Both transmembrane domains of SecG contribute to signal sequence recognition by the Escherichia coli protein export machinery

A chimeric protein containing the uncleaved signal sequence of plasminogen activators inhibitor-2 (PAI2) fused to alkaline phosphatase (AP) interferes with Escherichia coli protein export and arrests growth. Suppressors of this toxicity include secG mutations that define the Thr-41-Leu-42-Phe-43 (TLF) domain of SecG. These mutations slow down the export of PAI2-AP. Another construct encoding a truncated PAI2 signal sequence (hB-AP) is also toxic. Most suppressors exert their effect on both chimeric proteins. We describe here five secG suppressors that only suppress the toxicity of hB-AP and selectively slow down its export. These mutations do not alter the TLF domain: three encode truncated SecG, whereas two introduce Arg residues in the transmembrane domains of SecG. The shortest truncated protein only contains 13 residues of SecG, suggesting that the mutation is equivalent to a null allele. Indeed, a secG disruption selectively suppresses the toxicity of hB-AP. However, the missense mutations are not null alleles. They allow SecG binding to SecYE, although with reduced affinity. Furthermore, these mutated SecG are functional, as they facilitate the export of endogenous proteins. Thus, SecG participates in signal sequence recognition, and both transmembrane domains of SecG contribute to ensure normal signal sequence recognition by the translocase.     

A new genetic selection identifies essential residues in SecG, a component of the Escherichia coli protein export machinery.

The signal sequence of the murine serine protease inhibitor PAI-2 promotes alkaline phosphatase export to the E. coli periplasm. However, high level expression of this chimeric protein interferes with cell growth. Since most suppressors of this toxic phenotype map to secA and secY, growth arrest results from a defective interaction of the chimeric protein with the export machinery. We have characterized suppressors which map in secG, a newly defined gene of the export machinery. All single amino acid substitutions map to three adjacent codons. These secG mutants have a weak Sec phenotype, as determined by their effect on export mediated by wild-type and mutant signal sequences. Whilst a secG disruption allele also confers a weak Sec phenotype, it does not suppress the toxicity of the chimeric protein. This difference results from a selective effect of the secG suppressors on the kinetics of export mediated by the PAI-2 signal sequence. Using a malE signal sequence mutant, which has a Mal-phenotype in secG mutant strains, we have isolated extragenic Mal+ suppressors. Most suppressors map to secY, and several are allele-specific. Finally, SecG overexpression accelerates the kinetics of protein export, suggesting that there are two types of functional translocation complexes: with or without SecG.     

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.     

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.     

Functional identification of the product of the Bacillus subtilis yvaL gene as a SecG homologue

Protein export in Escherichia coli is mediated by translocase, a multisubunit membrane protein complex with SecA as the peripheral subunit and the SecY, SecE, and SecG proteins as the integral membrane domain. In the gram-positive bacterium Bacillus subtilis, SecA, SecY, and SecE have been identified through genetic analysis. Sequence comparison of the Bacillus chromosome identified a potential homologue of SecG, termed YvaL. A chromosomal disruption of the yvaL gene results in mild cold sensitivity and causes a beta-lactamase secretion defect. The cold sensitivity is exacerbated by overexpression of the secretory protein alpha-amylase, whereas growth and beta-lactamase secretion are restored by coexpression of yvaL or the E. coli secG gene. These results indicate that the yvaL gene codes for a protein that is functionally homologous to SecG.     

Coupled structure change of SecA and SecG revealed by the synthetic lethality of the secAcsR11 and ΔsecG::kan double mutant

An Escherichia coli strain carrying either the secAcsR11 or Δ secG :: kan mutation is unable to grow at low temperature owing to cold-sensitive protein translocation but grows normally at 37°C. However, introduction of the two mutations into the same cells caused a severe defect in protein translocation and the cells were unable to grow at any temperature examined, indicating that secG is essential for the secAcsR11 mutant. The mutant SecA (csSecA) was found to possess a single amino acid substitution in the precursor-binding region and was defective in the interaction with the precursor protein. Furthermore, the membrane insertion of SecA and the membrane topology inversion of SecG, both of which took place upon the initiation of protein translocation, were significantly retarded even at 37°C, when csSecA was used instead of the wild-type SecA. The insertion of the wild-type SecA was also significantly defective when SecG-depleted membrane vesicles were used in place of SecG-containing ones. No insertion of csSecA occurred into SecG-depleted membrane vesicles. Examination of in vitro protein translocation at 37°C revealed that SecG is essential for csSecA-dependent protein translocation. We conclude that SecG and SecA undergo a coupled structure change, that is critical for efficient protein translocation.     

Two SecG molecules present in a single protein translocation machinery are functional even after crosslinking

SecG, a membrane component of the protein translocation apparatus of Escherichia coli, undergoes membrane topology inversion, which is coupled to the membrane insertion and deinsertion cycle of SecA. Eighteen SecG derivatives possessing a single cysteine residue at various positions were constructed and expressed in a secG null mutant. All the SecG-Cys derivatives retained the SecG function, and stimulated protein translocation both in vivo and in vitro. Inverted membrane vesicles containing a SecG-Cys derivative were labeled with a membrane-permeable or -impermeable sulfhydryl reagent before or after solubilization with a detergent. The accessibility of these reagents to the cysteine residue of each derivative determined the topological arrangement of SecG in the membrane. Derivatives having the cysteine residue in the periplasmic region each existed as a homodimer crosslinked through disulfide bonds, indicating that two SecG molecules closely co-exist in a single translocation machinery. The crosslinking did not abolish the SecG function and the crosslinked SecG dimer underwent topology inversion upon protein translocation.     

Disruption of the gene encoding p12 (SecG) reveals the direct involvement and important function of SecG in the protein translocation of Escherichia coli at low temperature.

The Escherichia coli cytoplasmic membrane protein, p12, stimulates the protein translocation activity reconstituted with SecY, SecE and SecA. The gene encoding p12, which is located at 69 min on the E. coli chromosome, was deleted to examine the role of p12 in protein translocation in vivo. The deletion strain exhibited cold-sensitive growth. Pulse-chase experiments revealed that precursors of outer membrane protein A, maltose binding protein and beta-lactamase accumulated at 20 degrees C but not at 37 degrees C. The deletion strain harboring a plasmid which carries the gene encoding p12 under the control of the araBAD promoter was able to grow in the cold when p12 was expressed with the addition of arabinose. Furthermore, the accumulated precursors were rapidly processed to the mature forms upon the expression of p12. Immunoblot analysis revealed the steady-state accumulation of precursor proteins at 20 degrees C, whereas the accumulation was only marginal at 37 degrees C, indicating that the function of p12 is more critical at 20 degrees C than at 37 degrees C. Finally, proteoliposomes were reconstituted with or without p12 to demonstrate that the stimulation of the activity by p12 increases with a decrease in temperature. From these results, we concluded that p12 is directly involved in protein translocation in E. coli and plays a critical role in the cold. We propose the more systematic name, SecG, for p12.     

The replication initiator operon of promiscuous plasmid RK2 encodes a gene that complements an Escherichia coli mutant defective in single-stranded DNA-binding protein.

The amino acid sequence of the 13-kDa polypeptide (P116) encoded by the first gene of the trfA operon of IncP plasmid RK2 shows significant similarity to several known single-stranded DNA-binding proteins. We found that unregulated expression of this gene from its natural promoter (trfAp) or induced expression from a strong heterologous promoter (trcp) was sufficient to complement the temperature-sensitive growth phenotype of an Escherichia coli ssb-1 mutant. The RK2 ssb gene is the first example of a plasmid single-stranded DNA-binding protein-encoding gene that is coregulated with replication functions, indicating a possible role in plasmid replication.     

Overexpression of yccL (gnsA) and ydfY (gnsB) Increases Levels of Unsaturated Fatty Acids and Suppresses both the Temperature-Sensitive fabA6 Mutation and Cold-Sensitive secG Null Mutation of Escherichia coli

A multicopy suppressor of the cold-sensitive secG null mutation was isolated. The suppressor contained sfa and yccL, the former of which has been reported to be a multicopy suppressor of the fabA6 mutation carried by a temperature-sensitive unsaturated fatty acid auxotroph. Subcloning of the suppressor gene revealed that yccL, renamed gnsA (secG null mutant suppressor), was responsible for the suppression of both the secG null mutation and the fabA6 mutation. In contrast, the sfa gene did not suppress the fabA6 mutation. The ydfY (gnsB) gene, encoding a protein which is highly similar to GnsA, also suppressed both the secG null mutation and the fabA6 mutation. Although both gnsA and gnsB are linked to cold shock genes, the levels of GnsA and GnsB did not exhibit a cold shock response. A gnsA-gnsB double null mutant grew normally under all conditions examined; thus, the in vivo functions of gnsA and gnsB remain unresolved. However, overexpression of gnsA and gnsB stimulated proOmpA translocation of the secG null mutant at low temperature and caused a significant increase in the unsaturated fatty acid content of phospholipids. Taken together, these results suggest that an increase in membrane fluidity due to the increase in unsaturated fatty acids compensates for the absence of the SecG function, especially at low temperature.     

A promoter for the first nine genes of the Escherichia coli mra cluster of cell division and cell envelope biosynthesis genes, including ftsI and ftsW.

We constructed a null allele of the ftsI gene encoding penicillin-binding protein 3 of Escherichia coli. It caused blockage of septation and loss of viability when expression of an extrachromosomal copy of ftsI was repressed, providing a final proof that ftsI is an essential cell division gene. In order to complement this null allele, the ftsI gene cloned on a single-copy mini-F plasmid required a region 1.9 kb upstream, which was found to contain a promoter sequence that could direct expression of a promoterless lacZ gene on a mini-F plasmid. This promoter sequence lies at the beginning of the mra cluster in the 2 min region of the E. coli chromosome, a cluster of 16 genes which, except for the first 2, are known to be involved in cell division and cell envelope biosynthesis. Disruption of this promoter, named the mra promoter, on the chromosome by inserting the lac promoter led to cell lysis in the absence of a lac inducer. The defect was complemented by a plasmid carrying a chromosomal fragment ranging from the mra promoter to ftsW, the fifth gene downstream of ftsI, but not by a plasmid lacking ftsW. Although several potential promoter sequences in this region of the mra cluster have been reported, we conclude that the promoter identified in this study is required for the first nine genes of the cluster to be fully expressed.     

Nearest neighbor analysis of the SecYEG complex. 1. Identification of a SecY-SecG interface

Integral membrane components SecY, SecE, and SecG of protein translocase form a complex in the Escherichia coli plasma membrane. To characterize subunit interactions of the SecYEG complex, a series of SecY variants having a single cysteine in its cytoplasmic (C1-C6) or periplasmic (P1-P5) domain were subjected to site-specific cross-linking experiments using bifunctional agents with thiol-amine reactivity. Experiments using inverted membrane vesicles revealed specific cross-linkings between a cysteine residue placed in the C2 or C3 domain of SecY and the cytosolic lysine (Lys26) near the first transmembrane segment of SecG. These SecY Cys residues also formed a disulfide bond with an engineered cytosolic cysteine at position 28 of SecG. Thus, the C2-C3 region of SecY is in the proximity of the N-terminal half of the SecG cytoplasmic loop. Experiments using spheroplasts revealed the physical proximity of P2 (SecY) and the C-terminal periplasmic region of SecG. In addition, mutations in secG were isolated as suppressors against a cold-sensitive mutation (secY104) affecting the TM4-C3 boundary of SecY. These results collectively suggest that a C2-TM3-P2-TM4-C3 region of SecY serves as an interface with SecG.     

Construction of a genetically engineered microorganism for CO2 fixation using a Rhodopseudomonas/Escherichia coli shuttle vector

The CO2 fixation ability of Rhodopseudomonas palustris DH was enhanced by introducing the recombinant plasmid pMG-CBBM containing the form II ribulose-1,5-bisphosphate carboxylase/oxygenase (RubisCO) gene (cbbM) isolated from Rps. palustris NO. 7. Sequencing of a 3.0-kb PstI fragment containing the cbbM gene revealed an open reading frame encoding 461 amino acids, homologous to known cbbM genes, with a ribosome binding site upstream of cbbM and a terminator downstream of cbbM, without promoter. pMG-CBBM, a Rhodopseudomonas/Escherichia coli shuttle expression plasmid, was derived from the Rhodopseudomonas/E. coli shuttle cloning vector pMG105, by inserting the promoter of the pckA gene and the cbbM gene into its multiple cloning site. Plasmid pMG-CBBM was transformed into Rps. palustris DH by electroporation, and was stably maintained when transformants were grown either photoheterotrophically or photolithoautotrophically in the absence of antibiotics. This is the first report of an expression plasmid containing a Rps. palustris-specific promoter that allows stable expression of a foreign gene in the absence of antibiotic selection.