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.     

SEC11 is required for signal peptide processing and yeast cell growth

Among the collection of temperature-sensitive secretion mutants of Saccharomyces cerevisiae, sec11 mutant cells are uniquely defective in signal peptide processing of at least two different secretory proteins. At 37 degrees C, the restrictive growth temperature, sec11 cells accumulate core-glycosylated forms of invertase and acid phosphatase, each retaining an intact signal peptide. In contrast, other sec mutant strains in which transport of core-glycosylated molecules from the endoplasmic reticulum is blocked show no defect in signal peptide cleavage. A DNA fragment that complements the sec11-7 mutation has been cloned. Genetic analysis indicates that the complementing clone contains the authentic SEC11 gene, and that a null mutation at the SEC11 locus is lethal. The DNA sequence of SEC11 predicts a basic protein (estimated pI of 9.5) of 167 amino acids including an NH2-terminal hydrophobic region that may function as a signal and/or membrane anchor domain. One potential N-glycosylation site is found in the 18.8-kD (Sec 11p) predicted protein. The mass of the SEC11 protein is very close to that found for two of the subunits of the canine and hen oviduct signal peptidases. Furthermore, the chromatographic behavior of the hen oviduct enzyme indicates an overall basic charge comparable to the predicted pI of the Sec11p.     

Molecular characterization of a vacuolar processing enzyme related to a putative cysteine proteinase of Schistosoma mansoni.

Proproteins of various vacuolar proteins are post-translationally processed into mature forms by the action of a unique vacuolar processing enzyme. If such a processing enzyme is transported to vacuoles together with proprotein substrates, the enzyme must be a latent form. Immunocytochemical localization of a vacuolar processing enzyme, a 37-kD cysteine proteinase, in the endosperm of maturing castor bean seeds places the enzyme in the vacuolar matrix, where a variety of proproteins is also present. To characterize a molecular structure of vacuolar processing enzyme, we isolated a cDNA for the enzyme. Deduced primary structure of a 55-kD precursor is 33% identical to a putative cysteine proteinase of the human parasite Schistosoma mansoni. The precursor is composed of a signal peptide, a 37-kD active processing enzyme domain, and a propeptide fragment. Although the precursor expressed in Escherichia coli has no vacuolar processing activity, a 36-kD immunopositive protein expressed in E. coli is active. These results suggest that the activation of the vacuolar processing enzyme requires proteolytic cleavage of a 14-kD C-terminal propeptide fragment of the precursor.     

Two pathways for the degradation of the H2 subunit of the asialoglycoprotein receptor in the endoplasmic reticulum

An intermediate of 35 kD accumulates transiently during ER degradation of the H2 subunit of the asialoglycoprotein receptor; it is derived by an endoproteolytic cleavage in the exoplasmic domain near the transmembrane region. In the presence of cycloheximide all of the precursor H2 is converted to this intermediate, which is degraded only after cycloheximide is removed (Wikstrom, L., and H. F. Lodish. 1991. J. Cell Biol. 113:997-1007). Here we have generated mutants of H2 that do not form the 35-kD fragment, either in transfected cells or during in vitro translation reactions in the presence of pancreatic microsomes. In transfected cells the kinetics of ER degradation of these mutant proteins are indistinguishable from that of wild-type H2, indicating the existence of a second pathway of ER degradation which does not involve formation of the 35-kD fragment. Degradation of H2 in the ER by this alternative pathway is inhibited by TLCK or TPCK, but neither formation nor degradation of the 35-kD fragment is blocked by these reagents. As determined by NH2-terminal sequencing of the 35-kD fragment, formed either in transfected cells or during in vitro translation reactions in the presence of pancreatic microsomes, the putative cleavage sites are between small polar, uncharged amino acid residues. Substitution of the residues NH2- or COOH-terminal to the cleavage site by large hydrophobic or charged ones decreased the amount of 35-kD fragment formed and in some cases changed the putative cleavage site. Cleavage can also be affected by amino acid substitutions (e.g., to proline or glycine) which change protein conformation. Therefore, the endoprotease that generates the 35-kD fragment has specificity similar to that of signal peptidase. H2a and H2b are isoforms that differ only by a pentapeptide insertion in the exoplasmic juxtamembrane region of H2a. 100% of H2a is degraded in the ER, but up to 30% of H2b folds properly and matures to the cell surface. The sites of cleavage to form the 35-kD fragment are slightly different in H2a and H2b. Two mutant H2b proteins, with either a glycine or proline substitution at the position of insertion of the pentapeptide in H2a, have metabolic fates similar to that of H2a. These mutations are likely to change the protein conformation in this region. Thus the conformation of the juxtamembrane domain of the H2 protein is important in determining its metabolic fate within the ER.     

A serine-kinase-containing protein complex interacts with the terminal protein domain of polymerase of hepatitis B virus

Polymerase of human hepatitis B virus is required for viral replication and pregenomic RNA encapsidation. Using recombinant GST fusion proteins, we show that the terminal protein domain of polymerase can interact specifically with a protein complex containing kinase activity and a tightly associated 35-kD protein (p35). This kinase is termed terminal-protein-associated kinase (TPAK). The phosphoamino acid analysis of phosphorylated p35 demonstrates that TPAK is a serine kinase. Analysis of deletion mutants shows that amino acids 1–95 of the terminal protein domain are required for the interaction with TPAK/p35 and phosphorylation of p35. TPAK/p35 are found predominantly in the cytoplasm. Furthermore, TPAK can be inhibited by heparin and manganese ions, but is resistant to spermidine, DRB, H89 or H7. These results indicate that TPAK is not protein kinase A or protein kinase C.     

The 54-kD protein of signal recognition particle contains a methionine- rich RNA binding domain

Signal recognition particle (SRP) plays the key role in targeting secretory proteins to the membrane of the endoplasmic reticulum (Walter, P., and V. R. Lingappa. 1986. Annu. Rev. Cell Biol. 2:499- 516). It consists of SRP7S RNA and six proteins. The 54-kD protein of SRP (SRP54) recognizes the signal sequence of nascent polypeptides. The 19-kD protein of SRP (SRP19) binds to SRP7S RNA directly and is required for the binding of SRP54 to the particle. We used deletion mutants of SRP19 and SRP54 and an in vitro assembly assay in the presence of SRP7S RNA to define the regions in both proteins which are required to form a ribonucleoprotein particle. Deletion of the 21 COOH- terminal amino acids of SRP19 does not interfere with its binding to SRP7S RNA. Further deletions abolish SRP19 binding to SRP7S RNA. The COOH-terminal 207 amino acids of SRP54 (M domain) were found to be necessary and sufficient for binding to the SRP19/7S RNA complex in vitro. Limited protease digestion of purified SRP confirmed our results for SRP54 from the in vitro binding assay. The SRP54M domain could also bind to Escherichia coli 4.5S RNA that is homologous to part of SRP7S RNA. We suggest that the methionine-rich COOH terminus of SRP54 is a RNA binding domain and that SRP19 serves to establish a binding site for SRP54 on the SRP7S RNA.     

The Yeast Rad50 Gene Encodes a Predicted 153-Kd Protein Containing a Purine Nucleotide-Binding Domain and Two Large Heptad-Repeat Regions

The RAD50 gene of Saccharomyces cerevisiae is required for chromosome synapsis and recombination during meiosis and for repair of DNA damage during vegetative growth. The precise role of the RAD50 gene product in these processes is not known. Most rad50 mutant phenotypes can be explained by the proposal that the RAD50 gene product is involved in the search for homology between interacting DNA molecules or chromosomes, but there is no direct evidence for this model. We present here the nucleotide sequence of the RAD50 locus and an analysis of the predicted 153-kD RAD50 protein. The amino terminal region of the predicted protein contains residues suggestive of a purine nucleotide binding domain, most likely for adenine. The remaining 1170 amino acids consist of two 250 amino acid segments of heptad repeat sequence separated by 320 amino acids, plus a short hydrophobic carboxy-terminal tail. Heptad repeats occur in proteins such as myosin and intermediate filaments that form alpha-helical coiled coils. One of the two heptad regions in RAD50 shows similarity to the S-2 domain of rabbit myosin beyond that expected for two random coiled coil proteins.     

Identification and characterization of a prevacuolar compartment in stigmas of nicotiana alata

The stigmas of the ornamental tobacco plant Nicotiana alata accumulate large quantities of a series of 6-kD proteinase inhibitors (PIs) in the central vacuole that are derived from a 40-kD precursor protein, Na-PI. The sorting information that directs Na-PI to the vacuole is likely to reside in a C-terminal propeptide domain of 25 amino acids that forms an amphipathic alpha helix. Using cell fractionation techniques, we have examined transit of Na-PI through the endomembrane system and have identified a prevacuolar compartment that contains Na-PI with an intact targeting signal. In contrast, the targeting signal is not present on the predominant form of Na-PI in the vacuole. The prevacuolar compartment is marked by the presence of homologs of both the t-SNARE, PEP12p, and the putative vacuolar sorting receptor BP-80. Cross-linking and affinity precipitation studies revealed that Na-PI associates with BP-80 within this compartment, providing in vivo evidence for the function of BP-80 as a sorting receptor for a protein with a C-terminal vacuolar targeting signal.     

Reduced proteolysis of secreted gelatin and Yps1-mediated alpha-factor leader processing in a Pichia pastoris kex2 disruptant

Heterologous proteins secreted by yeast and fungal expression hosts are occasionally degraded at basic amino acids. We cloned Pichia pastoris homologs of the Saccharomyces cerevisiae basic residue-specific endoproteases Kex2 and Yps1 to evaluate their involvement in the degradation of a secreted mammalian gelatin. Disruption of the P. pastoris KEX2 gene prevented proteolysis of the foreign protein at specific monoarginylic sites. The S. cerevisiae alpha-factor preproleader used to direct high-level gelatin secretion was correctly processed at its dibasic site in the absence of the prototypical proprotein convertase Kex2. Disruption of the YPS1 gene had no effect on gelatin degradation or processing of the alpha-factor propeptide. When both the KEX2 and YPS1 genes were disrupted, correct precursor maturation no longer occurred. The different substrate specificities of both proteases and their mutual redundancy for propeptide processing indicate that P. pastoris kex2 and yps1 single-gene disruptants can be used for the alpha-factor leader-directed secretion of heterologous proteins otherwise degraded at basic residues.     

Primary structure and expression of a 24-kD vacuolar protein (VP24) precursor in anthocyanin-producing cells of sweet potato in suspension culture

A 24-kD vacuolar protein (VP24) accumulates abundantly in intravacuolar pigmented globules in anthocyanin-containing sweet potato (Ipomoea batatas) cells in suspension culture. A cDNA clone encoding VP24 was isolated from a cDNA library constructed from light-irradiated suspension-cultured cells. Sequence analysis revealed that a 2.9-kbp VP24 cDNA encodes a protein of 893 amino acid residues with a molecular mass of 96.3 kD. According to the deduced amino acid sequence of VP24 cDNA, VP24 is probably synthesized as a large precursor protein with an N-terminal extension composed of a signal peptide and a propeptide, plus the polypeptide of the mature VP24 and its C-terminal propeptide, which contains the multiple transmembrane domains. A search in the ProDom database revealed the mature VP24 domain belongs to the zinc metalloprotease family. Northern analysis revealed that the single 2.9-kb VP24 mRNA increases rapidly after light irradiation, whereas VP24 mRNA was undetectable in the dark-cultured cells or in the presence of a high concentration of 2,4-dichlorophenoxyacetic acid. Light-induced VP24 gene expression closely correlated with the accumulation of anthocyanin in the vacuoles. These results suggested that proteins derived from the VP24 precursor protein may be involved in vacuolar transport and/or accumulation of anthocyanin synthesized in the cytosol.     

Identification of a novel Fasciola hepatica cathepsin L protease containing protective epitopes within the propeptide

Cathepsin L (CL)-like proteases are important candidate vaccine antigens for protection against helminth infections. We previously identified an immunogenic 32 kDa protein specifically present in newly excysted juveniles (NEJs) of Fasciola hepatica. Here we show by N-terminal protein sequencing that this protein represents a CL-like protease still containing the propeptide. Two cDNAs encoding this CL were subsequently isolated from NEJs by RT-PCR. The predicted amino acid sequences of these cDNAs showed approximately 70% sequence homology to both CL1 and CL2 sequences isolated from adult stage F. hepatica and are, therefore, referred to as CL3. The CL3 clones encoded asparagine at position P1 of the propeptide cleavage site, suggesting a dependence on asparaginyl endopeptidases for maturation. Recombinant expression of a CL3 cDNA in Saccharomyces cerevisiae resulted in secretion of the proenzyme form. The propeptide of CL-like proteins was predicted to contain important B-cell epitopes. To determine the contribution of the propeptide to protective immunity, rats were vaccinated with Keyhole Limpet Haemocyanin-conjugated synthetic peptides encoding these putative B-cell epitopes derived from the CL1 or CL3 sequence. A subsequent challenge infection resulted in a significant (P < 0.05) reduction of fluke load compared to adjuvant controls. We conclude that the propeptide of CL3 plays an important role in inducing immunity against F. hepatica infection.     

Expression and characterization of recombinant gamma-tryptase

Tryptases are trypsin-like serine proteases whose expression is restricted to cells of hematopoietic origin, notably mast cells. gamma-Tryptase, a recently described member of the family also known as transmembrane tryptase (TMT), is a membrane-bound serine protease found in the secretory granules or on the surface of degranulated mast cells. The 321 amino acid protein contains an 18 amino acid propeptide linked to the catalytic domain (cd), followed by a single-span transmembrane domain. gamma-Tryptase is distinguished from other human mast cell tryptases by the presence of two unique cysteine residues, Cys(26) and Cys(145), that are predicted to form an intra-molecular disulfide bond linking the propeptide to the catalytic domain to form the mature, membrane-anchored two-chain enzyme. We expressed gamma-tryptase as either a soluble, single-chain enzyme with a C-terminal His tag (cd gamma-tryptase) or as a soluble pseudozymogen activated by enterokinase cleavage to form a two-chain protein with an N-terminal His tag (tc gamma-tryptase). Both recombinant proteins were expressed at high levels in Pichia pastoris and purified by affinity chromatography. The two forms of gamma-tryptase exhibit comparable kinetic parameters, indicating the propeptide does not contribute significantly to the substrate affinity or activity of the protease. Substrate and inhibitor library screening indicate that gamma-tryptase possesses a substrate preference and inhibitor profile distinct from that of beta-tryptase. Although the role of gamma-tryptase in mast cell function is unknown, our results suggest that it is likely to be distinct from that of beta-tryptase.     

HspBP1, an Hsp70 cochaperone,has two structural domains and is capable of altering the conformation of the Hsp70 ATPase domain

We present here the first structural information for HspBP1, an Hsp70 cochaperone. Using circular dichroism, HspBP1 was determined to be 35% helical. Although HspBP1 is encoded by seven exons, limited proteolysis shows that it has only two structural domains. Domain I, amino acids 1-83, is largely unstructured. Domain II, amino acids 84-359, is predicted to be 43% helical using circular dichroism. Using limited proteolysis we have also shown that HspBP1 association changes the conformation of the ATPase domain of Hsp70. Only domain II of HspBP1 is required to bring about this conformational change. Truncation mutants of HspBP1 were tested for their ability to inhibit the renaturation of luciferase and bind to Hsp70 in reticulocyte lysate. A carboxyl terminal truncation mutant that was slightly longer than domain I was inactive in these assays, but domain II was sufficient to perform both functions. Domain II was less active than full-length HspBP1 in these assays, and addition of amino acids from domain I improved both functions. These studies show that HspBP1 domain II can bind Hsp70, change the conformation of the ATPase domain, and inhibit Hsp70-associated protein folding.