Alexander Buchberger

Protein quality control in the cytosol and the endoplasmic reticulum: brothers in arms

In cells, both newly synthesized and pre-existing proteins are constantly endangered by misfolding and aggregation. The accumulation of damaged proteins can perturb cellular homeostasis and provoke aging, pathological states, and even cell death. To avert these dangers, cells have developed powerful quality control strategies that counteract protein damage in a compartment-specific way. Here, we compare the protein quality control systems of the eukaryotic cytosol and the endoplasmic reticulum, focusing on the principles of damage recognition, the triage decisions between chaperone-mediated refolding and proteolytic elimination of damaged proteins, the repair of misfolded and aggregated protein species, and the mechanisms by which perturbations of protein homeostasis are sensed to induce compartment-specific stress responses.

Interaction of Hsp70 chaperones with substrates

Determination of the structure of the substrate binding domain of the Escherichia coli Hsp70 chaperone, DnaK, and the biochemical characterisation of the motif it recognizes within substrates provide insights into the principles governing Hsp70 interaction with polypeptide chains. DnaK recognizes extended peptide strands composed of up to five consecutive hydrophobic residues within and positively charged residues outside the substrate binding cavity.

Membrane-bound Ubx2 recruits Cdc48 to ubiquitin ligases and their substrates to ensure efficient ER-associated protein degradation

Endoplasmic reticulum (ER)-associated protein degradation (ERAD) is a quality control system that removes misfolded proteins from the ER. ERAD substrates are channelled from the ER via a proteinacious pore to the cytosolic ubiquitin–proteasome system — a process involving dedicated ubiquitin ligases and the chaperone-like AAA ATPase Cdc48 (also known as p97). How the activities of these proteins are coupled remains unclear. Here we show that the UBX domain protein Ubx2 is an integral ER membrane protein that recruits Cdc48 to the ER. Moreover, Ubx2 mediates binding of Cdc48 to the ubiquitin ligases Hrd1 and Doa10, and to ERAD substrates. In addition, Ubx2 and Cdc48 interact with Der1 and Dfm1, yeast homologues of the putative dislocation pore protein Derlin-1 (refs 11–13). Lack of Ubx2 causes defects in ERAD that are exacerbated under stress conditions. These findings are consistent with a model in which Ubx2 coordinates the assembly of a highly efficient ERAD machinery at the ER membrane.

UBX domain proteins: major regulators of the AAA ATPase Cdc48/p97

Abstract.The highly conserved AAA ATPase Cdc48/p97 acts on ubiquitylated substrate proteins in cellular processes as diverse as the fusion of homotypic membranes and the degradation of misfolded proteins. The ‘Ubiquitin regulatory X’ (UBX) domain-containing proteins constitute the so far largest family of Cdc48/p97 cofactors. UBX proteins are involved in substrate recruitment to Cdc48/p97 and in the temporal and spatial regulation of its activity. In combination with UBX-like proteins and other cofactors, they can assemble into a large variety of Cdc48/p97-cofactor complexes possessing distinct cellular functions. This review gives an overview of the different subfamilies of UBX proteins and their functions, and discusses general principles of Cdc48/p97 regulation by these cofactors.

Cdc48: a power machine in protein degradation

Cdc48 is an essential, highly prominent ATP driven machine in eukaryotic cells. Physiological function of Cdc48 has been found in a multitude of cellular processes, for instance cell cycle progression, homotypic membrane fusion, chromatin remodeling, transcriptional and metabolic regulation, and many others. The molecular function of Cdc48 is arguably best understood in endoplasmic reticulum-associated protein degradation by the ubiquitin proteasome system. In this review, we summarize the general characteristics of Cdc48/p97 and the most recent results on the molecular function of Cdc48 in some of the above processes, which were found to finally end in proteolysis-connected pathways, either involving the proteasome or autophagocytosis-mediated lysosomal degradation.

From UBA to UBX: new words in the ubiquitin vocabulary

Ubiquitination is a versatile tool of eukaryotic cells for controlling the stability, function and subcellular localization of proteins. The variety of cellular processes regulated by ubiquitination demands high substrate specificity of the ubiquitination machinery as well as the existence of diverse downstream effector proteins interacting with ubiquitinated substrates. Most of these cellular effectors are characterized by a modular composition of ubiquitin-binding motifs and further domains mediating specific functions. Here, I give an overview of important ubiquitin-related protein motifs, including the UBA, UIM, UBD and UBX domains, and propose a model for the role of subclasses of UBA-domain-containing proteins in ubiquitin-mediated proteolysis.

Shp1 and Ubx2 are adaptors of Cdc48 involved in ubiquitin-dependent protein degradation

Known activities of the ubiquitin‐selective AAA ATPase Cdc48 (p97) require one of the mutually exclusive cofactors Ufd1/Npl4 and Shp1 (p47). Whereas Ufd1/Npl4 recruits Cdc48 to ubiquitylated proteins destined for degradation by the 26S proteasome, the UBX domain protein p47 has so far been linked exclusively to nondegradative Cdc48 functions in membrane fusion processes. Here, we show that all seven UBX domain proteins of Saccharomyces cerevisiae bind to Cdc48, thus constituting an entire new family of Cdc48 cofactors. The two major yeast UBX domain proteins, Shp1 and Ubx2, possess a ubiquitin‐binding UBA domain and interact with ubiquitylated proteins in vivo. Δshp1 and Δubx2 strains display defects in the degradation of a ubiquitylated model substrate, are sensitive to various stress conditions and are genetically linked to the 26S proteasome. Our data suggest that Shp1 and Ubx2 are adaptors for Cdc48‐dependent protein degradation through the ubiquitin/proteasome pathway.

The chaperone function of DnaK requires the coupling of ATPase activity with substrate binding through residue E171.

Central to the chaperone function of Hsp70 stress proteins including Escherichia coli DnaK is the ability of Hsp70 to bind unfolded protein substrates in an ATP‐dependent manner. Mg2+/ATP dissociates bound substrates and, furthermore, substrate binding stimulates the ATPase of Hsp70. This coupling is proposed to require a glutamate residue, E175 of bovine Hsc70, that is entirely conserved within the Hsp70 family, as it contacts bound Mg2+/ATP and is part of a hinge required for a postulated ATP‐dependent opening/closing movement of the nucleotide binding cleft which then triggers substrate release. We analyzed the effects of dnaK mutations which alter the corresponding glutamate‐171 of DnaK to alanine, leucine or lysine. In vivo, the mutated dnaK alleles failed to complement the delta dnaK52 mutation and were dominant negative in dnaK+ cells. In vitro, all three mutant DnaK proteins were inactive in known DnaK‐dependent reactions, including refolding of denatured luciferase and initiation of lambda DNA replication. The mutant proteins retained ATPase activity, as well as the capacity to bind peptide substrates. The intrinsic ATPase activities of the mutant proteins, however, did exhibit increased Km and Vmax values. More importantly, these mutant proteins showed no stimulation of ATPase activity by substrates and no substrate dissociation by Mg2+/ATP. Thus, glutamate‐171 is required for coupling of ATPase activity with substrate binding, and this coupling is essential for the chaperone function of DnaK.

The PUB Domain Functions as a p97 Binding Module in Human Peptide N-Glycanase

The AAA ATPase p97 is a ubiquitin-selective molecular machine involved in multiple cellular processes, including protein degradation through the ubiquitin-proteasome system and homotypic membrane fusion. Specific p97 functions are mediated by a variety of cofactors, among them peptide N-glycanase, an enzyme that removes glycans from misfolded glycoproteins. Here we report the three-dimensional structure of the aminoterminal PUB domain of human peptide N-glycanase. We demonstrate that the PUB domain is a novel p97 binding module interacting with the D1 and/or D2 ATPase domains of p97 and identify an evolutionary conserved surface patch required for p97 binding. Furthermore, we show that the PUB and UBX domains do not bind to p97 in a mutually exclusive manner. Our results suggest that PUB domain-containing proteins constitute a widespread family of diverse p97 cofactors.

Imbalances in p97 co‐factor interactions in human proteinopathy

The ubiquitin‐selective chaperone p97 is involved in major proteolytic pathways of eukaryotic cells and has been implicated in several human proteinopathies. Moreover, mutations in p97 cause the disorder inclusion body myopathy with Paget disease of bone and frontotemporal dementia (IBMPFD). The molecular basis underlying impaired degradation and pathological aggregation of ubiquitinated proteins in IBMPFD is unknown. Here, we identify perturbed co‐factor binding as a common defect of IBMPFD‐causing mutant p97. We show that IBMPFD mutations induce conformational changes in the p97 N domain, the main binding site for regulatory co‐factors. Consistently, mutant p97 proteins exhibit strongly altered co‐factor interactions. Specifically, binding of the ubiquitin ligase E4B is reduced, whereas binding of ataxin 3 is enhanced, thus resembling the accumulation of mutant ataxin 3 on p97 in spinocerebellar ataxia type 3. Our results suggest that imbalanced co‐factor binding to p97 is a key pathological feature of IBMPFD and potentially of other proteinopathies involving p97.