Mechanisms of protein localization

How proteins get into microbodies (peroxisomes, glyoxysomes, glycosomes)

All microbody proteins studies, including one microbody membrane protein, are made on free polysomes and imported post-translationally. This holds for animal tissues, plants, and fungi. The majority of microbody protein sub-units are synthesized in a form not detectably different from mature sub-units. In five cases a larger precursor protein has been found. The position of the extra piece in this precursor is not known. In two of the five cases, processing of the precursor is not coupled to import; in the other three this remains to be determined. It is not even known whether information in the prepiece contributes to topogenesis, or serves other purposes. Microbody preparations from Neurospora, plant tissue and rat liver can take up some newly synthesized microbody proteins in vitro. In most cases uptake is inefficient. No special requirements for uptake have been established and whether a receptor is involved is not yet known. Several examples have been reported of peroxisomal enzymes with a counterpart in another cell compartment. With the exception of catalase, no direct evidence is available in any of these cases for two isoenzymes specified by the same gene. In the Zellweger syndrome, a lethal hereditary disease of man, characterized by a lack of peroxisomes, the levels of several enzymes of lipid metabolism are strongly decreased. In contrast, D-amino-acid oxidase, L-alpha-hydroxyacid oxidase and catalase levels are normal. The catalase resides in the cytosol. Since there is no separate gene for cytosolic catalase, the normal catalase levels in Zellweger cells show that some peroxisomal enzymes can mature and survive stably in the cytosol. It is possible that maturation of the peroxisomal enzyme in the cytoplasm can account for the finding of cytosolic catalase in some normal mammalian cells. The glycosomes of trypanosomes are microbodies that contain a glycolytic system. Comparison of the glycosomal phosphoglycerate kinase with its cytosolic counterpart has shown that these isoenzymes are 93% homologous in amino-acid sequence, but less than 50% homologous to the corresponding enzymes of yeast and mammals. This implies that few alterations are required to direct a protein into microbodies. This interpretation is supported by the evidence for homology between some microbody and mitochondrial isoenzymes in other organisms mentioned under point 4. The major changes of the glycosomal phosphoglycerate kinase relative to the cytosolic enzyme are a large increase in positive charge and a C-terminal extension of 20 amino acids.(ABSTRACT TRUNCATED AT 400 WORDS)

Orientation and patching of the latent infection membrane protein encoded by Epstein-Barr virus

Epstein-Barr virus is known to encode three nuclear proteins and one membrane protein (LMP) in latently infected growth-transformed cells. Studies of the plasma membrane localization and orientation of LMP by protease digestion of live cells and by immunofluorescence indicated the following. (i) At least 30% of LMP is in the plasma membrane, as opposed to other cytoplasmic membranes. (ii) A small LMP domain which corresponds to a previously proposed outer reverse turn between the first two transmembrane domains is exposed on the outer cell surface (and two other proposed outer-reverse-turn domains may be exposed), whereas all or almost all of the rest of the protein is not exposed on the outer cell surface. (iii) LMP is present in patches in the cell plasma membrane.

Nucleotide sequence of the small double-stranded RNA segment of bacteriophage phi 6: novel mechanism of natural translational control

The lipid-containing bacteriophage phi 6 has a genome composed of three segments of double-stranded RNA. We determined the nucleotide sequence of a cDNA copy of the smallest RNA segment. The coding sequences of the four proteins on this segment were identified. These sequences were clustered. Three of the genes had overlapping initiation-termination codons. All noncoding sequences were at the ends of the molecule. The genes of the small double-stranded RNA segment comprised two translational polarity groups. We propose that the translational coupling is the result of an inability of ribosomes to bind independently to two of the four genes. Translation of these genes occurred when ribosomes were delivered to them by translation of an upstream gene.

Isolation and sequence analysis of the gene (cpdB) encoding periplasmic 2',3'-cyclic phosphodiesterase

The cpdB gene encodes a periplasmic 2',3'-cyclic phosphodiesterase (3'-nucleotidase). This enzyme has been purified previously and the gene is located at 96 min on the Escherichia coli chromosome. In this study the cpdB gene was cloned from ClaI-cleaved DNA, and the gene product was identified. DNA blotting experiments showed that the recombinant plasmid contains a deletion with respect to the expected genomic fragment of approximately 4 kilobases, which extends into the vector. Furthermore, the gene was absent from three other recombinant libraries. Together, these findings suggest the presence in the genome of an adjacent gene whose product is lethal when it is present on a multicopy plasmid. The nucleotide sequence of the cpdB gene was also determined. The 5' and 3' untranslated sequences contain characteristic sequences that are involved in the initiation and termination of transcription, including two possible promoters, one of which may contain two overlapping -10 sequences. A strong Shine-Dalgarno sequence is followed by an open reading frame which corresponds to a protein having a molecular weight of 70,954. The first 19 amino acid residues have the characteristics of a signal peptide. The 3' untranslated sequence contains two putative rho-independent transcription terminators having low thermodynamic stability.

Specific location of penicillin-binding proteins within the cell envelope of Escherichia coli

This communication deals with the location of penicillin-binding proteins in the cell envelope of Escherichia coli. For this purpose, bacterial cells have been broken by various procedures and their envelopes have been fractioned. To do so, inner (cytoplasmic) and outer membranes were separated by isopycnic centrifugation in sucrose gradients. Some separation methods (Osborn et al., J. Biol. Chem. 247:3962-3972, 1972; J. Smit, Y. Kamio, and H. Nikaido, J. Bacteriol. 124:942-958, 1975) revealed that penicillin-binding proteins are not exclusively located in the inner membrane. They are also found in the outer membrane (A. Rodríguez-Tébar, J. A. Barbas, and D. Vásquez, J. Bacteriol. 161:243-248, 1985). Under the milder conditions for cell rupture used in this work, an intermembrane fraction, sedimenting between the inner and outer membrane, can be recovered from the gradients. This fraction has a high content of both penicillin-binding proteins and phospholipase B activity and may correspond to the intermembrane adhesion sites (M. H. Bayer, G. P. Costello, and M. E. Bayer, J. Bacteriol. 149:758-769, 1982). We postulate that this intermembrane fraction is a labile structure that contains a high amount of all penicillin-binding proteins which are usually found in both the inner and outer membranes when the adhesion sites are destroyed by the cell breakage and fractionation procedures.

Protein translocation across and integration into membranes

This review concentrates mainly on the translocation of proteins across the endoplasmic reticulum membrane and cytoplasmic membrane in bacteria. It will start with a short historical review and will pinpoint the crucial questions in the field. Special emphasis will be given to the present knowledge on the molecular details of the first steps, i.e., on the function of the signal recognition particle and its receptor. The knowledge on the signal peptidase and the ribosome receptor(s) will also be summarized. The various models for the translocation of proteins across and the integration of proteins into membranes will be critically discussed. In particular, the function of signal, stop-transfer, and insertion sequences will be dealt with and molecular differences discussed. The cotranslational mode of membrane transfer will be compared with the post-translational transport found for mitochondria and chloroplasts. This review will conclude with open questions and an outlook.

Localization of hydrolytic enzymes in Acinetobacter calcoaceticus

The localization of hydrolytic enzymes, phosphatase, esterase, lipase and palmitoyl-CoA hydrolase was analysed in the cytosol, cytoplasmic membrane, periplasmic fraction, outer membrane and culture supernatant in dependence on the growth rate of the bacteria. The unspecific phosphatase was found to be a cytosolic enzyme. A lipase was the only extracellular enzyme detected. The results pointed to a secretion of the lipase into the culture medium via cytoplasmic and outer membrane. The palmitoyl-CoA hydrolase was found to be attached to the outer membrane, but activities were also detected in the periplasmic fraction. Unspecific esterolytic activities were mainly measured in the cytosol and in the cytoplasmic membrane.

Processing and secretion of a mutant yolk polypeptide in Drosophila

Flies homozygous for the female sterile mutation fs(1)1163 produce eggs deficient in YP1, one of the three major yolk polypeptides. Genetic studies showed that fs(1)1163 is cis acting on YP1 quantity, so that mutation does not control a diffusible substance regulating YP1 production. The sterility and YP1 quantity phenotypes were not genetically separated from each other or from the structural gene for YP1, indicating that the mutation is located in or near Yp1. The amount of translatable YP1 message in mutant and wild-type cells was approximately equal, but the primary translation products were different in size and, hence, different in structure. The signal peptide was cleaved normally from the mutant polypeptide, and phosphorylation and glycosylation of the mutant YP1 also occur. However, YP1 processing intermediates that are transient in wild-type cells become major species in fs(1)1163 cells. We conclude that fs(1)1163 alters the primary structure of YP1 in a way that does not block signal-peptide cleavage but does alter later processing steps and hence its rate of secretion, leading to the YP1 deficiency found in the hemolymph and eggs.

Binding of pea cytochrome f to the inner membrane of Escherichia coli requires the bacterial secA gene product

Various sequences from the 5' end of the pea chloroplast gene for cytochrome f have been fused in the correct reading frame with lacZ, and the cellular location of the hybrid polypeptides in Escherichia coli has been examined. Hybrid polypeptides containing N-terminal parts of cytochrome f are located in the cytoplasmic membrane of E. coli. Membrane localization is most efficient when the intact signal sequence of cytochrome f is present at the N-terminal end of the fusion proteins. Fusion within the signal sequence, so that the processing site is absent, reduces the efficiency of membrane binding. Membrane insertion of fusion proteins containing signal sequences is prevented in a temperature-sensitive secA strain at the nonpermissive temperature and the hybrid proteins accumulate in the cytoplasm. This indicates that specific recognition of the chloroplast signal sequence occurs in the bacterial secretory pathway.

Transcriptional regulation of a periodically controlled flagellar gene operon in Caulobacter crescentus

Temporal regulation of flagellar gene expression in Caulobacter crescentus has been examined by a detailed analysis of the flbG-flaJ-flbH-flaK hook operon. The approximate location of the promoter for this 4.4 X 10(3) base-pair transcriptional unit was determined by deletion mapping, and the flaK gene was shown by nucleotide sequencing to code for the hook protein. flaK messenger RNA was quantified by S1 nuclease mapping with an internal restriction fragment of the gene as the 5'-labeled DNA probe. The results of these assays provide the first direct evidence that periodic expression of a flagellar gene in the C. crescentus cell cycle is regulated at the transcriptional level. The effect of altering the time of gene duplication in the cell cycle was examined by subcloning the complete hook operon on a plasmid that replicates throughout the S phase. The normal periodicity of flaK transcription and translation was maintained in this merodiploid strain, which suggests that replication alone is not sufficient to initiate flagellar gene expression. We also show that the three adjacent transcriptional units III, IV and V are required in trans for transcription of the book operon, and we discuss the possible role of these genes in the hierarchical regulation of the flagellar gene expression.

In vivo and in vitro synthesis of Escherichia coli maltose-binding protein under regulatory control of the lacUV5 promoter-operator

It has not been possible to obtain in vitro expression of the positively regulated malE gene encoding the periplasmic maltose-binding protein (MBP) of Escherichia coli. To facilitate in vitro malE expression, we constructed plasmids that place the malE gene under transcriptional control of the lacUV5 promoter-operator. These plasmids could be grouped into three classes, based upon their ability to complement in vivo a chromosomal malE deletion in the presence or absence of isopropyl thiogalactoside. In the one class I plasmid analyzed, the lacUV5-malE junction was just 3' to the malE ATG initiation codon, and this plasmid did not complement the malE deletion. Class II and class III plasmids retained various amounts of the malE promoter. MBP synthesis was solely under control of the lacUV5 promoter in the class II plasmids, and MBP synthesis was under control of both the lacUV5 and malE promoters in the class III plasmids. A malE mutation that renders the MBP signal peptide export defective was genetically recombined onto one of the class II plasmids. The in vivo synthesis and export of plasmid-encoded MBP were studied in the presence and absence of isopropyl thiogalactoside and maltose and in a strain harboring a prlA mutation that suppresses the malE signal sequence mutation and is thought to alter the export machinery of cells. In addition, both class II and class III plasmids programmed the synthesis of precursor MBP in an in vitro-coupled transcription-translation system. When precursor MBP was synthesized in vitro in the presence of E. coli membrane vesicles, a significant portion of wild-type precursor MBP, but not export-defective precursor MBP, was converted to a form that migrated on sodium dodecyl sulfate-polyacrylamide gels identically to mature MBP synthesized in vivo.

Multiple mechanisms of protein insertion into and across membranes

Protein localization in cells is initiated by the binding of characteristic leader (signal) peptides to specific receptors on the membranes of mitochondria or endoplasmic reticulum or, in bacteria, to the plasma membrane. There are differences in the timing of protein synthesis and translocation into or across the bilayer and in the requirement for a transmembrane electrochemical potential. Comparisons of protein localization in these different membranes suggest underlying common mechanisms.

Single-site chromosomal Tn5 insertions affect the export of pectolytic and cellulolytic enzymes in Erwinia chrysanthemi EC16

Exponentially growing cells of Erwinia chrysanthemi EC16 usually export about 98% of their pectate lyase (PL) and protease, about 40% of their polygalacturonase (PG), and about 60% of their cellulase (endoglucanase or carboxymethyl cellulase; CL). By using the R plasmid, pJB4JI (pPH1JI::Mu::Tn5), three independent Tn5 insertion mutants were obtained that exported normal levels of protease but 10% or less of PL, PG, and CL. Physical analysis revealed that single copies of Tn5 had inserted into the E. chrysanthemi chromosome, producing a similar export-defective (Out-) phenotype. The synthesis of PL, PG, and CL was not affected by the Tn5 insertions. These enzymes were released from the mutants on spheroplast formation, indicating that they were located in the periplasmic space. Tn5 insertions caused the loss of a 35-kilodalton periplasmic protein, but did not alter the outer membrane protein composition. The findings are discussed with respect to the current knowledge on protein export in gram-negative bacteria.

Cloning and sequence analysis of a cDNA encoding porcine mitochondrial aspartate aminotransferase precursor

The primary structure of pig mitochondrial aspartate aminotransferase (mAspATase; L-aspartate:2-oxoglutarate aminotransferase, EC 2.6.1.1) precursor was deduced from its cDNA sequence. A library of cDNA clones was constructed from pig liver poly(A)+ RNA by applying the vector/primer method of Okayama and Berg [Okayama, H. & Berg, P. (1982) Mol. Cell. Biol. 2, 161-170]. The library was screened for pig mAspATase sequences by using a mixture of eight oligodeoxyribonucleotides as a probe. The sequences of the probe were deduced from the known amino acid sequence of pig mAspATase residues 196-201. Two recombinant plasmids containing inserts of about 2500 and 2600 base pairs were selected for sequence analysis. The amino acid sequence predicted from the cDNA sequence shows that the pig mAspATase precursor consists of the mature enzyme of 401 amino acid residues and an amino-terminal segment of 29 amino acid residues called the "presequence" that contains four basic amino acid residues, no acidic residues, and no hydrophobic amino acid stretch. The sequence of this 29-amino acid mAspATase precursor segment was compared with the presequences of other mitochondrial enzymes.

Final steps of the maturation of Omp F, a major protein from the outer membrane of Escherichia coli

Pulse-labelling experiments with E. coli cells allowed us to follow the incorporation of de novo proteins into the outer membrane of the cell envelope. Labelled membrane samples containing increasingly different levels of newly synthesized Omp F protein were subjected to chemical cross-linking with a bifunctional cleavable reagent in order to investigate the process of trimer formation of the protein. From the results obtained, we conclude that the formation of functional Omp F trimers is substantially delayed to, and can be distinguished from, the incorporation of Omp F monomers to the outer membrane.

Direct selection of mutations reducing transcription or translation of the recA gene of Escherichia coli with a recA-lacZ protein fusion

When a recA-lacZ protein fusion was cloned into phage lambda, the resulting transducing phage grew normally on wild-type Escherichia coli, but its growth was severely inhibited in lexA(Def) mutant strains that express recA constitutively at high levels. Mutants of the transducing phage that grew on the lexA(Def) strains were isolated and were found to affect production of the RecA-beta-galactosidase hybrid protein. Most mutants, including a number of nonsense mutants, were phenotypically LacZ-. LacZ+ mutants were also isolated; most of these expressed lower basal and induced levels of beta-galactosidase activity. DNA sequence analysis revealed that some of the LacZ+ mutations were in the recA promoter. One of these was found to prevent induction. Unexpectedly, three of the mutations that reduced expression were located in the recA structural gene, at codons 10, 11, and 12. Further analysis of the codon 10 mutant showed that it most likely affected translation since it had little effect on transcription as measured by beta-galactosidase synthesis from a recA-lacZ operon fusion. This expression defect was not limited to the protein fusion, since the codon 10 mutation also reduced synthesis of RecA protein when present in a complete recA gene. Analysis of the recA DNA sequence in the fusion revealed that each of the mutations at codons 10, 11, and 12 increases the homology between this region of the mRNA and a sequence found at codons 1 to 4. Thus, the secondary structure of the mutant recA mRNAs may be affecting translation.

Biosynthetic arginine decarboxylase in Escherichia coli is synthesized as a precursor and located in the cell envelope

The biosynthetic form of arginine decarboxylase (ADC) catalyzes the synthesis of agmatine, a precursor of putrescine, in Escherichia coli. Selective disruption of the cell envelope and an assessment of ADC activity or immunoprecipitable ADC in various fractions demonstrated its location between the cytoplasmic membrane and peptidoglycan layer. Expression in minicells of the speA gene encoding ADC resulted in the production of two immunoprecipitable species (74 and 70 kilodaltons). Studies in vivo with a pulse and chase of radiolabeled amino acid into the two species suggest a precursor-product relationship. This relationship was corroborated by demonstrating the accumulation of the 74-kilodalton species in a strain of E. coli unable to process signal sequences. Peptide mapping experiments with V8 protease, trypsin, and alpha-chymotrypsin demonstrated that the two species of ADC were very similar except for a minor difference. These data were used to substantiate the compartmentalization hypothesis as to how exogenous arginine can be channeled preferentially into putrescine.

Synthesis and localization of a development-specific protein in sclerotia of Sclerotinia sclerotiorum

A development-specific protein (SSP) makes up about 35 to 40% of the total protein in sclerotia of the fungus Sclerotinia sclerotiorum. The protein consists of three charge isomers, with one isomer making up 80 to 90% of the total. In vitro translation of poly(A)+ RNA isolated from cells in early stages of sclerotia formation revealed that 44% of the amino acids incorporated was into SSP. In vivo- and in vitro-synthesized forms of SSP migrated at identical rates on both isoelectric focusing and denaturing polyacrylamide gels, indicating that SSP was not synthesized as a larger precursor. This was significant because SSP accumulated in membrane-bound, organellelike structures which resemble protein bodies found in seeds of many higher plants.

Processing of the precursor to a chloroplast ribosomal protein made in the cytosol occurs in two steps, one of which depends on a protein made in the chloroplast

In pulse-chase experiments in which log-phase cells of Chlamydomonas reinhardtii were labeled in vivo for 5 min with H2(35)SO4, fluorographs of immunoprecipitates from whole cell extracts revealed that chloroplast ribosomal proteins L-2, L-6, L-21, and L-29, which are made in the cytosol and imported, appeared in their mature forms. However, in the case of chloroplast ribosomal protein L-18, which is also made in the cytoplasm and imported, a prominent precursor with an apparent molecular weight of 17,000 was found at the end of a 5-min pulse. This precursor was processed to its mature size (apparent molecular weight of 15,500) within the first 5 min of the subsequent chase. As determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the precursor to L-18 formed in vivo was 1.5 kilodaltons smaller than the primary product detected in translations of Chlamydomonas polyadenylated RNA in vitro. Upon a 10-min incubation with a postribosomal supernatant from Chlamydomonas, the 18,500-dalton precursor detected in vitro could be partially converted into a polypeptide that comigrated with the 17,000-dalton precursor detected in extracts of cells labeled in vivo. Under conditions in which the total amounts of chloroplast proteins had been reduced and cells were made to synthesize ribosomes rapidly, the apparent half-life of the 17,000-dalton precursor was extended over that seen in log-phase cells. When chloroplast protein synthesis was inhibited with lincomycin for 3 h before labeling under these conditions, the 17,000-dalton L-18 precursor but not the mature form was found, and the precursor was slowly degraded during a 60-min chase. When cells were placed in the dark for 3 h before labeling, processing of this precursor to the mature form appeared unaffected, but the chloroplast-synthesized ribosomal protein L-26 was detected, indicating that chloroplast protein synthesis was still occurring. We interpret these results to indicate that the maturation of protein L-18 in vivo involves at least two processing steps, one of which depends on a protein made on chloroplast ribosomes.

Nucleotide sequence of an Escherichia coli chromosomal hemolysin

We determined the DNA sequence of an 8,211-base-pair region encompassing the chromosomal hemolysin, molecularly cloned from an O4 serotype strain of Escherichia coli. All four hemolysin cistrons (transcriptional order, C, A, B, and D) were encoded on the same DNA strand, and their predicted molecular masses were, respectively, 19.7, 109.8, 79.9, and 54.6 kilodaltons. The identification of pSF4000-encoded polypeptides in E. coli minicells corroborated the assignment of the predicted polypeptides for hlyC, hlyA, and hlyD. However, based on the minicell results, two polypeptides appeared to be encoded on the hlyB region, one similar in size to the predicted molecular mass of 79.9 kilodaltons, and the other a smaller 46-kilodalton polypeptide. The four hemolysin gene displayed similar codon usage, which is atypical for E. coli. This reflects the low guanine-plus-cytosine content (40.2%) of the hemolysin DNA sequence and suggests the non-E. coli origin of the hemolysin determinant. In vitro-derived deletions of the hemolysin recombinant plasmid pSF4000 indicated that a region between 433 and 301 base pairs upstream of the putative start of hlyC is necessary for hemolysin synthesis. Based on the DNA sequence, a stem-loop transcription terminator-like structure (a 16-base-pair stem followed by seven uridylates) in the mRNA was predicted distal to the C-terminal end of hlyA. A model for the general transcriptional organization of the E. coli hemolysin determinant is presented.

Escherichia coli hemolysin is released extracellularly without cleavage of a signal peptide

A 110-kilodalton polypeptide isolated from cell-free culture supernatants of hemolytic Escherichia coli was shown to be associated with hemolytic activity. The relative amount of the extracellular 110-kilodalton species detected directly reflects the extracellular hemolysin activity associated with Escherichia coli strains harboring different hemolysin recombinant plasmids. The predicted molecular mass of the hemolysin structural gene (hlyA) based on DNA sequence analysis was 109,858 daltons. Amino-terminal amino acid sequence analysis of the 110-kilodalton polypeptide provided direct evidence that it was encoded by hlyA. Based on this information, it was also demonstrated that the HlyA polypeptide was released extracellularly without signal peptidase-like cleavage. An examination of hemolysin-specific polypeptides detected by use of recombinant plasmids in a minicell-producing strain of Escherichia coli was performed. These studies demonstrated how hemolysin-associated 110- and 58-kilodalton polypeptides detected in the minicell background could be misinterpreted as a precursor-product relationship.

ATP is essential for protein translocation into Escherichia coli membrane vesicles

The energy requirement for translocation of alkaline phosphatase and the outer membrane protein OmpA into Escherichia coli membrane vesicles was studied under conditions that permit posttranslational translocation and, hence, prior removal of various components necessary for protein synthesis. Translocation could be supported by an ATP-generating system or, less well, by the protonmotive force generated by D-lactate oxidation; the latter might act by generating ATP from residual bound nucleotides. However, when protonmotive force inhibitors were used or when ATP was further depleted by E. coli glycerol kinase, D-lactate no longer supported the translocation. Furthermore, ATP could still support protein translocation in the presence of proton uncouplers or with membranes defective in the F1 fraction of the H+-ATPase. We conclude that ATP is required for protein translocation in this posttranslational system (and probably also in cotranslational translocation); the protonmotive force may contribute but does not appear to be essential.

Defective secretion of maltose- and ribose-binding proteins caused by a truncated periplasmic protein in Escherichia coli

The secretion in Escherichia coli of a C-terminally truncated periplasmic enzyme from Salmonella typhimurium, the glpQ-encoded glycerolphosphate phosphodiesterase, was studied. Plasmid pRH100, carrying the truncated glpQ gene, directs the synthesis of a 30,000-molecular-weight (30 K) protein that is processed to a mature 27.5 K protein. (The mature wild-type protein is a 38 K protein.) The truncated protein is not released into the periplasm but remains membrane associated, although it becomes protease sensitive after conversion of cells to spheroplasts. The presence of pRH100 strongly reduces the amount of some other proteins in the periplasm, including the maltose- and ribose-binding proteins. The reduction does not occur at the level of transcription or early translation, as shown by lacZ fusions to the gene coding for the structural gene of the maltose-binding protein. Outer membrane proteins are not affected. A hydroxylamine-induced mutation in the sequence of glpQ corresponding to the mature polypeptide overcomes the inhibitory effect of pRH100. The mutated gene no longer directs the synthesis of the 30/27.5 K protein but directs that of a new 19 K protein which is not membrane bound. We propose that sorting signals in the mature GIpQ protein are necessary for effective translocation to the periplasm and that the C-terminal third of the protein is essential for release into the periplasm.

Selection for mutants altered in the expression or export of outer membrane porin OmpF

Strains in which the lacZ gene (which specifies beta-galactosidase) is fused to a gene encoding an envelope protein often exhibit a phenotype termed overproduction lethality. In such strains, high-level synthesis of the cognate hybrid protein interferes with the process of protein export, and this leads ultimately to cell death. A variation of this phenomenon has been discovered with lacZ fusions to the gene specifying the major outer membrane porin protein OmpF. In this case, we find that lambda transducing phage carrying an ompF-lacZ fusion will not grow on a host strain that constitutively overexpresses ompF. We have exploited this observation to develop a selection for ompF mutants. Using this protocol, we have isolated mutants altered in ompF expression and have identified mutations that block OmpF export. Our results suggest that it should be possible to adapt this selection for use with other genes specifying exported proteins.

Two major outer envelope glycoproteins of Epstein-Barr virus are encoded by the same gene

Two major outer envelope glycoproteins of Epstein-Barr virus, gp350 and gp220, are known to be encoded by 3.2- and 2.5-kilobase RNAs which map to the same DNA fragment (M. Hummel, D. Thorley-Lawson, and E. Kieff, J. Virol. 49:413-417). These RNAs have the same 5' and 3' ends. The larger RNA is encoded by a 2,777-base DNA segment which is preceded by TATTAAA, has AATAAA near its 3' end, and contains a 2,721-base open reading frame. The smaller RNA has one internal splice which maintains the same open reading frame. Translation of the 3.2- and 2.5-kilobase RNAs yielded proteins of 135 and 100 kilodaltons (Hummel et al., J. Virol. 49:413-417). The discrepancy between the 907 codons of the open reading frame and the 135-kilodalton size of the gp350 precursor is due to anomalous behavior of the protein in gel electrophoresis, since a protein translated from most of the Epstein-Barr virus open reading frame in Escherichia coli had similar properties. Antisera raised in rabbits to the protein expressed in E. coli specifically immunoprecipitated gp350 and gp220, confirming the mapping and sequencing results and the translational reading frame. The rabbit antisera also reacted with the plasma membranes of cells that were replicating virus and neutralized virus, particularly after the addition of complement. This is the first demonstration that the primary amino acid sequence of gp350 and gp220 has epitopes which can induce neutralizing antibody. We propose a model for the gp350 protein based on the theoretical analysis of its primary sequence.

Transposable lambda placMu bacteriophages for creating lacZ operon fusions and kanamycin resistance insertions in Escherichia coli

We have constructed several derivatives of bacteriophage lambda that translocate by using the transposition machinery of phage Mu (lambda placMu phages). Each phage carries the c end of Mu, containing the Mu cIts62, ner (cII), and A genes, and the terminal sequences from the Mu S end (beta end). These sequences contain the Mu attachment sites, and their orientation allows the lambda genome to be inserted into other chromosomes, resulting in a lambda prophage flanked by the Mu c and S sequences. These phages provide a means to isolate cells containing fusions of the lac operon to other genes in vivo in a single step. In lambda placMu50, the lacZ and lacY genes, lacking a promoter, were located adjacent to the Mu S sequence. Insertion of lambda placMu50 into a gene in the proper orientation created an operon fusion in which lacZ and lacY were expressed from the promoter of the target gene. We also introduced a gene, kan, which confers kanamycin resistance, into lambda placMu50 and lambda placMu1, an analogous phage for constructing lacZ protein fusions (Bremer et al., J. Bacteriol. 158:1084-1093, 1984). The kan gene, located between the cIII and ssb genes of lambda, permitted cells containing insertions of these phages to be selected independently of their Lac phenotype.

In vivo function and membrane binding properties are correlated for Escherichia coli lamB signal peptides

Wild-type and pseudorevertant signal peptides of the lamB gene product of Escherichia coli interact with lipid systems whereas a nonfunctional deletion mutant signal peptide does not. This conclusion is based on interaction of synthetic signal peptides with a lipid monolayer-water surface, conformational changes induced by presence of lipid vesicles in an aqueous solution of signal peptide, and capacities of the peptides to promote vesicle aggregation. Analysis of the signal sequences and previous conformational studies suggest that these lipid interaction properties may be attributable to the tendency of the functional signal peptides to adopt alpha-helical conformations. Although the possibility of direct interaction between the signal peptide and membrane lipids during protein secretion is controversial, the results suggest that conformationally related amphiphilicity and consequent membrane affinity of signal sequences are important for function in vivo.

Physical and genetic map of a Rhizobium meliloti nodulation gene region and nucleotide sequence of nodC

Infection of alfalfa by the soil bacterium Rhizobium meliloti proceeds by deformation of root hairs and bacterial invasion of host tissue by way of an infection thread. We studied an 8.7-kilobase (kb) segment of the R. meliloti megaplasmid, which contains genes required for infection. Site-directed Tn5 mutagenesis was used to examine this fragment for nodulation genes. A total of 81 R. meliloti strains with mapped Tn5 insertions in the 8.7-kb fragment were evaluated for nodulation phenotype on alfalfa plants; 39 of the insertions defined a 3.5-kb segment containing nodulation functions. Of these 39 mutants, 37 were completely nodulation deficient (Nod-), and 2 at the extreme nif-distal end were leaky Nod-. Complementation analysis was performed by inoculating plants with strains carrying a genomic Tn5 at one location and a plasmid-borne Tn5 at another location in the 3.5-kb nodulation segment. Mutations near the right border of the fragment behaved as two distinct complementation groups. The segment in which these mutations are located was analyzed by DNA sequencing. Several open reading frames were found in this region, but the one most likely to function is 1,206 bases long, reading from left to right (nif distal to proximal) and spanning both mutation groups. The genetic behavior of this segment may be due either to the gene product having two functional domains or to a recombinational hot spot between the apparent complementation groups.

Processing of the precursor to a chloroplast ribosomal protein made in the cytosol occurs in two steps, one of which depends on a protein made in the chloroplast

In pulse-chase experiments in which log-phase cells of Chlamydomonas reinhardtii were labeled in vivo for 5 min with H2(35)SO4, fluorographs of immunoprecipitates from whole cell extracts revealed that chloroplast ribosomal proteins L-2, L-6, L-21, and L-29, which are made in the cytosol and imported, appeared in their mature forms. However, in the case of chloroplast ribosomal protein L-18, which is also made in the cytoplasm and imported, a prominent precursor with an apparent molecular weight of 17,000 was found at the end of a 5-min pulse. This precursor was processed to its mature size (apparent molecular weight of 15,500) within the first 5 min of the subsequent chase. As determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, the precursor to L-18 formed in vivo was 1.5 kilodaltons smaller than the primary product detected in translations of Chlamydomonas polyadenylated RNA in vitro. Upon a 10-min incubation with a postribosomal supernatant from Chlamydomonas, the 18,500-dalton precursor detected in vitro could be partially converted into a polypeptide that comigrated with the 17,000-dalton precursor detected in extracts of cells labeled in vivo. Under conditions in which the total amounts of chloroplast proteins had been reduced and cells were made to synthesize ribosomes rapidly, the apparent half-life of the 17,000-dalton precursor was extended over that seen in log-phase cells. When chloroplast protein synthesis was inhibited with lincomycin for 3 h before labeling under these conditions, the 17,000-dalton L-18 precursor but not the mature form was found, and the precursor was slowly degraded during a 60-min chase. When cells were placed in the dark for 3 h before labeling, processing of this precursor to the mature form appeared unaffected, but the chloroplast-synthesized ribosomal protein L-26 was detected, indicating that chloroplast protein synthesis was still occurring. We interpret these results to indicate that the maturation of protein L-18 in vivo involves at least two processing steps, one of which depends on a protein made on chloroplast ribosomes.

Mutations in the cytoplasmic domain of the influenza virus hemagglutinin affect different stages of intracellular transport

Mutations have been introduced into the cloned DNA sequences coding for influenza virus hemagglutinin (HA), and the resulting mutant genes have been expressed in simian cells by the use of SV40-HA recombinant viral vectors. In this study we analyzed the effect of specific alterations in the cytoplasmic domain of the HA molecule on its rate of biosynthesis and transport, cellular localization, and biological activity. Several of the mutants displayed abnormalities in the pathway of transport from the endoplasmic reticulum to the cell surface. One mutant HA remained within the endoplasmic reticulum; others were delayed in reaching the Golgi apparatus after core glycosylation had been completed in the endoplasmic reticulum, but then progressed at a normal rate from the Golgi apparatus to the cell surface; another was delayed in transport from the Golgi apparatus to the plasma membrane. However, two mutants were indistinguishable from wild-type HA in their rate of movement from the endoplasmic reticulum through the Golgi apparatus to the cell surface. We conclude that changes in the cytoplasmic domain can powerfully influence the rate of intracellular transport and the efficiency with which HA reaches the cell surface. Nevertheless, absolute conservation of this region of the molecule is not required for maturation and efficient expression of a biologically active HA on the surface of infected cells.

Cell-bound and secreted proteases of Serratia marcescens

Exoprotease of Serratia marcescens ATCC 25419 is exceptional among members of the family Enterobacteriaceae in that it is secreted in large amounts by viable cells into the culture medium. Labeling of cells with radioactive amino acids revealed no intracellular protein that could be precipitated with antibodies raised against purified exoproteases. With substances known to interfere with the excretion of some proteins--tosyl-L-lysine chloromethyl ketone, phenethyl alcohol, procaine, and sodium azide--and with rifampin, an intracellular form (apparent molecular weight, 52,000) larger than the major exoform (molecular weight, 51,000) was identified. Moreover, the 52,000-molecular-weight form was the main protein in immunoprecipitates of a cysteine-auxotrophic mutant starved for cysteine. Beside the major exoform, protease I, two additional exoproteases, termed II and III, appeared in the medium of stationary cultures. They were precipitated by antibodies against protease I, were identical in the Ouchterlony double-diffusion assay, and exhibited only a small difference, if any at all, in the peptide pattern after partial hydrolysis with protease V8 of Staphylococcus aureus. The amino- and carboxy-terminal amino acid sequences of protease I and II were determined and found to be identical, NH2-Ala-Ala-Thr-Gly-Gly-Tyr-Asp-Ala-Val-Asp and Phe-Ile-Val-COOH, respectively. The microheterogeneity of the isolated exoforms revealed by anion-exchange chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis was also observed in samples pulse-labeled with radioactive amino acids. It remains to be determined whether the different protease forms are the result of processing (modification) reactions or whether they constitute isoenzymes encoded by very similar genes.

Protein export by a gram-negative bacterium: production of aerolysin by Aeromonas hydrophila

The synthesis and export of aerolysin, an extracellular protein toxin released by the gram-negative bacterium Aeromonas hydrophila, was studied by pulse-labeling with [35S]methionine. The toxin was synthesized as a higher-molecular-weight precursor. This was processed cotranslationally, resulting in the appearance within the cell of the mature protein, which was then exported to the supernatant. Precursor aerolysin accumulated in cells incubated in the presence of carbonyl cyanide m-chlorophenyl hydrazone, a substance which also inhibited the export of mature aerolysin from the cell. The entrapped mature toxin could not be shocked from the cells, although it could be digested by protease applied to shocked cells. The toxin was processed and translocated across the inner membrane of pleiotropic export mutants and accumulated in the periplasm. The results indicate that more than one step is required for the export of the protein and that aerolysin does not cross the inner and outer membranes simultaneously.

Molecular cloning and sequence analysis of a chondroitin sulfate proteoglycan cDNA

We report the identification and DNA sequence of a chondroitin sulfate proteoglycan core protein cDNA. A cDNA clone, pPG1, was selected from a rat yolk sac tumor poly(A)+RNA-derived cDNA library by using synthetic oligonucleotides predicted from the NH2-terminal peptide sequence of the mature chondroitin sulfate proteoglycan. The resulting sequence analysis demonstrated that the 874-base-pair pPG1 clone contained the complete coding region of the mature proteoglycan core protein as well as 5' and 3' flanking sequences. The 104 amino acid proteoglycan core protein sequence reveals that the core protein is composed of three regions, the most striking of which is the central 49 amino acid region composed of alternating serine and glycine residues. This region clearly functions as the acceptor site for the attachment of chondroitin sulfate side chains. The serine-glycine repeat region is flanked by a 14 amino acid NH2-terminal region identical to the NH2-terminal sequence of the proteoglycan obtained by amino acid sequencing and a 41 amino acid COOH-terminal region. RNA transfer blot hybridizations of poly(A)+ mRNA from rat yolk sac tumor cells with nick-translated pPG1 reveal a single mRNA of approximately equal to 1300 nucleotides. The possibility of detecting mRNAs and genomic sequences for other proteoglycans with a serine-glycine repeat by using this cDNA clone is discussed.

Alkaline phosphatase and OmpA protein can be translocated posttranslationally into membrane vesicles of Escherichia coli

We previously described a system for translocating the periplasmic enzyme alkaline phosphatase and the outer membrane protein OmpA into inverted membrane vesicles of Escherichia coli. We have now optimized and substantially improved the translocation system by including polyamines and by reducing the amount of membrane used. Under these conditions, efficient translocation was seen even posttranslationally, i.e., when vesicles were not added until after protein synthesis was stopped. This was the case not only with the OmpA protein, which is synthesized by free polysomes and hence is presumably exported posttranslationally in the cell, but also with alkaline phosphatase, which is synthesized only by membrane-bound polysomes and has been shown to be secreted cotranslationally in the cells. Prolonged incubation rendered the precursors inactive for subsequent translocation. Posttranslational translocation was impaired, like cotranslational translocation, by inhibitors of the proton motive force and by treatment of the vesicles with protease. Since it appears that E. coli can translocate the same proteins either cotranslationally or posttranslationally, the cotranslational mode may perhaps be more efficient, but not obligatory, for the secretion of bacterial proteins.

Two alkaline phosphatase genes positioned in tandem in Bacillus licheniformis MC14 require different RNA polymerase holoenzymes for transcription

Southern transfer analysis of Bacillus licheniformis MC14 DNA, using as probe a DNA fragment from within the coding region of a previously cloned alkaline phosphatase (APase) gene, revealed a second area of hybridization adjacent to the cloned APase gene. A second APase gene (APase II) was subcloned from the same plasmid clone, pMH8, from which the first APase gene (APase I) had been subcloned. The two genes are arranged in tandem with several hundred base pairs separating them. Immunoblot analysis showed that both code for Mr 60,000 proteins that crossreact with anti-APase. Both proteins enzymatically cleave 5-bromo-4-chloro-3-indolyl phosphate. In vitro transcription showed that APase I and APase II are transcribed in the same direction but that the two genes require different forms of Bacillus RNA polymerase: sigma 55- and sigma 37-containing RNA polymerase holoenzymes, respectively.

Invertase beta-galactosidase hybrid proteins fail to be transported from the endoplasmic reticulum in Saccharomyces cerevisiae

The yeast SUC2 gene codes for the secreted enzyme invertase. A series of 16 different-sized gene fusions have been constructed between this yeast gene and the Escherichia coli lacZ gene, which codes for the cytoplasmic enzyme beta-galactosidase. Various amounts of SUC2 NH2-terminal coding sequence have been fused in frame to a constant COOH-terminal coding segment of the lacZ gene, resulting in the synthesis of hybrid invertase-beta-galactosidase proteins in Saccharomyces cerevisiae. The hybrid proteins exhibit beta-galactosidase activity, and they are recognized specifically by antisera directed against either invertase or beta-galactosidase. Expression of beta-galactosidase activity is regulated in a manner similar to that observed for invertase activity expressed from a wild-type SUC2 gene: repressed in high-glucose medium and derepressed in low-glucose medium. Unlike wild-type invertase, however, the invertase-beta-galactosidase hybrid proteins are not secreted. Rather, they appear to remain trapped at a very early stage of secretory protein transit: insertion into the endoplasmic reticulum (ER). The hybrid proteins appear only to have undergone core glycosylation, an ER process, and do not receive the additional glycosyl modifications that take place in the Golgi complex. Even those hybrid proteins containing only a short segment of invertase sequences at the NH2 terminus are glycosylated, suggesting that no extensive folding of the invertase polypeptide is required before initiation of transmembrane transfer. beta-Galactosidase activity expressed by the SUC2-lacZ gene fusions cofractionates on Percoll density gradients with ER marker enzymes and not with other organelles. In addition, the hybrid proteins are not accessible to cell-surface labeling by 125I. Accumulation of the invertase-beta-galactosidase hybrid proteins within the ER does not appear to confer a growth-defective phenotype to yeast cells. In this location, however, the hybrid proteins and the beta-galactosidase activity they exhibit could provide a useful biochemical tag for yeast ER membranes.

Identification of five new essential genes involved in the synthesis of a secreted protein in Escherichia coli

To define additional components of the export machinery of Escherichia coli, I have isolated extragenic suppressors of a mutant [secA(Ts)] that is temperature sensitive for growth and secretion at 37 degrees C. Suppressors that restored growth at 37 degrees C, but that rendered the cell cold sensitive for growth at 28 degrees C, were obtained. The suppressor mutations fall into at least seven loci, two of which (prlA and secC) have been previously implicated in protein secretion. The five remaining loci (ssaD, ssaE, ssaF, ssaG, and ssaH) have been mapped by P1 transduction and appear to define new genes in E. coli. All of the suppressor mutations allow both enhanced growth and protein secretion of the secA(Ts) mutant at 37 degrees C, but not 42 degrees C, indicating a continued requirement for SecA protein. Strains carrying solely the cold-sensitive mutations show reduced levels of certain periplasmic proteins when grown at low temperatures. In at least one case, that of maltose-binding protein, this defect is at the level of synthesis of the protein. Since mutants in any of seven genes as well as secA amber mutants halt or reduce the synthesis of an exported protein, it appears that E. coli may possess a general and complex mechanism for coupling protein synthesis and secretion.