Purification and characterization of the chaperonin 10 and chaperonin 60 proteins from Rhodobacter sphaeroides.

Two heat-shock proteins that show high identity with the Escherichia coli chaperonin 60 (groEL) and chaperonin 10 (groES) chaperonin proteins were purified and characterized from photolithoautotrophically grown Rhodobacter sphaeroides. The proteins were purified by using sucrose density gradient centrifugation and Mono-Q anion-exchange chromatography. In the presence of 1 mM ATP, the chaperonin 10 and chaperonin 60 proteins bound to each other and comigrated as a large complex during sucrose density gradient centrifugation. The native molecular weights of each protein as determined by gel filtration chromatography were 889,200 for chaperonin 60 and 60,000 for chaperonin 10. Chaperonin 60 is comprised of monomers with a molecular weight of 61,000 and chaperonin 10 is comprised of monomers with a molecular weight of 12,700 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Chaperonin 60 was 9.3% of the total soluble cell protein during photolithoautotrophic growth which increased to 28.5% following heat-shock treatment. When cells were grown photoheterotrophically or chemoheterotrophically, chaperonin 60 was reduced to 6.7% and 3.5%, respectively, of the total soluble protein. The N-terminal amino acid sequence of each protein was determined; chaperonin 60 of R. sphaeroides showed 72% identity to E. coli chaperonin 60 protein, and R. sphaeroides chaperonin 10 showed 45% identity with E. coli chaperonin 10. R. sphaeroides chaperonin 60 catalyzed ATP hydrolysis with a specific activity of 134 nmol min-1 mg-1 (kcat = 0.13 s-1) and was inhibited by R. sphaeroides chaperonin 10, but not E. coli chaperonin 10. The E. coli chaperonin 60 ATPase activity was inhibited by chaperonin 10 from both R. sphaeroides and E. coli.     

Isolation and expression of the Rhodobacter sphaeroides gene (pgsA) encoding phosphatidylglycerophosphate synthase.

The Rhodobacter sphaeroides pgsA gene (pgsARs), encoding phosphatidylglycerophosphate synthase (PgsARs), was cloned, sequenced, and expressed in both R. sphaeroides and Escherichia coli. As in E. coli, pgsARs is located immediately downstream of the uvrC gene. Comparison of the deduced amino acid sequences revealed 41% identity and 69% similarity to the pgsA gene of E. coli, with similar homology to the products of the putative pgsA genes of several other bacteria. Comparison of the amino acid sequences of a number of enzymes involved in CDP-diacylglycerol-dependent phosphatidyltransfer identified a highly conserved region also found in PgsARs. The pgsARs gene carried on multicopy plasmids was expressed in R. sphaeroides under the direction of its own promoter, the R. sphaeroides rrnB promoter, and the E. coli lac promoter, and this resulted in significant overproduction of PgsARs activity. Expression of PgsARs activity in E. coli occurred only with the E. coli lac promoter. PgsARs could functionally replace the E. coli enzyme in both a point mutant and a null mutant of E. coli pgsA. Overexpression of PgsARs in either E. coli or R. sphaeroides did not have dramatic effects on the phospholipid composition of the cells, suggesting regulation of the activity of this enzyme in both organisms.     

Fractionation and characterization of the phosphoenolpyruvate: fructose 1-phosphotransferase system from Pseudomonas aeruginosa

The initial reactions involved in the catabolism of fructose in Pseudomonas aeruginosa include the participation of a phosphoenolpyruvate:fructose 1-phosphotransferase system (F-PTS). Fractionation of crude extracts of fructose-grown cells revealed that both membrane-associated and soluble components were essential for F-PTS activity. Further resolution of the soluble fraction by both size exclusion and ion-exchange chromatography revealed the presence of only one component, functionally analogous to enzyme I. Enzyme I exhibited a relative molecular weight of 72,000, catalyzed the pyruvate-stimulated hydrolysis of phosphoenolpyruvate to pyruvate, and mediated the phosphorylation of fructose when combined with a source of enzyme II (washed membranes). No evidence for the requirement of a phosphate carrier protein, such as HPr, could be demonstrated. Thus, the F-PTS requires a minimum of two components, a soluble enzyme I and a membrane-associated enzyme II complex, and both were shown to be inducible. Reconstituted F-PTS activity was specific for phosphoenolpyruvate as a phosphate donor (Km, approximately -0.6 mM) and fructose as the sugar substrate (Km, approximately 18 microM). Components of the Pseudomonas F-PTS did not restore activity to extracts of deletion mutants of Salmonella typhimurium deficient in individual proteins of the PTS or to fractionated membrane and soluble components of the F-PTS of Escherichia coli. Similarly, membrane and soluble components of E. coli and S. typhimurium would not cross-complement the F-PTS components from P. aeruginosa.     

Levanase operon of Bacillus subtilis includes a fructose-specific phosphotransferase system regulating the expression of the operon

The levanase gene (sacC) of Bacillus subtilis is the distal gene of a fructose-inducible operon containing five genes. The complete nucleotide sequence of this operon was determined. The first four genes levD, levE, levF and levG encode polypeptides that are similar to proteins of the mannose phosphotransferase system of Escherichia coli. The levD and levE gene products are homologous to the N and C-terminal part of the enzyme IIIMan, respectively, whereas the levF and levG gene products have similarities with the enzymes IIMan. Surprisingly, the polypeptides encoded by the levD, levE, levF and levG genes are not involved in mannose uptake, but form a fructose phosphotransferase system in B. subtilis. This transport is dependent on the enzyme I of the phosphotransferase system (PTS) and is abolished by deletion of levF or levG and by mutations in either levD or levE. Four regulatory mutations (sacL) leading to constitutive expression of the lavanase operon were mapped using recombination experiments. Three of them were characterized at the molecular level and were located within levD and levE. The levD and levE gene products that form part of a fructose uptake PTS act as negative regulators of the operon. These two gene products may be involved in a PTS-mediated phosphorylation of a regulator, as in the bgl operon of E. coli.     

Purification and properties of acyl coenzyme A thioesterase II from Rhodopseudomonas sphaeroides

A high molecular weight acyl coenzyme A (acyl-CoA) thioesterase, designated thioesterase II, has been purified 5300-fold from photoheterotrophically grown cells of Rhodopseudomonas sphaeroides. In contrast to R. sphaeroides acyl-CoA thioesterase I [Boyce, S.G., & Lueking, D.R. (1984) Biochemistry 23, 141-147], thioesterase II has a native molecular mass (Mr) of 120,000, is capable of hydrolyzing saturated and unsaturated acyl-CoA substrates with acyl chain lengths ranging from C4 to C18, and is completely insensitive to the serine esterase inhibitor diisopropyl fluorophosphate. Palmitoyl-CoA and stearoyl-CoA are the preferred (lowest Km) saturated acyl-CoA substrates and vaccenoyl-CoA is the preferred unsaturated substrate. However, comparable Vmax values were obtained with a variety of acyl-CoA substrates. Unlike a similar thioesterase present in cells of Escherichia coli [Bonner, W.M., & Bloch, K. (1972) J. Biol. Chem. 247, 3123-3133], R. sphaeroides thioesterase II displays a high ratio of decanoyl-CoA to palmitoyl-CoA activities and exhibits little ability to hydrolyze 3-hydroxyacyl-CoA substrates. Only 3-hydroxydodecanoyl-CoA supported a measurable rate of enzyme activity. With the purification of thioesterase II, the enzymes responsible for greater than 90% of the acyl-CoA thioesterase activity present in cell-free extracts of R. sphaeroides have now been identified.     

Analysis of mutations affecting the expression of catabolite-sensitive operons in Escherichia coli K12 mutants defective in the HPr-component of the carbohydrate transport system

Expression of catabolite-sensitive operons in mutants devoid of HPr (a component of the glucose transport system) is severely repressed. ptsH mutants do not utilize substrates of the phosphoenolpyruvate: carbohydrate system (PTS) and many other sugars. Analysis of mutations suppressing the effect of the delta ptsH mutation revealed a new class of reversions which restore the growth of bacteria on different substrates. This mutation (named ptsS) intensifies the growth rate of ptsH mutants and increases the differential rate of beta-galactosidase production. ptsS mutation was mapped in the region of ptsF gene (coding for the fructose specific enzyme II of the PTS) on the 46th min. of the E. coli chromosome map. The effect of the ptsS mutation on the expression of catabolite-sensitive operons manifests only in the presence of the intact enzyme I of the PTS.     

The phosphotransferase system of Corynebacterium glutamicum: features of sugar transport and carbon regulation

In this review, we describe the phosphotransferase system (PTS) of Corynebacterium glutamicum and discuss genes for putative global carbon regulation associated with the PTS. C. glutamicum ATCC 13032 has PTS genes encoding the general phosphotransferases enzyme I, HPr and four enzyme II permeases, specific for glucose, fructose, sucrose and one yet unknown substrate. C. gluamicum has a peculiar sugar transport system involving fructose efflux after hydrolyzing sucrose transported via sucrose EII. Also, in addition to their primary PTS, fructose and glucose are each transported by a second transporter, glucose EII and a non-PTS permease, respectively. Interestingly, C. glutamicum does not show any preference for glucose, and thus co-metabolizes glucose with other sugars or organic acids. Studies on PTS-mediated sugar uptake and its related regulation in C. glutamicum are important because the production yield of lysine and cell growth are dependent on the PTS sugars used as substrates for fermentation. In many bacteria, the PTS is also involved in several regulatory processes. However, the detailed molecular mechanism of global carbon regulation associated with the PTS in this organism has not yet been revealed.     

Identification of a fourth cheY gene in Rhodobacter sphaeroides and interspecies interaction within the bacterial chemotaxis signal transduction pathway

The Escherichia coli chemotaxis signal transduction pathway has: CheA, a histidine protein kinase; CheW, a linker between CheA and sensory proteins; CheY, the effector; and CheZ, a signal terminator. Rhodobacter sphaeroides has multiple copies of these proteins (2 x CheA, 3 x CheW and 3 x CheY, but no CheZ). In this study, we found a fourth cheY and expressed these R. sphaeroides proteins in E. coli. CheA2 (but not CheA1) restored swarming to an E. coli cheA mutant (RP9535). CheW3 (but not CheW2) restored swarming to a cheW mutant of E. coli (RP4606). R. sphaeroides CheYs did not affect E. coli lacking CheY, but restored swarming to a cheZ strain (RP1616), indicating that they can act as signal terminators in E. coli. An E. coli CheY, which is phosphorylated but cannot bind the motor (CheY109KR), was expressed in RP1616 but had no effect. Overexpression of CheA2, CheW2, CheW3, CheY1, CheY3 and CheY4 inhibited chemotaxis of wild-type E. coli (RP437) by increasing its smooth-swimming bias. While some R. sphaeroides proteins restore tumbling to smooth-swimming E. coli mutants, their activity is not controlled by the chemosensory receptors. R. sphaeroides possesses a phosphorelay cascade compatible with that of E. coli, but has additional incompatible homologues.     

Cooperative binding of the sugar substrates and allosteric regulatory protein (enzyme IIIGlc of the phosphotransferase system) to the lactose and melibiose permeases in Escherichia coli and Salmonella typhimurium

An Escherichia coli strain which overproduces the lactose permease was used to investigate the mechanism of allosteric regulation of this permease and those specific for melibiose, glycerol, and maltose by the phosphoenolpyruvate-sugar phosphotransferase system (PTS). Thio-beta-digalactoside, a high affinity substrate of the lactose permease, released the glycerol and maltose permeases from inhibition by methyl-alpha-d-glucoside. Resumption of glycerol uptake occurred immediately upon addition of the galactoside. The effect was not observed in a strain which lacked or contained normal levels of the lactose permease, but growth of wild-type E. coli in the presence of isopropyl-beta-thiogalactoside plus cyclic AMP resulted in enhanced synthesis of the lactose permease so that galactosides relieved inhibition of glycerol uptake. Thiodigalactoside also relieved the inhibition of glycerol uptake caused by the presence of other PTS substrates such as fructose, mannitol, glucose, 2-deoxyglucose, and 5-thioglucose. Inhibition of adenylate cyclase activity by methyl-alpha-glucoside was also relieved by thiodigalactoside in E. coli T52RT provided that the lactose permease protein was induced to high levels. Cooperative binding of sugar and enzyme III(Glc) to the melibiose permease in Salmonella typhimurium was demonstrated, but no cooperativity was noted with the glycerol and maltose permeases. These results are consistent with a mechanism of PTS-mediated regulation of the lactose and melibiose permeases involving a fixed number of allosteric regulatory proteins (enzyme III(Glc)) which may be titrated by the increased number of substrate-activated permease proteins. This work suggests that the cooperativity in the binding of sugar substrate and enzyme III(Glc) to the permease, demonstrated previously in in vitro experiments, has mechanistic significance in vivo. It substantiates the conclusion that PTS-mediated regulation of non-PTS permease activities involves direct allosteric interaction between the permeases and enzyme III(Glc), the postulated regulatory protein of the PTS.     

Cloning and sequence analysis of the Escherichia coli metH gene encoding cobalamin-dependent methionine synthase and isolation of a tryptic fragment containing the cobalamin-binding domain

A gene encoding cobalamin-dependent methionine synthase (EC 2.1.1.13) has been isolated from a plasmid library of Escherichia coli K-12 DNA by complementation to methionine prototrophy in an E. coli strain lacking both cobalamin-dependent and -independent methionine synthase activities (RK4536:metE, metHH). Maxicell expression of a series of plasmids containing deletions in the metH structural gene was employed to map the position and orientation of the gene on the cloned DNA fragment. A 6.3-kilobase EcoRI-SalI fragment containing the gene was cloned into the sequencing vector pGEM3B for double-stranded DNA sequencing; the MetH coding region consists of 3372 nucleotides. The enzyme was purified from an overproducing strain of E. coli harboring the recombinant plasmid, in which the level of methionine synthase was elevated 30- to 40-fold over wild-type E. coli. Recombinant enzyme is a protein of 123,640 molecular weight and has a turnover number of 1,450 min-1 in the standard assay. These values are to be compared with previously reported values of 133,000 for the molecular weight and 1,240-1,560 min-1 for the turnover number of the homogenous enzyme purified from a wild-type strain of E. coli B (Frasca, V., Banerjee, R. V., Dunham, W. R., Sands, R. H., and Matthews, R. G. (1988) Biochemistry 27, 8458-8465). Limited proteolysis of the native enzyme with trypsin resulted in loss of enzyme activity but retention of bound cobalamin on a peptide fragment of 28,000 molecular weight. This fragment has been shown to extend from residue 643 to residue 900 of the 1124-residue deduced amino acid sequence.     

Purification and characterization of two fructose diphosphate aldolases from Escherichia coli (Crookes'' strain)

Two fructose diphosphate aldolases (EC 4.1.2.13) were detected in extracts of Escherichia coli (Crookes' strain) grown on pyruvate or lactate. The two enzymes can be resolved by chromatography on DEAE-cellulose at pH7.5, or by gel filtration on Sephadex G-200, and both have been obtained in a pure state. One is a typical bacterial aldolase (class II) in that it is strongly inhibited by metal-chelating agents and is reactivated by bivalent metal ions, e.g. Ca(2+), Zn(2+). It is a dimer with a molecular weight of approx. 70000, and the K(m) value for fructose diphosphate is about 0.85mm. The other aldolase is not dependent on metal ions for its activity, but is inhibited by reduction with NaBH(4) in the presence of substrate. The K(m) value for fructose diphosphate is about 20mum (although the Lineweaver-Burk plot is not linear) and the enzyme is probably a tetramer with molecular weight approx. 140000. It has been crystallized. On the basis of these properties it is tentatively assigned to class I. The appearance of a class I aldolase in bacteria was unexpected, and its synthesis in E. coli is apparently favoured by conditions of gluconeogenesis. Only aldolase of class II was found in E. coli that had been grown on glucose. The significance of these results for the evolution of fructose diphosphate aldolases is briefly discussed.     

Re-design of Rhodobacter sphaeroides dimethyl sulfoxide reductase. Enhancement of adenosine N1-oxide reductase activity

The periplasmic DMSO reductase from Rhodobacter sphaeroides f. sp. denitrificans has been expressed in Escherichia coli BL21(DE3) cells in its mature form and with the R. sphaeroides or E. coli N-terminal signal sequence. Whereas the R. sphaeroides signal sequence prevents formation of active enzyme, addition of a 6x His-tag at the N terminus of the mature peptide maximizes production of active enzyme and allows for affinity purification. The recombinant protein contains 1.7-1.9 guanines and greater than 0.7 molybdenum atoms per molecule and has a DMSO reductase activity of 3.4-3.7 units/nmol molybdenum, compared with 3.7 units/nmol molybdenum for enzyme purified from R. sphaeroides. The recombinant enzyme differs from the native enzyme in its color and spectrum but is indistinguishable from the native protein after redox cycling with reduced methyl viologen and Me2SO. Substitution of Cys for the molybdenum-ligating Ser-147 produced a protein with DMSO reductase activity of 1.4-1.5 units/nmol molybdenum. The mutant protein differs from wild type in its color and absorption spectrum in both the oxidized and reduced states. This substitution leads to losses of 61-99% of activity toward five substrates, but the adenosine N1-oxide reductase activity increases by over 400%.     

The levanase operon of Bacillus subtilis expressed in Escherichia coli can substitute for the mannose permease in mannose uptake and bacteriophage lambda infection.

Bacteriophage lambda adsorbs to its Escherichia coli K-12 host by interacting with LamB, a maltose- and maltodextrin-specific porin of the outer membrane. LamB also serves as a receptor for several other bacteriophages. Lambda DNA requires, in addition to LamB, the presence of two bacterial cytoplasmic integral membrane proteins for penetration, namely, the IIC(Man) and IID(Man) proteins of the E. coli mannose transporter, a member of the sugar-specific phosphoenolpyruvate:sugar phosphotransferase system (PTS). The PTS transporters for mannose of E. coli, for fructose of Bacillus subtilis, and for sorbose of Klebsiella pneumoniae were shown to be highly similar to each other but significantly different from other PTS transporters. These three enzyme II complexes are the only ones to possess distinct IIC and IID transmembrane proteins. In the present work, we show that the fructose-specific permease encoded by the levanase operon of B. subtilis is inducible by mannose and allows mannose uptake in B. subtilis as well as in E. coli. Moreover, we show that the B. subtilis permease can substitute for the E. coli mannose permease cytoplasmic membrane components for phage lambda infection. In contrast, a series of other bacteriophages, also using the LamB protein as a cell surface receptor, do not require the mannose transporter for infection.     

Isolation and preliminary characterization of two forms of ribulose 1,5-bisphosphate carboxylase from Rhodopseudomonas capsulata.

The presence of two distinct forms of ribulose 1,5-bisphosphate carboxylase has been demonstrated in extracts of Rhodopseudomonas capsulata, similar to the form I (peak I) and form II (peak II) carboxylases previously described from R. sphaeroides (J. Gibson and F. R. Tabita, J. Biol. Chem 252:943-949, 1977). The two activities, separated by diethylaminoethyl-cellulose chromatography, were shown to be of different molecular size after assay on polyacrylamide gels. The higher-molecular-weight carboxylase from R. capsulata was designated form I-C, whereas the smaller enzyme was designated form II-C. Catalytic studies revealed significant differences between the two enzymes in response to pH and the effector 6-phosphogluconate. Immunological studies with antisera directed against the carboxylases from R. sphaeroides demonstrated antigenic differences between the two R. capsulata enzymes; cross-reactivity was observed only between R. sphaeroides anti-form II serum and the corresponding R. capsulata enzyme, form II-C.     

Regulation of E. coli glycogen phosphorylase activity by HPr

Bacteria sense continuous changes in their environment and adapt metabolically to effectively compete with other organisms for limiting nutrients. One system which plays an important part in this adaptation response is the phosphoenol-pyruvate:sugar phosphotransferase system (PTS). Many proteins interact with and are regulated by PTS components in bacteria. Here we review the interaction with and allosteric regulation of Escherichia coli glycogen phosphorylase (GP) activity by the histidine phosphocarrier protein HPr, which acts as part of a phosphoryl shuttle between enzyme I and sugar-specific proteins of the PTS. HPr mediates crosstalk between PTS sugar uptake and glycogen breakdown. The evolution of the allosteric regulation of E. coli GP by HPr is compared to that of other phosphorylases.     

Glucosamine synthetase from Escherichia coli: purification, properties, and glutamine-utilizing site location

L-Glutamine:D-fructose-6-phosphate amidotransferase (glucosamine synthetase) has been purified to homogeneity from Escherichia coli. A subunit molecular weight of 70,800 was estimated by gel electrophoresis in sodium dodecyl sulfate. Pure glucosamine synthetase did not exhibit detectable NH3-dependent activity and did not catalyze the reverse reaction, as reported for more impure preparations [Gosh, S., Blumenthal, H. J., Davidson, E., & Roseman, S. (1960) J. Biol. Chem. 235, 1265]. The enzyme has a Km of 2 mM for fructose 6-phosphate, a Km of 0.4 mM for glutamine, and a turnover number of 1140 min-1. The amino-terminal sequence confirmed the identification of residues 2-26 of the translated E. coli glmS sequence [Walker, J. E., Gay, J., Saraste, M., & Eberle, N. (1984) Biochem. J. 224, 799]. Methionine-1 is therefore removed by processing in vivo, leaving cysteine as the NH2-terminal residue. The enzyme was inactivated by the glutamine analogue 6-diazo-5-oxo-L-norleucine (DON) and by iodoacetamide. Glucosamine synthetase exhibited half-of-the-sites reactivity when incubated with DON in the absence of fructose 6-phosphate. In its presence, inactivation with [6-14C]DON was accompanied by incorporation of 1 equiv of inhibitor per enzyme subunit. From this behavior, a dimeric structure was tentatively assigned to the native enzyme. The site of reaction with DON was the NH2-terminal cysteine residue as shown by Edman degradation.