Recently, the homolog of yeast protein Sec63p was identified in dog pancreas microsomes. This pancreatic DnaJ-like protein was shown to be an abundant protein, interacting with both the Sec61p complex and lumenal DnaK-like proteins, such as BiP. The pancreatic endoplasmic reticulum contains a second DnaJ-like membrane protein, which had been termed Mtj1p in mouse. Mtj1p is present in pancreatic microsomes at a lower concentration than Sec63p but has a higher affinity for BiP. In addition to a lumenal J-domain, Mtj1p contains a single transmembrane domain and a cytosolic domain which is in close contact with translating ribosomes and appears to have the ability to modulate translation. The interaction with ribosomes involves a highly charged region within the cytosolic domain of Mtj1p. We propose that Mtj1p represents a novel type of co-chaperone, mediating transmembrane recruitment of DnaK-like chaperones to ribosomes and, possibly, transmembrane signaling between ribosomes and DnaK-like chaperones of the endoplasmic reticulum.
In human cells, one-third of all polypeptides enter the secretory pathway at the endoplasmic reticulum (ER). The specificity and efficiency of this process are guaranteed by targeting of mRNAs and/or polypeptides to the ER membrane. Cytosolic SRP and its receptor in the ER membrane facilitate the cotranslational targeting of most ribosome-nascent precursor polypeptide chain (RNC) complexes together with the respective mRNAs to the Sec61 complex in the ER membrane. Alternatively, fully synthesized precursor polypeptides are targeted to the ER membrane post-translationally by either the TRC, SND, or PEX19/3 pathway. Furthermore, there is targeting of mRNAs to the ER membrane, which does not involve SRP but involves mRNA- or RNC-binding proteins on the ER surface, such as RRBP1 or KTN1. Traditionally, the targeting reactions were studied in cell-free or cellular assays, which focus on a single precursor polypeptide and allow the conclusion of whether a certain precursor can use a certain pathway. Recently, cellular approaches such as proximity-based ribosome profiling or quantitative proteomics were employed to address the question of which precursors use certain pathways under physiological conditions. Here, we combined siRNA-mediated depletion of putative mRNA receptors in HeLa cells with label-free quantitative proteomics and differential protein abundance analysis to characterize RRBP1- or KTN1-involving precursors and to identify possible genetic interactions between the various targeting pathways. Furthermore, we discuss the possible implications on the so-called TIGER domains and critically discuss the pros and cons of this experimental approach.
The first step in the secretion of most mammalian proteins is their transport into the lumen of the endoplasmic reticulum (ER). Transport of pre-secretory proteins into the mammalian ER requires signal peptides in the precursor proteins and a protein translocase in the ER membrane. In addition, hitherto unidentified lumenal ER proteins have been shown to be required for vectorial protein translocation. This requirement was confirmed in this study by using proteoliposomes that were made from microsomal detergent extracts and contained either low or high concentrations of lumenal ER proteins. Furthermore, immunoglobulin-heavy-chain-binding protein (BiP) was shown to be able to substitute for the full set of lumenal proteins and, in the case of biotinylated precursor proteins, avidin was found to be able to substitute for lumenal proteins. Thus, the polypeptide-chain-binding protein BiP was identified as one lumenal protein that is involved in efficient vectorial protein translocation into the mammalian ER. EMBO reports 4, 505-510 (2003) doi:10.1038/sj.embor.embor826 INTRODUCTIONThe initial step in the secretion of most mammalian proteins, in which it is decided whether they enter the secretory pathway, is their transport into the lumen of the endoplasmic reticulum (ER; Blobel & Dobberstein, 1975). The transport of pre-secretory proteins into the ER requires cleavable signal peptides at the amino termini of the precursor proteins and a transport machinery that operates co-or posttranslationally. Transport occurs in a sequence of three consecutive steps: first, membrane association of the precursor protein; second, membrane insertion (assayed as signal peptide cleavage); and third, completion of translocation (assayed as sequestration). This transport requires a protein translocase, which comprises Sec61-α, Sec61-β and Sec61-γ as its central components (Görlich & Rapoport, 1993).In addition, ATP-binding proteins of the ER lumen are part of the protein translocase and facilitate the insertion of pre-secretory proteins into the Sec61 complex (Klappa et al., 1991;Liao et al., 1997). A functional approach, involving proteoliposomes made from microsomal detergent extracts, identified the ATP-binding proteins as the ER-resident members of the heat-shock protein 70 (Hsp70) protein family, immunoglobulin-heavy-chain-binding protein (BiP)/glucoseregulated protein 78 (Grp78) and Grp170 (Dierks et al., 1996;Hamman et al., 1998). On the basis of analogy to the situation in yeast (Brodsky et al., 1995;Young et al., 2001), these Hsp70 protein family members that reside in the mammalian ER may be recruited to the Sec61 complex by the membrane-integrated Hsp40 protein family member, Sec63 (Meyer et al., 2000;Tyedmers et al., 2000). Furthermore, the reticuloplasm (the complete set of ER lumenal proteins) has been shown to be required for vectorial protein translocation into mammalian microsomes (Nicchitta & Blobel, 1993). This latter requirement was confirmed here by using proteoliposomes that were made from microsomal detergent ...
In mammalian cells, one-third of all polypeptides is transported into or through the ER-membrane via the Sec61-channel. While the Sec61-complex facilitates the transport of all polypeptides with amino-terminal signal peptides (SP) or SP-equivalent transmembrane helices (TMH), the translocating chain-associated membrane protein (now termed TRAM1) was proposed to support transport of a subset of precursors. To identify possible determinants of TRAM1 substrate specificity, we systematically identified TRAM1-dependent precursors by analyzing cellular protein abundance changes upon TRAM1 depletion in HeLa cells using quantitative label-free proteomics. In contrast to previous analysis after TRAP depletion, SP and TMH analysis of TRAM1 clients did not reveal any distinguishing features that could explain its putative substrate specificity. To further address the TRAM1 mechanism, live-cell calcium imaging was carried out after TRAM1 depletion in HeLa cells. In additional contrast to previous analysis after TRAP depletion, TRAM1 depletion did not affect calcium leakage from the ER. Thus, TRAM1 does not appear to act as SP-or TMHreceptor on the ER-membrane's cytosolic face and does not appear to affect the open probability of the Sec61-channel. It may rather play a supportive role in protein transport, such as making the phospholipid bilayer conducive for accepting SP and TMH in the vicinity of the lateral gate of the Sec61-channel.
Protein import into the endoplasmic reticulum (ER) is the first step in the biogenesis of around 10,000 different soluble and membrane proteins in humans. It involves the co- or post-translational targeting of precursor polypeptides to the ER, and their subsequent membrane insertion or translocation. So far, three pathways for the ER targeting of precursor polypeptides and four pathways for the ER targeting of mRNAs have been described. Typically, these pathways deliver their substrates to the Sec61 polypeptide-conducting channel in the ER membrane. Next, the precursor polypeptides are inserted into the ER membrane or translocated into the ER lumen, which may involve auxiliary translocation components, such as the TRAP and Sec62/Sec63 complexes, or auxiliary membrane protein insertases, such as EMC and the TMCO1 complex. Recently, the PEX19/PEX3-dependent pathway, which has a well-known function in targeting and inserting various peroxisomal membrane proteins into pre-existent peroxisomal membranes, was also found to act in the targeting and, putatively, insertion of monotopic hairpin proteins into the ER. These either remain in the ER as resident ER membrane proteins, or are pinched off from the ER as components of new lipid droplets. Therefore, the question arose as to whether this pathway may play a more general role in ER protein targeting, i.e., whether it represents a fourth pathway for the ER targeting of precursor polypeptides. Thus, we addressed the client spectrum of the PEX19/PEX3-dependent pathway in both PEX3-depleted HeLa cells and PEX3-deficient Zellweger patient fibroblasts by an established approach which involved the label-free quantitative mass spectrometry of the total proteome of depleted or deficient cells, as well as differential protein abundance analysis. The negatively affected proteins included twelve peroxisomal proteins and two hairpin proteins of the ER, thus confirming two previously identified classes of putative PEX19/PEX3 clients in human cells. Interestingly, fourteen collagen-related proteins with signal peptides or N-terminal transmembrane helices belonging to the secretory pathway were also negatively affected by PEX3 deficiency, which may suggest compromised collagen biogenesis as a hitherto-unknown contributor to organ failures in the respective Zellweger patients.
Heterodimeric luciferase from Vibrio harveyi had been established as a unique model enzyme for direct measurements of the effects of molecular chaperones and folding catalysts on protein folding and subunit assembly after de novo synthesis of subunits in rabbit reticulocyte lysate. It was observed that luciferase assembly can be separated in time from synthesis of the two subunits and that under these post-translational conditions assembly was inhibited by either ATP depletion or inhibition of peptidylprolyl cis/trans isomerases, that is, by addition of cyclosporin A or FK506. Furthermore, it was observed that the inhibitory effect of FK506 on luciferase assembly can be suppressed by addition of purified cyclophilin, thereby providing the first direct evidence for the involvement of peptidylprolyl cis/trans isomerases in protein biogenesis in the eukaryotic cytosol. Here the ATP requirement in luciferase assembly has been characterized. Depletion of either Hsp90 or CCT from reticulocyte lysate did not interfere with luciferase assembly. However, addition of purified Hsc70 stimulated luciferase assembly. While addition of purified Hsp40 did not have any effect on luciferase assembly, the stimulatory effect of Hsc70 was further increased by Hsp40. Thus, after synthesis of the two subunits in reticulocyte lysate assembly of heterodimeric luciferase involves Hsc70 and its co-chaperone Hsp40. Therefore, Hsc70 aids protein biogenesis in the eukaryotic cytosol not only at the levels of nascent polypeptide chains and precursor proteins that have to be kept competent for transport into cell organelles, but also at the level of subunits that have to be kept competent for assembly.Keywords: assembly; bacterial luciferase; Hsc70; Hsp40; PPIase.Protein folding and subunit assembly in the various compartments of the eukaroytic cell following de novo synthesis of polypeptides is generally assumed to be assisted by molecular chaperones and folding catalysts. In this respect, the role of Hsc70 in the cytosol so far is mainly seen as chaperoning nascent polypeptide chains [1±3].Various laboratories started to use light emitting luciferases in order to address questions related to folding in either the mammalian cytosol (by employing rabbit reticulocyte lysate or wheat germ lysate as a translation and folding system) or in the mammalian endoplasmic reticulum (by employing rabbit reticulocyte lysate as a system for synthesis of precursor proteins and dog pancreas microsomes as a folding system). Specifically, it was asked which molecular chaperones and folding catalysts are involved in folding and assembly of a monomeric or a heterodimeric luciferase [4±10]. Heterodimeric luciferase is a cytosolic enzyme in Vibrio harveyi and catalyzes oxygen-dependent and FMNH 2 -dependent conversion of a long-chain aldehyde to the corresponding fatty acid. Monomeric luciferase is a peroxisomal enzyme in Photinus pyralis and catalyzes the oxygen-dependent and Mg 21-ATP-dependent oxidation of luciferin. There are several advantages to employing the...
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