Substrate-specific regulation of the ribosome- translocon junction by N-terminal signal sequences.

Amino-terminal signal sequences target nascent secretory and membrane proteins to the endoplasmic reticulum for translocation. Subsequent interactions between the signal sequence and components of the translocation machinery at the endoplasmic reticulum are thought to be important for the productive engagement of the translocon by the ribosome-nascent chain complex. However, it is not clear whether all signal sequences carry out these posttargeting steps identically, or if there are differences in the interactions directed by one signal sequence versus another. In this study, we find substantial differences in the ability of signal sequences from different substrates to mediate closure of the ribosome--translocon junction early in translocation. We also show that these differences in some cases necessitate functional coordination between the signal sequence and mature domain for faithful translocation. Accordingly, the translocation of some proteins is sensitive to replacement of their signal sequences. In a particularly dramatic example, the topology of the prion protein was found to depend highly on the choice of signal sequence used to direct its translocation. Taken together, our results reveal an unanticipated degree of substrate-specific functionality encoded in N-terminal signal sequences.

A trabecular meshwork glucocorticoid response (TIGR) gene mutation affects translocational processing.

PURPOSE: To examine possible effects of the E323K mutation in the trabecular meshwork glucocorticoid response (TIGR) gene (also known as myocilin [MYOC]), using assays of translocational processing through the endoplasmic reticulum (ER). The E323K mutation was of particular interest, since the mutation shows a strong association with early onset open-angle glaucoma, but has a minimal predicted effect on protein structure. METHODS: Normal and mutant TIGR cDNA constructs were used to generate protein products in the presence of endoplasmic reticulum (ER) membranes, using an assay previously developed to detect alterations in the ER translocation function. "Paused" regions for potential protein modifications were defined by proteinase K (PK) sensitivity in the presence of ER membranes, with the ability to restart translocation when treated with EDTA. The effects of the E323K mutation were evaluated, as well as mutations located on either side of E323K (G246R, G364V, P370L) as the other mutations had substantial predicted structural changes in addition to clear disease associations. RESULTS: The native TIGR molecule was observed to have a paused region that corresponds to the region of highest olfactomedin (OLF) homology. The E323K mutation, located near the beginning of this region, dramatically altered the normal pattern of nascent proteins observed in the translocational pausing assay. A prominent band appeared with the E323K mutation, which could represent a new product or a marked enhancement of a faint band normally seen, approximately 3 kDa higher than the major paused band. The other TIGR mutants examined did not show this effect. CONCLUSIONS: The major translocational pause that starts near the beginning of the region of high OLF homology may help to explain the high frequency of glaucoma-associated mutations in this area. The observed effect of the E323K mutation on the products of translocational processing suggests a delay in the normal pausing process of TIGR biogenesis. This delay points to a potentially distinct pathogenic mechanism for E323K as compared with the other TIGR mutations so far evaluated.

Regulation of protein biogenesis at the endoplasmic reticulum membrane.

The biogenesis of most secretory and membrane proteins involves targeting the nascent protein to the endoplasmic reticulum (ER), translocation across or integration into the ER membrane and maturation into a functional product. The essential machinery that directs these events for model secretory and membrane proteins has been identified, shifting the focus of studies towards the molecular mechanisms by which these core components function. By contrast, regulatory mechanisms that allow certain proteins to serve multiple functions within a cell remain entirely unexplored. This article examines each stage of protein biogenesis as a potential site of regulation that could be exploited by the cell to effectively increase the diversity of functional gene expression.

Transmissible and genetic prion diseases share a common pathway of neurodegeneration.

Prion diseases can be infectious, sporadic and genetic. The infectious forms of these diseases, including bovine spongiform encephalopathy and Creutzfeldt-Jakob disease, are usually characterized by the accumulation in the brain of the transmissible pathogen, an abnormally folded isoform of the prion protein (PrP) termed PrPSc. However, certain inherited PrP mutations appear to cause neurodegeneration in the absence of PrPSc, working instead by favoured synthesis of CtmPrP, a transmembrane form of PrP. The relationship between the neurodegeneration seen in transmissible prion diseases involving PrPSc and that associated with ctmPrP has remained unclear. Here we find that the effectiveness of accumulated PrPSc in causing neurodegenerative disease depends upon the predilection of host-encoded PrP to be made in the ctmPrP form. Furthermore, the time course of PrPSc accumulation in transmissible prion disease is followed closely by increased generation of CtmPrP. Thus, the accumulation of PrPSc appears to modulate in trans the events involved in generating or metabolising CtmPrP. Together, these data suggest that the events of CtmPrP-mediated neurodegeneration may represent a common step in the pathogenesis of genetic and infectious prion diseases.

Regulation of protein topology by trans-acting factors at the endoplasmic reticulum.

In mammalian cells, the Sec61 complex and translocating chain-associated membrane protein (TRAM) are necessary and sufficient to direct the biogenesis, in the appropriate topology, of all secretory and membrane proteins examined thus far. We demonstrate here that the proper translocation of the prion protein (PrP), a substrate that can be synthesized in more than one topologic form, requires additional factors. In the absence of these additional factors, PrP is synthesized exclusively in the transmembrane topology (termed the CtmPrP form) associated with the development of neurodegenerative disease. Thus, translocation accessory factors, acting on some but not other substrates, can function as molecular switches to redirect nascent proteins toward divergent topologic fates with different functional consequences.

Translocational pausing of apolipoprotein B can be regulated by membrane lipid composition.

One potential mechanism by which apolipoprotein (apo) B secretion is regulated is via transient pausing during translocation across the endoplasmic reticulum membrane. We have previously shown that translocation and secretion of full-length and truncated variants of apoB 100 are impaired in hepatocytes in which microsomal membranes are enriched in the phospholipid phosphatidylmonomethylethanolamine (PMME). We have now investigated whether or not the decreased translocation of apoB is the result of altered membrane lipid composition having an impact on translocational pausing. Our experiments showed that less in vitro translated apoB-15 (the N-terminal 15% of human apoB-100) was translocated into the lumen of PMME-enriched microsomes than of control microsomes. Proteinase K treatment of the translocation products yielded discrete N-terminal fragments of apoB indicating that both types of microsomal membranes contained translocationally paused nascent chains. Similarly, apoB generated from a truncated mRNA lacking a stop codon was also found to be translocationally paused. However, restarting of translocation after translocational pausing was impaired in PMME-enriched, but not in control, microsomes. These data suggest that secretion of apoB-containing lipoproteins can be regulated by membrane lipid composition at the level of translocational pausing.

TRAM regulates the exposure of nascent secretory proteins to the cytosol during translocation into the endoplasmic reticulum.

Translocational pausing is a mechanism used by certain specialized secretory proteins whereby discrete domains of a nascent chain destined for the endoplasmic reticulum lumen are transiently exposed to the cytosol. Proteoliposomes reconstituted from total endoplasmic reticulum proteins properly assemble translocationally paused intermediates. The capacity of the translocon to correctly pause the nascent chain is dependent on a glycoprotein fraction whose active component is TRAM. In the absence of TRAM, the normally sealed ribosome-membrane junction still opens in response to a pause transfer sequence. However, nascent chain domains that are not exposed to the cytosol in the presence of TRAM are so exposed in its absence. Thus, TRAM regulates which domains of the nascent chain are visible to the cytosol during a translocational pause.

A transmembrane form of the prion protein in neurodegenerative disease.

At the endoplasmic reticulum membrane, the prion protein (PrP) can be synthesized in several topological forms. The role of these different forms was explored with transgenic mice expressing PrP mutations that alter the relative ratios of the topological forms. Expression of a particular transmembrane form (termed CtmPrP) produced neurodegenerative changes in mice similar to those of some genetic prion diseases. Brains from these mice contained CtmPrP but not PrPSc, the PrP isoform responsible for transmission of prion diseases. Furthermore, in one heritable prion disease of humans, brain tissue contained CtmPrP but not PrPSc. Thus, aberrant regulation of protein biogenesis and topology at the endoplasmic reticulum can result in neurodegeneration.

Asymmetric distribution of pause transfer sequences in apolipoprotein B-100.

Lipoprotein assembly requires a complex and regulated set of events that includes apolipoprotein B (apoB) translocation across the endoplasmic reticulum (ER) membrane, folding, and association with lipids. Unlike simple secretory proteins which are cotranslationally translocated directly into the ER lumen, nascent apoB contains pause transfer (PT) sequences that direct the transient stopping and subsequent restarting of its translocation, a phenomenon termed translocational pausing. During one particular translocational pause in apoB, the ribosome-membrane junction and ER translocation channel have been shown to be altered in such a way as to expose the nascent polypeptide to the cytosol and direct a change in the proteins neighboring the nascent chain. In this study, we have experimentally identified the location and distribution of the translocational pauses that are present throughout apoB-100. We find that pause transfer sequences are distributed asymmetrically, clustering in three distinct domains: a) nine functional PT sequences appear in the amino terminal 20% of apoB, b) four more PT sequences occur just before the end of apoB-48, and c) an additional ten PT sequences are found between apoB-65-95. These clusters are interrupted by two lipid binding regions of approximately 100 kD each in which no PT sequences occur. The implications of this asymmetric distribution of PT sequences, and their correlation with previously hypothesized structural and functional domains of apoB, are discussed.

Sequence-specific alteration of the ribosome-membrane junction exposes nascent secretory proteins to the cytosol.

Tight docking of the ribosome at the translocation channel ensures that nascent secretory proteins are shielded from the cytoplasm during transfer into the endoplasmic reticulum. Discrete pause transfer sequences mediate the transient stopping of translocation in certain proteins. Here we show that during a translocational pause, the junction between the ribosome and translocation channel is opened, exposing the nascent chain to the cytosol. While transient, this opening is sufficient to demonstrate macromolecular interactions between the translocating chain and molecules added to the cytosol, such as antibodies and site-specific proteases. Moreover, this opening is accompanied by alterations in the proteins that neighbor the nascent chain. These results demonstrate that specific sequences within a translocating nascent chain can elicit dramatic and reversible structural changes in the translocation machinery. Thus, the translocon is dynamic and can be regulated.

California's Proposition 186: lessons from a single-payer health care reform ballot initiative campaign.

Proposition 186 was an initiative on the November 1994 California ballot which proposed to establish a state single-payer health care program. Although Prop 186 was overwhelmingly defeated in the November 1994 election (73% No, 27% Yes), it accomplished many things. Model legislation was developed showing the feasibility of a specific single-payer program for California. It was placed on the ballot by an unprecedented volunteer signature-gathering effort and was the largest grassroots political campaign fund-raising effort in California history. A novel strategy for the discussion of complex issues through 1500 house parties was launched. Prop 186 was defeated by an insurance industry-led coalition with an anti-government message. Lessons for future efforts include increasing the size and duration of the grassroots organizing and educational effort, and decreasing reliance on conventional political campaign tactics and the mainstream media.

Complex environment of nascent polypeptide chains.

Nascent polypeptides enter into high molecular weight complexes with other proteins during chain elongation in vitro and in vivo. The nature of these complexes was investigated using an in vitro translation system programmed with a single mRNA lacking a translational termination codon. Complexes containing nascent polypeptides (molecular mass < 20 kDa), the molecular chaperone hsp 73 and other unidentified proteins can be released from the translationally arrested polysomes by puromycin treatment. The apparent native molecular mass of the nascent chain binding complex was determined to be > 700 kDa by gel-filtration analysis. Complexes between the nascent polypeptide and at least hsp 73 appear to be sensitive to (disrupted by) ATP. The presence of ATP also dramatically alters the sensitivity of the nascent polypeptide chains to digestion by exogenous protease. Collectively, our data indicate that there may be a cytoplasmic machinery, including hsp 70, which comprises a nascent polypeptide chain binding complex.

Determinants of carboxyl-terminal domain translocation during prion protein biogenesis.

The prion protein (PrP) displays some unusual features in its biogenesis. In cell-free systems it can be synthesized as either an integral transmembrane protein spanning the membrane twice, with both amino and carboxyl domains in the lumen of the endoplasmic reticulum, or as a fully translocated polypeptide. A charged, extracytoplasmic region, termed the Stop Transfer Effector (STE) sequence, has been shown to direct the nascent translocating chain to stop at the adjoining hydrophobic domain to generate the first membrane-spanning region (TM1). However, the determinants of the second translocation event in the biogenesis of the transmembrane form have not been identified previously. Moreover, the relationship of transmembrane and fully translocated forms of PrP has not been well understood. Here, we report progress in resolving both of these issues. Using protein chimeras in cell-free translation systems and Xenopus oocytes, we identify the sequence which directs nascent PrP to span the membrane a second time, with its carboxyl-terminal domain in the endoplasmic reticulum lumen. Surprisingly, PrP carboxyl-terminal domain translocation does not appear to be directed by an internal signal or signal-anchor sequence located downstream of TM1, as would have been expected from studies of other multispanning membrane proteins. Rather, carboxyl-terminal domain translocation appears to be another consequence of the action of STE-TM1, that is, the same sequence responsible for generating the first membrane-spanning region. Studies of an STE-TM1-containing protein chimera in Xenopus oocytes demonstrate that most of these chains upon completion of their translation, initially span the membrane twice, with a topology similar to that of transmembrane PrP, but are carbonate-extractable. These chains have the transmembrane orientation only transiently and chase into a fully translocated form. These results support a model in which a metastable "transmembrane" intermediate, residing within the aqueous environment of the translocation channel, can be converted into either the integrated transmembrane or the fully translocated form of PrP, perhaps directed by trans-acting factor (s). Such a model may explain why stable the transmembrane isoform of PrP has not been observed in normal cells and how nascent PrP might be directed to alternate pathways of folding.

Transmembrane orientation and topogenesis of the third and fourth membrane-spanning regions of human P-glycoprotein (MDR1).

Understanding how the multidrug resistance phenotype is manifest in human cancer cells will require insight into the mechanism of assembly, transmembrane topology, and intracellular trafficking of human P-glycoprotein (MDR1). Previously, we showed that MDR1 amino terminus biogenesis occurred through an unexpected interaction between novel topogenic sequence subtypes and that transmembrane topology of corresponding amino and carboxy halves was not equivalent. We now investigate topology and topogenic activities of the third and fourth transmembrane regions (TM3 and TM4) of human MDR1 using protease protection of defined reporter epitopes expressed in Xenopus laevis oocytes. As was previously observed for TM1 and TM2, determinants in TM3 and TM4 exhibited cooperativity in directing proper assembly and transmembrane orientation. The signal sequence encompassing TM3 required residues from TM4 to reinitiate translocation of the MDR1 chain into the endoplasmic reticulum (ER) lumen. Remaining residues from TM4 terminated translocation and established a polytopic transmembrane topology in which TM3 and TM4 both spanned the membrane in the orientation predicted by hydropathy-based models. Remarkably, when translocating sequentially into the ER lumen, neither TM4 alone nor TM4 together with TM3 efficiently terminated translocation. Thus, MDR1 biogenesis required both the presence of these sequences and their proper orientation with respect to the ER translocation apparatus. This conclusion was supported by experiments in which TM3 and TM4 topology was reproduced in a defined chimeric protein which mimicked native MDR1 presentation. These additional variations on simple themes of protein topogenesis utilized by MDR1 demonstrate that events of complex protein biogenesis may be dissected and studied using protein chimeras with defined translocation properties.

Biogenesis and transmembrane topology of the CHIP28 water channel at the endoplasmic reticulum.

CHIP28 is a 28-kD hydrophobic integral membrane protein that functions as a water channel in erythrocytes and renal tubule epithelial cell membranes. We examined the transmembrane topology of CHIP28 in the ER by engineering a reporter of translocation (derived from bovine prolactin) into nine sequential sites in the CHIP28 coding region. The resulting chimeras were expressed in Xenopus oocytes, and the topology of the reporter with respect to the ER membrane was determined by protease sensitivity. We found that although hydropathy analysis predicted up to seven potential transmembrane regions, CHIP28 spanned the membrane only four times. Two putative transmembrane helices, residues 52-68 and 143-157, reside on the lumenal and cytosolic surfaces of the ER membrane, respectively. Topology derived from these chimeric proteins was supported by cell-free translation of five truncated CHIP28 cDNAs, by N-linked glycosylation at an engineered consensus site in native CHIP28 (residue His69), and by epitope tagging of the CHIP28 amino terminus. Defined protein chimeras were used to identify internal sequences that direct events of CHIP28 topogenesis. A signal sequence located within the first 52 residues initiated nascent chain translocation into the ER lumen. A stop transfer sequence located in the hydrophobic region from residues 90-120 terminated ongoing translocation. A second internal signal sequence, residues 155-186, reinitiated translocation of a COOH-terminal domain (residues 186-210) into the ER lumen. Integration of the nascent chain into the ER membrane occurred after synthesis of 107 residues and required the presence of two membrane-spanning regions. From this data, we propose a structural model for CHIP28 at the ER membrane in which four membrane-spanning alpha-helices form a central aqueous channel through the lipid bilayer and create a pathway for water transport.

A eukaryotic cytosolic chaperonin is associated with a high molecular weight intermediate in the assembly of hepatitis B virus capsid, a multimeric particle.

We have established a system for assembly of hepatitis B virus capsid, a homomultimer of the viral core polypeptide, using cell-free transcription-linked translation. The mature particles that are produced are indistinguishable from authentic viral capsids by four criteria: velocity sedimentation, buoyant density, protease resistance, and electron microscopic appearance. Production of unassembled core polypeptides can be uncoupled from production of capsid particles by decreasing core mRNA concentration. Addition of excess unlabeled core polypeptides allows the chase of the unassembled polypeptides into mature capsids. Using this cell-free system, we demonstrate that assembly of capsids proceeds by way of a novel high molecular weight intermediate. Upon isolation, the high molecular weight intermediate is productive of mature capsids when energy substrates are manipulated. A 60-kD protein related to the chaperonin t-complex polypeptide 1 (TCP-1) is found in association with core polypeptides in two different assembly intermediates, but is not associated with either the initial unassembled polypeptides or with the final mature capsid product. These findings implicate TCP-1 or a related chaperonin in viral assembly and raise the possibility that eukaryotic cytosolic chaperonins may play a distinctive role in multimer assembly apart from their involvement in assisting monomer folding.

Translocational pausing is a common step in the biogenesis of unconventional integral membrane and secretory proteins.

Signal, stop transfer, and signal-anchor sequences direct a nascent polypeptide to a single topology with respect to the membrane of the endoplasmic reticulum. However, other types of sequences direct nascent proteins, either transiently or permanently, to more than one topologic form. Pause transfer sequences direct nascent apolipoprotein B to pause during its translocation, resulting in nonintegrated, transmembrane intermediates that become fully translocated over time. The stop transfer effector sequence (STE) directs the nascent prion protein either to integrate at the hydrophobic domain which immediately follows (TM1) or to become fully translocated, in a manner dependent on cytosolic factors. Although the action of pause transfer sequences has been dissected into stop and restart steps, the mechanism of STE action is unknown. Using chimeric proteins expressed in vitro, we show that STE, independent of TM1, acts as a pause transfer sequence. We also demonstrate that translocational pausing at STE is a common step preceding either complete translocation or integration into the membrane of a chimeric protein containing STE and TM1. These findings have implications for the role of pausing in the biogenesis of both secretory and membrane proteins.

Amino-terminal assembly of human P-glycoprotein at the endoplasmic reticulum is directed by cooperative actions of two internal sequences.

Transmembrane topology of polytopic integral membrane proteins is established during protein synthesis at the endoplasmic reticulum membrane. For some polytopic proteins, sequential and independent signal, stop transfer, and/or signal anchor sequences contained in the nascent chain direct this process. Here we define the topology of human P-glycoprotein (MDR1) through the first two transmembrane regions (TM1 and TM2, respectively) of the amino-terminal half of the protein. We show that unlike TM7 and TM8, which comprise homologous regions in the carboxyl half of the protein (Skach, W., Calayag, M. C., and Lingappa, V. (1993) J. Biol. Chem. 268, 6903-6908), TM1 and TM2 achieve the orientation predicted by conventional structural models. However, TM1 and TM2 appear to utilize a mechanism of biogenesis different in a key respect from that observed in multispanning proteins studied previously. TM1 and TM2, with their flanking regions, independently direct the topology observed for each of these sequences in the native protein. Each can interact with signal recognition particle to direct targetting to the endoplasmic reticulum, nascent chain translocation, and correct transmembrane orientation. Unlike the transmembrane regions of previously studied multispanning membrane proteins, neither TM1 nor TM2 alone is sufficient to integrate the chain into the membrane. However, when TM1 and TM2 are both present, as occurs in native MDR1, integration is achieved. These results suggest that cooperative interactions between TM1 and TM2 are necessary for chain integration and thus add a new complexity to the current view of polytopic integral membrane protein biogenesis.

Analysis of a pause transfer sequence from apolipoprotein B.

In contrast to typical secretory proteins, apolipoprotein B pauses at distinct points along the nascent chain during its translocation into the lumen of the endoplasmic reticulum. Specific pause transfer sequences mediate such discrete pauses in the translocation of apolipoprotein B. These sequences have been shown to confer this translocational behavior to heterologous chimeric proteins. To investigate the function of pause transfer sequences, we: (i) examine whether the multiple pause transfer sequences of apolipoprotein B act independently or are dependent upon the action of upstream pause transfer sequences, (ii) identify residues of the prototypical B' pause transfer sequence that are involved in pausing, and (iii) determine whether the stopping step of a translocational pause is a consequence of translational pausing, as has been suggested by other investigators. We conclude that pause transfer sequences act independently of each other and of translation; translocational pausing occurs even in the absence of ongoing protein synthesis. Furthermore, like other topogenic sequences such as signal sequences, pause transfer sequences are degenerate in structure yet have distinctive features necessary for their action. This characterization of the B' pause transfer sequence may aid in the identification of such sequences elsewhere in apolipoprotein B and in other proteins and has implications for the mechanism of translocational pausing.