Overproduction of L-Lysine from methanol by Methylobacillus glycogenes derivatives carrying a plasmid with a mutated dapA gene.

The dapA gene, encoding dihydrodipicolinate synthase (DDPS) partially desensitized to inhibition by L-lysine, was cloned from an L-threonine- and L-lysine-coproducing mutant of the obligate methylotroph Methylobacillus glycogenes DHL122 by complementation of the nutritional requirement of an Escherichia coli dapA mutant. Introduction of the dapA gene into DHL122 and AL119, which is the parent of DHL122 and an L-threonine producing mutant, elevated the specific activity of DDPS 20-fold and L-lysine production 2- to 3-fold with concomitant reduction of L-threonine in test tube cultures. AL119 containing the dapA gene produced 8 g of L-lysine per liter in a 5-liter jar fermentor from methanol as a substrate. Analysis of the nucleotide sequence of the dapA gene shows that it encodes a peptide with an M(r) of 30,664 and that the encoded amino acid sequence is extensively homologous to those of other organisms. In order to study the mutation that occurred in DHL122, the dapA genes of the wild type and AL119 were cloned and sequenced. Comparison of the nucleotide sequences of the dapA genes revealed that the amino acid at residue 88 was F in DHL122 whereas it was L in the wild type and AL119, suggesting that this amino acid alteration that occurred in DHL122 caused the partial desensitization of DDPS to the inhibition by L-lysine. The similarity in the amino acid sequences of DDPS in M. glycogenes and other organisms suggests that the mutation of the dapA gene in DHL122 is located in the region concerned with interaction of the allosteric effector, L-lysine.     

Characterization of six lipoproteins in the sigmaE regulon

In Escherichia coli, sigma(E) regulon functions are required for envelope homeostasis during stress and are essential for viability under all growth conditions. The E. coli genome encodes approximately 100 lipoproteins, and 6 of these are regulated by sigma(E). Phenotypes associated with deletion of each of these lipoproteins are the subject of this report. One lipoprotein, YfiO, is essential for cellular viability. However, overexpression of this protein is not sufficient to alleviate the requirement of sigma(E) for viability, suggesting that the sigma(E) regulon provides more than one essential function. The remaining five lipoproteins in the sigma(E) regulon are nonessential; cells are viable even when all five are removed simultaneously. Deletion of three nonessential lipoprotein genes (nlpB, yraP, ygfL) results in the exhibition of phenotypes that suggest they are important for maintenance of the integrity of the cell envelope. deltanlpB cells are selectively sensitive to rifampin; deltayraP cells are selectively sensitive to sodium dodecyl sulfate. Such selective sensitivity has not been previously reported. Both deltayraP and deltanlpB are synthetically lethal with surA::Cm, which encodes a periplasmic chaperone and PPIase, suggesting that NlpB and YraP play roles in a periplasmic folding pathway that functions in parallel with that of SurA. Finally, the deltayfgL mutant exhibits a broad range of envelope defects, including sensitivity to several membrane-impermeable agents, an altered outer membrane protein profile, synthetic lethality with both surA::Cm and deltafkpA::Cm strains, and sensitivity to a bactericidal permeability-increasing peptide. We suggest that this lipoprotein performs a very important but as-yet-unknown function in maintaining the integrity of the cell envelope.     

A maturation protein is essential for production of active forms of Lactococcus lactis SK11 serine proteinase located in or secreted from the cell envelope.

The complete nucleotide sequence of a gene located immediately upstream of the Lactococcus lactis subsp. cremoris SK11 prtP gene encoding the cell envelope-attached proteinase was determined. This gene, designated prtM, was found to be transcribed from the same promotor region as was the proteinase gene but in the opposite direction. The prtM gene directed the expression in Escherichia coli of a protein with a size similar to the expected value of 33 kilodaltons, as deduced from the nucleotide sequence data. The derived amino acid sequence of the PrtM protein indicated the presence of a consensus lipoprotein signal sequence at the N terminus, which suggested that PrtM is a lipoprotein. Plasmids containing the prtM gene, the prtP gene, or both were constructed. Expression studies of L. lactis clones containing these plasmids showed that the prtM gene encodes a trans-acting activity involved in the maturation of cell envelope-located and -secreted forms of the SK11 proteinase.     

YfiO stabilizes the YaeT complex and is essential for outer membrane protein assembly in Escherichia coli

Recent advances in the study of bacterial membranes have led to the identification of a multicomponent YaeT complex in the outer membrane (OM) of Gram-negative bacteria that is involved in the targeting and folding of beta-barrel outer membrane proteins (OMPs). In Escherichia coli, this complex consists of an essential OMP, YaeT, and three OM lipoproteins, YfgL, NlpB and YfiO. YfiO is the only essential lipoprotein component of the complex. We show that this lipoprotein is required for the proper assembly and/or targeting of OMPs to the OM but not the assembly of lipopolysaccharides (LPS). Depletion of YfiO causes similar phenotypes as does the depletion of YaeT, and we conclude that YfiO plays a critical role in YaeT-mediated OMP folding. We demonstrate that YfiO and YfgL directly interact with YaeT in vitro, while NlpB interacts directly with YfiO. Genetic analysis verifies the importance of YfiO and its interactions with NlpB in maintaining the functional integrity of the YaeT complex.     

Overproduction of NlpE, a new outer membrane lipoprotein, suppresses the toxicity of periplasmic LacZ by activation of the Cpx signal transduction pathway.

The LamB-LacZ-PhoA tripartite fusion protein is secreted to the periplasm, where it exerts a toxicity of unknown origin during high-level synthesis in the presence of the inducer maltose, a phenotype referred to as maltose sensitivity. We selected multicopy suppressors of this toxicity that allow growth of the tripartite fusion strains in the presence of maltose. Mapping and subclone analysis of the suppressor locus identified a previously uncharacterized chromosomal region at 4.7 min that is responsible for suppression. DNA sequence analysis revealed a new gene with the potential to code for a protein of 236 amino acids with a predicted molecular mass of 25,829 Da. The gene product contains an amino-terminal signal sequence to direct the protein for secretion and a consensus lipoprotein modification sequence. As predicted from the sequence, the suppressor protein is labeled with [3H]palmitate and is localized to the outer membrane. Accordingly, the gene has been named nlpE (for new lipoprotein E). Increased expression of NlpE suppresses the maltose sensitivity of tripartite fusion strains and also the extracytoplasmic toxicities conferred by a mutant outer membrane protein, LamBA23D. Suppression occurs by activation of the Cpx two-component signal transduction pathway. This pathway controls the expression of the periplasmic protease DegP and other factors that can combat certain types of extracytoplasmic stress.     

Nucleotide sequence of the lspA gene,the structural gene for lipoprotein signal peptidase of Escherichia coli

The nucleotide sequence of the lspA gene coding for lipoprotein signal peptidase of Escherichia coli was determined and the amino acid sequence of the peptidase was deduced from it. The molecular mass and amino acid composition of the predicted lipoprotein signal peptidase were consistent with those of the signal peptidase purified from cells harboring the lspA gene-carrying plasmid. The peptidase most probably has no cleavable signal peptide. The lspA gene was preceded by the ileS gene coding for isoleucyl-tRNA synthetase and the tandem termination codons of the ileS gene overlapped with the initiation codon of the lspA gene.     

Enhancement of L-lysine production in methylotroph Methylophilus methylotrophus by introducing a mutant LysE exporter

The obligate methylotroph Methylophilus methylotrophus AS1 expressing a mutant form of dapA (dapA24) encoding a dihydrodipicolinate synthase desensitized from feedback inhibition by L-lysine could secrete L-lysine into the medium, but also maintained a high concentration of intracellular L-lysine. To improve the yield from excretion, we attempted to introduce an L-lysine/L-arginine exporter (LysE) from Corynebacterium glutamicum 2256 into M. methylotrophus. We were unable to stably transform M. methylotrophus with a plasmid expressing the wild type lysE gene, but happened to obtain a transformant carrying a spontaneously mutated lysE gene (designated lysE24) which could induce L-lysine production even in the wild type strain. The transformant also possessed increased tolerance to S-(2-aminoethyl)-L-cysteine (an L-lysine analog). lysE24 has a single-base insertion mutation in the middle of the lysE gene, and its product is presumably quite different in structure from wild-type LysE. When lysE24 was introduced into an L-lysine producer of M. methylotrophus carrying dapA24, the level of intracellular L-lysine fell. During fermentation, M. methylotrophus carrying both lysE24 and dapA24 produced 10-fold more L-lysine (11.3 gl(-1) in jar-fermentation) than the parent producer carrying only dapA24 or lysE24. These results show the importance of the factor (lysE24) involved in the excretion of L-lysine on its overproduction in M. methylotrophus.     

Characterization of pectin methylesterase B, an outer membrane lipoprotein of Erwinia chrysanthemi 3937

The secretion of extracellular pectinases, among which there are least six isoenzymes of pectate lyase and one pectin methylesterase, allows the phytopathogenic bacterium Erwinia chrysanthemi to degrade pectin. A gene coding for a novel pectin methylesterase has been cloned from an E. chrysanthemi strain 3937 gene library. This gene, pemB , codes for a 433-amino-acid protein. The PemB N-terminal region has the characteristics of lipoprotein signal sequences. We have shown that the PemB precursor is processed and that palmitate is incorporated into the mature protein. The PemB lipoprotein is not released into the extracellular medium and is localized in the outer membrane. The PemB sequence presents homology with other pectin methylesterases from bacterial and plant origin. pemB -like proteins were detected in four other E. chrysanthemi strains but not in Erwinia carotovora strains. PemB was overproduced in Escherichia coli and purified to homogeneity. PemB activity is strongly increased by non-ionic detergents. The enzyme is more active on methylated oligogalacturonides than on pectin, and it is necessary for the growth of the bacteria on oligomeric substrates. PemB is more probably involved in the degradation of methylated oligogalacturonides present in the periplasm of the bacteria, rather than in a direct action on extracellular pectin. pemB expression is inducible in the presence of pectin and is controlled by the negative regulator KdgR.     

Organization of the human cholesteryl ester transfer protein gene

The plasma cholesteryl ester transfer protein (CETP) catalyzes the transfer of phospholipids and neutral lipids between the lipoproteins. Thus, this protein may be important in modulating lipoprotein levels in the plasma. We have determined the primary structure and organization of the human CETP gene. Southern blotting of cellular DNA indicated a single copy of the CETP gene exists per haploid genome. Analysis of three overlapping genomic clones showed that the gene spans approximately 25 kbp and contains 16 exons (size range 32-250 bp). Overall, the sequence and organization of the CETP gene do not resemble those of other lipid-metabolizing enzymes or apolipoproteins. However, comparison of the CETP sequence, one exon at a time, with the sequences in the sequence databases revealed a striking identity of a pentapeptide sequence (ValLeuThrLeuAla) within the hydrophobic core of the signal sequences of human CETP, apolipoproteins A-IV and A-I, and lipoprotein lipase. This pentapeptide sequence was not found in the signal sequences of other proteins, suggesting that it may mediate a specialized function related to lipid metabolism or transport.     

Expression of the Proteus mirabilis lipoprotein gene in Escherichia coli. Existence of tandem promoters

The Ipp gene from Proteus mirabilis was cloned onto pBR322 and expressed in Escherichia coli. The P. mirabilis lpp gene is unique in that it has two tandem promoters transcribing two mRNAs that differ in length by approximately 70 nucleotides at their 5'-ends. The two mRNAs thus encode the identical lipoprotein. The P. mirabilis prolipoprotein has a 19-amino acid signal peptide and a 59-amino acid lipoprotein sequence. In spite of the substantial differences in the amino acid sequence from the E. coli prolipoprotein, the P. mirabilis prolipoprotein is normally modified and processed in E. coli, and the resultant lipoprotein is assembled in the E. coli outer membrane as is the E. coli lipoprotein.     

TCP pilus biosynthesis in Vibrio cholera O1: gene sequence of tcpC encoding an outer membrane lipoprotein

The nucleotide sequence of the tcpC gene has been determined. It encodes a 53995-Da protein precursor with a signal sequence and cleavage site typical of a number of outer membrane lipoproteins, which are cleaved by the equivalent of signal peptidase II (Lsp) of Escherichia coli. The location of the tcpC gene is such that it is predicted to be translationally coupled to the 5' and 3' flanking genes, tcpY and tcpD, respectively, indicating that it forms part of an operon. Together with the lipoprotein signal sequence and the several hydrophobic domains it seems likely that TcpC is a surface-anchored trans-outer membrane lipoprotein.     

Lipoprotein-28, a cytoplasmic membrane lipoprotein from Escherichia coli. Cloning, DNA sequence, and expression of its gene

Escherichia coli contains several lipoproteins in addition to the major outer membrane lipoprotein (Ichihara, S., Hussain, M., and Mizushima, S. (1981) J. Biol. Chem. 256, 3125-3129). We cloned the gene for one of these new lipoproteins by using a synthetic 15-mer oligonucleotide probe identical to the DNA sequence at the signal peptide cleavage site of the major lipoprotein. The DNA sequence of the cloned gene revealed an open reading frame encoding a 272-amino acid protein with a signal peptide of 23 amino acid residues. The amino acid sequence of the putative cleavage site region of the signal peptide, -Leu-Leu-Ala-Gly-Cys-, is identical to that of the major lipoprotein. When the cloned gene was expressed in E. coli, a gene product with an apparent molecular weight of approximately 29,000 was identified which agrees well with the calculated molecular weight (27,800). The product was labeled with [3H]glycerol, and a precursor molecule of increased molecular weight was accumulated when cells were treated with globomycin, a specific inhibitor for prolipoprotein signal peptidase. We thus designed the gene product as lipoprotein-28. Unlike the major lipoprotein, lipoprotein-28 was found to be localized in the cytoplasmic membrane. A possible orientation of lipoprotein-28 in the E. coli envelope is discussed.     

Comparison of the lipoprotein gene among the enterobacteriaceae. DNA sequence of Morganella morganii lipoprotein gene and its expression in Escherichia coli

A DNA sequence of 532 base pairs encompassing the entire Morganella morganii lipoprotein gene (lpp) was determined. Sequence comparisons of the M. morganii lpp gene with the lpp genes from Escherichia coli, Serratia marcescens, and Erwinia amylovora reveal that the M. morganii lpp gene is more distantly related to the E. coli lpp gene than any of the other lpp genes examined. Between the E. coli and M. morganii lpp genes, the following homologies were found: 44% in the promoter region (bases, -45 to -1), 88% in the 5'-end untranslated region of the mRNA, 58% in the signal sequence coding region, 75% in the coding region for the first 51 and 43% for the last 7 amino acid residues. Upstream of the promoter region and downstream of the termination codon, there are extensive insertions, deletions, and base substitutions. In spite of the differences in the DNA sequences, the lipoprotein structure was found to be highly conserved except for the carboxyl-terminal sequence of 7 amino residues. The coding region of the M. morganii lpp gene including the signal sequence was inserted into an expression cloning vector so that the production of the M. morganii lipoprotein could be induced in E. coli by a lac inducer, isopropyl-beta-D-thioglactoside. It was found that when induced, the M. morganii prolipoprotein was apparently secreted normally across the E. coli cytoplasmic membrane, modified with glycerol and palmitic acid, processed to the mature lipoprotein, and assembled in the E. coli outer membrane. The bound form covalently linked to the peptidoglycan was also found.     

Defective Escherichia coli signal peptides function in yeast

To investigate structural characteristics important for eukaryotic signal peptide function in vivo, a hybrid gene with interchangeable signal peptides was cloned into yeast. The hybrid gene encoded nine residues from the amino terminus of the major Escherichia coli lipoprotein, attached to the amino terminus of the entire mature E. coli beta-lactamase sequence. To this sequence were attached sequences encoding the nonmutant E. coli lipoprotein signal peptide, or lipoprotein signal peptide mutants lacking an amino-terminal cationic charge, with shortened hydrophobic core, with altered potential helicity, or with an altered signal-peptide cleavage site. These signal-peptide mutants exhibited altered processing and secretion in E. coli. Using the GAL10 promoter, production of all hybrid proteins was induced to constitute 4-5% of the total yeast protein. Hybrid proteins with mutant signal peptides that show altered processing and secretion in E. coli, were processed and translocated to a similar degree as the non-mutant hybrid protein in yeast (approximately 36% of the total hybrid protein). Both non-mutant and mutant signal peptides appeared to be removed at the same unique site between cysteine 21 and serine 22, one residue from the E. coli signal peptidase II processing site. The mature lipo-beta-lactamase was translocated across the cytoplasmic membrane into the yeast periplasm. Thus the protein secretion apparatus in yeast recognizes the lipoprotein signal sequence in vivo but displays a specificity towards altered signal sequences which differs from that of E. coli.     

Cloning of genes encoding a 15,000-dalton peptidoglycan-associated outer membrane lipoprotein and an antigenically related 15,000-dalton protein from Haemophilus influenzae.

We have cloned and expressed in Escherichia coli a gene encoding a 15,000-apparent-molecular-weight peptidoglycan-associated outer membrane lipoprotein (PAL) of Haemophilus influenzae. The nucleotide sequence of this gene encodes an open reading frame of 153 codons with a predicted mature protein of 134 amino acids. The amino acid composition and sequence of the predicted mature protein agree with the chemically determined composition and partial amino acid sequence of PAL purified from H. influenzae outer membranes. We have also identified a second gene from H. influenzae that encodes a second 15,000-apparent-molecular-weight protein which is recognized by antiserum against PAL. This protein has been shown to be a lipoprotein. The nucleotide sequence of this gene encodes an open reading frame of 154 codons with a predicted mature protein of 136 amino acids and has limited sequence homology with that of the gene encoding PAL. Southern hybridization analysis indicates that both genes exist as single copies in H. influenzae chromosomal DNA. Both genes encode polypeptides which have amino-terminal sequences similar to those of reported membrane signal peptides and are associated primarily with the outer membrane when expressed in E. coli.     

Prolipoprotein signal peptidase of Escherichia coli requires a cysteine residue at the cleavage site

A signal peptidase specifically required for the secretion of the lipoprotein of the Escherichia coli outer membrane cleaves off the signal peptide at the bond between a glycine and a cysteine residue. This cysteine residue was altered to a glycine residue by guided site-specific mutagenesis using a synthetic oligonucleotide and a plasmid carrying an inducible lipoprotein gene. The induction of mutant lipoprotein production was lethal to the cells. A large amount of the prolipoprotein was accumulated in the outer membrane fraction. No protein of the size of the mature lipoprotein was detected. These results indicate that the prolipoprotein signal peptidase requires a glyceride modified cysteine residue at the cleavage site.     

The pYV plasmid of Yersinia encodes a lipoprotein, YlpA, related to TraT

A series of lipoproteins was detected in the membrane fraction of Yersinia enterocolitica W227, a typical strain from serotype O:9. At least two of them, YlpA and YlpB, are encoded by the pYV plasmid. The sequence of ylpA reveals the presence of a typical lipoprotein signal peptide. The mature YlpA protein would be 223 residues long with a calculated molecular weight of 23798 for the proteic moiety of the molecule. YlpA shares 88% identical residues with the TraT protein encoded by plasmid pED208, 80% identity with TraT proteins encoded by plasmids R100 and F, and 77% identity with the TraT protein encoded by the virulence plasmid of Salmonella typhimurium. The ylpA gene hybridized with the pYV plasmid of Yersinia pseudotuberculosis, suggesting that this gene is conserved among Yersinia spp. The production of YlpA is controlled by virF and only occurs at 37 degrees C in the absence of Ca2+ ions. This co-regulation with the yop genes suggests that ylpA is a virulence determinant. However, mutations in ylpA clearly affect neither the resistance to human serum nor the virulence for intravenously inoculated mice.     

The H8 antigen of pathogenic Neisseriae

We cloned and sequenced the H8 gene from N. meningitidis FAM18. The predicted amino acid sequence included a consensus lipoprotein signal sequence processing site, consistent with lipid modification that could account for the unusual electrophoretic and solubilization properties of H8. The amino acid sequence was rich in alanine and proline, especially in an imperfectly periodic region near the amino terminus, which encompassed the epitope recognized by available monoclonal antibodies. In a panel of neisserial strains, the presence of DNA homologous to the H8 gene correlated with the expression of an H8 protein. We cloned a gene from N. meningitidis JB515 that was distinct from the H8 gene but encoded a protein also recognized by an anti-H8 monoclonal antibody. Mice were not protected from meningococcemia by passive immunization with such an antibody.