Mechanism of orphan subunit recognition during assembly quality control.

Cells contain numerous abundant molecular machines assembled from multiple subunits. Imbalances in subunit production and failed assembly generate orphan subunits that are eliminated by poorly defined pathways. Here, we determined how orphan subunits of the cytosolic chaperonin CCT are recognized. Several unassembled CCT subunits recruited the E3 ubiquitin ligase HERC2 using ZNRD2 as an adaptor. Both factors were necessary for orphan CCT subunit degradation in cells, sufficient for CCT subunit ubiquitination with purified factors, and necessary for optimal cell fitness. Domain mapping and structure prediction defined the molecular features of a minimal HERC2-ZNRD2-CCT module. The structural model, whose key elements were validated in cells using point mutants, shows why ZNRD2 selectively recognizes multiple orphaned CCT subunits without engaging assembled CCT. Our findings reveal how failures during CCT assembly are monitored and provide a paradigm for the molecular recognition of orphan subunits, the largest source of quality control substrates in cells.

De novo formation and maintenance of mammalian peroxisomes in cultured PEX16-knockout cells generated by CRISPR/Cas9.

Mammalian PEX16 has been considered essential for generating and maintaining peroxisomal membranes. This view is based primarily on the finding that fibroblasts from several PEX16-deficient patients are devoid of peroxisomal structures but can form peroxisomes upon expression of PEX16. However, unlike these patient-derived cells, pex16 mutants in other model organisms contain partially functional peroxisomes. Here, we report that PEX16-knockout (KO) cells derived from three mammalian cultured cell lines comprise cells containing a fewer number of enlarged peroxisomes and cells lacking peroxisomes. We also suggest that PEX16 accelerates the process by which peroxisome-less cells form peroxisomal membranes and subsequently establish mature peroxisomes, independently of its ability to mediate peroxisomal targeting of PEX3. Nevertheless, PEX16 is not absolutely required for this process. Moreover, a well-known patient-derived PEX16 mutant inhibits the de novo formation of peroxisomal membranes. Our findings suggest that although PEX16 is undoubtedly important for optimal peroxisomal membrane biogenesis, mammalian cells may be able to form peroxisomes de novo and maintain the organelles without the aid of PEX16.

Mitotic phosphorylation of Pex14p regulates peroxisomal import machinery.

Peroxisomal matrix proteins are imported into peroxisomes via membrane-bound docking/translocation machinery. One central component of this machinery is Pex14p, a peroxisomal membrane protein involved in the docking of Pex5p, the receptor for peroxisome targeting signal type 1 (PTS1). Studies in several yeast species have shown that Pex14p is phosphorylated in vivo, whereas no function has been assigned to Pex14p phosphorylation in yeast and mammalian cells. Here, we investigated peroxisomal protein import and its dynamics in mitotic mammalian cells. In mitotically arrested cells, Pex14p is phosphorylated at Ser-232, resulting in a lower import efficiency of catalase, but not the majority of proteins including canonical PTS1 proteins. Conformational change induced by the mitotic phosphorylation of Pex14p more likely increases homomeric interacting affinity and suppresses topological change of its N-terminal part, thereby giving rise to the retardation of Pex5p export in mitotic cells. Taken together, these data show that mitotic phosphorylation of Pex14p and consequent suppression of catalase import are a mechanism of protecting DNA upon nuclear envelope breakdown at mitosis.

The architecture of EMC reveals a path for membrane protein insertion.

Approximately 25% of eukaryotic genes code for integral membrane proteins that are assembled at the endoplasmic reticulum. An abundant and widely conserved multi-protein complex termed EMC has been implicated in membrane protein biogenesis, but its mechanism of action is poorly understood. Here, we define the composition and architecture of human EMC using biochemical assays, crystallography of individual subunits, site-specific photocrosslinking, and cryo-EM reconstruction. Our results suggest that EMC's cytosolic domain contains a large, moderately hydrophobic vestibule that can bind a substrate's transmembrane domain (TMD). The cytosolic vestibule leads into a lumenally-sealed, lipid-exposed intramembrane groove large enough to accommodate a single substrate TMD. A gap between the cytosolic vestibule and intramembrane groove provides a potential path for substrate egress from EMC. These findings suggest how EMC facilitates energy-independent membrane insertion of TMDs, explain why only short lumenal domains are translocated by EMC, and constrain models of EMC's proposed chaperone function.

Deficiency of a Retinal Dystrophy Protein, Acyl-CoA Binding Domain-containing 5 (ACBD5), Impairs Peroxisomal ß-Oxidation of Very-long-chain Fatty Acids.

Acyl-CoA binding domain-containing 5 (ACBD5) is a peroxisomal protein that carries an acyl-CoA binding domain (ACBD) at its N-terminal region. The recent identification of a mutation in the ACBD5 gene in patients with a syndromic form of retinal dystrophy highlights the physiological importance of ACBD5 in humans. However, the underlying pathogenic mechanisms and the precise function of ACBD5 remain unclear. We herein report that ACBD5 is a peroxisomal tail-anchored membrane protein exposing its ACBD to the cytosol. Using patient-derived fibroblasts and ACBD5 knock-out HeLa cells generated via genome editing, we demonstrate that ACBD5 deficiency causes a moderate but significant defect in peroxisomal ß-oxidation of very-long-chain fatty acids (VLCFAs) and elevates the level of cellular phospholipids containing VLCFAs without affecting peroxisome biogenesis, including the import of membrane and matrix proteins. Both the N-terminal ACBD and peroxisomal localization of ACBD5 are prerequisite for efficient VLCFA ß-oxidation in peroxisomes. Furthermore, ACBD5 preferentially binds very-long-chain fatty acyl-CoAs (VLC-CoAs). Together, these results suggest a direct role of ACBD5 in peroxisomal VLCFA ß-oxidation. Based on our findings, we propose that ACBD5 captures VLC-CoAs on the cytosolic side of the peroxisomal membrane so that the transport of VLC-CoAs into peroxisomes and subsequent ß-oxidation thereof can proceed efficiently. Our study reclassifies ACBD5-related phenotype as a novel peroxisomal disorder.

Assembly of Peroxisomal Membrane Proteins via the Direct Pex19p-Pex3p Pathway.

Correct targeting of peroxisomal membrane proteins (PMPs) is essential for the formation and maintenance of functional peroxisomes. Activities of Pex19p to interact with PMPs on one hand and Pex3p on the other, including formation of ternary complexes between Pex19p, PMP and Pex3p, strongly support posttranslational translocation of PMPs via the Pex19p- and Pex3p-dependent direct pathway, termed the class I pathway. However, it remains elusive whether Pex19p-PMP complexes are indeed capable of being imported into peroxisomal membranes through the interaction between Pex19p and Pex3p. We resolve this issue by investigating the targeting process of several topologically distinct PMPs, including multimembrane spanning PMPs. We show here that Pex19p forms cytosolic complexes with PMPs and directly translocates them to peroxisomes. Using a semi-intact mammalian cell-based import assay system, we prove that PMPs in the cytosolic complexes are imported into peroxisomes via the interaction between cargo-loaded Pex19p and Pex3p. Furthermore, we demonstrate for the first time that peroxisomal targeting of ATAD1, an N-terminally signal-anchored protein that resides on both mitochondria and peroxisomes, is also achieved through the Pex19p- and Pex3p-dependent class I pathway. Together, our results suggest that translocation of PMPs via the class I pathway is a common event in mammalian cells.

Tail-anchored PEX26 targets peroxisomes via a PEX19-dependent and TRC40-independent class I pathway.

Tail-anchored (TA) proteins are anchored into cellular membranes by a single transmembrane domain (TMD) close to the C terminus. Although the targeting of TA proteins to peroxisomes is dependent on PEX19, the mechanistic details of PEX19-dependent targeting and the signal that directs TA proteins to peroxisomes have remained elusive, particularly in mammals. The present study shows that PEX19 formed a complex with the peroxisomal TA protein PEX26 in the cytosol and translocated it directly to peroxisomes by interacting with the peroxisomal membrane protein PEX3. Unlike in yeast, the adenosine triphosphatase TRC40, which delivers TA proteins to the endoplasmic reticulum, was dispensable for the peroxisomal targeting of PEX26. Moreover, the basic amino acids within the luminal domain of PEX26 were essential for binding to PEX19 and thereby for peroxisomal targeting. Finally, our results suggest that a TMD that escapes capture by TRC40 and is followed by a highly basic luminal domain directs TA proteins to peroxisomes via the PEX19-dependent route.

Distinct HIV-1 escape patterns selected by cytotoxic T cells with identical epitope specificity.

Pol283-8-specific, HLA-B*51:01-restricted, cytotoxic T cells (CTLs) play a critical role in the long-term control of HIV-1 infection. However, these CTLs select for the reverse transcriptase (RT) I135X escape mutation, which may be accumulating in circulating HIV-1 sequences. We investigated the selection of the I135X mutation by CTLs specific for the same epitope but restricted by HLA-B*52:01. We found that Pol283-8-specific, HLA-B*52:01-restricted CTLs were elicited predominantly in chronically HIV-1-infected individuals. These CTLs had a strong ability to suppress the replication of wild-type HIV-1, though this ability was weaker than that of HLA-B*51:01-restricted CTLs. The crystal structure of the HLA-B*52:01-Pol283-8 peptide complex provided clear evidence that HLA-B*52:01 presents the peptide similarly to HLA-B*51:01, ensuring the cross-presentation of this epitope by both alleles. Population level analyses revealed a strong association of HLA-B*51:01 with the I135T mutant and a relatively weaker association of HLA-B*52:01 with several I135X mutants in both Japanese and predominantly Caucasian cohorts. An in vitro viral suppression assay revealed that the HLA-B*52:01-restricted CTLs failed to suppress the replication of the I135X mutant viruses, indicating the selection of these mutants by the CTLs. These results suggest that the different pattern of I135X mutant selection may have resulted from the difference between these two CTLs in the ability to suppress HIV-1 replication.

Peroxisome biogenesis disorders: molecular basis for impaired peroxisomal membrane assembly: in metabolic functions and biogenesis of peroxisomes in health and disease.

Peroxisome is a single-membrane organelle in eukaryotes. The functional importance of peroxisomes in humans is highlighted by peroxisome-deficient peroxisome biogenesis disorders (PBDs) such as Zellweger syndrome (ZS). Gene defects of peroxins required for both membrane assembly and matrix protein import are identified: ten mammalian pathogenic peroxins for ten complementation groups of PBDs, are required for matrix protein import; three, Pex3p, Pex16p and Pex19p, are shown to be essential for peroxisome membrane assembly and responsible for the most severe ZS in PBDs of three complementation groups 12, 9, and 14, respectively. Patients with severe ZS with defects of PEX3, PEX16, and PEX19 tend to carry severe mutation such as nonsense mutations, frameshifts and deletions. With respect to the function of these three peroxins in membrane biogenesis, two distinct pathways have been proposed for the import of peroxisomal membrane proteins in mammalian cells: a Pex19p- and Pex3p-dependent class I pathway and a Pex19p- and Pex16p-dependent class II pathway. In class II pathway, Pex19p also forms a soluble complex with newly synthesized Pex3p as the chaperone for Pex3p in the cytosol and directly translocates it to peroxisomes. Pex16p functions as the peroxisomal membrane receptor that is specific to the Pex3p-Pex19p complexes. A model for the import of peroxisomal membrane proteins is suggested, providing new insights into the molecular mechanisms underlying the biogenesis of peroxisomes and its regulation involving Pex3p, Pex19p, and Pex16p. Another model suggests that in Saccharomyces cerevisiae peroxisomes likely emerge from the endoplasmic reticulum.

Isolation and characterization of mutant animal cell line defective in alkyl-dihydroxyacetonephosphate synthase: localization and transport of plasmalogens to post-Golgi compartments.

We herein isolated plasmalogen-deficient Chinese hamster ovary (CHO) mutant, ZPEG251, with a phenotype of normal import of peroxisomal matrix and membrane proteins. In ZPEG251, plasmenylethanolamine (PlsEtn) was severely reduced. Complementation analysis by expression of genes responsible for the plasmalogen biogenesis suggested that alkyl-dihydroxyacetonephosphate synthase (ADAPS), catalyzing the second step of plasmalogen biogenesis, was deficient in ZPEG251. ADAPS mRNA was barely detectable as verified by Northern blot and reverse transcription-PCR analyses. Defect of ADAPS expression was also assessed by immunoblot. As a step toward delineating functional roles of PlsEtn, we investigated its subcellular localization. PlsEtn was localized to post-Golgi compartments and enriched in detergent-resistant membranes. Transport of PlsEtn to post-Golgi compartments was apparently affected by lowering cellular ATP, but not by inhibitors of microtubule assembly and vesicular transport. Partitioning of cholesterol and sphingomyelin, a typical feature of lipid rafts, was not impaired in plasmalogen-deficient cells, including peroxisome assembly-defective mutants, hence suggesting that PlsEtn was not essential for lipid-raft architecture in CHO cells.