Biogenesis of membrane-bound and secreted immunoglobulins. I. Two distinct translation products of human mu-chain, with identical N-termini and different C-termini.

Structural differences between the heavy chain of membrane-bound IgM (mu m) and the heavy chain of secreted IgM (mu s) were investigated. The primary translation products of the mu-chain, free of posttranslational modifications, were synthesized in a wheat-germ cell-free system, programmed with messenger RNA derived from human lymphoblastoid cell lines positive for both membrane-bound and secreted IgM. Encoded in this sytem were two mu-chains, which shared N-terminal signal peptides and which differed both in molecular weight and in C-terminal amino acid sequence. In vivo pulse labeling of cells confirmed that, as intermediates in the rough endoplasmic reticulum, these two forms expressed the same idiotype and maintained their difference in molecular weight and in C-terminal sequence. By correlation with pulse-chase kinetics and with immunofluorescence, one form of mu-chain represents mu m, and the other, mu s. Because the molecular weight difference between the two is manifest at the level of their primary translation products, these studies demonstrate that mu m is distinguished from mu s by a difference in primary structure, at least in part at the C-terminus.

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.

A former amino terminal signal sequence engineered to an internal location directs translocation of both flanking protein domains.

To determine whether a functional amino terminal signal sequence can be active at an internal position, a hybrid gene was constructed in which the entire coding region of bovine preprolactin cDNA was inserted into chimpanzee alpha-globin cDNA 109 codons downstream from the initiation codon of globin. When RNA synthesized in vitro from this plasmid (pSPGP1) was translated in the rabbit reticulocyte cell-free system, a 32-kD protein was produced that was both prolactin and globin immunoreactive. When microsomal membranes were present during translation (but not when added posttranslationally), a 26-kD and a 14-kD product were also observed. By immunoreactivity and electrophoretic mobility, the 26-kD protein was identical to mature prolactin, and the 14-kD protein appeared to be the globin domain with the prolactin signal sequence attached at its carboxy terminus. From (a) posttranslational proteolysis in the presence and absence of detergent, (b) sedimentation of vesicles in the presence and absence of sodium carbonate pH 11.5, and (c) N-linked glycosylation of the globin-immunoreactive fragment after insertion of an Asn-X-Ser N-linked glycosylation site into the globin coding region of pSPGP1, it appears that all of the 26-kD and some of the 14-kD products, but none of the 32-kD precursor, have been translocated to the lumen of the membrane vesicles. Thus, when engineered to an internal position, the prolactin signal sequence is able to translocate both flanking protein domains. These data have implications for the understanding of translocation of proteins across the membrane of the endoplasmic reticulum.

Secreted hepatitis B surface antigen polypeptides are derived from a transmembrane precursor.

Hepatitis B surface antigen (HBsAg), the major coat protein of hepatitis B virus, is also independently secreted from infected cells as a lipoprotein particle. Secretion proceeds without signal sequence removal or cleavage of other segments of the polypeptide. We have examined the synthesis and transport of HBsAg in cultured cells expressing the cloned surface antigen gene. Our results show that HBsAg is initially synthesized as a integral membrane protein. This transmembrane form is slowly converted to a secreted lipoprotein complex in the lumen of the endoplasmic reticulum via a series of definable intermediates, after which it is secreted from the cell. This unusual export process shares many features with the assembly and budding reactions of conventional enveloped animal viruses. However, it differs importantly in its absence of a requirement for the participation of nucleocapsid or other viral proteins.

Translocation of globin fusion proteins across the endoplasmic reticulum membrane in Xenopus laevis oocytes.

We have studied the translocation of a normally cytoplasmic protein domain across the membrane of the endoplasmic reticulum in cell-free systems and in Xenopus laevis oocytes. Coding regions for the normally cytoplasmic protein globin were engineered in frame either 3' or 5' to the coding region for the signal sequence of either Escherichia coli b-lactamase or bovine preprolactin, respectively, in SP6 expression plasmids. RNA transcribed from these plasmids was microinjected into oocytes as well as translated in cell-free systems. We demonstrate that both in vivo and in vitro, a previously amino-terminal signal sequence can direct translocation of domains engineered to either side. Moreover, the domain preceding the signal sequence can be as large as that which follows it. While, in general, cell-free systems were found to faithfully reflect translocation events in vivo, our results suggest that a mechanism for clearance of signal peptides after cleavage is present in intact cells that is not reconstituted in cell-free systems.

Evidence for a two-step mechanism involved in assembly of functional signal recognition particle receptor.

The signal recognition particle (SRP) and SRP receptor act sequentially to target nascent secretory proteins to the membrane of the ER. The SRP receptor consists of two subunits, SR alpha and SR beta, both tightly associated with the ER membrane. To examine the biogenesis of the SRP receptor we have developed a cell-free assay system that reconstitutes SR alpha membrane assembly and permits both anchoring and functional properties to be assayed independently. Our experiments reveal a mechanism involving at least two distinct steps, targeting to the ER and anchoring of the targeted molecule on the cytoplasmic face of the membrane. Both steps can be reconstituted in vitro to restore translocation activity to ER microsomes inactivated by alkylation with N-ethyl-maleimide. The characteristics elucidated for this pathway distinguish it from SRP-dependent targeting of secretory proteins, SRP-independent ER translocation of proteins such as prepromellitin, and direct insertion mechanisms of the type exemplified by cytochrome b5.

Nascent chicken ovalbumin contains the functional equivalent of a signal sequence.

Highly purified mRNA for chicken ovalbumin has been translated in a cell-free protein synthesizing system from rabbit reticulocytes in the presence or absence of EDTA-stripped microsomal membranes from dog pancreas. Nascent--but not completed--ovalbumin was transferred across the microsomal membrane, as demonstrated by cotranslational core glycosylation of ovalbumin nascent chains, by resistance to posttranslational proteolysis of only the glycosylated ovalbumin chains, and by cosedimentation with the membrane of exclusively the glycosylated form. Furthermore, nascent chains of bovine prolactin were observed to compete with nascent ovalbumin for transfer across the microsomal membrane. However, no competition for membrane sites was observed between nascent chains of rabbit globin and either nascent ovalbumin or prolactin. We interpret these results to suggest that nascent ovalbumin contains the functional equivalent of a signal sequence for transfer across membranes, and that membrane components involved in the segregation of secretory proteins with cleaved signal sequences also function in the segregation of ovalbumin.

Expression of human cathepsin D in Xenopus oocytes: phosphorylation and intracellular targeting.

We have obtained expression of a cDNA clone for human cathepsin D in Xenopus laevis oocytes. Biosynthetic studies with [35S]methionine labeling demonstrated that most of the cathepsin D remained intracellular and underwent proteolytic cleavage, converting a precursor of Mr 47,000 D to a mature form of Mr 39,000 D with processing intermediates of Mr 43,000-41,000 D. greater than 90% of the cathepsin D synthesized by oocytes bound to a mannose 6-phosphate (Man-6-P) receptor affinity column, indicating the presence of phosphomannosyl residues. An analysis of [2-3H]mannose-labeled oligosaccharides directly demonstrated phosphomannosyl residues on cathepsin D. Sucrose-gradient fractionation, performed to define the membranous compartments that cathepsin D traversed during its biosynthesis, demonstrated that cathepsin D is targeted to a subpopulation of yolk platelets, the oocyte equivalent of a lysosome. Xenopus oocytes were able to endocytose lysosomal enzymes from the medium and this uptake was inhibited by Man-6-P, thus demonstrating the presence of Man-6-P receptors in these cells. Therefore, the entire Man-6-P dependent pathway for targeting of lysosomal enzymes is present in the oocytes. Xenopus oocytes should be a useful system for examining signals responsible for the specific targeting of lysosomal enzymes to lysosomes.

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.

Uncoupling translocation from translation: implications for transport of proteins across membranes.

The segregation of secretory proteins into the cisternae of the endoplasmic reticulum (ER) is normally tightly coupled to their synthesis. This feature distinguishes their biogenesis from that of proteins targeted to many other organelles. In the examples presented, translocation across the ER membrane is dissociated from translation. Transport, which is normally cotranslational, may proceed in the absence of chain elongation. Moreover, translocation across the ER membrane does not proceed spontaneously since, even in the absence of protein synthesis, energy substrates are required for translocation. These conclusions have been extended to the cotranslational integration of newly synthesized transmembrane proteins.

Unusual topogenic sequence directs prion protein biogenesis.

Biosynthetic studies of the prion protein (PrP) have shown that two forms of different topology can be generated from the same pool of nascent chains in cell-free translation systems supplemented with microsomal membranes. A transmembrane form is the predominant product generated in wheat germ (WG) extracts, whereas a completely translocated (secretory) form is the major product synthesized in rabbit reticulocyte lysates (RRL). An unusual topogenic sequence within PrP is now shown to direct this system-dependent difference. The actions of this topogenic sequence were independent of on-going translation and could be conferred to heterologous proteins by the engineering of a discrete set of codons. System-dependent topology conferred by addition of RRL to WG translation products suggests that this sequence interacts with one or more cytosolic factors.

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.

Hepatitis B surface antigen: an unusual secreted protein initially synthesized as a transmembrane polypeptide.

Hepatitis B surface antigen (HBsAg), the major coat protein of hepatitis B virus, is also secreted from cells as a subviral particle, without concomitant cleavage of N-terminal amino acid sequences. We examined this unusual export process in a cell-free system and showed that the initial product of HBsAg biosynthesis is an integral transmembrane protein, with most or all of its C-terminal half on the lumenal side of the endoplasmic reticulum membrane. To study the nature of its topogenic signals, we synthesized fusion proteins between HBsAg and the nonsecreted protein alpha-globin. Fusion proteins in which approximately 100 amino acids of globin preceded all HBsAg sequences were successfully translocated in vitro; the same domain as in the wild-type HBsAg was transported into the vesicle lumen. Fusions in which the entire globin domain was C terminal were able to translocate both the C-terminal region of HBsAg and its attached globin domain. Thus, uncleaved signal sequences in p24s function to direct portions of the molecule across the membrane and are able to perform this function even when positioned in an internal protein domain.

Biogenesis and transmembrane orientation of the cellular isoform of the scrapie prion protein [published errratum appears in Mol Cell Biol 1987 May;7(5):2035].

Considerable evidence suggests that the scrapie prion protein (PrP) is a component of the infectious particle. We studied the biogenesis and transmembrane orientation of an integral-membrane form of PrP in a cell-free transcription-linked translation-coupled translocation system programmed with a full-length PrP cDNA cloned behind the SP6 promoter. Translation of SP6 transcripts of the cDNA or of native mRNA from either normal or infected hamster brain in the absence of dog pancreas membranes resulted in the synthesis of a single PrP immunoreactive polypeptide (each polypeptide was the same size; Mr, 28,000), as predicted from the known sequence of the coding region. In the cotranslational presence of membranes, two additional forms were observed. Using peptide antisera specific to sequences from the amino- or the carboxy-terminal domain of PrP together with proteinase K or endoglycosidase H digestion or both, we showed that one of these forms included an integrated and glycosylated form of PrP (Mr = 33,000) which spans the bilayer twice, with domains of both the amino and carboxy termini in the extracytoplasmic space. By these criteria, the other form appeared to be an unglycosylated intermediate of similar transmembrane orientation. The PrP cell-free translation products did not display resistance to proteinase K digestion in the presence of nondenaturing detergents. These results suggest that the PrP cell-free translation products most closely resemble the normal cellular isoform of the protein, since its homolog from infected brain was proteinase K resistant. The implications of these findings for PrP structure and function are discussed.

Multiple topogenic sequences determine the transmembrane orientation of the hepatitis B surface antigen.

To investigate the mechanism by which complex membrane proteins achieve their correct transmembrane orientation, we examined in detail the hepatitis B surface antigen for sequences which determine its membrane topology. The results demonstrated the presence of at least two kinds of topogenic elements: an N-terminal uncleaved signal sequence and an internal element containing both signal and stop-transfer function. Fusion of reporter groups to either end of the protein suggested that both termini are translocated across the membrane bilayer. We propose that this topology is generated by the conjoint action of both elements and involves a specifically oriented membrane insertion event mediated by the internal sequence. The functional properties of each element can be instructively compared with those of simpler membrane proteins and may provide insight into the generation of other complex protein topologies.

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.

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.

Signal sequences for early events in protein secretion and membrane assembly.

Signal sequences for the transfer of proteins across membranes are usually found at the NH2-terminus of nascent secretory and transmembrane proteins. The functionally equivalent signal sequence of chicken ovalbumin however, is localized in the middle of the molecule. The implication of this surprising finding for biogenesis of membrane proteins is discussed.

Synthesis and secretion of rat pancreatic proteins by Xenopus laevis oocytes.

An in vivo translation system, the Xenopus laevis oocyte, was employed to study the synthesis and secretion of pancreatic proteins. RNA was purified from normal and diabetic rat pancreas and normal rat liver by use of guanidine isothiocyanate lysis and cesium chloride gradient centrifugation. The presence of functional mRNA was documented by translation in a reticulocyte lysate that yielded precursors of all major secretory proteins, i.e., slightly higher Mr than proteins synthesized in situ by pancreatic acini. Mature X. laevis oocytes were then microinjected with either total RNA or purified mRNA. When oocytes were subsequently incubated with 35S-methionine, pancreatic secretory proteins or hepatic albumin could be immunoprecipitated from oocyte lysate with specific polyclonal antibodies against amylase, trypsin, ribonuclease, and albumin. Amylase was shown to be enzymatically active. Moreover, oocytes released pancreatic secretory proteins into the medium when injected with pancreatic RNA in a time-dependent manner. Only the mature form of amylase was secreted and secretion was not regulated by secretagogues. When a comparison was made after injection of RNA from diabetic pancreas known to contain altered amounts of individual mRNAs, there was a decrease in amylase and an increase in trypsinogen synthesis in oocytes that was comparable to the results of cell free translation. The oocyte expression system, therefore, should be useful not only for studies of protein synthesis but also for processing and secretion.