The tonB gene of Serratia marcescens: sequence, activity and partial complementation of Escherichia coli tonB mutants

The TonB protein plays a key role in the energy-coupled transport of iron siderophores, of vitamin B12, and of colicins of the B-group across the outer membrane of Escherichia coli. In order to obtain more data about which of its particular amino acid sequences are necessary for TonB function, we have cloned and sequenced the tonB gene of Serratia marcescens. The nucleotide sequence predicts an amino acid sequence of 247 residues (Mr 27,389), which is unusually proline-rich and contains the tandem sequences (Glu-Pro)5 and (Lys-Pro)5. In contrast to the TonB proteins of E. coli and Salmonella typhimurium, translation of the S. marcescens TonB protein starts at the first methionine residue of the open reading frame, which is the only amino acid removed during TonB maturation and export. Only the N-terminal sequence is hydrophobic, suggesting its involvement in anchoring the TonB protein to the cytoplasmic membrane. The S. marcescens tonB gene complemented an E. coli tonB mutant with regard to uptake of iron siderophores, and sensitivity to phages T1 and phi 80, and to colicins B and M. However, an E. coli tonB mutant transformed with the S. marcescens tonB gene remained resistant to colicins Ia and Ib, to colicin B derivatives carrying the amino acid replacements Val/Ala and Val/Gly at position 20 in the TonB box, and they exhibited a tenfold lower activity with colicin D. In addition, the S. marcescens TonB protein did not restore T1 sensitivity of an E. coli exbB tolQ double mutant, as has been found for the overexpressed E. coli TonB protein, indicating a lower activity of the S. marcescens TonB protein. Although the S. marcescens TonB protein was less prone to proteolytic degradation, it was stabilized in E. coli by the ExbBD proteins. In E. coli, TonB activity of S. marcescens depended either on the ExbBD or the TolQR activities.     

Conformational effects of amino acid substitutions at positions 10, 12, and 13 in the P21 protein

Substitutions of amino acids for Gly 12 or Gly 13 in theras oncogene-encoded P21 proteins have been demonstrated to produce unique structural changes in these proteins that correlate with their ability to produce cell transformation. For example, the P21 proteins with Arg 12 or Val 13 are both known to be actively transforming. Recent site-specific mutagenesis experiments on the transforming Arg 12 protein have found that the substitution of Val for Gly 10 has no effect on transforming activity whereas the substitution of Val for Gly 13 led to a loss of transforming activity. In this study, we examine the structural effects of these substitutions on the amino terminal hydrophobic decapeptide (Leu 6-Gly 15) of P21 using conformational energy analysis. The results show that the transforming proteins with Gly 10 and Arg 12 or Val 10 and Arg 12 can both adopt the putative malignancy-causing conformation, whereas, for the nontransforming protein with Arg 12 and Val 13, this conformation is energetically disallowed. These results further support the theory that due to structural changes the transforming P21 proteins are unable to bind to some regulatory cellular element which may be the recently identified binding protein responsible for the induction of increased GTPase activity in normal P21 compared with transforming mutants.     

A mutant of Escherichia coli defective in the first step of endotoxin biosynthesis

Using localized mutagenesis of whole cells, we have isolated a temperature-sensitive UDP-N-acetylglucosamine acyltransferase mutant of Escherichia coli that loses all detectable acyltransferase activity and quickly dies after a shift from 30 to 42 degrees C. Acyltransferase activity and temperature resistance are restored by transforming the mutant with a hybrid plasmid containing the E. coli gene for UDP-GlcNAc acyltransferase (lpxA). In addition, a new assay has been developed for quantitating the amount of lipid A (the active component of endotoxin) in E. coli and related Gram-negative strains. Cells are labeled with 32Pi and extracted with chloroform/methanol/water (1:2:0.8, v/v) to remove glycerophospholipids. The residue is then hydrolyzed with 0.2 M HCl to liberate the "monophosphoryl" lipid A degradation products (Qureshi, N., Cotter, R. J. and Takayama, K. (1986) J. Microbiol. Methods 5, 65-77), each of which bears a single phosphate residue at position 4'. The amount of lipid A is normalized to the total amount of labeled glycerophospholipid present in the cells. The steady state ratio of lipid A to glycerophospholipid in wild-type cells is approximately 0.12. The lipid A content of the acyltransferase mutant is reduced 2-3-fold, and the rate of lipid A synthesis is reduced 10-fold when compared to wild-type after 60 min at 42 degrees C. These results provide physiological evidence that UDP-N-acetylglucosamine acyltransferase is the major committed step for lipid A biosynthesis in E. coli and that lipid A is an essential molecule.     

Conformational effects of the substitution of Arg for Gly 13 in the ras oncogene-encoded P21 protein

The effect of the substitution of Arg for Gly 13 on the structure of the transforming region decapeptide (Leu 6-Gly 15) of the ras oncogene encoded P21 protein has been investigated using conformational energy analysis. A human malignancy has been identified that contains a ras gene with a single mutation in the thirteenth codon such that the encoded protein would have Arg substituted for Gly at this position, and transfection of cells in culture with this gene results in malignant transformation. Conformational analysis demonstrates that the Arg 13 decapeptide adopts a conformation identical to that for other peptides with substitutions at position 13 (Asp 13, Val 13) from transforming proteins that is distinctively different from that for peptides (Gly 13, Ser 13) from normal, nontransforming proteins. This is found to be an indirect effect resulting from changes in the conformation of Gly 12 produced by substitutions at position 13. These results are consistent with recent analysis of crystallographic data of proteins on conformational preferences for glycine in tripeptide sequences.     

Site-directed mutagenesis of the phosphate-binding consensus sequence in Escherichia coli adenylosuccinate synthetase.

Adenylosuccinate synthetases from different sources contain an N-terminal glycine-rich sequence GDEGKGK, which is homologous to the conserved sequence GXXXXGK found in many other guanine nucleotide-binding proteins or enzymes. To determine the role of this sequence in the structure and function of Escherichia coli adenylosuccinate synthetase, site-directed mutagenesis was performed to generate five mutant enzymes: G12V (Gly12----Val), G15V (Gly15----Val), G17V (Gly17----Val), K18R (Lys18----Arg), and I19T (Ile19----Thr). Comparison of the kinetic properties of the wild-type enzyme and those of the mutant enzymes revealed that the sequence is critical for enzyme activity. Replacement of Gly12, Gly15, or Gly17 with Val, or replacement of Lys18 with Arg, resulted in significant decreases in the kcat/Km values of the enzyme. Because the consensus sequence GXXXXGK(T/S) has been found in many GTP-binding proteins, isoleucine at position 19 in the E. coli adenylosuccinate synthetase was changed to threonine to produce the sequence GDEGKGKT. This mutation, which more closely resembles the consensus sequence, resulted in a 160-fold increase in the Km value for substrate GTP; however, there were no great changes for the other two substrates, IMP and aspartate. Based on these data, we suggest that the N-terminal glycinerich sequence in E. coli adenylosuccinate synthetase plays a more important role in enzyme catalysis than in substrate binding. In addition, a hydrophobic amino acid residue such as isoleucine, leucine, or valine, rather than threonine, may play a critical role in GTP binding in adenosuccinate synthetase. These findings suggest that the glycine-rich sequence in adenylosuccinate synthetase functions differently relative to those in other GTP binding proteins or enzymes.     

The proteomics of N-terminal methionine cleavage

Methionine aminopeptidase (MAP) is a ubiquitous, essential enzyme involved in protein N-terminal methionine excision. According to the generally accepted cleavage rules for MAP, this enzyme cleaves all proteins with small side chains on the residue in the second position (P1'), but many exceptions are known. The substrate specificity of Escherichia coli MAP1 was studied in vitro with a large (>120) coherent array of peptides mimicking the natural substrates and kinetically analyzed in detail. Peptides with Val or Thr at P1' were much less efficiently cleaved than those with Ala, Cys, Gly, Pro, or Ser in this position. Certain residues at P2', P3', and P4' strongly slowed the reaction, and some proteins with Val and Thr at P1' could not undergo Met cleavage. These in vitro data were fully consistent with data for 862 E. coli proteins with known N-terminal sequences in vivo. The specificity sites were found to be identical to those for the other type of MAPs, MAP2s, and a dedicated prediction tool for Met cleavage is now available. Taking into account the rules of MAP cleavage and leader peptide removal, the N termini of all proteins were predicted from the annotated genome and compared with data obtained in vivo. This analysis showed that proteins displaying N-Met cleavage are overrepresented in vivo. We conclude that protein secretion involving leader peptide cleavage is more frequent than generally thought.     

Modulation of the affinity of the single-stranded DNA-binding protein of Escherichia coli (E. coli SSB) to poly(dT) by site-directed mutagenesis

A vector for site-directed mutagenesis and overproduction of the Escherichia coli single-stranded-DNA-binding protein (E. coli SSB) was constructed. An E. coli strain carrying this vector produces up to 400 mg pure protein from 25 g wet cells. The vector was used to mutate specifically the Phe60 residue of E. coli SSB. Phe60 had been proposed to be located near the single-stranded-DNA-binding site. Substitution of the Phe60 residue by Val, Ser, Leu, His, Tyr and Trp gave proteins with no or only minor conformational changes, as detected by NMR spectroscopy. The affinity of the mutant E. coli SSB proteins for single-stranded DNA decreased in the order Trp greater than Phe (wild-type) greater than Tyr greater than Leu greater than His greater than Val greater than Ser, leading to the conclusion that position 60 is a site of hydrophobic interaction of the protein with DNA.     

The production of anti-hexapeptide antibodies which recognize the S7, L6 and L13 ribosomal proteins of Escherichia coli.

Here we report the synthesis of the N-terminal hexapeptide H-Pro-Arg-Arg-Arg-Val-Ile-OH of the E. coli ribosomal protein S7. the C-terminal hexapeptide H-Lys-Glu-Ala-Lys-Lys-Lys-OH of L6 and the C-terminal hexapeptide H-Pro-Gln-Val-Leu-Asp-Ile-OH of L13. All peptides were prepared by SPPS following the Fmoc-strategy, using DIC/HOBt and/or HBTU as coupling reagents and 2-chlorotrityl chloride resin as the solid support. The carrier linked synthetic peptides were injected into rabbits and elicited an anti-peptide response. These anti-hexapeptide antibodies were found to recognize the corresponding peptides and proteins.     

HlyC, the internal protein acyltransferase that activates hemolysin toxin: the role of conserved tyrosine and arginine residues in enzymatic activity as probed by chemical modification and site-directed mutagenesis.

Internal fatty acylation of proteins is a recognized means of modifying biological behavior. Escherichia coli hemolysin A (HlyA), a toxic protein, is transcribed as a nontoxic protein and made toxic by internal acylation of two lysine residue epsilon-amino groups; HlyC catalyzes the acyl transfer from acyl-acyl carrier protein (ACP), the obligate acyl donor. Conserved residues among the respective homologous C proteins that activate 13 different RTX (repeats in toxin) toxins of which HlyA is the prototype likely include some residues that are important in catalysis. Possible roles of two conserved tyrosines and two conserved arginines were investigated by noting the effects of chemical modifiers and site-directed mutagenesis. TNM modification of HlyC at pH 8.0 led to extensive inhibition that was prevented by the presence of the substrate myristoyl-ACP but not by the product, ACPSH. NAI had no effect. Y70G and Y150G greatly diminished enzyme activity, whereas mutations Y70F and Y150F exhibited wild-type activity. Modification of arginine residues with PG markedly lowered acyltransferase activity with moderate protection by both myristoyl-ACP and ACPSH. Under optimum conditions, four separate mutations of the two conserved arginine residues (R24A, R24K, R87A, and R87K) had little effect on acyltransferase activity.     

Molecular cloning of the genes for lipid A disaccharide synthase and UDP-N-acetylglucosamine acyltransferase in Escherichia coli.

Several enzymes have been discovered recently in crude extracts of Escherichia coli that appear to be involved in the biosynthesis of the lipid A component of lipopolysaccharide. Two of these are lipid A disaccharide synthase and UDP-N-acetylglucosamine acyltransferase. Lipid A disaccharide synthase activity is barely detectable in cells harboring a lesion in the lpxB (pgsB) gene. We subcloned the lpxB gene from plasmid pLC26-43 of the Clarke and Carbon collection (L. Clarke and J. Carbon, Cell 9:91-99, 1976) and localized it to a 1.7-kilobase-pair fragment of DNA counterclockwise of dnaE on the E. coli chromosome. Furthermore, we discovered a new gene (lpxA) located adjacent to and counterclockwise of lpxB that encodes or controls UDP-N-acetylglucosamine acyltransferase. Our data prove that lpxB and lpxA are transcribed in the clockwise direction and suggest that they may be cotranscribed.     

Cloning and sequencing of Escherichia coli murZ and purification of its product, a UDP-N-acetylglucosamine enolpyruvyl transferase.

The Escherichia coli gene murZ, encoding the enzyme UDP-N-acetylglucosamine enolpyruvyl transferase, has been cloned and sequenced. Identified by screening an E. coli genomic library for clones that conferred phosphomycin resistance, murZ encoded a 419-amino-acid polypeptide and was mapped to 69.3 min on the E. coli chromosome. MurZ protein was purified to near homogeneity and found to have the expected UDP-N-acetylglucosamine enolpyruvyl transferase activity. Sequence analysis of the predicted product revealed 44% identity to OrfR from Bacillus subtilis (K. Trach, J.W. Chapman, P. Piggot, D. LeCoq, and J.A. Hoch, J. Bacteriol. 170:4194-4208, 1988), suggesting that orfR may also encode a UDP-N-acetylglucosamine enolpyruvyl transferase enzyme. MurZ is also homologous to the aromatic amino acid biosynthetic enzyme enolpyruvyl shikimate phosphate synthase, the other enzyme known to catalyze an enolpyruvyl transfer.     

Sequences of the envM gene and of two mutated alleles in Escherichia coli.

The nucleotide sequence of the Escherichia coli envM gene was determined. It codes for a protein of 262 amino acids. The sequences of the E. coli and Salmonella typhimurium EnvM proteins are 98% identical. Gene envM is preceded in E. coli by a 43-nucleotide-long structural element, termed 'box c', which occurs in several E. coli operons between structural genes. This sequence element is totally absent in S. typhimurium. Gene envM was mapped at coordinate position 1366.8 kb of the physical map of Kohara et al. (Cell, 1987, 50, 495-508). As in S. typhimurium, a Gly for Ser exchange at position 93 of the amino acid sequence leads to a diazaborine-resistant E. coli phenotype. A Ser for Phe exchange at position 241 of the EnvM protein results in a temperature-sensitive growth phenotype. Comparison of the EnvM amino acid sequence with sequences available in databases showed significant homology with the family of short-chain alcohol dehydrogenases.     

Compartmentalization of mammalian proteins produced in Escherichia coli

We have examined the patterns of compartmentalization of several mammalian proteins in Escherichia coli which do not have signal peptides or functional signal peptide equivalents. These proteins include (i) human proapolipoprotein A-I (proapoA-I), a 249-residue protein which contains a hexapeptide NH2-terminal prosegment plus a mature domain of 243 residues comprised of tandemly arrayed, docosapeptide repeats with predicted amphipathic alpha-helical structure; (ii) the mature apoA-I molecule without its prosegment; (iii) mouse interleukin-1 beta (IL-1 beta), a 17-kDa protein which is composed of 12 beta strands that form a tetrahedral structure; and (iv) the 31-kDa precursor of IL-1 beta, proIL-1 beta. Efficient expression of these proteins in E. coli was achieved using a plasmid that contains the nalidixic acid-inducible recA promoter and ribosome binding site from the gene 10 leader of bacteriophage T7. In induced cultures the mammalian proteins represented up to 20% of the total bacterial protein mass. Surprisingly, cell fractionation using cold (osmotic) shock indicated that proapoA-I, apoA-I, and IL-1 beta, but not its 31-kDa precursor, were segregated into the periplasmic space with high efficiency: the ratio of periplasmic space/spheroplast distribution ranged from 0.6 to 1.1 in cells harvested 60-180 min after nalidixic acid induction. Not only was this compartmentalization efficient but it was also selective: analysis of the osmotic shock fractions revealed that the periplasmic space preparations were not contaminated with cytoplasmic proteins (e.g. phosphoglycerate dehydrogenase). Sequential Edman degradation showed that these proteins had not undergone any NH2-terminal proteolytic processing. The mammalian proteins did not affect the export of a prototypic bacterial preprotein, beta-lactamase. Together the data suggest that osmotic shock fractionation of E. coli may facilitate the purification of functional foreign proteins produced in this prokaryote. They also raise the possibility that structural elements in these proteins other than conventional signal peptides may effect periplasmic targeting in E. coli.     

Effect of Ssc protein mutations on the outer membrane permeability barrier function in Salmonella typhimurium: a study using ssc mutant alleles made by site-directed mutagenesis

We have previously discovered and characterized a novel essential enterobacterial protein, the Ssc protein of Salmonella typhimurium and found that the mutation Val291----Met in this protein inhibits bacterial growth at 42 degrees C and the function of its outer membrane permeability barrier at 37 degrees C [7]. In the present paper we prepared, by site-directed mutagenesis, a series of novel plasmid-encoded Ssc mutant proteins and tested their ability to compensate the loss of wild-type Ssc. The mutant proteins Met288----Lys and Gly289----Asp completely lacked this ability, and accordingly, were very defective. Ssc mutants Met288----Leu, Met290----Lys, and Met292----Lys were partially defective. Mutants Met290----Leu and Met292----Leu were non-defective as were also four randomly made mutant proteins with mutations outside the 288-292 region. The S. typhimurium derivative which contained both the chromosomally encoded Ssc Val291----Met and the plasmid-encoded Ssc Gly289----Asp had an outer membrane defect more severe than that caused by SscMet291 only. The mutant Ssc proteins had very little, if any, effect on the outer membrane function in the presence of wild-type Ssc. Even though the function of Ssc is not yet known, our results indicate that region 288-292 is important and that SscAsp289 is thus far the most defective mutant Ssc.     

Viable transmembrane region mutants of bacteriophage M13 coat protein prepared by site-directed mutagenesis

Bacteriophage M13 coat protein - a 50-residue protein located at the E. coli host membrane during phage reproduction - is subjected to cytoplasmic, membrane-bound, and DNA-interactive environments during the phage life cycle. In research to examine the specific features of primary/secondary structure in the effective transmembrane (TM) region of the protein (residues 21-39: YIGYAWAMVVVIVGATIGI) which modulate its capacity to respond conformationally to the progressive influences of these varying environments, we have prepared over two dozen viable mutant phages with alterations in their coat protein TM regions. Mutants were obtained through use of site-directed mutagenesis techniques in combination with three "randomized" oligonucleotides which spanned the TM region. No subcloning was required. Among mutations observed were those in which each of the four TM Val residues was changed to Ala, and several with increased Ser or Thr content, including one double Ser mutant (G23S-A25S). Polar substitutions arising at Gly23 and Tyr24-including G23D, Y24H, Y24D and Y24N-suggested that this local segment resides external to the host membrane. Milligram quantities of mutant coat proteins are obtained by growing M13 mutant phages in liter preparations, with isotopic (e.g., 13C) labelling at desired sites, for subsequent characterization and conformational analysis in membrane-mimetic media.     

Correlation of structure with transforming activity of the P21 proteins with substitutions of L-amino acids for Gly at position 13

The effects of amino acid substitutions for Gly 13 on the structure of the transforming region (Leu 6-Gly 15) of the P21 proteins have been explored using conformational energy calculations. It has been found that the substitution of Asp for Gly at this position results in a protein capable of transforming cells into malignant ones. Proteins that contain Ser at position 13 (but no other substitutions), however, transform cells with a greatly reduced activity. The transforming peptide with Asp 13 adopts a conformation that is different from the one for the peptide from the normal protein (with Gly 12 and Gly 13) and that may result in expression of a higher energy malignancy-producing form. The Ser-containing peptide adopts as its lowest energy conformation one that is identical to that of the peptide from the normal protein, thus explaining its lack of transforming activity. From analysis of the interactions preventing the Asp 13-containing peptide from adopting the normal conformation, it is predicted that substitutions of amino acids with branched side chains atC , such as Val, Ile, and Thr, should promote cell transformation. This prediction with Val has recently been confirmed in genetic experiments.     

A Chlamydia trachomatis UDP-N-acetylglucosamine acyltransferase selective for myristoyl-acyl carrier protein. Expression in Escherichia coli and formation of hybrid lipid A species

Chlamydia trachomatis lipid A is unusual in that it is acylated with myristoyl chains at the glucosamine 3 and 3' positions. We have cloned and expressed the gene encoding UDP-N-acetylglucosamine 3-O-acyltransferase of C. trachomatis (CtlpxA), the first enzyme of lipid A biosynthesis. C. trachomatis LpxA displays approximately 20-fold selectivity for myristoyl-ACP over R/S-3-hydroxymyristoyl-ACP under standard assay conditions, consistent with the proposed structure of C. trachomatis lipid A. CtLpxA is the first reported UDP-N-acetylglucosamine acyltransferase that prefers a non-hydroxylated acyl-ACP to a hydroxyacyl-ACP. When CtlpxA was expressed in RO138, a temperature-sensitive lpxA mutant of Escherichia coli, five new hybrid lipid A species were made in vivo after 2 h at 42 degrees C, in place of Escherichia coli lipid A. These compounds were purified and analyzed by matrix-assisted laser desorption ionization/time of flight mass spectrometry. In each case, a myristoyl chain replaced one or both of the ester linked 3-hydroxymyristoyl residues of E. coli lipid A. With prolonged growth at 42 degrees C, all the ester-linked 3-hydroxymyristoyl residues were replaced with myristate chains. Re-engineering the structure of E. coli lipid A should facilitate the microbiological production of novel agonists or antagonists of the innate immunity receptor TLR-4, with possible uses as adjuvants or anti-inflammatory agents.     

Primary structure of protein S13 from the small subunit of escherichia coli ribosomes.

The experimental details which led to the determination of the complete primary structure of protein S13 from the small subunit of Escherichia coli ribosomes are presented. S13 consists of 117 amino acid residues and has the following composition: Asp6, Asn2, Thr6, Ser6, Glu6, Gln2, Pro4, Gly11, Ala11, Cys1, Val7, Met2, Ile12, Leu9, Tyr2, Phe1, His3, Lys11 and Arg15. Tryptophan was not found. The molecular weight of protein S13 as derived from the sequence shown in Fig. 1 is 12970. The amino acid sequence of the protein was determined by combining the results obtained from liquid phase Edman degradation of the intact protein with those from the peptides isolated after enzymatic digestions with trypsin, Staphylococcus aureus protease and thermolysin. Additional information about the primary structure was derived from analysis of the chymotryptic peptides of protein S13 and from its digestion with carboxypeptidase C. The amino acid sequence of protein S13 was compared with the published sequences of the other ribosomal proteins of E. coli and predictions for the secondary structure of this protein were made.     

Structure-function relationships in the GTP binding domain of EF-Tu: mutation of Val20, the residue homologous to position 12 in p21.

Val20 of elongation factor Tu (EF-Tu), one of the best-characterized GTP binding proteins, is a variable residue within the consensus motif G-X-X-X-X-G-K involved in the interaction with the phosphates of GDP/GTP. To investigate the structure-function relationships of EF-Tu, which is widely used as a model protein, Val20 has been substituted by Gly using oligonucleotide-directed mutagenesis. The most important effects are: (i) a strong reduction of the intrinsic GTPase activity, (ii) a remarkable enhancement of the association and dissociation rates of EF-TuGly20-GDP, mimicking the effect of elongation factor Ts (EF-Ts) and (iii) the inability of ribosomes to influence the intrinsic GTPase of EF-Tu uncoupled from poly(Phe) synthesis. EF-TuGly20 can sustain poly(Phe) synthesis, albeit at a much lower rate than wild-type EF-TuVal20. As with the latter, poly(Phe) synthesis by EF-TuGly20 is inhibited by the antibiotic kirromycin, but differs remarkably in that it is largely independent of the presence of EF-Ts. According to primary sequence alignment, position 20 is homologous to position 12 of ras protein p21. As in p21, this position in EF-Tu is critical, influencing specifically the GDP/GTP interaction as well as other functions. The effect of the mutation displays diversities but also similarities with the situation reported for p21 having the corresponding residues in position 12. The differences observed with two homologous residues, Gly20 and Gly12 in EF-Tu and p21 respectively, show the importance of a variable residue in a consensus element in defining specific functions of GTP binding proteins.     

The influence of amino substitutions within the mature part of an Escherichia coli outer membrane protein (OmpA) on assembly of the polypeptide into its membrane

The membrane part of the 325-residue outer membrane protein OmpA of Escherichia coli encompasses residues 1-177. This part is thought to cross the membrane eight times in antiparallel beta-strands, forming four loops of an amphipathic beta-barrel. With the aim of gaining some insight into the mechanism of sorting, i.e. the way the protein recognizes and assembles into its membrane, a set of point mutants in the ompA gene has been generated. Selection for toxicity of ompA expression following mutagenesis with sodium bisulfite yielded genes with multiple base pair substitutions, the majority of which resulted in amino acid substitutions in the membrane moiety of the protein. None of the altered proteins was blocked in membrane incorporation. A proline residue exists at or near each of the presumed turns at the inner side of the outer membrane. Using oligonucleotide-directed mutagenesis, each of them was replaced by a leucine residue which is thought to be a turn blocking residue. None of these proteins had lost the ability to be incorporated into the membrane. Apparently, leucine residues are tolerated at turns in this protein. To interfere with the formation of antiparallel beta-strands, four double mutants were prepared: ompA-ON3 (Ala11----Pro, Leu13----Pro), -ON4 (Ala11----Asp, Leu13----Pro), -ON5 (Gly160----Val, Leu162----Arg), and -ON6 (Leu164----Pro, Val166----Asp). The former three proteins and even quadruple mutants consisting of a combination of ompA-ON2 or -ON4 with -ON5 were not defective in membrane assembly. In contrast, the OmpA-ON6 protein was translocated across the plasma membrane but could not be incorporated into the outer membrane. It is concluded that at least one rather small area of the polypeptide is of crucial importance for the assembly of OmpA into the outer membrane.