Crc is involved in catabolite repression control of the bkd operons of Pseudomonas putida and Pseudomonas aeruginosa.

Crc (catabolite repression control) protein of Pseudomonas aeruginosa has shown to be involved in carbon regulation of several pathways. In this study, the role of Crc in catabolite repression control has been studied in Pseudomonas putida. The bkd operons of P. putida and P. aeruginosa encode the inducible multienzyme complex branched-chain keto acid dehydrogenase, which is regulated in both species by catabolite repression. We report here that this effect is mediated in both species by Crc. A 13-kb cloned DNA fragment containing the P. putida crc gene region was sequenced. Crc regulates the expression of branched-chain keto acid dehydrogenase, glucose-6-phosphate dehydrogenase, and amidase in both species but not urocanase, although the carbon sources responsible for catabolite repression in the two species differ. Transposon mutants affected in their expression of BkdR, the transcriptional activator of the bkd operon, were isolated and identified as crc and vacB (rnr) mutants. These mutants suggested that catabolite repression in pseudomonads might, in part, involve control of BkdR levels.

The nucleotide sequence of the Pseudomonas aeruginosa pyrE-crc-rph region and the purification of the crc gene product.

The gene (crc) responsible for catabolite repression control in Pseudomonas aeruginosa has been cloned and sequenced. Flanking the crc gene are genes encoding orotate phosphoribosyl transferase (pyrE) and RNase PH (rph). New crc mutants were constructed by disruption of the wild-type crc gene. The crc gene encodes an open reading frame of 259 amino acids with homology to the apurinic/apyrimidinic endonuclease family of DNA repair enzymes. However, crc mutants do not have a DNA repair phenotype, nor can the crc gene complement Escherichia coli DNA repair-deficient strains. The crc gene product was overexpressed in both P. aeruginosa and in E. coli, and the Crc protein was purified from both. The purified Crc proteins show neither apurinic/apyrimidinic endonuclease nor exonuclease activity. Antibody to the purified Crc protein reacted with proteins of similar size in crude extracts from Pseudomonas putida and Pseudomonas fluorescens, suggesting a common mechanism of catabolite repression in these three species.

Cloning of a catabolite repression control (crc) gene from Pseudomonas aeruginosa, expression of the gene in Escherichia coli, and identification of the gene product in Pseudomonas aeruginosa.

Mutants which are defective in catabolite repression control (CRC) of multiple independently regulated catabolic pathways have been previously described. The mutations were mapped at 11 min on the Pseudomonas aeruginosa chromosome and designated crc. This report describes the cloning of a gene which restores normal CRC to these Crc- mutants in trans. The gene expressing this CRC activity was subcloned on a 2-kb piece of DNA. When this 2-kb fragment was placed in a plasmid behind a phage T7 promoter and transcribed by T7 RNA polymerase, a soluble protein with a molecular weight (MW) of about 30,000 was produced in Escherichia coli. A soluble protein of identical size was overproduced in a Crc- mutant when it contained the 2-kb fragment on a multicopy plasmid. This protein could not be detected in the mutant containing the vector without the 2-kb insert or with no plasmid. When a 0.3-kb AccI fragment was removed from the crc gene and replaced with a kanamycin resistance cassette, the interrupted crc gene no longer restored CRC to the mutant, and the mutant containing the interrupted gene no longer overproduced the 30,000-MW protein. Pools of intracellular cyclic AMP and the activities of adenylate cyclase and phosphodiesterase were measured in mutant and wild-type strains with and without a plasmid containing the crc gene. No consistent differences between any strains were found in any case. These results provide original evidence for a 30,000-MW protein encoded by crc+ that is required for wild-type CRC in P. aeruginosa and confirms earlier reports that the mode of CRC is cyclic AMP independent in this bacterium.

Isolation and characterization of catabolite repression control mutants of Pseudomonas aeruginosa PAO.

Independently controlled, inducible, catabolic genes in Pseudomonas aeruginosa are subject to strong catabolite repression control by intermediates of the tricarboxylic acid cycle. Mutants which exhibited a pleiotropic loss of catabolite repression control of multiple pathways were isolated. The mutations mapped in the 11-min region of the P. aeruginosa chromosome near argB and pyrE and were designated crc. Crc- mutants no longer showed repression of mannitol and glucose transport, glucose-6-phosphate dehydrogenase, glucokinase, Entner-Doudoroff dehydratase and aldolase, and amidase when grown in the presence of succinate plus an inducer. These activities were not expressed constitutively in Crc- mutants but exhibited wild-type inducible expression.

Factors influencing the in vitro translocation of the Escherichia coli maltose-binding protein.

An in vitro system has been utilized to study the translocation of newly synthesized Escherichia coli maltose-binding protein (MBP) into inverted membrane vesicles. Approximately 40% of precursor MBP (pMBP) synthesized with a wild-type signal peptide was imported into vesicles. However, MBP species with even minor alterations in the signal peptide hydrophobic core were imported into vesicles with an efficiency much lower than predicted from in vivo studies. Posttranslational import of wild-type pMBP into vesicles could be demonstrated if membranes were added after the termination of protein synthesis. However, if vesicles were present throughout the synthesis reaction, most pMBP import occurred either cotranslationally or very soon after completion of synthesis. The wild-type pMBP rapidly became incompetent for posttranslational translocation upon continued incubation in the absence of membranes, whereas pMBP species with altered folding properties remained competent for significantly longer periods. The rate of in vitro pMBP folding was affected by the nature of the signal peptide. The evidence suggests that one or more soluble factors may interact with the newly synthesized pMBP to help maintain it in a translocation-competent state and to promote its entrance into the export pathway.

In vivo and in vitro synthesis of Escherichia coli maltose-binding protein under regulatory control of the lacUV5 promoter-operator.

It has not been possible to obtain in vitro expression of the positively regulated malE gene encoding the periplasmic maltose-binding protein (MBP) of Escherichia coli. To facilitate in vitro malE expression, we constructed plasmids that place the malE gene under transcriptional control of the lacUV5 promoter-operator. These plasmids could be grouped into three classes, based upon their ability to complement in vivo a chromosomal malE deletion in the presence or absence of isopropyl thiogalactoside. In the one class I plasmid analyzed, the lacUV5-malE junction was just 3' to the malE ATG initiation codon, and this plasmid did not complement the malE deletion. Class II and class III plasmids retained various amounts of the malE promoter. MBP synthesis was solely under control of the lacUV5 promoter in the class II plasmids, and MBP synthesis was under control of both the lacUV5 and malE promoters in the class III plasmids. A malE mutation that renders the MBP signal peptide export defective was genetically recombined onto one of the class II plasmids. The in vivo synthesis and export of plasmid-encoded MBP were studied in the presence and absence of isopropyl thiogalactoside and maltose and in a strain harboring a prlA mutation that suppresses the malE signal sequence mutation and is thought to alter the export machinery of cells. In addition, both class II and class III plasmids programmed the synthesis of precursor MBP in an in vitro-coupled transcription-translation system. When precursor MBP was synthesized in vitro in the presence of E. coli membrane vesicles, a significant portion of wild-type precursor MBP, but not export-defective precursor MBP, was converted to a form that migrated on sodium dodecyl sulfate-polyacrylamide gels identically to mature MBP synthesized in vivo.

An activity from Escherichia coli membranes responsible for the modification of nitrate reductase to its precursor form.

An enzymatic activity which modifies nitrate reductase has been identified in the cytoplasmic membrane of Escherichia coli. This activity changes subunit B to a form with a slightly greater electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels (B'). The B' polypeptide produced by this modifying enzyme was compared to an apparently identical polypeptide identified in the precursor form of nitrate reductase which can be found in the cytoplasm of all strains and in the membrane of mutants defective in the insertion of nitrate reductase. These B' polypeptides were all identical with respect to mobility on gradient sodium dodecyl sulfate gels and peptides produced by limited digests using trypsin, papain, and Staphylococcus aureus V8 protease. When compared to subunit B, the proteolytic gel maps of B' polypeptides showed minor differences. From the identity of the modified B' with precursor B', the ability to convert B into B' in vitro and the in vivo nature of B' as a precursor of B, it was concluded that the modification of B to B' is a reversible process and is due to the removal of one or more small nonprotein molecules.

Cytochrome b from Escherichia coli nitrate reductase. Its properties and association with the enzyme complex.

Membrane-bound nitrate reductase purified from Escherichia coli was resolved into two separate forms. The majority of the enzyme complex had a subunit composition of 2A:2B:4C, exhibited cytochrome b spectra, and was found to be stable after purification. A second form of nitrate reductase activity was a modified complex with a subunit composition of 2A:2B and lacked cytochrome. The subunit B from this complex was altered in its mobility on sodium dodecyl sulfate-polyacrylamide gels. The cytochrome-containing enzyme had 28 +/- 2 atoms of iron and 1.35 atoms of molybdenum whereas iron and molybdenum in cytochromeless enzyme were 24 +/- 2 atoms and 1.18 atoms/molecule, respectively. Besides cytochrome-containing nitrate reductase, two other cytochrome b-containing fractions were also resolved. These were cytochrome b associated with formate dehydrogenase and a novel cytochrome b with reduced absorption maxima at 430, 529.5, and 560 nm. Nitrate reductase cytochrome b (subunit C) was isolated from subunits A and B as a partially denatured form and its renaturation was accomplished by dialyzing against hemin. The renatured cytochrome yielded absorption spectra similar to the holoenzyme. The pure cytochrome aggregated upon heating, even in the presence of sodium dodecyl sulfate. It had a high isoelectric point (pH greater than 9.5) and had 45% hydrophobic amino acids.

Escherichia coli nitrate reductase subunit A: its role as the catalytic site and evidence for its modification.

Subunits A and B were isolated from purified nitrate reductase by preparative electrophoresis in low levels of sodium dodecyl sulfate. Nonheme iron and low levels of molybdenum were associated with isolated subunit A but not with isolated subunit B. After dialysis against a source of molybdenum cofactor, subunit A regained tightly bound molybdenum and concomitantly regained enzyme activity and reactivity with anti-nitrate reductase antiserum. Subunit B neither bound cofactor nor regained activity or reactivity with antiserum. These data indicate that subunit A contains the active site of the enzyme. Subunit A was also found to be modified posttranslationally in a similar fashion as is subunit B. This was determined by comparison of partial proteolytic digests and amino acid analyses of A subunits from precursor and membrane-bound forms of nitrate reductase.

Nitrate reductase in Escherichia coli K-12: involvement of chlC, chlE, and chlG loci.

We examined the properties of mutants of E. coli which are defective with respect to nitrate reductase activity. chlE::Mu cts and chlG::Mu cts mutants were all chlorate resistant, and the strains that we examined all synthesized nitrate reductase apoenzyme. We concluded that the chlE and chlG loci, like the chlA, chlB, and chlD loci, are involved in the synthesis of insertion of molybdenum cofactor. We identified at least four distinct phenotypic classes of chlC::Tn10 mutants, all of which were fully or partially sensitive to chlorate. Two of these classes may represent lesions in the structural genes for nitrate reductase subunits A and C. Two other classes may be altered in the regulation of the expression of nitrate reductase or other anaerobic enzymes. We propose the mnemonic nar for naming individual genes within the chlC locus.

New mechanism for post-translational processing during assembly of a cytoplasmic membrane protein?

Insertion of nitrate reductase into the Escherichia coli cytoplasmic membrane was examined by following the fate of pulse-labeled enzyme in both the membrane and cytoplasm during various times after the addition of an unlabeled chase. The polypeptide composition of this labeled enzyme was determined by autoradiography of immunoprecipitated material after separation on sodium dodecyl sulfate-polyacrylamide gels. The data presented here indicate that immediately after appropriate insertion of the enzyme into the membrane, a post-translational event occurs which converts the cytoplasmically synthesized form of subunit B (B') to the form found in the completely assembled enzyme (B). B' is distinguished from B by its more rapid electrophoretic mobility. B' was found in the cytoplasm of all strains tested, in the membrane of strains with defects in enzyme insertion (hemA and chlE), and as a transient component in the membrane of wild-type cells.

Synthesis and degradation of nitrate reductase in Escherichia coli.

The biosynthesis, insertion, and in vivo stability of nitrate reductase were examined by following the amount of labeled enzyme present in both membranes and cytoplasm at varying times after a short pulse of radioactive sulfate. Nitrate reductase levels were measured by autoradiography of immunoprecipitated material after fractionation on sodium dodecyl sulfate-polyacrylamide gels. These experiments demonstrated that subunits A and B were synthesized in the cytoplasm and subsequently inserted into membranes. The insertion of these subunits was dependent upon the synthesis of another protein, and the rate of synthesis of this protein determined the rate of insertion of subunits A and B. The nitrate reductase produced by the chlA mutant was inserted into membranes in the normal fashion, whereas the nitrate reductase produced by the chlC and chlE mutants was poorly incorporated. The nitrate reductase in the wild type was completely stable in vivo under inducing or noninducing conditions, whereas in the chlC and chlE mutants nitrate reductase was degraded extensively in both the cytoplasm and membranes, even under inducing conditions. Under similar conditions, nitrate reductase was stable in the chlA mutant.

Localization of proteolytic activity in the outer membrane of Escherichia coli.

An enzyme in the cytoplasmic membrane, nitrate reductase, can be solubilized by heating membranes to 60 degrees C for 10 min at alkaline pH. A protease in the cell envelope has been shown to be responsible for this solubilization. The localization of this protease in the outer membrane was demonstrated by separating the outer membrane from the cytoplasmic membrane, adding back various forms of outer membrane protein to the cytoplasmic membrane, and following the increase in nitrate reductase solubilization with increasing amounts of outer membrane proteins. This solubilization is accompanied by the cleavage of one of the subunits of nitrate reductase and is inhibited by the protease inhibitor p-aminobenzamidine. Analysis of membrane proteins synthesized by cells grown in the presence of various amounts of p-aminobenzamidine revealed that p-aminobenzamidine affects the synthesis of the major outer membrane proteins but has little effect on the synthesis of cytoplasmic membrane proteins. When outer membrane is reacted with the protease inhibitor [3H]diisopropylfluorophosphate, a single protein in the outer membrane is labeled. Since the interaction with diisopropylfluorophosphate is inhibited by p-aminobenzamidine, it is suggested that this single outer membrane protein is responsible for the in vitro solubilization of nitrate reductase and the in vivo processing of the major outer membrane proteins.

Do cytochromes function as oxygen sensors in the regulation of nitrate reductase biosynthesis?

The observation that oxygen represses nitrate reductase biosynthesis in a hemA mutant grown aerobically with or without delta-aminolevulinic acid indicates that cytochromes are not responsible for nitrate reductase repression in aerobically grown cells.

Biosynthesis of membrane-bound nitrate reductase in Escherichia coli: evidence for a soluble precursor.

Membrane-bound nitrate reductase of Escherichia coli consists of three subunits designated as A, B, and C, with subunit C being the apoprotein of cytochrome b, A hemA mutant that cannot synthesize delta-aminolevulinic acid (ALA) produces a normal, stable, membrane-bound enzyme when grown with ALA. When grown without ALA, this mutant makes a reduced amount of membrane-bound enzyme that is unstable and contains no C subunit. Under the same growth conditions, this mutant accumulates a large amount of a soluble form of the enzyme in the cytoplasm. Accumulation of this cytoplasmic form begins immediately upon induction of the enzyme with nitrate. The cytoplasmic form is very similar to the soluble form of the enzyme obtained by alkaline heat extraction. It is a high-molecular-weight complex with a Strokes radius of 8.0 nm and consists of intact A and B subunits. When ALA is added to a culture growing without ALA, the cytoplasmic form of the enzyme is incorporated into the membrane in a stable form, coincident with the formation of functional cytochrome b. Reconstitution experiments indicate that subunit C is present in cultures grown without ALA but is reduced in amount or unstable. These results indicate that membrane-bound nitrate reductase is synthesized via a soluble precursor containing subunits A and B, which then binds to the membrane upon interaction with the third subunit, cytochrome b.

Solubilization of Escherichia coli nitrate reductase by a membrane-bound protease.

Nitrate reductase extracted from the membrane of Escherichia coli by alkaline heat treatment was purified to homogeneity and used to prepare specific antibody. Nitrate reductase, precipitated by this antibody from Triton extracts of the membrane, contained a third subunit not present in the purified enzyme used to prepare the antibody. Nitrate reductase precipitated by antibody from alkaline heat extracts was composed of peptide fragments of various sizes. These fragments were produced by a membrane-bound protease which was activated by alkaline pH and heat. It is the action of this protease that releases the enzyme from the membrane, as shown by the observations that protease inhibitors decreased the amount of solubilization of the enzyme, and the enzyme remaining in the membrane after heating showed much less proteolytic cleavage than that which was released.