Structural and functional characterization of the OmpF and OmpC porins of the Escherichia coli outer membrane: studies involving chimeric proteins

The roles of submolecular regions of OmpF and OmpC, major outer membrane proteins of Escherichia coli, as concerns their biogenesis, structure and function were studied using a large number of chimeric genes constructed from the ompF and ompC genes through single or double homologous in vivo recombination. When recombination between the two genes took place at certain regions of their central regions, no chimeric protein was detected, irrespective of whether the amino-terminal and carboxy-terminal regions were derived from OmpF or OmpC. Biochemical studies revealed that these proteins were synthesized and exported across the cytoplasmic membrane normally, but that they were not properly assembled into the outer membrane and hence were degraded rapidly. Characterization of these chimeric proteins, in which recombination between OmpF and OmpC took place once or twice, suggested that the central region of each of these proteins plays an important role in the respective assembly, whereas the roles of the amino-terminal and carboxy-terminal regions may be marginal. Functional characterization of these chimeric proteins revealed the regions important for the receptor functions of OmpF and OmpC for phages TuIa and TuIb, respectively.

Energy-dependent in vitro translocation of a model protein into Escherichia coli inverted membrane vesicles can take place efficiently in the complete absence of the cytosol fraction

The translocation of the precursor of a secretory protein into Escherichia coli inverted membrane vesicles was demonstrated in the absence of the cytosol fraction. A small, hydrophilic chimeric protein, OmpF-Lpp, possessing an uncleavable signal peptide was used as the model protein. As much as 80% translocation of the precursor protein into membrane vesicles was observed within 6 min in the absence of the cytosol fraction, when the precursor protein purified by means of immunoaffinity chromatography was used. The translocation was dependent on both ATP and respiratory substrates such as succinate. ATP could be replaced by a higher concentration of CTP or UTP, whereas GTP was inactive. Trichloroacetic acid treatment of the precursor protein, which is reported to result in removal of the trigger factor that is attached to a precursor protein (Crooke, E., and Wickner, W. (1987) Proc. Natl. Acad. Sci. U.S.A. 84, 5216-5220), did not lower the translocation efficiency significantly. Finally, the precursor protein, which was highly purified by means of successive immunoaffinity chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis, could still be efficiently translocated into the membrane vesicles. The precursor proteins purified in the presence and absence of bovine serum albumin were both active. Neither washing of the membrane vesicles for prevention of possible contamination by cytosolic factors nor the addition of the cytosol fraction to the reaction mixture affected the translocation efficiency. These results indicate that the in vitro translocation of the OmpF-Lpp precursor protein can take place in the complete absence of cytosolic soluble proteins.

Proton motive force-dependent and -independent protein translocation revealed by an efficient in vitro assay system of Escherichia coli

Inverted membrane vesicles prepared from Escherichia coli spheroplasts were fractionated by means of sucrose gradient centrifugation, and a vesicle preparation exhibiting efficient and quantitative translocation of secretory proteins was obtained. The translocation of OmpA and an uncleavable model protein, uncleavable OmpF-Lpp, took place almost completely in 2-3 min, whereas that of OmpF-Lpp, a chimeric secretory protein, required 20 min for completion. The requirement of the proton motive force (delta muH+) for in vitro translocation was then examined with these three proteins. The translocation of all these proteins was significantly inhibited by the addition of carbonyl cyanide m-chlorophenylhydrazone (CCCP) or when stripped membrane vesicles lacking F1-ATPase were used, suggesting that delta muH+ generally participates in the translocation reaction. The inhibition was complete with OmpF-Lpp, whereas significant amounts of uncleavable OmpF-Lpp and OmpA were translocated at a slower rate even with the stripped membrane vesicles in the presence of a high concentration of carbonyl cyanide m-chlorophenylhydrazone. The delta muH+-independent translocation was inhibited by a nonhydrolyzable ATP analogue. These results indicate that although translocation of OmpF-Lpp obligatory requires delta muH+, the latter two proteins can be translocated in not only a delta muH+-dependent manner but also a delta mu H+-independent manner.

SecA protein is directly involved in protein secretion in Escherichia coli

A high-expression plasmid for the secA gene was constructed. The SecA protein was then overproduced in E. coli and purified. The purified SecA stimulated the in vitro translocation of a model secretory protein into inverted membrane vesicles pretreated with 4 M urea. Membrane vesicles from a secAts mutant exhibited lower translocation activity, which was enhanced by SecA. These results indicate that SecA is directly involved in protein secretion across the cytoplasmic membrane.

Introduction of basic amino acid residues after the signal peptide inhibits protein translocation across the cytoplasmic membrane of Escherichia coli. Relation to the orientation of membrane proteins

The introduction of positive charges at the amino terminus of the mature domain of secretory proteins resulted in strong inhibition of their translocation across the cytoplasmic membrane of Escherichia coli, both in vitro and in vivo. The model secretory proteins used were OmpF-Lpp chimeric proteins possessing a cleavable or uncleavable signal peptide, beta-lactamase (Bla) and Bla-Lpp chimeric proteins. It is suggested that positively charged residues preceding the hydrophobic domain of the signal peptide have a positive effect, and ones following the hydrophobic domain, a negative effect on the translocation. These findings are discussed in relation to the orientation of membrane proteins, of which positive charges are predominant on the cytoplasmic surface.

Stereospecific positioning of the cis-acting sequence with respect to the canonical promoter is required for activation of the ompC gene by a positive regulator, OmpR, in Escherichia coli

Expression of the ompC gene coding for a major outer-membrane protein of Escherichia coli is regulated by a transcriptional activation mechanism that requires the ompR gene product, OmpR. It was demonstrated that multiple OmpR molecules bind to a cis-acting sequence located upstream from the canonical -35 and -10 regions of the ompC promoter. Using an ompC-lacZ fusion gene, the distance between the cis-acting upstream sequence (OmpR-binding site) and the -35 and -10 regions (RNA polymerase-binding site) has been changed. We demonstrated that the ompC transcription was activated in an OmpR-dependent manner even when the cis-acting upstream sequence was separated from the -35 and -10 regions by several turns of the DNA helix, providing that the distance between them was a near-integral multiple of one turn of the DNA helix. Evidence is presented that stereospecific positioning of the cis-acting upstream sequence with respect to the canonical promoter is required for activation of the ompC gene by the positive regulator, OmpR.

Isolation and characterization of mutants of a marine Vibrio strain that are defective in production of extracellular proteins

A marine Vibrio strain, Vibrio sp. strain 60, produces several extracellular proteins, including protease, amylase, DNase, and hemagglutinin. Mutants of Vibrio sp. strain 60 (epr mutants) pleiotropically defective in production of these extracellular proteins were isolated. They fell into two classes, A and B. In class A, no protease activity was detected in the cells either, whereas in class B, considerable protease activity was detected in the cells. Gel electrophoretic analysis revealed that the protease detected in class B mutant cells was similar to the protease excreted by the parent strain. In addition, the protease in class B mutant cells was found to be localized in the periplasmic space. These results suggest that the passage of the protease through the outer membrane is blocked in class B mutants. Comparison of membrane protein profiles by polyacrylamide gel electrophoresis revealed that all the epr mutants contained an increased amount of a 94,000-Mr protein that may be an outer membrane protein. Four epr mutations were mapped in two different regions of the Vibrio chromosome by transduction; two class A mutations and one class B mutation were located close to each other, whereas another class B mutation was located in a different region of the chromosome.

Expression and excretion of human pancreatic secretory trypsin inhibitor in lipoprotein-deletion mutant of Escherichia coli

We constructed a gene coding for the 56-amino acid human pancreatic secretory trypsin inhibitor (PSTI), and ligated it on a plasmid downstream from the trp promoter and the signal peptide sequence of alkaline phosphatase. The resulting plasmid was transfected into a lipoprotein deletion mutant (Escherichia coli JE5505) and the plasmid-carrying cells were induced with 3-indoleacrylic acid. A considerable amount (50 micrograms/ml culture) of the mature PSTI protein was detected in the culture supernatant. The excreted PSTI was identical to the natural PSTI protein with respect to the trypsin-inhibiting activity, the N-terminal and the C-terminal amino acid sequences and the amino acid composition.

Clinical and neuropathological study of a familial case of juvenile parkinsonism

This is a detailed autopsy case of rare juvenile parkinsonism with dominant heredity. The patient displayed parkinsonian symptoms which began at the age of 24, and expired in a state of quadriplegia-in-flexion at 35. In the later stage, myoclonic jerks, epileptiform convulsions and dementia appeared. L-dopa was effective only in the early stages. The autopsy revealed severe degeneration and the formation of atypical Lewy bodies in the cerebral cortex, as well as typical lesions of idiopathic parkinsonism with a Lewy body formation in the brain stem. This case was considered to belong essentially to idiopathic parkinsonism. The pathology of juvenile parkinsonism is reviewed briefly.

Efficient in vitro translocation into Escherichia coli membrane vesicles of a protein carrying an uncleavable signal peptide. Characterization of the translocation process

The translocation into Escherichia coli cytoplasmic membrane vesicles of a protein containing an uncleavable signal peptide was studied. The signal peptide cleavage site of the ompF-lpp chimeric protein, a model secretory protein, was changed from Ala-Ala to Phe-Pro through oligonucleotide-directed site-specific mutagenesis of the ompF-lpp gene on a plasmid. The mutant protein was no longer processed by the signal peptidase. When proteinase K treatment was adopted as a probe for protein translocation into inverted membrane vesicles, the mutant protein exhibited rapid and almost complete translocation, most likely due to the lack of premature cleavage of the signal peptide before the translocation. This result also indicates that cleavage of the signal peptide is not required for translocation of the mature domain of the protein. The establishment of an efficient system made it possible to perform precise and quantitative analysis of the translocation process. The translocation was time-dependent, vesicle-dependent, and required ATP and NADH. Translocation into membrane vesicles was also observed with the uncleavable precursor protein purified by means of immunoaffinity chromatography, although the efficiency was appreciably low. The translocation required only ATP and NADH. Addition of the cytosolic fraction did not enhance the translocation.

Ruminant forestomach and abomasal mucormycosis under rumen acidosis

Spores of Absidia corymbifera were inoculated orally into sheep with ruminal acidosis produced by feeding barley. Lesions, which developed in forestomachs of all four inoculated cases, included desquamation of superficial layers of the mucosae and focal necrosis from lamina propria to muscular layers. Granulomatous lesions were in the submucosa of three sheep. Lesions in the abomasum (two sheep) included focal necrosis, diffuse hemorrhages, and infiltration of neutrophils. All lesions were accompanied by mycotic proliferation. These results show that A. corymbifera can invade forestomach mucosae through degenerate epithelium resulting from ruminal acidosis.

Purification and characterization of a signal peptide, a product of protein secretion across the cytoplasmic membrane of Escherichia coli

A signal peptide, a processing product of the precursor of the lipoprotein in the cytoplasmic membrane of Escherichia coli, has been purified through extractions with butanol and ethyl ether and chromatographies with a Sephadex LH-60 column and Sep-pak C18. Analysis of the amino acid composition and sequencing of the N- and C-termini indicate that the signal peptide was intact, suggesting that the first step of the signal peptide catabolism in the cytoplasmic membrane is the cleavage of the intact signal peptide. During the purification, the signal peptide exhibited unique features, including strong interaction with phospholipids. The possible importance of such features in the process of protein translocation across membranes is discussed.

Interaction of OmpR, a positive regulator, with the osmoregulated ompC and ompF genes of Escherichia coli. Studies with wild-type and mutant OmpR proteins

The OmpR protein is a positive regulator involved in osmoregulatory expression of the ompC and ompF genes that specify the major outer membrane proteins OmpC and OmpF, respectively. We purified the OmpR protein not only from wild-type cells but also from two ompR mutants (ompR2 and ompR3) exhibiting quite different phenotypes as to osmoregulation of the ompC and ompF genes. The OmpR2 protein has an amino acid conversion in the C-terminal portion of the OmpR polypeptide, whereas the OmpR3 protein has one in the N-terminal portion. Comparative studies on these purified OmpR proteins were carried out in terms of their interaction with the ompC and ompF promoters. The nucleotide sequences involved in OmpR-binding were determined in individual promoter regions by deoxyribonuclease I footprinting. The OmpR3 protein as well as the wild-type OmpR protein appeared to bind, to similar extents, to both the ompC and ompF promoters. In contrast, the OmpR2 protein bound preferentially to the ompF promoter and failed to protect the ompC promoter against DNAse I digestion. These results support the view that the C-terminal portion of the OmpR protein is responsible for the binding of the OmpR protein to the ompC and ompF promoter DNAs. Based on these results, the structure and function of the OmpR protein are discussed in relation to the mechanism of osmoregulation.

Molecular assembly of the lipoprotein trimer on the peptidoglycan layer of Escherichia coli

The molecular assembly of the major outer membrane lipoprotein on the peptidoglycan layer was studied using two hybrid genes coding for different OmpF-lipoprotein hybrid proteins. One gene codes for a "lipoprotein" in which the diacylglyceryl cysteine residue is replaced with the Ala-Glu residue of the NH2 terminus of the OmpF protein (hybrid protein I). The other gene codes for the lipid-free "lipoprotein" from which the COOH-terminal lysine residue was further deleted (hybrid protein II). Hybrid protein I existed as a trimer. A significant portion of it was found to be composed of only the free form, which was noncovalently associated with the peptidoglycan layer. The purified hybrid protein I trimer was dissociated into the subunit in the presence of guanidine-HCl and reassociated on dialysis. Both the native and reassociated trimers were bound to the lipoprotein-free peptidoglycan layer. No enhancement of the binding was observed when the reassociation reaction was carried out simultaneously. Hybrid protein II, on the other hand, did not exhibit association with peptidoglycan in both the cellular fractionation and in vitro binding experiments, although it existed as a trimer. It is concluded that 1) the protein domain of the lipoprotein exists as a trimer which is noncovalently as well as covalently associated with the peptidoglycan layer and 2) although the deletion of the COOH terminal lysine residue did not interfere with the trimerization, it interfered with the noncovalent interaction with the peptidoglycan layer.

NMR analyses of the conformations of L-isoleucine and L-valine bound to Escherichia coli isoleucyl-tRNA synthetase

The 400-MHz 1H NMR spectra of L-isoleucine and L-valine were measured in the presence of Escherichia coli isoleucyl-tRNA synthetase (IleRS). Because of chemical exchange of L-isoleucine or L-valine between the free state and the IleRS-bound state, a transferred nuclear Overhauser effect (TRNOE) was observed among proton resonances of L-isoleucine or L-valine. However, in the presence of isoleucyl adenylate tightly bound to the amino acid activation site of IleRS, no TRNOE for L-isoleucine or L-valine was observed. This indicates that the observed TRNOE is due to the interaction of L-isoleucine or L-valine with the amino acid activation site of IleRS. The conformations of these amino acids in the amino acid activation site of IleRS were determined by the analyses of time dependences of TRNOEs and TRNOE action spectra. The IleRS-bound L-isoleucine takes the gauche+ form about the C alpha-C beta bond and the trans form about the C beta-C gamma 1 bond. The IleRS-bound L-valine takes the gauche- form about the C alpha-C beta bond. Thus, the conformation of IleRS-bound L-valine is the same as that of IleRS-bound L-isoleucine except for the delta-methyl group. The side chain of L-isoleucine or L-valine lies in an aliphatic hydrophobic pocket of the active site of IleRS. Such hydrophobic interaction with IleRS is more significant for L-isoleucine than for L-valine. The TRNOE analysis is useful for studying the amino acid discrimination mechanism of aminoacyl-tRNA synthetases.

Use of a series of ompF-ompC chimeric proteins for locating antigenic determinants recognized by monoclonal antibodies against the ompC and ompF proteins of the Escherichia coli outer membrane

A method is presented for the efficient location of antigenic determinants using a series of chimeric proteins. By means of in vivo homologous recombination between the ompC and ompF genes coding for OmpC and OmpF, homologous proteins of the Escherichia coli outer membrane, a series of ompF-ompC chimeric genes was constructed (Nogami, T., Mizuno, T., & Mizushima, S. (1985) J. Bacteriol. 164, 797-801, and this work). The OmpF-OmpC chimeric proteins expressed by these genes were successfully used to locate antigenic determinants recognized by monoclonal antibodies, which specifically react with either the OmpC or OmpF protein. Interaction between monoclonal antibodies and the chimeric proteins was examined by means of either enzyme-linked immunosorbent assay or immunoblot analysis. The antigenic determinants recognized by three anti-OmpC antibodies and one anti-OmpF antibody were thus located. Finally, the polypeptides covering these regions were chemically synthesized for two of them and then tested as to their reactivity with the antibodies. The peptides reacted with the corresponding antibodies when the former were chemically coupled with bovine serum albumin. Most of the monoclonal antibodies isolated in this work were highly specific to the unfolded monomer of the protein against which the antibody was raised. But they did not react with the trimer, the native form. These results are discussed in relation to the structures and functions of the OmpC and OmpF proteins. The use of a series of monoclonal antibodies for studying the mechanism of protein translocation across the cytoplasmic membrane is also discussed.

Function of micF as an antisense RNA in osmoregulatory expression of the ompF gene in Escherichia coli

To analyze the function of micF as an antisera RNA in the osmoregulatory expression of the ompF gene in Escherichia coli, we performed two experiments. In the first experiment, two strains were constructed in which the transcription initiation site of the ompF gene and the transcription termination site of the micF gene were separated by 186 and 4,100 base pairs, respectively, on the chromosome. These two strains showed almost the same profile of ompF expression as the wild-type strain in which the two genes are separated by 10(6) base pairs. When a high-copy-number plasmid carrying the micF gene was introduced into these strains, ompF expression was completely repressed, whereas no repression was observed with a low-copy-number plasmid carrying the micF gene. These results indicate that the distance between the two genes on the chromosome is not critical for the function of micF. In the second experiment, expression of the ompF gene was examined by pulse-labeling in both the micF+ and the micF deletion strains. Upon a shift from a low- to a high-osmolarity medium, suppression of OmpF protein synthesis occurred more quickly and more extensively in the micF+ strain than in the micF deletion strain. The steady-state synthesis of the OmpF protein was also completely suppressed in the micF+ strain in the high-osmolarity medium, whereas the suppression was incomplete in the micF deletion strain. From these results we conclude that (i) the micF gene contributes to the fast and complete response of the OmpF synthesis to the medium osmolarity, and that (ii) the distance between the micF and ompF genes on the chromosomes is not critical for the function of the micF gene. The results suggest, rather, that the ratio of the copy numbers of the two genes is critical for the function of the micF gene.

Novel rpoA mutation that interferes with the function of OmpR and EnvZ, positive regulators of the ompF and ompC genes that code for outer-membrane proteins in Escherichia coli K12

The expression of the ompF and ompC genes that code for major outer-membrane proteins of Escherichia coli is positively regulated by the products of the ompR and envZ genes. Recently, we isolated the ompR77 mutation, which suppresses the envZ11 mutation. In this work, a novel mutation that interferes with the suppression of the envZ11 mutation by ompR77 was isolated. The mutation was located in the rpoA gene that codes for the alpha subunit of DNA-dependent RNA polymerase. These results suggest that an interaction between the positive regulators and RNA polymerase is involved in the initiation of transcription of the ompF and ompC genes. In addition, the results suggest that during transcription the RNA polymerase migrates along DNA strands with the alpha subunit facing backward and the beta beta' subunits facing forward.

Characterization of the sppA gene coding for protease IV, a signal peptide peptidase of Escherichia coli

The sppA gene codes for protease IV, a signal peptide peptidase of Escherichia coli. Using the gene cloned on a plasmid, we constructed an E. coli strain carrying the ampicillin resistance gene near the chromosomal sppA gene and an sppA deletion strain in which the deleted portion was replaced by the kanamycin resistance gene. Using these strains, we mapped the sppA gene at 38.5 min on the chromosome, the gene order being katE-xthA-sppA-pncA. Although digestion of the signal peptide that accumulated in the cell envelope fraction was considerably slower in the deletion mutant than in the sppA+ strain, it was still significant, suggesting the participation of another envelope protease(s) in signal peptide digestion.

Construction of a series of ompC-ompF chimeric genes by in vivo homologous recombination in Escherichia coli and characterization of their translational products

OmpC and OmpF are major outer membrane proteins and although they are homologous proteins, they function differently in several respects. As an approach to elucidate the submolecular structures that determine their differences, we have constructed a series of ompC-ompF chimeric genes by in vivo homologous recombination between these two genes, which are adjacent on a plasmid. The recombination sites in the chimeric genes were localized by means of restriction endonuclease analysis and nucleotide sequence determination. Most of the chimeric gene products were accumulated in the outer membrane. One of the chimeric gene products, with a fusion site in a central region between the OmpC and OmpF proteins, was normally expressed but not accumulated in the outer membrane. The trimeric structures of some of the chimeric gene products appeared to be extremely unstable in a SDS solution. From these results, domains contributing to the formation of specific structures in which the OmpC and OmpF proteins differ were identified. Bacterial cells possessing the chimeric gene products were also investigated as to their sensitivity to phages that require either OmpC or OmpF as a receptor component. With the aid of the chimeric gene products, the immunogenic determinants for three anti-OmpC monoclonal antibodies were found to be localized at different portions of the OmpC polypeptide: the N-terminal, central and C-terminal portions, respectively.

Roles of the Pribnow box in positive regulation of the ompC and ompF genes in Escherichia coli

The roles of the first base of the Pribnow box in positive regulation of the ompC and ompF genes were studied. G- and A-to-T substitutions of the first base of the ompC and ompF Pribnow boxes, respectively, resulted in a high-level functioning of the promoters in the ompR background. The level was further enhanced significantly in the ompR+ background. The effects of other substitutions were also studied. Based on these observations, the roles of the Pribnow box in the positive regulation are discussed.

In vitro translocation of protein across Escherichia coli membrane vesicles requires both the proton motive force and ATP

The energy requirement for protein translocation across membrane was studied with inverted membrane vesicles from an Escherichia coli strain that lacks all components of F1F0-ATPase. An ompF-lpp chimeric protein was used as a model secretory protein. Translocation of the chimeric protein into membrane vesicles was totally inhibited in the presence of carbonyl cyanide m-chlorophenylhydrazone (CCCP) or valinomycin and nigericin and partially inhibited when either valinomycin or nigericin alone was added. Depletion of ATP with glucose and hexokinase resulted in the complete inhibition of the translocation process, and the inhibition was suppressed by the addition of ATP-generating systems such as phosphoenolpyruvate-pyruvate kinase or creatine phosphate-creatine kinase. These results indicate that both the proton motive force and ATP are required for the translocation process. The results further suggest that both the membrane potential and the chemical gradient of protons (delta pH), of which the proton motive force is composed, participate in the translocation process.

Isolation and characterization of deletion mutants of ompR and envZ, regulatory genes for expression of the outer membrane proteins OmpC and OmpF in Escherichia coli

Expression of the ompC and ompF genes coding for the major outer membrane proteins, OmpC and OmpF, respectively, is known to be controlled by at least two regulatory genes, ompR and envZ, which together comprise a single ompB operon. We constructed chromosomal mutants with either ompR-envZ deletion or envZ deletion. Characterization of these deletion strains showed that the OmpR protein is necessary for transcription of the ompC and ompF genes, and the EnvZ protein is essential for normal regulation of the ompC and ompF expression, which is affected by the medium osmolarity. We also constructed several plasmids carrying different portions of the ompB operon. Characterization of these plasmids allowed us to identify the OmpR protein with an apparent molecular weight of 29 kilodaltons (kDa) and the EnvZ protein with an apparent molecular weight of 50 kDa. The initiation codon for EnvZ translation appeared to overlap with the termination codon for OmpR translation. It was also found that a truncated EnvZ polypeptide (44 kDa) which lacks the N-terminal 55 amino acid residues can complement the envZ deletion mutant. Based on these results, the structure and function of the ompB operon are discussed in relation to the regulation of ompC and ompF expression.

Interaction between two regulatory proteins in osmoregulatory expression of ompF and ompC genes in Escherichia coli: a novel ompR mutation suppresses pleiotropic defects caused by an envZ mutation

The ompR and envZ genes, which together constitute the ompB operon, are involved in osmoregulatory expression of the OmpF and OmpC proteins, major outer membrane proteins of Escherichia coli. The envZ11 mutation results in the OmpF- OmpC-constitutive phenotype. A mutant which suppressed defects caused by the envZ11 mutation was isolated. The suppressor mutation also suppressed the LamB- PhoA- phenotype caused by the envZ11 mutation. The mutation occurred in the ompR gene and hence was termed ompR77. The ompR77 mutation alone produced no obvious phenotype. Functioning of the ompR77 allele remained envZ gene dependent. Although the ompR77 mutation suppressed the envZ11 mutation, it did not suppress a mutation that occurred in another position within the envZ gene (envZ160). These results indicate that OmpR and EnvZ, two regulatory proteins, functionally interact with each other.

[A case of Pick's disease with long duration--an extraordinary cerebral change in the fore part of cerebrum]

An autopsied case of Pick's disease, having an extraordinary cerebral change in the anterior portion of Lobus frontalis and temporalis, was reported. Our case is a 71 year-old woman at death with a fourteen year history of chronic progressive dementia and mental deterioration, and it may be stressed that the existence lasted 8 years, over the latter half of clinical course, was depended on the tube feeding. The first symptoms suddenly appeared in 1964, 2 months after her husband's death of illness, when she was 57. She prepared the table for breakfast late at night, calculated wrongly in her domestic account book, and stole foods in the grocery. Two years later, her illness was diagnosed as presenile dementia by characteristic personality change and marked dilatation of anterior horn of lateral ventriculus. On admission to National Musashi Sanatorium, three years after the first symptoms' appearance, she presented restless walking, insomnia, memory loss, weakness of concentration, and high degree of disorientation. Particularly, it was noticeable that she behaved with bizzare contact. After 1970, tube feeding was introduced continuously, because of swallowing difficulty. Death occurred in July 1978 from a general weakness and a broncho-pneumonia, 14 years after the onset of the first symptoms. Autopsy revealed small and atrophied brain weighed 820 g. Cerebral cortical atrophy extended to frontal, temporal, insular, and parietal lobes, but right T-1 was relatively well preserved. On section, frontal and temporal ventriculus were remarkably enlarged and caudate nuclei were extremely atrophic.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of the OmpR protein, a positive regulator involved in osmoregulatory expression of the ompF and ompC genes in Escherichia coli

The OmpR protein is a positive regulator involved in osmoregulatory expression of the ompF and ompC genes, which respectively code for major outer membrane proteins OmpF and OmpC of Escherichia coli. The OmpR protein has been purified to homogeneity from an overproducing strain harboring an ompR gene-carrying plasmid. Throughout the purification the OmpR protein behaved as a single entity. The molecular weight determined on sodium dodecyl sulfate-polyacrylamide gel, the total amino acid composition, and the NH2-terminal amino acid sequence of the purified protein were essentially the same as those deduced from the nucleotide sequence of the ompR gene. Molecular weight determination and cross-linking study on the native protein revealed that the purified protein exists as a monomer. The purified OmpR protein was specifically bound to the promoter regions of the ompC and ompF genes. Experiments with a series of upstream deletions of the ompC and ompF promoters revealed that the region upstream from the -35 region was indispensable for OmpR binding to both the ompC and the ompF promoters. Although it has been proposed that depending on the medium osmolarity the OmpR protein may exist in two alternative structures, which respectively regulate functioning of the ompC and the ompF promoters, the purified OmpR protein appeared to be homogeneous and interacted with both promoters to the same extent.

Characterization by deletion and localized mutagenesis in vitro of the promoter region of the Escherichia coli ompC gene and importance of the upstream DNA domain in positive regulation by the OmpR protein

The ompC gene codes for a major outer membrane protein whose expression is regulated by the ompR and envZ genes. Two sets of promoter deletion mutants, with upstream and downstream deletions, were constructed on a plasmid in vitro, and their promoter activity was studied by connecting them with the lacZ gene. The DNA sequence for the ompC promoter, including the -35 and -10 regions and the mRNA start site, was defined at the region about 100 base pairs upstream from the ATG initiation codon for the pro-OmpC protein. An additional 61-base-pair sequence extending upstream from the -35 region was required for the ompC promoter to function fully. After targeting the upstream region of the ompC promoter fused to the lacZ gene on a plasmid, in vitro-localized mutagenesis was performed to isolate cis-dominant mutations that affect ompC transcription. Four mutant groups, each of which had common phenotypes for expression and regulation of the gene, were identified. The individual groups also had common base substitutions. In two of the groups, the common base substitutions were localized in the upstream region of the ompC promoter, whereas in the other two they were localized in the -35 region. From these results, the upstream region of the ompC promoter was considered to be the domain responsible for activation by the ompR gene product.

Complementation analysis of the wild-type and mutant ompR genes exhibiting different phenotypes of osmoregulation of the ompF and ompC genes of Escherichia coli

Expression of the ompF and ompC genes, which encode the major outer membrane proteins, OmpF and OmpC, respectively, is affected in a reciprocal manner by the osmolarity of the growth medium. This osmoregulation is mediated by the OmpR protein, a positive regulator of both genes, which is encoded by the ompR gene. Structural and functional properties of this regulatory protein were studied through complementation analysis of the wild-type and five mutant ompR genes that exhibited differences in osmoregulation of the expression of the OmpF and OmpC proteins. Complementation was carried out with combinations of a host strain and a plasmid, each of which carried either the wild-type or a mutant ompR gene. In some combinations, negative complementation was observed. For example, ompR1, a deletion mutation with an OmpF- OmpC- phenotype, was dominant to OmpF+ or OmpC+ phenotypes conferred by other ompR genes. Positive complementation of two mutant ompR genes was also observed in other combinations, when the two mutations were distantly located from each other on the OmpR protein. These results, together with other observations, support the view that the OmpR protein has a two-domain structure, each domain exhibiting a different role in the expression of the OmpF and OmpC proteins, and that this protein takes a multimeric structure as a functional unit.

Molecular cloning and sequencing of the sppA gene and characterization of the encoded protease IV, a signal peptide peptidase, of Escherichia coli

Clones carrying a gene causing overproduction of protease IV, a signal peptide peptidase of Escherichia coli, were isolated from the Clarke and Carbon's collection. Restriction mapping analysis revealed that pLC7-10 and pLC40-13, thus isolated, shared the same chromosomal DNA region. The 2.3-kilobase RsaI-SalI fragment in this region, which was found to carry the gene, was subjected to nucleotide sequence determination. Only one long open reading frame was found. The hypothetical polypeptide sequence deduced from the DNA sequence has a molecular mass of 67,241 daltons. The putative gene was named sppA. Protease IV was purified to homogeneity from the cytoplasmic membrane of an overproducing strain harboring a sppA gene-carrying plasmid. The purified enzyme gave a single polypeptide band of 67,000-dalton molecular mass on sodium dodecyl sulfate-polyacrylamide gel. This molecular mass and the amino acid composition of the purified enzyme were consistent with the deduced primary structure of the sppA gene product. The molecular mass thus determined was almost twice as large as that previously reported by Pacaud (Pacaud, M. (1982) J. Biol. Chem. 257, 4333-4339). A cross-linking study revealed that protease IV is a tetramer of the polypeptide. From these results, we conclude that protease IV is a tetramer of the sppA gene product.

Trimeric structure and localization of the major lipoprotein in the cell surface of Escherichia coli

A hybrid gene consisting of the ompF promoter, the coding regions for the signal peptide, and the Ala-Glu residue of the OmpF NH2 terminus and the coding region for the major outer membrane lipoprotein devoid of the NH2-terminal cysteine residue was constructed. Escherichia coli carrying the cloned gene produced the predicted hybrid protein that is the same as the major lipoprotein except that the diacyl glycerylcysteine residue at the NH2 terminus is replaced by the Ala-Glu residue. The hybrid protein was localized in the periplasmic space as a trimer with a noncovalent interaction in addition to the previously known covalent interaction with the peptidoglycan. These results strongly indicate that the major lipoprotein exists as a trimer in the periplasmic space with covalent and noncovalent interactions with the peptidoglycan layer through the protein domain on one side and with the hydrophobic interaction with the outer membrane through the lipid domain on the other side. The trimeric structure of the lipoprotein was directly demonstrated by the chemical cross-linking of the native lipoprotein with both cleavable and uncleavable reagents. The cross-linking study also revealed interaction between the lipoprotein and the OmpA protein, a major outer membrane protein.

Molecular analysis of mutant ompR genes exhibiting different phenotypes as to osmoregulation of the ompF and ompC genes of Escherichia coli

Expression of the ompF and ompC genes coding for major outer membrane proteins is osmoregulated by solutes, such as sucrose and NaCl, in the growth medium. The OmpR protein, a positive regulator of these genes, is involved in the osmoregulation (Dairi et al. 1985; Nara et al. 1984). In the present work, five mutant ompR genes exhibiting different phenotypes of osmoregulation were cloned and sequenced. Three of them, ompR1, ompR2 and ompR20, were previously isolated mutants. The others, ompR3 and ompR4, were isolated in the present work. The ompR1 mutation resulted in the deletion of 19 amino acids near the C-terminus of the OmpR protein. The ompR3 and ompR4 mutations resulted in Arg15 to Cys and Arg71 to Thr conversions, respectively, at the N-terminal portion, whereas the ompR20 and ompR2 mutations resulted in Arg150 to Cys and Val207 to Met conversions, respectively, at the C-terminal portion. Based on these results, the structure and function of the OmpR protein are discussed in relation to the mechanism of osmoregulation.

Secretion into the culture medium of a foreign gene product from Escherichia coli: use of the ompF gene for secretion of human beta-endorphin

The ompF gene codes for a major outer membrane protein of Escherichia coli. A plasmid was constructed in which the structural gene for human beta-endorphin is preceded by the upstream region of the ompF gene consisting of the promoter region and the coding regions for the signal peptide and the N terminus of the OmpF protein. When the plasmid was introduced into E. coli N99, and OmpF-beta-endorphin fused peptide was synthesized and secreted into the culture medium through both the cytoplasmic and outer membranes. The OmpF signal peptide was cleaved correctly during the secretion, indicating that the export of the fused protein across the cytoplasmic membrane was dependent on the signal peptide. The secretion into the culture medium was apparently selective. Neither beta-lactamase nor alkaline phosphatase (both are periplasmic proteins) appeared in the culture medium in significant amounts. The mode of passage of the fused peptide across the outer membrane is discussed.

Domains involved in osmoregulation of the ompF gene in Escherichia coli

Expression of the ompF gene, which is under the control of the OmpR protein, is regulated by the osmolarity of the medium. To study the mechanism of osmoregulation, plasmids carrying two different types of chimeric genes were constructed. In one type, the coding region of the ompF gene was linked to the trp promoter (trpPO) preceding ompF, and in the other type the ompF upstream region, mostly composed of the region for regulation by OmpR and the promoter region, was linked to the lacZ gene by protein fusion. Expression of beta-galactosidase by the lacZ chimeric gene was OmpR dependent and osmoregulated as sensitively as that of the intact ompF gene. In the ompR20 background the direction of osmoregulation was opposite that of normal osmoregulation, as was the direction of osmoregulation of the intact ompF gene. Osmoregulation was also observed with trpPO-ompF chimeric genes. However, the regulation was not as sensitive to the osmolarity of the medium as was regulation of the intact ompF gene and was independent of OmpR. These results suggest that OmpR-dependent osmoregulation played a primary role in the osmoregulation of ompF expression and that ompR-independent osmoregulation most likely did not play a crucial role. Studies with a series of trpPO-ompF chimeric genes also suggest that the untranslated leader region, about 100 base pairs in length, between the transcription initiation site and the initiation codon was not required for osmoregulation.

Construction of a series of ompF-ompC chimeric genes by in vivo homologous recombination in Escherichia coli and characterization of the translational products

OmpF and OmpC are major outer membrane proteins. Although they are homologous proteins, they function differently in several respects. As an approach to elucidate the submolecular structures that determine the difference, a method was developed to construct a series of ompF-ompC chimeric genes by in vivo homologous recombination between these two genes, which are adjacent on a plasmid. The genomic structures of these chimeric genes were determined by restriction endonuclease analysis and nucleotide sequence determination. In almost all cases, recombination took place between the corresponding homologous regions of the ompF and ompC genes. Many of the chimeric genes produced proteins that migrated to various positions between the OmpF and OmpC proteins on polyacrylamide gel. On the basis of the results, a domain contributing to the mobility difference the OmpF and OmpC proteins was identified. Some chimeric genes did not accumulate outer membrane proteins, despite the fact that the fusion of the ompF and ompC genes was in frame. Bacterial cells possessing the chimeric proteins were also tested as to their sensitivity to phages which require either OmpF or OmpC as a receptor component. The chimeric proteins were either of the OmpF or OmpC type with respect to receptor activity. Based on the observations, the roles of submolecular domains in the structure, function, and biogenesis of the OmpF and OmpC proteins are discussed.

Positive control of transcription initiation in Escherichia coli. A base substitution at the Pribnow box renders ompF expression independent of a positive regulator

Expression of the ompF gene coding for a major outer membrane protein of Escherichia coli is positively regulated by the product of the ompR gene, OmpR. Using an ompF-tet chimera gene, ompF promoter mutants that render the ompF expression independent of the OmpR protein were isolated. In all of the four mutants that were isolated separately, the first base of the Pribnow box was changed from A to T. The mutant promoter did not require the upstream domain of the -35 region that is required for the OmpR-dependent functioning of the wild-type promoter. It is concluded that the domain upstream from the -35 region plays a role in the positive regulation by the OmpR protein. A statistical survey of the E. coli promoter sequence revealed that almost all of the genes that do not require an activator protein for their expression possess T at the first position of the Pribnow box, while the position is occupied by other bases in almost all of the positively regulated genes. Based on these facts, the mechanism of positive regulation of the gene expression by an activator protein is discussed.

Isolation of gram quantities of isoleucyl-tRNA synthetase from an overproducing strain of Escherichia coli and its use for purification of cognate tRNA

The ileS gene coding for isoleucyl-tRNA synthetase was cloned on a runaway-replication plasmid. From the cells harboring the plasmid, gram quantities of the synthetase were isolated using two column procedures. The synthetase was used for the purification of cognate tRNA. Isoleucine tRNAGAU of greater than 90% purity was easily isolated by taking advantage of a specific complex formation of the synthetase with cognate tRNA.

Construction and characterization of a deletion mutant lacking micF, a proposed regulatory gene for OmpF synthesis in Escherichia coli

A method is presented for the construction of a deletion mutant lacking the micF gene, which has been proposed to negatively regulate expression of the ompF gene. The method includes (i) construction of a temperature-sensitive plasmid containing a chromosomal fragment that carries both flanking regions of the micF gene but does not carry micF itself and (ii) replacement of the corresponding chromosomal domain with the fragment. The method is applicable to construction of a deletion mutant for any Escherichia coli chromosomal gene provided that it is dispensable. The micF deletion was confirmed by genetic and biochemical tests, including nucleotide sequence analysis. ompF expression in the micF deletion mutant thus constructed was normally regulated and was not enhanced. When micF was cloned into a high-copy-number plasmid it repressed ompF gene expression, whereas when cloned into a low-copy-number plasmid it did not. From these results, it is concluded that a single copy of the micF gene on the E. coli chromosome does not play a critical role in ompF gene expression.

Clinicopathologic studies on neuro-Behçet's disease

Nine cases of neuro-Behcet's disease were investigated clinicopathologically. Pathological pictures of the central nervous system were characterized as follows: the site of predilection was the brain stem, followed by the spinal cord, cerebrum and cerebellum. The pathognomonic changes were recurrent inflammations around small vessels, causing a softening of the tissue. Lesions were composed of a perivascular infiltration of lymphocytes, histiocytes and microglias and, moreover, diapedesis, degenerated nerve cells and oligodendroglias, glial nodule, breakdown of myelin and axon, fatty granule cells and glio-mesenchymal proliferation were present occasionally. Electron microscopic studies on the neurons revealed no evidence of viral particles except for some accumulations of electron dense bodies.

Projected structure of the pore-forming OmpC protein from Escherichia coli outer membrane

A single-projection structure analysis of a bacterial outer membrane protein, OmpC, has been carried out by electron microscopy of frozen hydrated specimens. Two distinct crystal polymorphs have been observed in the frozen-hydrated samples, and projection structures of both forms have been obtained to a resolution of 13.5 A. Preliminary examination of negatively stained samples revealed the expected, trimeric appearance of pores in the OmpC specimens. Electron microscopy of unstained, frozen-hydrated OmpC reveals the trimeric pore structure with equal clarity. In addition, the overall molecular envelope of the protein is readily discerned, and a major lipid-containing domain can also be seen. Because of the small coherent patch size, mosaic disorder, and unpredictable polymorphism of the presently available specimens, three-dimensional reconstruction of frozen-hydrated OmpC has not been carried out.

Characterization by deletion mutagenesis in vitro of the promoter region of ompF, a positively regulated gene of Escherichia coli

The ompF gene codes for a major outer membrane protein whose expression is positively regulated by the ompR and envZ genes. Two sets of promoter deletions, upstream deletions and downstream deletions, were generated in vitro, and the promoter function was studied by connecting them with the tet genes. One of the hybrid genes thus constructed had a functioning ompF-tet hybrid promoter. The 107 base-pair fragment was found to be functioning as the ompF promoter, 90 nucleotides upstream and 17 nucleotides downstream of the mRNA start site that was also determined in this study. The start site was preceded by a convenient Pribnow box. Although the sequence at the -35 region had a low degree of homology to the consensus sequence, analyses of the hybrid promoter suggested that this region is involved in the promoter function in relation to the Pribnow box. They also indicated that the domain responsible for regulation by the ompR gene is located within the -35 region and its upstream region.

Protease IV, a cytoplasmic membrane protein of Escherichia coli, has signal peptide peptidase activity

During export of the outer membrane lipoprotein across the cytoplasmic membrane, the signal peptide of the lipoprotein undergoes two successive proteolytic attacks, cleavage of the signal peptide by signal peptidase and digestion of the cleaved signal peptide by an enzyme called signal peptide peptidase(s) (Hussain, M., Ichihara, S., and Mizushima, S. (1982) J. Biol. Chem. 257, 5177-5182; Hussain, M., Ozawa, Y., Ichihara, S., and Mizushima, S. (1982) Eur. J. Biochem. 129, 233-239). Here we report that protease IV, a cytoplasmic membrane protease, exhibits the signal peptide peptidase activity. The signal peptide peptidase activity was cofractionated with protease IV throughout the entire process of purification of the latter enzyme. Only the signal peptide was digested by the peptidase among membrane proteins. Both the signal peptide peptidase activity and the protease IV activity were inhibited to similar degrees by antipain, leupeptin, chymostatin, and elastatinal that are known to inhibit the signal peptide peptidase activity in the cell envelope. From these results we conclude that protease IV is the signal peptide peptidase that is responsible for signal peptide digestion in the cytoplasmic membrane. The peptidase attacked the signal peptide only after its release from the precursor protein.

Mutation causing reverse osmoregulation of synthesis of OmpF, a major outer membrane protein of Escherichia coli

Supplementation of growth media with high concentrations of substances like sucrose results in the induction of OmpC synthesis and the suppression of OmpF synthesis. We isolated a novel mutant in which OmpF synthesis is in the opposite direction from normal osmoregulation. By transductional mapping, the mutation was localized at 75 min between malA and aroB on the Escherichia coli chromosome map where the ompR-envZ region is. The mutation was suppressed by a plasmid carrying the ompR gene but not by a plasmid carrying the envZ gene alone. The mutation also resulted in the almost complete suppression of OmpC synthesis. However, the remaining OmpC synthesis was osmoregulated normally. Based on these observations, the mechanism of osmoregulation of OmpF-OmpC synthesis is discussed.