their ORFs corresponded to p34, p43, p50 and p84. The proteins p20, p26 and p28 were further shown to be selectively included within mature HCMV particles, virions, non-infectious enveloped particles and dense bodies. Immunoaffinity protein purification was used to prepare the samples for liquid chromatography coupled to tandem mass spectrometry. This analysis revealed that p20, p26 and p28 were derived from the UL112 ORF, most likely through post-translational proteolytic cleavage.

Targeting proteins for degradation

Protein degradation plays a central role in many cellular functions. Misfolded and damaged proteins are removed from the cell to avoid toxicity. The concentrations of regulatory proteins are adjusted by degradation at the appropriate time. Both foreign and native proteins are digested into small peptides as part of the adaptive immune response. In eukaryotic cells, an ATP-dependent protease called the proteasome is responsible for much of this proteolysis. Proteins are targeted for proteasomal degradation by a two-part degron, which consists of a proteasome binding signal and a degradation initiation site. Here we describe how both components contribute to the specificity of degradation.

Autocatalytic processing of m-AAA protease subunits in mitochondria

m-AAA proteases are ATP-dependent proteolytic machines in the inner membrane of mitochondria which are crucial for the maintenance of mitochondrial activities. Conserved nuclear-encoded subunits, termed paraplegin, Afg3l1, and Afg3l2, form various isoenzymes differing in their subunit composition in mammalian mitochondria. Mutations in different m-AAA protease subunits are associated with distinct neuronal disorders in human. However, the biogenesis of m-AAA protease complexes or of individual subunits is only poorly understood. Here, we have examined the processing of nuclear-encoded m-AAA protease subunits upon import into mitochondria and demonstrate autocatalytic processing of Afg3l1 and Afg3l2. The mitochondrial processing peptidase MPP generates an intermediate form of Afg3l2 that is matured autocatalytically. Afg3l1 or Afg3l2 are also required for maturation of newly imported paraplegin subunits after their cleavage by MPP. Our results establish that mammalian m-AAA proteases can act as processing enzymes in vivo and reveal overlapping activities of Afg3l1 and Afg3l2. These findings might be of relevance for the pathogenesis of neurodegenerative disorders associated with mutations in different m-AAA protease subunits.

A conserved unfoldase activity for the p97 AAA-ATPase in proteasomal degradation

The multifunctional AAA-ATPase p97 is one of the most abundant and conserved proteins in eukaryotic cells. The p97/Npl4/Ufd1 complex dislocates proteins that fail the protein quality control in the endoplasmic reticulum to the cytosol where they are subject to degradation by the ubiquitin/proteasome system. Substrate dislocation depends on the unfoldase activity of p97. Interestingly, p97 is also involved in the degradation of specific soluble proteasome substrates but the exact mode of action of p97 in this process is unclear. Here, we show that both the central pore and ATPase activity of p97 are necessary for the degradation of cytosolic ubiquitin-fusion substrates. Addition of a flexible extended C-terminal peptide to the substrate relieves the requirement for p97. Deletion mapping reveals a conserved length dependency of 20 residues for the peptide, which allows p97-independent degradation to occur. Our results suggest that initiation of unfolding may be more complex than previously anticipated and that the 19S regulatory complex of the proteasome can require preprocessing of highly folded, ubiquitylated substrates by the p97(Ufd1/Npl4) complex. Our data provide an explanation for the observation that p97 is only essential for a subpopulation of soluble substrates and predict that a common characteristic of soluble p97-dependent substrates is the lack of an initiation site to facilitate unfolding by the 26S proteasome.

Recognition and processing of ubiquitin-protein conjugates by the proteasome

The proteasome is an intricate molecular machine, which serves to degrade proteins following their conjugation to ubiquitin. Substrates dock onto the proteasome at its 19-subunit regulatory particle via a diverse set of ubiquitin receptors and are then translocated into an internal chamber within the 28-subunit proteolytic core particle (CP), where they are hydrolyzed. Substrate is threaded into the CP through a narrow gated channel, and thus translocation requires unfolding of the substrate. Six distinct ATPases in the regulatory particle appear to form a ring complex and to drive unfolding as well as translocation. ATP-dependent, degradation-coupled deubiquitination of the substrate is required both for efficient substrate degradation and for preventing the degradation of the ubiquitin tag. However, the proteasome also contains deubiquitinating enzymes (DUBs) that can remove ubiquitin before substrate degradation initiates, thus allowing some substrates to dissociate from the proteasome and escape degradation. Here we examine the key elements of this molecular machine and how they cooperate in the processing of proteolytic substrates.

The role of ubiquitin in NF-kappaB regulatory pathways

Nuclear factor kappa enhancer binding protein (NF-kappaB) regulates diverse biological processes including immunity, inflammation, and apoptosis. A vast array of cellular stimuli converges on NF-kappaB, and ubiquitination plays an essential role in the coordination of these signals to regulate NF-kappaB activity. At least three steps in NF-kappaB activation directly involve ubiquitination: proteasomal degradation of inhibitor of NF-kappaB (IkappaB), processing of NF-kappaB precursors, and activation of the transforming growth factor (TGF)-beta-activated kinase (TAK1) and IkappaB kinase (IKK) complexes. In this review, we discuss recent advances in the identification and characterization of ubiquitination and deubiquitination machinery that regulate NF-kappaB. Particular emphasis is given to proteasome-independent functions of ubiquitin, specifically its role in the activation of protein kinase complexes and in coordination of cell survival and apoptosis signals downstream of tumor necrosis factor alpha (TNFalpha).

Analysis of quality control substrates in distinct cellular compartments reveals a unique role for Rpn4p in tolerating misfolded membrane proteins

ER quality control (ERQC) prevents the exit of misfolded secretory and membrane proteins from the ER. A critical aspect of ERQC is a transcriptional response called the unfolded protein response (UPR), which up-regulates genes that enable cells to cope with misfolded, ER-retained proteins. In this study, we compare the transcriptional responses in yeast resulting from the acute expression of misfolded proteins residing in three different cellular compartments (the ER lumen, membrane, and cytosol), and find that each elicits a distinct transcriptional response. The classical UPR response, here-designated UPR-L, is induced by the ER lumenal misfolded protein, CPY*. The UPR-Cyto response is induced by the cytosolic protein, VHL-L158P, and is characterized by a rapid, transient induction of cytosolic chaperones similar to the heat-shock response. In contrast, the misfolded membrane protein with a cystolic lesion, Ste6p*, elicits a unique response designated UPR-M/C, characterized by the modest induction of >20 genes regulated by Rpn4p, an activator of proteasomal genes. Independently, we identified several genes required for yeast viability during UPR-M/C stress, but not UPR-L or UPR-Cyto stress. Among these is RPN4, highlighting the importance of the Rpn4p-dependent response in tolerating UPR-M/C stress. Further analysis suggests the requirement for Rpn4p reflects severe impairment of the proteasome by UPR-M/C stress.

Identification of lysines within membrane-anchored Mga2p120 that are targets of Rsp5p ubiquitination and mediate mobilization of tethered Mga2p90

Mga2p90 is an endoplasmic reticulum (ER)-localized transcription factor that is released from the ER membrane by a unique ubiquitin (Ub)-dependent mechanism. Mga2p90 mobilization requires polyubiquitination of its associating membrane-bound Mga2p120 anchor and subsequent Mga2p120-Mga2p90 complex disassembly that is mediated by ATPase Cdc48p and its heteromeric Ub-binding adaptor Npl4p-Ufd1p. Although previous studies have identified the Ub ligase (i.e., Rsp5p) and ligase-binding site on Mga2p120 that play a role in this process, the amino acids of Mga2p120 that are targets of ubiquitination and promote Mga2p90 mobilization are unknown. We have identified, using mass spectrometry analysis of in vitro ubiquitinated Mga2p120-Mga2p90 complex, that lysine residues 983 and 985 contained within the carboxy-terminal domain of Mga2p120 are Rsp5p-directed Ub-conjugation sites. Mutation of these residues as well as proximally located lysine 980 results in suppression of Mga2p120 ubiquitination in vitro and in vivo, inefficient liberation of Mga2p90 by Cdc48p(Npl4p/Ufd1p)in vitro, and ER retention of Mga2p in cells. Moreover, mga2Delta/spt23ts harboring Rsp5p binding and conjugation mga2 mutants express low OLE1 (an Mga2p90 target gene) transcripts and display reduced growth. We conclude that residues 980, 983, and 985 are targets of Rsp5p-induced polyubiquitination and mediate Cdc48p(Npl4p/Ufd1p)-dependent Mga2p90-Mga2p120 separation and Mga2p90 mobilization.

Lysine 63-linked polyubiquitin chain may serve as a targeting signal for the 26S proteasome

Recruitment of substrates to the 26S proteasome usually requires covalent attachment of the Lys48-linked polyubiquitin chain. In contrast, modifications with the Lys63-linked polyubiquitin chain and/or monomeric ubiquitin are generally thought to function in proteasome-independent cellular processes. Nevertheless, the ubiquitin chain-type specificity for the proteasomal targeting is still poorly understood, especially in vivo. Using mass spectrometry, we found that Rsp5, a ubiquitin-ligase in budding yeast, catalyzes the formation of Lys63-linked ubiquitin chains in vitro. Interestingly, the 26S proteasome degraded well the Lys63-linked ubiquitinated substrate in vitro. To examine whether Lys63-linked ubiquitination serves in degradation in vivo, we investigated the ubiquitination of Mga2-p120, a substrate of Rsp5. The polyubiquitinated p120 contained relatively high levels of Lys63-linkages, and the Lys63-linked chains were sufficient for the proteasome-binding and subsequent p120-processing. In addition, Lys63-linked chains as well as Lys48-linked chains were detected in the 26S proteasome-bound polyubiquitinated proteins. These results raise the possibility that Lys63-linked ubiquitin chain also serves as a targeting signal for the 26S proteaseome in vivo.

Proteasomes can degrade a significant proportion of cellular proteins independent of ubiquitination

The critical role of the ubiquitin-26S proteasome system in regulation of protein homeostasis in eukaryotes is well established. In contrast, the impact of the ubiquitin-independent proteolytic activity of proteasomes is poorly understood. Through biochemical analysis of mammalian lysates, we find that the 20S proteasome, latent in peptide hydrolysis, specifically cleaves more than 20% of all cellular proteins. Thirty intrinsic proteasome substrates (IPSs) were identified and in vitro studies of their processing revealed that cleavage occurs at disordered regions, generating stable products encompassing structured domains. The mechanism of IPS recognition is remarkably well conserved in the eukaryotic kingdom, as mammalian and yeast 20S proteasomes exhibit the same target specificity. Further, 26S proteasomes specifically recognize and cleave IPSs at similar sites, independent of ubiquitination, suggesting that disordered regions likely constitute the universal structural signal for IPS proteolysis by proteasomes. Finally, we show that proteasomes contribute to physiological regulation of IPS levels in living cells and the inactivation of ubiquitin-activating enzyme E1 does not prevent IPS degradation. Collectively, these findings suggest a significant contribution of the ubiquitin-independent proteasome degradation pathway to the regulation of protein homeostasis in eukaryotes.

Gly-Ala repeats induce position- and substrate-specific regulation of 26 S proteasome-dependent partial processing

Partial degradation or regulated ubiquitin proteasome-dependent processing by the 26 S proteasome has been demonstrated, but the underlying molecular mechanisms and the prevalence of this phenomenon remain obscure. Here we show that the Gly-Ala repeat (GAr) sequence of EBNA1 affects processing of substrates via the ubiquitin-dependent degradation pathway in a substrate- and position-specific fashion. GAr-mediated increase in stability of proteins targeted for degradation via the 26 S proteasome was associated with a fraction of the substrates being partially processed and the release of the free GAr. The GAr did not cause a problem for the proteolytic activity of the proteasome, and its fusion to the N terminus of p53 resulted in an increase in the rate of degradation of the entire chimera. Interestingly the GAr had little effect on the stability of EBNA1 protein itself, and targeting EBNA1 for 26 S proteasome-dependent degradation led to its complete degradation. Taken together, our data suggest a model in which the GAr prevents degradation or promotes endoproteolytic processing of substrates targeted for the 26 S proteasome by interfering with the initiation step of substrate unfolding. These results will help to further understand the underlying mechanisms for partial proteasome-dependent degradation.

Functional and biochemical characterization of the 20S proteasome in a yeast temperature-sensitive mutant, rpt6-1

Background

Rpt6-1 is a thermosensitive yeast mutant with a deletion of a gene encoding a regulatory subunit of the 26S proteasome, RPT6, which is able to grow at 25°C but not at 37°C. In this study, peptidase activities, activation profiles, and the subunit composition of the 20S proteasome purified from the rpt6-1 mutant was characterized.

Results

The 20S proteasome purified from rpt6-1 exhibited low levels of peptidase activities in the absence of activators, but nearly same activated activities in the presence of activators, suggesting a gating defect in the proteasome channel. Detailed analyses of the composition of the 20S proteasome through separation of all subunits by two-dimensional gel electrophoresis followed by identification of each subunit using MALDI-TOF-MS revealed that two subunits, α1 and α7, differed from those of wild-type cells in both electrophoretic mobility and pI values. The changes in these two α-subunits were apparent at the permissive temperature, but disappeared during stress response at the restrictive temperature. Interestingly, upon disappearance of these changes, the levels of peptidase activity of the 20S proteasome in the rpt6-1 mutant were restored as the wild-type. These results suggest that two different forms of the α-subunits, α1 and α7, block the proteasome channel in the rpt6-1 mutant.

Conclusion

Two α-subunits (α1 and α7) of the 20S proteasome in the rpt6-1 mutant differed from their wild-type counterparts and peptidase activities were found to be lower in the mutant than in the wild-type strain.

Mass spectrometry analysis of proteome-wide proteolytic post-translational degradation of proteins

Protein proteolytic degradation is an essential component to proper cell function and its life cycle. Here, we study the protein degradation in yeast Saccharomyces cerevisiae cells on a proteome-wide scale by detection of the intermediate peptides produced from the intracellular degradation of proteins using sequencing-based tandem mass spectrometry. By tracing the detected approximately 1100 peptides and their approximately 200 protein-substrate origins we obtain evidence for new insights into the proteome-wide protein-selective degradation in yeast cells. This evidence shows that the yeast cytoplasm is the largest pool for the degradation of proteins with both biochemical and geometric specificities, whereas the yeast nucleus seems to be a proteolysis-inert organelle under the condition studied. Yeast V-ATPase subunits appear to be degraded during their disassembly, and yeast mitochondrial proteins functioning as precursors, transport carriers, and gates are preferentially degraded. Ubiquitylation may be unnecessary for the proteasomal degradation of yeast cytoplasmic regulatory and enzyme proteins according to our observations. This study shows that the intracellular peptides are informational targets for directly probing the protein degradation-involved molecular mechanisms and cell biology processes.

Ubiquitin-independent degradation of proteins by the proteasome

The proteasome is the main proteolytic machinery of the cell and constitutes a recognized drugable target, in particular for treating cancer. It is involved in the elimination of misfolded, altered or aged proteins as well as in the generation of antigenic peptides presented by MHC class I molecules. It is also responsible for the proteolytic maturation of diverse polypeptide precursors and for the spatial and temporal regulation of the degradation of many key cell regulators whose destruction is necessary for progression through essential processes, such as cell division, differentiation and, more generally, adaptation to environmental signals. It is generally believed that proteins must undergo prior modification by polyubiquitin chains to be addressed to, and recognized by, the proteasome. In reality, however, there is accumulating evidence that ubiquitin-independent proteasomal degradation may have been largely underestimated. In particular, a number of proto-oncoproteins and oncosuppressive proteins are privileged ubiquitin-independent proteasomal substrates, the altered degradation of which may have tumorigenic consequences. The identification of ubiquitin-independent mechanisms for proteasomal degradation also poses the paramount question of the multiplicity of catabolic pathways targeting each protein substrate. As this may help design novel therapeutic strategies, the underlying mechanisms are critically reviewed here.

Protein disaggregation by the AAA+ chaperone ClpB involves partial threading of looped polypeptide segments

The ring-forming AAA+ chaperone ClpB cooperates with the DnaK chaperone system to reactivate aggregated proteins. With the assistance of DnaK, ClpB extracts unfolded polypeptides from aggregates via substrate threading through its central channel. Here we analyze the processing of mixed aggregates consisting of protein fusions of misfolded and native domains. ClpB-DnaK reactivated all aggregated fusion proteins with similar efficiency, without unfolding native domains, demonstrating that partial threading of the misfolded moiety is sufficient to solubilize aggregates. Reactivation by ClpB-DnaK occurred even when two stably folded domains flanked the aggregated moiety, indicating threading of internal substrate segments. In contrast with the related AAA+ chaperone ClpC, ClpB lacks a robust unfolding activity, enabling it to sense the conformational state of substrates. ClpB rings are highly unstable, which may facilitate dissociation from trapped substrates during threading.

Dissecting the ER-associated degradation of a misfolded polytopic membrane protein

It remains unclear how misfolded membrane proteins are selected and destroyed during endoplasmic reticulum-associated degradation (ERAD). For example, chaperones are thought to solubilize aggregation-prone motifs, and some data suggest that these proteins are degraded at the ER. To better define how membrane proteins are destroyed, the ERAD of Ste6p(*), a 12 transmembrane protein, was reconstituted. We found that specific Hsp70/40s act before ubiquitination and facilitate Ste6p(*) association with an E3 ubiquitin ligase, suggesting an active role for chaperones. Furthermore, polyubiquitination was a prerequisite for retrotranslocation, which required the Cdc48 complex and ATP. Surprisingly, the substrate was soluble, and extraction was independent of a ubiquitin chain extension enzyme (Ufd2p). However, Ufd2p increased the degree of ubiquitination and facilitated degradation. These data indicate that polytopic membrane proteins can be extracted from the ER, and define the point of action of chaperones and the requirement for Ufd2p during membrane protein quality control.

N-linked glycosylation does not impair proteasomal degradation but affects class I major histocompatibility complex presentation

The addition of N-linked glycans to nascent polypeptides occurs cotranslationally in the endoplasmic reticulum (ER). For many proteins the state of the glycans serves as an indicator, which allows the ER quality control system to monitor the conformation of polypeptides upon folding. Proteins that fail to fold in the ER are often dislocated to the cytoplasm, where they are subjected to proteasomal degradation. Although the addition of N-linked glycans occurs within the ER, non-lysosomal removal of the glycans occurs in the cytosol by the action of peptide N-glycanase (PNGase). In this study, we investigated the interplay between PNGase action and proteasomal degradation of ER misfolded proteins (i.e. whether PNGase acts prior to or following proteasomal degradation). Interestingly, we found that glycan removal from N-terminally extended peptides modulates the presentation of class I major histocompatibility complex-restricted epitopes. Our findings provide direct evidence that the proteasome is capable of degrading glycoproteins without prior removal of their glycans. This degradation is independent of either the identity of the glycosylated protein or the type and number of N-linked glycans it harbors. We also captured and characterized glycopeptides generated following proteasomal degradation of RNaseB. Although the carbohydrate moiety reduced the variability of the degradation products that include the glycosylated residue (local effect), the overall global digestion pattern of RNaseB was unaffected. Together with earlier findings by others, our data support a model in which PNGase may act both upstream and downstream to proteasomal degradation and demonstrates its important role in class I major histocompatibility complex antigen presentation.

Aging and regulated protein degradation: who has the UPPer hand?

In all cells, protein degradation is a constant, ongoing process that is critical for cell survival and repair. The ubiquitin/proteasome pathway (UPP) is the major proteolytic pathway that degrades intracellular proteins in a regulated manner. It plays critical roles in many cellular processes and diseases. Disruption of the UPP is particularly relevant to pathophysiological conditions that provoke the accumulation of aberrant proteins, such as in aging as well as in a variety of neurodegenerative disorders including Alzheimer's and Parkinson's diseases. For unknown reasons, most of these neurodegenerative disorders that include familial and sporadic cases exhibit a late onset. It is possible that these neurodegenerative conditions exhibit a late onset because proteasome activity decreases with aging. Aging-dependent impairment in proteolysis mediated by the proteasome may have profound ramifications for cell viability. It can lead to the accumulation of modified, potentially toxic proteins in cells and can cause cell injury or premature cell death by apoptosis or necrosis. While it is accepted that aging affects UPP function, the question is why does aging cause a decline in regulated protein degradation by the UPP? Herein, we review some of the properties of the UPP and mechanisms mediating its age-dependent impairment. We also discuss the relevance of these findings leading to a model that proposes that UPP dysfunction may be one of the milestones of aging.

Cdc48p(Npl4p/Ufd1p) binds and segregates membrane-anchored/tethered complexes via a polyubiquitin signal present on the anchors

Cdc48p is an abundant and conserved member of the AAA ATPase family of molecular chaperones. Cdc48p performs ubiquitin-selective functions, which are mediated by numerous ubiquitin binding adaptors, including the Npl4p-Ufd1p complex. Previous studies suggest that Cdc48p-containing complexes carry out many biochemical activities, including ubiquitination, deubiquitination, protein complex segregation, and targeting of ubiquitinated substrates to the proteasome. The molecular mechanisms by which Cdc48p-containing complexes participate in these processes remain poorly defined. We show here by using physiologically relevant Cdc48p substrates (i.e., endoplasmic membrane-associated/tethered dimers of Mga2p and Spt23p) and in vitro systems with purified proteins that Cdc48p(Npl4p/Ufd1p) binds to and promotes segregation of the tethered proteins via a polyubiquitin signal present on the membrane-bound proteins. Mobilization does not involve retrotranslocation of the associated anchors. These results provide biochemical evidence that Cdc48p(Npl4p/Ufd1p) functions as a polyubiquitin-selective segregase and that a polyubiquitin-Cdc48p pathway modulates protein interactions at cell membranes.

A novel protein-processing domain in Gli2 and Gli3 differentially blocks complete protein degradation by the proteasome

The proteasome usually completely degrades its target proteins, but it can also degrade a handful of proteins in a limited and site-specific manner. The molecular mechanism for such limited degradation is unknown. The repressor forms of Gli2 and Gli3 transcription factors are generated from their full-length proteins through limited proteasome-mediated protein degradation. In this study, we have taken advantage of the fact that Gli3 is efficiently processed, whereas Gli2 is not, and identified a region of approximately 200 residues in their C termini that determine differential processing of the two proteins. This region, named processing determinant domain, functions as a signal for protein processing in the context of not only Gli2 and Gli3 protein sequences but also a heterologous hybrid protein, which would otherwise be completely degraded by the proteasome. Thus, the processing determinant domain constitutes a novel domain that functions independently. Our findings explain, at the molecular level, why Gli2 and Gli3 are differentially processed and, more importantly, may help understand a probably general mechanism by which the proteasome degrades some of its target proteins partially rather than completely.

Efficient degradation of misfolded mutant Pma1 by endoplasmic reticulum‐associated degradation requires Atg19 and the Cvt/autophagy pathway

Misfolded proteins are usually arrested in the endoplasmic reticulum (ER) and degraded by the ER-associated degradation (ERAD) machinery. Several mutant alleles of PMA1, the gene coding for the plasma membrane H(+)-ATPase, render misfolded proteins that are retained in the ER and degraded by ERAD. A subset of misfolded PMA1 mutants exhibit a dominant negative effect on yeast growth since, when coexpressed with the wild-type allele, both proteins are retained in the ER. We have used a pma1-D378T dominant negative mutant to identify new genes involved in ERAD. A genetic screen was performed for isolation of multicopy suppressors of a GAL1-pma1-D378T allele. ATG19, a member of the cytoplasm to vacuole targeting (Cvt) pathway, was found to suppress the growth arrest phenotype caused by the expression of pma1-D378T. ATG19 accelerates the degradation of pma1-D378T thus allowing the co-retained wild-type Pma1 to reach the plasma membrane. ATG19 was also able to suppress other dominant lethal PMA1 mutations. The degradation of the mutant ATPase occurs in the proteasome and requires intact both ERAD and Cvt/autophagy pathways. We propose the cooperation of both pathways for an efficient degradation of misfolded Pma1.