A SecE mutation that modulates SecY-SecE translocase assembly,identified as a specific suppressor of SecY defects

The SecY39(Cs) (cold-sensitive) alteration of Arg357 results in a defect of translocation initiation. As a means to dissect the Sec translocation machinery, we isolated mutations that act as suppressors of the secY39 defect. A specific secE mutation, designated secE105, was thus isolated. This mutation proved to be identical with the prlG2 mutation and to suppress a number of cold-sensitive secY mutations. However, other prlG mutations did not effectively suppress the secY defects. Evidence indicates that the Ser105-to-Pro alteration in the C-terminal transmembrane segment of SecE weakens SecY-SecE association. In vitro analyses showed that the SecE(S105P) alteration preferentially stimulates the initial phase of translocation. It is suggested that the S105P alteration affects the SecYEG channel such that it is more prone to open and to accept the translocation initiation domain of a preprotein molecule.     

Inactivation of protein translocation by cold-sensitive mutations in the yajC-secDF operon

Most mutations in the yajC-secDF operon identified via genetic screens confer a cold-sensitive growth phenotype. Here we report that two of these mutations confer this cold-sensitive phenotype by inactivating the SecDF-YajC complex in protein translocation.     

A Mutation Affecting the Regulation of a Seca-Lacz Fusion Defines a New Sec Gene

It was shown previously that the secA gene of Escherichia coli is derepressed in cells that have a defect in protein export. Here it is demonstrated that the beta-galactosidase produced by a secA-lacZ gene fusion strain is regulated in the same way. Studies on the fusion strain reveal that the promoter or a site involved in regulation of the secA gene is located considerably upstream from the structural gene. The properties of the fusion strain provide a new selection for mutants that are defective in protein export. Selection for increased lac expression of a secA-lacZ fusion strain yields mutations in three of the known sec genes, secA, secD and prlA/secY. In addition, mutations in several genes not previously known to affect secA expression were obtained. A mutation in one of these genes causes a pleiotropic defect in protein export and a cold-sensitive growth defect; this gene, which maps at approximately 90 min on the bacterial chromosome, has been named secE.     

One of three transmembrane stretches is sufficient for the functioning of the SecE protein, a membrane component of the E. coli secretion machinery.

The E. coli secE (prlG) gene codes for an integral cytoplasmic membrane protein which is part of the cell's secretory machinery. A deletion of nearly the entire gene renders the cell dependent on the presence of a complementing secE+ plasmid, indicating that the SecE protein is essential for growth. Deletions which remove carboxy-terminal sequences or substantial amounts near the amino-terminus of SecE can still complement the lethal deletion. This deletion analysis suggests that the essential domain of the SecE protein includes only a single one of its three hydrophobic membrane-spanning segments. Two of three dominant prlG signal sequence suppressors map to this segment. Consistent with the insensitivity of SecE to major structural changes, several cold-sensitive mutations cause lethality not because of any change in the protein, but because of a reduction in its level of expression. Our results suggest that higher levels of the protein are needed at the lower temperature. These findings are discussed in terms of the interactions between various components of the secretory machinery.     

Suppressors of the secY24 mutation: identification and characterization of additional ssy genes in Escherichia coli

We previously reported (Shiba et al., J. Bacteriol. 160:696-701, 1984) the isolation and characterization of the mutation (ssy) that suppresses the protein export defect due to the secY24(Ts) mutation and causes cold-sensitive growth of Escherichia coli. This report describes more systematic isolation of ssy mutations. Among temperature-resistant revertants of the secY24 mutant, 65 mutants were found to be cold sensitive. These cold-sensitive mutations have been classified by genetic mapping. Twenty-two mutations fell into the ssyA class previously described. The remaining mutations were located at five new loci: ssyB at 9.5 min between tsx and lon; ssyD around 3 min; ssyE at 72.5 min near secY; ssyF at 20.5 min within rpsA; and ssyG at 69.0 min near argG. Two predominant classes, ssyA and ssyB, are probably affected in protein synthesis at the elongation step, whereas the ssyF mutant contained an altered form of ribosomal protein S1 (the gene product of rpsA). These cold-sensitive ssy mutations which suppress secY24 may define genes whose function is somehow involved in the secY-dependent protein secretion mechanism. However, the existence of multiple suppressor loci makes it unlikely that all of these genes specify additional components of the export machinery. A delicate balance may exist between the systems for synthesizing and exporting proteins.     

Multicopy suppression: an approach to understanding intracellular functioning of the protein export system.

Escherichia coli genes were cloned onto a multicopy plasmid and selected by the ability to restore growth and protein export defects caused by a temperature-sensitive secY or secA mutation. When secA51 was used as the primary mutation, only clones carrying groE, which specifies the chaperonin class of heat shock protein, were obtained. Selection using secY24 yielded three major classes of genes. The first class encodes another heat shock protein, HtpG; the most frequently obtained second class encodes a neutral histonelike protein, H-NS; and the third class, msyB, encodes a 124-residue protein of which 38 residues are acidic amino acids. Possible mechanisms of suppression as well as the significance and limitations of the multicopy suppression approach are discussed.     

Altered translation initiation factor 2 in the cold-sensitive ssyG mutant affects protein export in Escherichia coli.

The Escherichia coli gene secY (pr1A) codes for an integral membrane protein that plays an essential role in protein export. We previously isolated cold-sensitive mutations (ssy) as extragenic suppressors of temperature-sensitive secY24 mutation. Now we show that the ssyG class of mutations are within infB coding for the translation initiation factor IF2. The mutants produce altered forms of IF2 with a cold-sensitive in vitro activity to form a translation initiation complex. The mutation suppresses not only secY24 but also other secretion-defective mutations such as secA51 and rp10215. The beta-galactosidase enzyme activity of the MalE-LacZ 72-47 hybrid protein is strikingly reduced in the ssyG mutant at the permissive high temperature, while the hybrid protein itself is normally synthesized. This effect, which was observed only for the hybrid protein with a functional signal sequence, may result from some alteration in the cellular localization of the protein. These results suggest that IF2 or the translation initiation step can modulate protein export reactions. The isolation of cold-sensitive ssyG mutations in infB provides genetic evidence that IF2 is indeed essential for normal growth of E. coli cells.     

Export of the outer membrane lipoprotein is defective in secD, secE, and secF mutants of Escherichia coli.

The export of major outer membrane lipoprotein has been found to be affected in secD, secE, and secF mutants of Escherichia coli, which are defective in protein export in general. After a shift to the nonpermissive temperature, the kinetics of accumulation of prolipoprotein and pre-OmpA protein was indistinguishable from that of pre-OmpA protein accumulation in the secD and secF mutants but different in the secE mutant. The prolipoprotein accumulated in the secD, secE, and secF mutants at the nonpermissive temperature was not modified with glyceride. We conclude from these results and those of previous studies that the export of lipoprotein requires all common sec gene products except the SecB protein, i.e., the SecA, SecD, SecE, SecF, and SecY proteins.     

PrlA and PrlG suppressors reduce the requirement for signal sequence recognition.

Selection for suppressors of defects in the signal sequence of secretory proteins has led most commonly to identification of prlA alleles and less often to identification of prlG alleles. These genes, secY/prlA and secE/prlG, encode integral membrane components of the protein translocation system of Escherichia coli. We demonstrate that an outer membrane protein, LamB, that lacks a signal sequence can be exported with reasonable efficiency in both prlA and prlG suppressor strains. Although the signal sequence is not absolutely required for export of LamB, the level of export in the absence of prl suppressor alleles is exceedingly low. Such strains are phenotypically LamB-, and functional LamB can be detected only by using sensitive infectious-center assays. Suppression of the LamB signal sequence deletion is dependent on normal components of the export pathway, indicating that suppression is not occurring through a bypass mechanism. Our results indicate that the majority of the known prlA suppressors function by an identical mechanism and, further, that the prlG suppressors work in a similar fashion. We propose that both PrlA and PrlG suppressors lack a proofreading activity that normally rejects defective precursors from the export pathway.     

SecG function and phospholipid metabolism in Escherichia coli

SecG is an auxiliary protein in the Sec-dependent protein export pathway of Escherichia coli. Although the precise function of SecG is unknown, it stimulates translocation activity and has been postulated to enhance the membrane insertion-deinsertion cycle of SecA. Deletion of secG was initially reported to result in a severe export defect and cold sensitivity. Later results demonstrated that both of these phenotypes were strain dependent, and it was proposed that an additional mutation was required for manifestation of the cold-sensitive phenotype. The results presented here demonstrate that the cold-sensitive secG deletion strain also contains a mutation in glpR that causes constitutive expression of the glp regulon. Introduction of both the glpR mutation and the secG deletion into a wild-type strain background produced a cold-sensitive phenotype, confirming the hypothesis that a second mutation (glpR) contributes to the cold-sensitive phenotype of secG deletion strains. It was speculated that the glpR mutation causes an intracellular depletion of glycerol-3-phosphate due to constitutive synthesis of GlpD and subsequent channeling of glycerol-3-phosphate into metabolic pathways. In support of this hypothesis, it was demonstrated that addition of glycerol-3-phosphate to the growth medium ameliorated the cold sensitivity, as did introduction of a glpD mutation. This depletion of glycerol-3-phosphate is predicted to limit phospholipid biosynthesis, causing an imbalance in the levels of membrane phospholipids. It is hypothesized that this state of phospholipid imbalance imparts a dependence on SecG for proper function or stabilization of the translocation apparatus.     

Point mutations in the transmembrane domain of DjlA, a membrane-linked DnaJ-like protein, abolish its function in promoting colanic acid production via the Rcs signal transduction pathway

DjlA is a novel DnaJ-like protein localized to the inner membrane of Escherichia coli through the single transmembrane domain (TMD) found at the N-terminus. The overproduction of DjlA activates expression of the cps operon, controlling synthesis and export of the extracellular polysaccharide colanic acid via the Rcs/B two-component signal transduction pathway. We now show that both the TMD and the J-region are essential for the induction of cps expression observed with the overproduction of DjlA. Furthermore, we describe the isolation and characterization of different point mutations in the TMD that completely or partially block the induction of cps expression associated with overproduction of DjlA. These mutations were shown not to affect the localization, stability or topology of the mutant DjlA proteins. We propose that these mutations are affecting specific interactions between the TMD of DjlA and its substrate protein(s), for example RcsC, the membrane sensor kinase partner of the Rcs/B signal transduction pathway.     

A new suppressor of a lamB signal sequence mutation, prlZ1, maps to 69 minutes on the Escherichia coli chromosome.

Reversion analysis has been employed to isolate suppressors that restore export of a unique LamB signal sequence mutant. The mutation results in a substitution of Arg for Met at position 19, which prevents LamB export to the outer membrane and leads to a Dex- phenotype. Unlike other LamB signal sequence mutants utilized for reversion analysis, LamB19R becomes stably associated with the inner membrane in an export-specific manner. In this study, Dex+ revertants were selected and various suppressors were isolated. One of the extragenic suppressors, designated prlZ1, was chosen for further study. prlZ1 maps to 69 min on the Escherichia coli chromosome. The suppressor is dominant and SecB dependent. In addition to its effect on lamB19R, prlZ1 suppresses the export defect of signal sequence point mutations at positions 12, 15, and 16, as well as several point mutations in the maltose-binding protein signal sequence. prlZ1 does not suppress deletion mutations in either signal sequence. This pattern of suppression can be explained by interaction of a helical LamB signal sequence with the suppressor.     

The Cs Sec Mutants of Escherichia Coli Reflect the Cold Sensitivity of Protein Export Itself

We have found that temperature can have a striking effect upon protein export in Escherichia coli, suggesting that there is a cold-sensitive step in the protein export pathway. Cs mutations comprise the largest class of mutations affecting the membrane-localized Sec proteins SecD, SecE, SecF and SecY. Although some of these mutations could encode cold-labile proteins, this is unlikely to account for the Cs phenotype of most export mutants, as mutations which simply produce lower amounts of SecE protein have the same phenotype. Certain signal sequence mutations affecting maltose binding protein are also cold sensitive for export. These effects appear to arise by a specific interaction of cold with certain export defects. We believe that the Cs sec mutations are representative of a large class of conditional lethal mutations, whose conditional phenotype reflects an underlying thermal sensitivity of the process in which they are involved.     

Expression of gpsA encoding biosynthetic sn-glycerol 3-phosphate dehydrogenase suppresses both the LB− phenotype of a secB null mutant and the cold-sensitive phenotype of a secG null mutant

SecB maintains the structures of a subset of precursor proteins competent for translocation across the Escherichia coli cytoplasmic membrane. SecG, a membrane component of the translocation machinery, stimulates protein translocation by undergoing the cycle of membrane topology inversion. Null mutants of secB and secG are unable to form isolated colonies on rich medium and at low temperature respectively. A 3.2 kb DNA fragment carrying the secB–gpsA region on a multicopy plasmid was found to suppress the null mutation of either gene. However, subcloning of the DNA fragment revealed that secB is not involved in the suppression of either mutation. Instead, gpsA located downstream from the secB gene was found to be responsible for the suppression of both mutations. The activity of the gpsA -encoded sn -glycerol-3-phosphate dehydrogenase, which is involved in phospholipid synthesis, was significantly lower in the secB null mutant than in the wild type, presumably because of a polar effect. Suppression of the secB null mutation required the wild-type level of GpsA activity. In contrast, overexpression of the enzyme was essential for suppression of the secG null mutation. Moreover, the gpsA -dependent suppression of the secG null mutation occurred only on rich medium, i.e. not on minimal medium. These results indicate that the SecB function is dispensable even in rich medium, and further demonstrate that overexpression of enzymes involved in phospholipid synthesis partly compensates for the SecG function.     

lep operon proximal gene is not required for growth or secretion by Escherichia coli.

Leader peptidase is an essential enzyme of Escherichia coli and is required for protein export. The structural gene for leader peptidase (lep) is separated from its promoter by an upstream gene of unknown function (lepA). The gene lepA was shown by the use of minicell analysis and overproduction to encode a protein of 74,000 daltons. To determine whether this 74,000-dalton protein functions in protein export, a mutant of E. coli H560 was constructed which has a 1.5-kilobase-pair deletion in the lepA gene. The lepA deletion mutant had no apparent defect for growth or protein export, indicating that lepA is nonessential and that the two cotranscribed genes lepA and lep probably have unrelated functions.     

Involvement of SecB, a chaperone, in the export of ribose-binding protein.

Ribose-binding protein (RBP) is an exported protein of Escherichia coli that functions in the periplasm. The export of RBP involves the secretion machinery of the cell, consisting of a cytoplasmic protein, SecA, and the integral membrane translocation complex, including SecE and SecY. SecB protein, a chaperone known to mediate the export of some periplasmic and outer membrane proteins, was previously reported not to be involved in RBP translocation even though small amounts of in vitro complexes between SecB and RBP have been detected. In our investigation, it was shown that a dependence on SecB could be demonstrated under conditions in which export was compromised. Species of RBP which carry two mutations, one in the leader that blocks export and a second in the mature protein which partially suppresses the export defect, were shown to be affected by SecB for efficient translocation. Five different changes which suppress the effect of the signal sequence mutation -17LP are all located in the N domain of the tertiary structure of RBP. All species of RBP show similar interaction with SecB. Furthermore, a leaky mutation, -14AE, generated by site-specific mutagenesis causes reduced export in the absence of SecB. These results indicate that SecB can interact with RBP during secretion, although it is not absolutely required under normal circumstances.     

SecD and SecF facilitate protein export in Escherichia coli.

We show here that the rate of protein translocation in the bacterium Escherichia coli depends on the levels of the SecD and SecF proteins in the cell. Overexpression of SecD and SecF stimulates translocation in wild type cells and improves export of proteins with mutant signal sequences. Depletion of SecD and SecF from the cell greatly reduces but does not abolish protein translocation. A secDF::kan null mutant deleted for the genes encoding both proteins is cold-sensitive for growth and protein export, has a severe export defect at 37 degrees C and is barely viable. The phenotypes of a secD null mutant and a secF null mutant are identical to the secDF::kan double null mutant. These results partially resolve the conflict between genetic studies and results from in vitro translocation systems which do not require SecD and SecF for activity, affirm the importance of these proteins to the export process, and suggest that SecD and SecF function together to stimulate protein export in a role fundamentally different from other Sec proteins. Our results provide additional support for the notion that an early step in protein export is cold-sensitive.