Ribonucleoparticle-independent transport of proteins into mammalian microsomes

There are at least two different mechanisms for the transport of secretory proteins into the mammalian endoplasmic reticulum. Both mechanisms depend on the presence of a signal peptide on the respective precursor protein and involve a signal peptide receptor on the cis-side and signal peptidase on the trans-side of the membrane. Furthermore, both mechanisms involve a membrane component with a cytoplasmically exposed sulfhydryl. The decisive feature of the precursor protein with respect to which of the two mechanisms is used is the chain length of the polypeptide. The critical size seems to be around 70 amino acid residues (including the signal peptide). The one mechanism is used by precursor proteins larger than about 70 amino acid residues and involves two cytosolic ribonucleoparticles and their receptors on the microsomal surface. The other one is used by small precursor proteins and relies on the mature part within the precursor molecule and a cytosolic ATPase.     

Regulation and structure of an Escherichia coli gene coding for an outer membrane protein involved in export of K88ab fimbrial subunits.

The nucleotide sequence of the faeD gene of Escherichia coli and the amino acid sequence of its product is presented. The faeD product is an outer membrane protein required for transport of K88ab fimbrial subunits across the outer membrane. The protein is synthesized as a precursor containing a signal peptide, and the tentative mature protein comprises 777 amino acid residues. The distribution of amino acids in the faeD protein is similar to that of other outer membrane proteins; showing a fairly even distribution of charged residues and the absence of extensive hydrophobic stretches. Secondary structure predictions revealed a region of 250 amino acid residues which might be embedded in the outer membrane. The 5'-end of faeD is located within a region showing dyad symmetry. This region serves to couple translation of faeD to the translation of the gene preceding it (faeC). The 3'-end of faeD shows an overlap of 5 bases with the next gene (faeE).     

Signal peptide mutants ofEscherichia coli

Numerous secretory proteins of the Gram-negative bacteriaE. coli are synthesized as precursor proteins which require an amino terminal extension known as the signal peptide for translocation across the cytoplasmic membrane. Following translocation, the signal peptide is proteolytically cleaved from the precursor to produce the mature exported protein. Signal peptides do not exhibit sequence homology, but invariably share common structural features: (1) The basic amino acid residues positioned at the amino terminus of the signal peptide are probably involved in precursor protein binding to the cytoplasmic membrane surface. (2) A stretch of 10 to 15 nonpolar amino acid residues form a hydrophobic core in the signal peptide which can insert into the lipid bilayer. (3) Small residues capable of -turn formation are located at the cleavage site in the carboxyl terminus of the signal peptide. (4) Charge characteristics of the amino terminal region of the mature protein can also influence precursor protein export. A variety of mutations in each of the structurally distinct regions of the signal peptide have been constructedvia site-directed mutagenesis or isolated through genetic selection. These mutants have shed considerable light on the structure and function of the signal peptide and are reviewed here.     

An alternate pathway for the processing of the prolipoprotein signal peptide in Escherichia coli

Previous studies showed that when the signal sequence plus 9 amino acid residues from the amino terminus of the major lipoprotein of Escherichia coli was fused to beta-lactamase, the resulting hybrid protein was modified, proteolytically processed, and assembled into the outer membrane as was the wild-type lipoprotein (Ghrayeb, J., and Inouye, M. (1983) J. Biol. Chem. 259, 463-467). We have constructed several hybrid proteins with mutations at the cleavage site of the prolipoprotein signal peptide. These mutations are known to block the lipid modification of the lipoprotein at the cysteine residue, resulting in the accumulation of unprocessed, unmodified prolipoprotein in the outer membrane. The mutations blocked the lipid modification of the hybrid protein. However, in contrast to the mutant lipoproteins, the cleavage of the signal peptides for the mutant hybrid proteins did occur, although less efficiently than the unaltered prolipo-beta-lactamase. The mutant prolipo-beta-lactamase proteins were cleaved at a site 5 amino acid residues downstream of the prolipoprotein signal peptide cleavage site. This new cleavage between alanine and lysine residues was resistant to globomycin, a specific inhibitor for signal peptidase II. This indicates that signal peptidase II, the signal peptidase which cleaves the unaltered prolipo-beta-lactamase, is not responsible for the new cleavage. The results demonstrate that the cleavage of the signal peptide is a flexible process that can occur by an alternative pathway when the normal processing pathway is blocked.     

Dual functions of the signal peptide in protein transfer across the membrane

Most secretory proteins in both prokaryotic and eukaryotic cells are synthesized from a precursor with an amino-terminal extension of 20 to 25 amino acid residues called a signal peptide. These signal peptides are removed during translocation of the secretory proteins across the membrane. When two precursor structures are fused, the internalized second signal peptide was found to exert two different roles, depending upon either the distance between the two signal peptides, or whether the first signal peptide functions cotranslationally or posttranslationally. One role is to function as the usual signal peptide to translocate the protein downstream of the internal signal peptide. The other role is to function as a stop-transfer signal to create a transmembrane protein with the second signal peptide anchoring the protein in the membrane.     

The primary structure of the N-terminal region of mature alkaline phosphatase is critical for secretion and function of the enzyme

The export signal has been assumed to be localized not only in the signal peptide of a secreted protein precursor, but also in the N-terminal region of the mature polypeptide chain. Mutant alkaline phosphatases with amino acid substitutions of two positively charged residues (Lys or Arg) in this region at different distances from the signal peptide have been studied to test this assumption. The efficiency of secretion has been shown to decrease in mutant proteins with amino acid substitutions in the region of 16-18 amino acid residues; the closer to the signal peptide is the substitution, the greater is the decrease. A change in the primary structure of the N-terminal domain results also in an increase in the Michaelis constant, which is greater the farther is the amino acid substitution from the signal peptide, suggesting a change in the enzyme function as well.     

Critical region in the extension peptide for the import of cytochrome P-450(SCC) precursor into mitochondria

In order to establish the role of the extension peptide of the precursor of P-450(SCC), a mitochondrial inner membrane protein, in the import into the organella, three deletion mutants of the precursor, in which the deletions were in the mature portion, were constructed. These mutant precursors were imported into mitochondria in vitro as efficiently as the original precursor, indicating that the extension peptide contains sufficient information for the import of the precursor into mitochondria. To investigate which portion of the extension peptide contains the mitochondrial targeting signal, various lengths of the amino-terminal portion of the extension peptide of P-450(SCC) precursor were fused to the mature portion of adrenodoxin. The fusion proteins consisting of 44 and 19 amino-terminal amino acids and mature adrenodoxin were imported into mitochondria, whereas those containing 14, 7, and 2 amino-terminal amino acid residues were not. The importance of the amino-terminal portion of the extension peptide was confirmed by the deletion from the amino-terminal end of a fusion protein consisting of the amino-terminal 44 amino acid residues of P-450(SCC) precursor and mature adrenodoxin, SCC44RAd. The amino-terminal deletions abolished the import of the fusion proteins into mitochondria. Substitution of all of the three basic amino acids, Arg(4), Arg(9), and Lys(14) in the extension peptide of SCC44RAd to Ser or Thr inhibited the binding of the fusion protein to mitochondria as well as its import.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synthesis of Escherichia coli heat-stable enterotoxin STp as a pre-pro form and role of the pro sequence in secretion.

Escherichia coli heat-stable enterotoxin STp is presumed from its DNA sequence to be synthesized in vivo as a 72-amino-acid residue precursor that is cleaved to generate mature STp consisting of the 18 carboxy-terminal amino acid residues. There are two methionine residues in the inferred STp sequence in addition to the methionine residue at position 1. In order to confirm production of the STp 72-amino-acid residue precursor, we substituted the additional methionine residues by oligonucleotide-directed site-specific mutagenesis. Since these substitutions did not cause a significant change in STp production, it can be concluded that STp is normally synthesized as the 72-amino-acid residue precursor. The length of the STp precursor indicated the existence of a pro sequence between the signal peptide and the mature protein. In order to identify the pro sequence and determine its role in protein secretion, deletion and fusion proteins were made. A deletion mutant in which the gene fragment encoding amino acid residues 22 to 53 of STp was removed was made. STp activity was found in the culture supernatant of cells. Amino acid sequence analysis of the purified STp deletion mutant revealed that the pro sequence encompasses amino acid residues 20 to 54. A hybrid protein consisting of STp amino acids 1 to 53 fused in frame from residue 53 to nuclease A was not secreted into the culture supernatant. These results indicate that the pro sequence does not function to guide periplasmic protein into the extracellular milieu.     

Isolation of human, swine, and rat prepepsinogens and calf preprochymosin, and determination of the primary structures of their NH2-terminal signal sequences

The total RNAs were extracted from human, swine, rat, and calf gastric mucosae, and translated in vitro in the presence of radiolabeled amino acids using a wheat germ cell-free system. Upon sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis of the translation products, a protein band with a molecular weight of about 43,000 was obtained in each case as one of the major products. These products could be specifically immunoprecipitated with a corresponding anti-pepsinogen or anti-chymosin antiserum. Radiosequence analysis of these translation products purified by SDS-polyacrylamide gel electrophoresis showed that each of them is a precursor form, i.e., prepepsinogen or preprochymosin, having an amino-terminal extension peptide (signal sequence) comprising 15 (human and swine) or 16 (rat and calf) amino acid residues. The primary structures of these signal sequences were determined to be as follows: (Sequence: see text). These signal sequences share common characteristics with those of other pre-secretory proteins, i.e., the presence of positive charges in the NH2-terminal region, hydrophobic amino acid clusters in the interior part, and amino acids with short side chains at the site of cleavage by the signal peptidase.     

Identification of Lassa virus glycoprotein signal peptide as a trans-acting maturation factor

Lassa virus glycoprotein is translated as a precursor (pre-GP-C) into the lumen of the endoplasmic reticulum and is cotranslationally cleaved into the signal peptide and GP-C, before GP-C is proteolytically processed into its subunits GP1 and GP2. The signal peptide of pre-GP-C comprises 58 amino acids. The substitution of Lassa virus pre-GP-C signal peptide with another signal peptide still mediates translocation and the release of signal peptide but abolishes the proteolytic cleavage of GP-C into GP1 and GP2. Remarkably, cleavage of GP-C from these hybrid pre-GP-C substrates was restored on coexpression of the wild-type pre-GP-C signal peptide, indicating that the signal peptide functions as a trans-acting factor to promote Lassa virus GP-C processing. To our knowledge, this is the first report on a signal peptide that is essential for proteolytic processing of a secretory pathway protein.     

Export of honeybee prepromelittin in Escherichia coli depends on the membrane potential but does not depend on proteins secA and secY

Honeybee prepromelittin (70 amino acid residues), the precursor of an eukaryotic secretory protein, and a hybrid protein between prepromelittin and mouse dihydrofolate reductase (257 amino acid residues) were expressed in Escherichia coli and characterized with respect to their requirements for transport across the plasma membrane. Both precursor proteins are posttranslationally processed and exported into the periplasm, and they both depend on the membrane potential for this to occur. With respect to dependence on components of the export machinery, however, the two precursor proteins show striking differences: the small precursor protein prepromelittin does not require the function of proteins secA and secY; the large precursor protein prepromelittin-dihydrofolate reductase, on the other hand, depends on both components. The implications of these observations with respect to the mechanisms of protein export in E. coli and of protein import into the endoplasmic reticulum are discussed.     

Prerequisites for terminal processing of thylakoidal Tat substrates

In bacteria and chloroplasts, the Tat (twin arginine translocation) system is capable of translocating folded passenger proteins across the cytoplasmic and thylakoidal membranes, respectively. Transport depends on signal peptides that are characterized by a twin pair of arginine residues. The signal peptides are generally removed after transport by specific processing peptidases, namely the leader peptidase and the thylakoidal processing peptidase. To gain insight into the prerequisites for such signal peptide removal, we mutagenized the vicinity of thylakoidal processing peptidase cleavage sites in several thylakoidal Tat substrates. Analysis of these mutants in thylakoid transport experiments showed that the amino acid composition of both the C-terminal segment of the signal peptide and the N-terminal part of the mature protein plays an important role in the maturation process. Efficient removal of the signal peptide requires the presence of charged or polar residues within at least one of those regions, whereas increased hydrophobicity impairs the process. The relative extent of this effect varies to some degree depending on the nature of the precursor protein. Unprocessed transport intermediates with fully translocated passenger proteins are found in membrane complexes of high molecular mass, which presumably represent Tat complexes, as well as free in the lipid bilayer. This seems to indicate that the Tat substrates can be laterally released from the complexes prior to processing and that membrane transport and terminal processing of Tat substrates are independent processes.     

In vitro kinetic analysis of the role of the positive charge at the amino-terminal region of signal peptides in translocation of secretory protein across the cytoplasmic membrane in Escherichia coli

By using an in vitro system for the translocation of secretory proteins in Escherichia coli, detailed and quantitative studies were performed as to the function of the positively charged amino acid residues at the amino terminus of the signal peptide. Uncleavable OmpF-Lpp, a model secretory protein carrying an uncleavable signal peptide, and mutant proteins derived from it were used as translocation substrates. When the positive charge, +2 (LysArg) for the wild-type, was changed to 0, -1, or -2, little or no translocation was observed. The number of the positive charge was altered by introducing different numbers of Lys or Arg residues into the amino terminus. The rate of translocation was roughly proportional to this number, irrespective of whether the charged amino acid residues were Lys or Arg. When the amino-terminal LysArg was replaced by His residues, translocation took place more efficiently at pH 6.5 than pH 8.0, whereas that of the wild-type was about the same as the two pH values. We conclude that the signal peptide requires a positive charge at its amino-terminal region to function in the translocation reaction and that the rate of translocation is roughly proportional to the number of the positively charged group, irrespective of the amino acid species that donates the charge. Evidence suggesting that the positive charge is involved in the binding of precursor proteins to the membrane surface to initiate translocation is also presented.     

Generalized transposon shuttle mutagenesis in Neisseria gonorrhoeae: a method for isolating epithelial cell invasion-defective mutants

Hybrid genes were constructed to express bifunctional hybrid proteins in which staphyloccal nuclease A with or without an amino-terminai OmpA signal sequence was fused with TEM β-lactamase (at the carboxyl terminal side) using the signal peptide of the major outer membrane lipoprotein of Escherichia coli as an internal linker. The hybrid proteins were found to be inserted in the membrane. Orientation of the hybrid protein with the OmpA signal peptide showed that the nuclease was translocated into the periplasm and the β-lactamase remained in the cytoplasm. This indicates that the cleavable OmpA signal peptide served as a secretory signal for nuclease and the internal lipoprotein signal served as the transmembrane anchor, in the absence of the OmpA signal sequence the topology of the hybrid protein was reversed indicating that the internal lipoprotein signal peptide initially served as the signal peptide for the secretion of the carboxy terminal β-lactamase domain across the membrane and subsequently as a membrane anchoring signal. The role of charged amino acids in the translocation and transmembrane orientation of membrane proteins was also analysed by introducing charged amino acids to either or both sides of the internal lipoprotein signal sequence in the bifunctional hybrid proteins in the absence of the amino-terminal signal sequence. Introduction of two lysine residues at the carboxy-terminal side of the internal signal sequence reversed the topology of the transmembrane protein by translocating the aminoterminal nuclease domain across the membrane, leaving the carboxyl terminal β-actamase domain in the cytoplasm. When three more lysine residues were added to the amino-terminal side of the internal signal sequence of the same construct the membrane topology flipped back to the original orientation. A similar reversion of the topology could be obtained by introducing negatively charged residues at the amino-terminal side of the internal signal sequence. Present results demonstrate for the first time that a bifunctional transmembrane protein can be engineered to assume either of the two opposite orientations and that charge balance around the transmembrane domain is a major factor in controlling the topology of a transmembrane protein.     

A novel 7-β-(4-carboxybutanamido)-cephalosporanic acid acylase isolated from Pseudomonas strain C427 and its high-level production in Escherichia coli

We cloned the gene for 7-β-(4-carboxybutanamido)-cephalosporanic acid (GL-7ACA) acylase from Pseudomonas strain C427. The DNA sequence revealed an open reading frame of 2154 bp coding for 718 amino acid residues. The deduced amino acid sequence consists of 4 structural domains: (i) a signal peptide (positions 1–27), (ii) a small subunit of the acylase (positions 28–190), designated as α, (iii) a spacer peptide (positions 191–198), (iv) a large subunit (positions 199–718), designated as β. Plasmids were constructed to direct the synthesis of the acylase in Escherichia coli and the following results were obtained. The active acylase consists of two subunits which are processed from a single precursor protein, removing the spacer peptide during processing. A proportion of active acylase is secreted into the periplasm and the remainder is retained in the cytoplasm. The amount of precursor protein accumulated in the cytoplasm is greatly reduced when plasmids for the acylase lacking the signal sequence are expressed. Therefore, processing is independent of the translocation of the gene product through the cytoplasmic membrane, in contrast to the situation for penicillin G acylase. A high level of active enzyme production was achieved with a plasmid coding for an acylase in which the amino terminal sequence (positions 1–32) of native acylase is replaced by MFPTT.     

The molecular organization of the lysostaphin gene and its sequences repeated in tandem

Summary The gene encoding lysostaphin of Staphylococcus staphylolyticus was cloned in Escherichia coli and its DNA sequence was determined. The complete coding region comprises 1440 base pairs corresponding to a precursor of 480 amino acids (molecular weight 51669). It was shown by NH₂-terminal amino acid sequence analysis of the purified extracellular lysostaphin from S. staphylolyticus that the mature lysostaphin consists of 246 amino acid residues (molecular weight 26926). Polyacrylamide gel electrophoresis revealed a similar molecular weight for the most active form. By computer analysis the secondary protein structure was predicted. It revealed three distinct regions in the precursor protein: a typical signal peptide (ca. 38 aa), a hydrophilic and highly ordered protein domain with 14 repetitive sequences (296 aa) and the hydrophobic mature lysostaphin. The lysostaphin precursor protein appears to be organized as a preprolysostaphin.Abbreviations aa amino acid(s)     

A single gamma-carboxyglutamic acid residue in a novel cysteine-rich secretory protein without propeptide

Gamma-glutamyl carboxylase catalyzes the modification of specific glutamyl residues to gamma-carboxyglutamyl (Gla) residues in precursor proteins that possess the appropriate gamma-carboxylation recognition signal within the propeptide region. We describe the immunopurification and first biochemical characterization of an invertebrate high molecular weight Gla-containing protein with homologues in mammals. The protein, named GlaCrisp, was isolated from the venom of the marine cone snail Conus marmoreus. GlaCrisp gave intense signals in Western blot experiments employing the Gla-specific antibody M3B, and the presence of Gla was chemically confirmed by amino acid analysis after alkaline hydrolysis. Characterization of a full-length cDNA clone encoding GlaCrisp deduced a precursor containing an N-terminal signal peptide but, unlike other Gla-containing proteins, no apparent propeptide. The predicted mature protein of 265 amino acid residues showed considerable sequence similarity to the widely distributed cysteine-rich secretory protein family and closest similarity (65% identity) to the recently described substrate-specific protease Tex31. In addition, two cDNA clones encoding the precursors of two isoforms of GlaCrisp were identified. The predicted precursor isoforms differed at three amino acid positions (-6, 9, and 25). Analysis by Edman degradation and nanoelectrospray ionization mass spectrometry, before and after methyl esterfication, identified a Gla residue at amino acid position 9 in GlaCrisp. This is the first example of a Gla-containing protein without an obvious gamma-carboxylation recognition site. The results define a new class of Gla proteins and support the notion that gamma-carboxylation of glutamyl residues is phylogenetically older than blood coagulation and the vertebrate lineage.