In vitro translation and processing of rat kidney gamma-glutamyl transpeptidase

Rat kidney gamma-glutamyl transpeptidase is composed of two nonidentical glycosylated subunits. The enzyme is localized on the lumenal surface of the brush-border membranes of proximal tubule epithelial cells; it is attached to the membranes via an NH2-terminal segment of the larger of the two subunits. Tissue-labeling experiments followed by immunoprecipitation with antibodies directed against the enzyme and its two subunits demonstrate that a glycosylated single chain precursor (Mr = 78,000), containing the elements of both the subunits, is initially synthesized. Pulse-chase studies in the presence of pactamycin, and inhibitor of protein synthesis initiation, indicate that the larger of the two subunits is located at the NH2 terminus of the Mr = 78,000 precursor. The initial events in the biosynthesis and processing of gamma-glutamyl transpeptidase were investigated by in vitro translation of rat kidney mRNA. Such translation results in the synthesis of a Mr = 63,000 unglycosylated polypeptide which has been shown immunologically to contain the domains for both subunits. The Mr = 63,000 species is processed to a Mr = 78,000 core-glycosylated polypeptide when translation of mRNA is carried out in the presence of dog pancreas microsomes. This processing does not appear to be associated with cleavage of an NH2-terminal leader sequence. The Mr = 78,000 polypeptide is integrated into the microsomal membranes with an orientation that is analogous to that found on the brush-border membranes. Glycosylation and membrane integration of transpeptidase are cotranslational events. Upon longer incubation, the Mr = 78,000 species sequestered within the microsomal vesicles is cleaved to species corresponding in size to the two subunits of the kidney enzyme.     

Evidence for biosynthesis of lactase-phlorizin hydrolase as a single-chain high-molecular weight precursor

Precursor forms of lactase-phlorizin hydrolase, sucrase-isomaltase and aminopeptidase N were studied by pulse-labelling of organ-cultured human intestinal biopsies. After labelling the biopsies were fractionated by the Ca2+-precipitation method and the enzymes isolated by immunoprecipitation. The results indicate that the lactase-phlorizin hydrolase is synthesized as a Mr 245 000 polypeptide, which is intracellularly cleaved into its mature Mr 160 000 form. Sucrase-isomaltase is shown to be synthesized as a single chain precursor (Mr 245 000 and 265 000) while the precursor of aminopeptidase N is shown to be of apparently the same size as the mature enzyme (Mr 140 000 and 160 000).     

The mode of anchoring and precursor forms of sucrase-isomaltase and maltase-glucoamylase in chicken intestinal brush-border membrane. Phylogenetic implications

Chicken intestinal sucrase-isomaltase and maltase-glucoamylase have been isolated in their intact form by detergent solubilization and characterized as to their subunit composition and mode of anchoring in the brush-border membrane. Both are heterodimeric enzyme complexes composed of two subunits each of approximately 140 and 130 kDa. Contrary to the mammalian sucrase-isomaltase, chicken isomaltase was identified as the smaller of the two subunits. As was shown by hydrophobic labeling, only one of the two subunits in each heterodimer is anchored in the bilayer, the smaller 130 kDa isomaltase subunit of the sucrase-isomaltase complex, and the larger 140 kDa subunit of the maltase-glucoamylase complex. Both preparations contain a high-molecular weight polypeptide of approximately 250 kDa which in the case of sucrase-isomaltase could be identified by peptide mapping as a single-chain precursor not (yet) proteolytically processed to the final heterodimer. These first data on the mode of membrane anchoring of non-mammalian glycosidases indicate that they are synthesized, inserted into the membrane, and processed in ways similar to the mammalian enzymes. The fundamental unity between avian and mammalian sucrase-isomaltases suggests that the partial gene duplication of an ancestral isomaltase gene and the subsequent mutation of one of the active sites resulting in pro-sucrase-isomaltase has occurred prior to the separation of mammals from reptiles, i.e. more than 300 million years ago.     

A precursor form of latent collagenase produced in a cell-free system with mRNA from rabbit synovial cells

mRNA extracted from rabbit synovial fibroblasts which had been induced to produce large amounts of collagenase (EC 3.4.23.7) by urate crystals was translated in a cell-free wheat germ system. Collagenase was identified by immunoprecipitation using mono-specific antibody to rabbit synovial collagenase. In the absence of microsomal membranes, a single precursor with Mr = 59,000 was synthesized. This polypeptide was susceptible to proteolytic degradation. In the presence of canine pancreatic microsomes, the nascent protein was processed to a polypeptide with Mr = 57,000 (identical in mobility on sodium dodecyl sulfate-gel electrophoresis to the major latent collagenase secreted from cells) and was protected from tryptic digestion unless a detergent was used to disrupt the membranes. In addition to Mr = 57,000 material, cells secreted immunologically reactive latent collagenase with Mr = 61,000. High molecular weight collagenase was separated from Mr = 57,000 species by binding to concanavalin a-Sepharose, suggesting that this enzyme was a product of post-translational glycosylation. Both latent enzymes were activated by trypsin and human plasma kallikrein to Mr = 45,000 and 49,000. The evidence indicates that rabbit synovial fibroblast collagenase is synthesized and secreted as a single polypeptide zymogen, not as an enzyme-inhibitor complex.     

The mouse leukocyte adhesion proteins Mac-1 and LFA-1: studies on mRNA translation and protein glycosylation with emphasis on Mac-1

Translation in vitro of mRNA and immunoprecipitation with specific rabbit antisera showed that the unglycosylated precursor polypeptides of the mouse Mac-1 and lymphocyte function associated antigen (LFA-1) alpha subunits are 130,000 Mr and 140,000 Mr, respectively. Furthermore, polysomes purified by using anti-Mac-1 IgG yielded a similar major product of translation in vitro of Mr = 130,000. The Mac-1 and LFA-1 alpha subunit translation products are immunologically noncross-reactive, showing that differences between these related proteins are not due to post-translational processing. Mac-1 and LFA-1 alpha subunits could only be in vitro translated from mRNA from cell lines the surfaces of which express the corresponding Mac-1 and LFA-1 alpha-beta complexes, showing tissue-specific expression is regulated at the mRNA level. The glycosylation of Mac-1 was examined by both translation in vitro in the presence of dog pancreas microsomes and by biosynthesis in vivo and treatment with tunicamycin, endoglycosidase H, and the deglycosylating agent trifluoromethane sulfonic acid. High mannose oligosaccharides are added to the Mac-1 alpha and beta polypeptide backbones of Mr = 130,000 and 72,000, respectively, to yield precursors of Mr = 164,000 and 91,000, respectively. The alpha and beta subunit precursors are then processed with partial conversion of high mannose to complex type carbohydrate to yield the mature subunits of Mr = 170,000 and 95,000, respectively.     

Mosquito vitellogenin subunits originate from a common precursor

Using a cell-free translation system, we demonstrated that the two subunits of mosquito vitellogenin (VG), 200 kDa and 65 kDa, originate from a common precursor. The precursor polypeptide of 220 kDa is a translation product specific to mRNA from vitellogenic mosquitoes. In immunoprecipitation analysis, the 220-kDa polypeptide was recognized by monoclonal antibodies directed either to the large or the small VG subunit. Peptide mapping showed homology between the 220-kDa polypeptide and both subunits, thus providing further proof that the 220-kDa product of translation is the precursor for both VG subunits. In the presence of microsomal membranes, the molecular size of the VG precursor increased to 235 kDa suggesting this as a first step in co-translational modifications of VG.     

Biosynthesis and import into the mitochondrion of L-3-glycerophosphate dehydrogenase, and the effect of thyroid hormone deficiency on gene expression

Mitochondrial L-3-glycerophosphate dehydrogenase (EC 1.1.99.5) is synthesised in bovine kidney (NBL-1) cells treated with uncoupler as a cytosolic precursor with Mr = 76,000 indistinguishable from the mature form. In vitro translation of rat liver mRNA also gives rise to a product of Mr = 76,000 but when this is imported into mitochondria it is processed to a product of Mr = 66,000. L-3-Glycerophosphate dehydrogenase activity and immunoreactive protein are greatly decreased in liver mitochondria from hypothyroid rats. Paradoxically, in vitro translation of the mRNA from such animals gives rise to large amounts of the protein, much greater than that synthesised from euthyroid mRNA and comparable with that produced from hyperthyroid mRNA.     

Cell-free synthesis, membrane integration, and glycosylation of pro-sucrase-isomaltase

Cell-free translation of total RNA from rabbit intestinal mucosa in a rabbit reticulocyte lysate, after immunoprecipitation with antibodies directed against sucrase-isomaltase, yielded a polypeptide of 200 kDa, which was identified as pro-sucrase-isomaltase. Addition of dog pancreatic microsomal vesicles to the translation system resulted in the appearance of an additional 220-kDa polypeptide. The 220-kDa polypeptide was associated with the membranes in a way that made it inaccessible to proteolysis; this protection was abolished by lytic detergent concentrations, indicating that the polypeptide was segregated into the microsomal vesicle. The 220-kDa polypeptide was glycosylated as evidenced by it being bound to concanavalin A-Sepharose and eluted with alpha-methyl-D-mannopyranoside. The increase in apparent molecular mass (approximately 20 kDa) of the primary translation product upon translocation was due to the addition of carbohydrate; treatment of the 220-kDa polypeptide with endo-beta-N-acetylglucosaminidase H increased its electrophoretic mobility to that of the 200-kDa polypeptide which was obtained in the absence of membranes. Partial N-terminal amino acid sequence of a translation product labeled with [3H]Leu in the absence of membranes revealed that Leu was incorporated into identical positions as in the final (pro)-sucrase-isomaltase, thus indicating the lack of a transient signal peptide.     

Primary structure and processing of the Candida tsukubaensis alpha-glucosidase. Homology with the rabbit intestinal sucrase-isomaltase complex and human lysosomal alpha-glucosidase.

The nucleotide sequence of a 4.39-kb DNA fragment encoding the alpha-glucosidase gene of Candida tsukubaensis is reported. The cloned gene contains a major open reading frame (ORF 1) which encodes the alpha-glucosidase as a single precursor polypeptide of 1070 amino acids with a predicted molecular mass of 119 kDa. N-terminal amino acid sequence analysis of the individual subunits of the purified enzyme, expressed in the recombinant host Saccharomyces cerevisiae, confirmed that the alpha-glucosidase precursor is proteolytically processed by removal of an N-terminal signal peptide to yield the two peptide subunits 1 and 2, of molecular masses 63-65 kDa and 50-52 kDa, respectively. Both subunits are secreted by the heterologous host S. cerevisiae in a glycosylated form. Coincident with its efficient expression in the heterologous host, the C. tsukubaensis alpha-glucosidase gene contains many of the canonical features of highly expressed S. cerevisiae genes. There is considerable sequence similarity between C. tsukubaensis alpha-glucosidase, the rabbit sucrase-isomaltase complex (proSI) and human lysosomal acid alpha-glucosidase. The cloned DNA fragment from C. tsukubaensis contains a second open reading frame (ORF 2) which has the capacity to encode a polypeptide of 170 amino acids. The function and identity of the polypeptide encoded by ORF 2 is not known.     

The properties of the large subunit of maize ribulose bisphosphate carboxylase/oxygenase synthesised in Escherichia coli

The maize chloroplast gene for the large subunit of ribulose bisphosphate carboxylase/oxygenase has been expressed in Escherichia coli in vivo. This enables the properties of the native large-subunit polypeptide to be examined in the absence of small-subunit polypeptides, and avoids the use of denaturing agents. The product synthesised in bacteria is slightly larger (Mr 54300) than the form present in the chloroplast (Mr 53 300), suggesting the involvement of a precursor polypeptide. In addition several smaller polypeptides are synthesised, predominantly of molecular mass 41 and 30 kDa, but also some of 44 and 12-14 kDa. Pulse-chase experiments with [35S]methionine indicate that all the immunoprecipitable polypeptides are stable. The smaller products are probably the result of premature termination of translation. Virtually all of the large subunits are insoluble, whether synthesised at levels of 100-200 molecules per cell, or up to 60 000 molecules per cell. A small amount of the full-length polypeptide is soluble, but the major soluble product, as determined by sucrose gradient centrifugation, is a polypeptide of molecular mass 12-14 kDa. Ribulose bisphosphate carboxylase activity was undetectable in cell extracts, and binding of a mixture of the radiolabelled transition state analogues carboxyribitol 1,5-bisphosphate and carboxyarabinitol 1,5-bisphosphate could not be detected. It is proposed that other components are required to prevent the large subunit from adopting an inactive, insoluble conformation after, or during, synthesis.     

Biosynthesis of prostatic acid phosphatase in a normal human cell-line

The biosynthesis of the prostatic form of human acid phosphatase was studied in normal embryonic lung cells, WI-38, by metabolic labeling with tritiated leucine and [32P]phosphate, followed by specific immunoprecipitation, gel electrophoresis, and fluorography. Of the total tartrate-inhibitable acid phosphatase activity in WI-38 cells, 30% is due to the prostatic form. The primary translation product that leads eventually to the mature prostatic enzyme is a precursor polypeptide of 112 kDa. The precursor polypeptide is processed to mature polypeptides of 59, 55, and 49 kDa via an intermediate 91-kDa precursor. WI-38 cells also secrete a 113-kDa peptide into the medium. The precursor and mature polypeptides are glycosylated and phosphorylated. Upon treatment with endo-beta-hexosaminidase H, the apparent molecular weighs of the polypeptides are reduced by approximately 4 kDa and phosphate is lost.     

Subcellular location of enzymes involved in the N-glycosylation and processing of asparagine-linked oligosaccharides in Saccharomyces cerevisiae

A particulate translation system isolated from the yeast Saccharomyces cerevisiae was shown to translate faithfully in-vitro-transcribed mRNA coding for a mating hormone precursor (prepro-alpha-factor mRNA) and to N-glycosylate the primary translation product after its translocation into the lumen of the microsomal vesicles. Glycosylation of its three potential sugar attachment sites was found to be competitively inhibited by acceptor peptides containing the consensus sequence Asn-Xaa-Thr, supporting the view that the glycan chains are N-glycosidically attached to the prepro-alpha-factor polypeptide. The accumulation in the presence of acceptor peptides of a membrane-specific, unglycosylated translation product (pp-alpha-F0) differing in molecular mass from a cytosolically located, protease-K-sensitive alpha-factor polypeptide (pp-alpha-Fcyt) by about 1.3 kDa, suggests that, in contrast to previous reports, a signal sequence is cleaved from the mating hormone precursor on/after translocation. This conclusion is supported by the observation that the multiply glycosylated alpha-factor precursor is cleaved by endoglucosaminidase H to a product with a molecular mass smaller than the primary translation product pp-alpha-Fcyt but larger than the membrane-specific pp-alpha-F0. Translation and glycosylation experiments carried out in the presence of various glycosidase inhibitors (e.g. 1-deoxynojirimycin, N-methyl-1-deoxynojirimyin and 1-deoxymannojirimycin) indicate that the N-linked oligosaccharide chains of the glycosylated prepro-alpha-factor species are extensively processed under the in vitro conditions of translation. From the specificity of the glycosidase inhibitors applied and the differences in the molecular mass of the glycosylated translation products generated in their presence, we conclude that the glycosylation-competent microsomes contain trimming enzymes, most likely glucosidase I, glucosidase II and a trimming mannosidase, which process the prepro-alpha-factor glycans down to the (Man)8(GlcNAc)2 stage. Furthermore, several arguments strongly suggest that these three enzymes, which apparently represent the full array of trimming activities in yeast, are exclusively located in the lumen of microsomal vesicles derived from endoplasmic reticulum membranes.     

Assembly of the sarcoplasmic reticulum. Cell-free synthesis of te Ca2+ + Mg2+-adenosine triphosphatase and calsequestrin

Polyadenylated RNA prepared from neonatal rat muscle was translated in a rabbit reticulocyte cell-free system. Two sarcoplasmic reticulum proteins, the Ca2+ + Mg2+-dependent adenosine triphosphatase (ATPase) and calsequestrin, were isolated from the translation mixture by immunoprecipitation, followed by electrophoresis in sodium dodecyl sulfate-polyacrylamide gels. The [35S]methionine-labeled translation products were characterized by molecular weight, peptide mapping, and NH2-terminal sequence analysis. The ATPase synthesized in the cell-free system was found to have the same molecular weight (Mr = 100,000) and [35S]-methionine-labeled peptide map as the mature ATPase. The methionine residue present at the NH2 terminus of the mature ATPase was donated by initiator methionyl-tRNArMet and it became acetylated during translation. These results suggest that the ATPase was synthesized without an NH2-terminal signal sequence. Calsequestrin (Mr - 63,000) was synthesized as a higher molecular weight precursor (Mr = 66,000) that contained an additional [35S]methionine-labeled peptide when compared to mature calsequestrin. The NH2-terminal sequence of the precursor was different from the mature protein. The precursor was processed to a polypeptide with a molecular weight identical with mature calsequestrin when microsomal membranes prepared from canine pancreas were included during translation. These results show that calsequestrin is synthesized with an NH2-terminal signal sequence that is removed during translation. These data add to the evidence that the ATPase and calsequestrin follow distinctly different biosynthetic pathways, even though, ultimately, they are both located in the same membrane.     

A two-active site one-polypeptide enzyme: the isomaltase from sea lion small intestinal brush-border membrane. Its possible phylogenetic relationship with sucrase-isomaltase

The enzyme responsible for all of the isomaltase activity and much of the maltase activity in the small intestine of the Californian sea lion (Zalophus californianus) was isolated by detergent solubilization of the brush-border membrane, followed by immunoadsorption chromatography using antibodies directed against rabbit sucrase-isomaltase. In 0.1% Triton X-100, sea lion isomaltase occurs as a monomer of Mr = 245,000 and is composed of a single polypeptide chain. As judged from the stoichiometry of the covalent binding of the affinity label, conduritol-B-epoxide, this polypeptide chain carries two enzymatically active sites; they are apparently identical and do not show either positive or negative cooperativity. In addition to cross-reacting immunologically with rabbit sucrase-isomaltase, sea lion isomaltase has similar overall enzymatic properties, with the exception of not hydrolyzing sucrose. The Alaskan fur seal (Collarhinus ursinus) has a two-active site isomaltase; however, in contrast to the sea lion, this animal is endowed with a small but significant sucrase activity. Along with (fully active) pro-sucrase-isomaltase, sea lion isomaltase is one of the very few examples of enzymes with more than one active site on a single polypeptide chain acting "in parallel" (rather than "in series"). Furthermore, this enzyme triggers some interesting questions on the phylogenetical pedigree of small intestinal sucrase-isomaltase.     

Human DNA polymerase alpha catalytic polypeptide binds ConA and RCA and contains a specific labile site in the N-terminus.

The catalytic polypeptide of DNA polymerase alpha is often observed in vitro as a family of phosphopolypeptides predominantly of 180 and 165 kDa derived from a single primary structure. The estimated Mr of this polypeptide deduced from the full-length cDNA is 165 kDa. Immunoblot analysis with polyclonal antibodies against peptides of the N- and C-termini of the deduced primary sequence indicates that the observed family of polypeptides from 180 kDa to lower molecular weight results from proteolytic cleavage from the N-terminus. Antibodies against the N-terminal peptide detect only the 180 kDa species suggesting that this higher molecular weight polypeptide may be the result of posttranslational modification of the 165 kDa primary translation product. The catalytic polypeptide is not only phosphorylated but is also found to react with lectins ConA and RCA. N-terminal sequencing of the isolated catalytic polypeptide from human cells and of the recombinant fusion proteins indicates that the often observed 165 kDa polypeptide is the in vitro proteolytic cleavage product of the modified 180 kDa protein at the specific site between lys123 and lys124 within the sequence -RNVKKLAVTKPNN-.     

Construction of an alpha-amylase/glucoamylase fusion gene and its expression in Saccharomyces cerevisiae.

A fusion gene which encoded a polypeptide comprised of 1116 amino acids was constructed using the alpha-amylase and glucoamylase cDNAs of Aspergillus shirousamii. When the fusion gene was expressed in Saccharomyces cerevisiae using a yeast expression plasmid under the control of the yeast ADH1 promoter, a bifunctional fusion protein (145 kDa) having both alpha-amylase and glucoamylase activities was secreted into the culture medium. The fusion protein had higher raw-starch-digesting activity than those of the original alpha-amylase and glucoamylase, and adsorbed onto raw starch like the glucoamylase. It was suggested that the characteristics are a result of the raw-starch-affinity site in the glucoamylase domain of the fusion protein.     

Membrane and cytosolic components affecting transport of the precursor for ornithine carbamyltransferase into mitochondria

A higher molecular weight precursor (Mr = 39,000) to the liver mitochondrial matrix enzyme, ornithine carbamyltransferase (Mr = 36,000), is imported and processed by heart mitochondria in vitro in a manner similar to liver mitochondria. In both systems, however, an additional 37-kDa ornithine carbamyltransferase polypeptide appears, but this arises from nonspecific events and, therefore, does not represent a bona fide intermediate in the overall processing sequence. Our experiments demonstrate that the outer mitochondrial membrane of mitochondria contains a protease-sensitive (5 micrograms of trypsin or chymotrypsin/ml, 15 min at 2 degrees C), salt-resistant (1.0 M KCl) protein which is required to maintain import functions. In addition, functional post-translational import requires a component of the reticulocyte lysate (i.e. cytosol) that is used for initially synthesizing precursor enzyme. The component is retained by Sephadex G-25. Import of Sephadex G-25-excluded precursor is restored by fresh reticulocyte lysate but not by a combination of other additives, including Mg2+, K+, ATP, ADP, Pi, succinate, and total translation mixture (minus lysate).