A mutation in the rnh-locus of Escherichia coli affects the structural gene for RNase H. Examination of the mutant and wild type protein

Ribonuclease H (RNase H, EC 3.1.26.4) was purified to homogeneity from Escherichia coli wild type strain KS 351 and the RNase H mutant strain FB 2. The specific activity of the wild type enzyme was 43,200 units/mg, while that of the mutant enzyme was 3,430 units/mg, less than 8% of the wild type activity. Isoelectric focusing also revealed differences in the protein from mutant and wild type. The activity of the wild type enzyme was separated into two peaks with isoelectric points of 9.6 and 9.0. In contrast, the activity of the mutant enzyme focused in a single peak with a pI of 9.4. These results indicate that the mutation in the FB2 strain affects the structural gene for RNase H. The molecular weight of both enzymes was determined by gel filtration as well as NaDodSO4-polyacrylamide gel electrophoresis and found to be identical. Both enzymes are very sensitive to increased temperatures and show indistinguishable rates of inactivation. The basis for the heterogeneity of the isoelectric point and the altered activity of the mutant enzyme is still unknown.     

Demonstration of 2 enzymes with beta-galactosidase activity in Rhizobium meliloti]

The beta-galactosidase (EC 3.2.1.23) activities of wild-type Rhizobium meliloti and its lactose slow-hydrolyzing mutant have been compared. The properties of the enzyme are very different in each strain. These differences allow us to prove that two enzymes with a beta-galactosidase activity can be found in the wild-type whereas only one enzyme remains in the mutant strain.     

Cyclic AMP phosphodiesterase in Salmonella typhimurium: characteristics and physiological function.

The physiological function of cyclic AMP (cAMP) phosphodiesterase in Salmonella typhimurium was investigated with strains which were isogenic except for the cpd locus. In crude broken-cell extracts the properties of the enzyme were found to be similar to those reported for Escherichia coli. The specific activity in the mutant was less than 1% that in the wild type. Rates of cAMP production in the mutant were as much as twice those observed in the wild type. The amount of cAMP accumulated when cells grew overnight with limiting glucose was 4.5-fold greater in the mutant than in the wild type. The intracellular concentration of cAMP in the two strains was measured directly, using four different techniques to wash the cells to remove extracellular cAMP. The cAMP level in the cpd strain was only 25% greater than in the wild type. The functional concentration of the cAMP receptor protein-cAMP complex was estimated indirectly from the specific activity of beta-galactosidase in the two strains after introducing F'lac. When cells were grown with carbon sources permitting synthesis of different levels of cAMP, the specific activity of the enzyme was at most 25% greater in the cpd strain. The cpd strain was more sensitive to the effects of exogenous cAMP. Exogenous cAMP relieved both permanent and transient catabolite repression of the lac operon at lower concentrations in the cpd strain than in the wild type. When cells grew with glucose, glycerol, or ribose, exogenous cAMP inhibited growth of the mutant strain more than the wild type.     

Active site residues of human beta-glucuronidase. Evidence for Glu(540) as the nucleophile and Glu(451) as the acid-base residue.

Human beta-glucuronidase (hGUSB) is a member of family 2 glycosylhydrolases that cleaves beta-D-glucuronic acid residues from the nonreducing termini of glycosaminoglycans. Amino acid sequence and structural homology of hGUSB and Escherichia coli beta-galactosidase active sites led us to propose that residues Glu(451), Glu(540), and Tyr(504) in hGUSB are involved in catalysis, Glu(451) being the acid-base residue and Glu(540) the nucleophile. To test this hypothesis, we introduced mutations in these residues and determined their effects on enzymes expressed in COS cells and GUSB-deficient fibroblasts. The extremely low activity in cells expressing Glu(451), Glu(540), and Tyr(504) hGUSBs supported their roles in catalysis. For kinetic analysis, wild type and mutant enzymes were produced in baculovirus and purified to homogeneity by affinity chromatography. The k(cat)/K(m) values (mM(-1).s(-1)) of the E540A, E451A, and Y504A enzymes were 34,000-, 9100-, and 830-fold lower than that of wild type hGUSB, respectively. High concentrations of azide stimulated the activity of the E451A mutant enzyme, supporting the role of Glu(451) as the acid-base catalyst. We conclude that, like their homologues in E. coli beta-galactosidase, Glu(540) is the nucleophilic residue, Glu(451) the acid-base catalyst, and Tyr(504) is also important for catalysis, although its role is unclear. All three residues are located in the active site cavity previously determined by structural analysis of hGUSB.     

Altered control of chorismate mutase leads to tryptophan auxotrophy of Pichia guilliermondii

We have isolated the tryptophan auxotrophic mutant strain, PK101, of Pichia guilliermondii. This strain is not defective in any of the tryptophan biosynthetic enzymes, but its chrismate mutase, an enzyme of the phenylalanine-tyrosine biosynthesis, is changed. In comparison with the wild type chorismate mutase, the enzyme of PK101 is characterized by a complete loss of sensitivity to l-phenylalanine inhibition and to a considerable loss of sensitivity to l-tryptophan activation. Furthermore, the chorismate mutase activity of the mutant is more than 7-fold higher in the absence of l-tryptophan than in the wild type. The PK101 enzyme is also changed in the pH optimum and in some kinetic constants. We found an increased intracellular pool of both phenylalanine and tyrosine and a reduced contents of tryptophan in the mutant cells. Our genetic data indicate that the mutant phenotype is dominant over the wild type.     

(Na, K)ATPase activity in membrane preparations of ouabain-resistant HeLa cells.

Membrane preparations from two independent ouabain-resistant HeLa cell clones, HI-B1 and HI-C1, each appear to contain two species of (Na,K)ATPase. Two-thirds of the total (Na,K)ATPase in each mutant is indistinguishable from the enzyme in preparations of wild type cells with respect to ouabain binding, ouabain inhibition of (Na,K)ATPase activity, and dependence of ATP hydrolysis on Na, Mg, K, and ATP concentration. The remaining (Na,K)ATPase activity in the mutants is up to 1000 and 10 000 times, respectively, more resistant to ouabain than wild type enzyme. Resistance results from a lower affinity of the mutant enzymes for the inhibitor. The presence of Na, K, or Mg has little or no effect on the degree of resistance expressed by the mutant enzymes, although the resistance of the wild type enzyme varies 400-fold in the presence of different ligands. Incubation with 5 X 10(-8) M ouabain abolishes the activity of the wild type enzyme without affecting the activity of the resistant enzymes. Using this procedure we compared the parameters of ATP hydrolysis via the resistant and wild type enzymes. Ouabain-resistant (Na,K)ATPase of HI-C1 has an apparent K0.5 for potassium 3-4 times higher than that of either wild type enzyme or the resistant enzyme of HI-B1.     

Overproduction of Thermus sp. Strain T2 beta-galactosidase in Escherichia coli and preparation by using tailor-made metal chelate supports

A novel thermostable chimeric beta-galactosidase was constructed by fusing a poly-His tag to the N-terminal region of the beta-galactosidase from Thermus sp. strain T2 to facilitate its overexpression in Escherichia coli and its purification by immobilized metal-ion affinity chromatography (IMAC). The poly-His tag fusion did not affect the activation, kinetic parameters, and stability of the beta-galactosidase. Copper-iminodiacetic acid (Cu-IDA) supports enabled the most rapid adsorption of the His-tagged enzyme, favoring multisubunit interactions, but caused deleterious effects on the enzyme stability. To improve the enzyme purification a selective one-point adsorption was achieved by designing tailor-made low-activated Co-IDA or Ni-IDA supports. The new enzyme was not only useful for industrial purposes but also has become an excellent model to study the purification of large multimeric proteins via selective adsorption on tailor-made IMAC supports.     

Site-directed mutagenesis of a family 42 β-galactosidase from an antarctic bacterium

Site directed mutagenesis was used to modify the active site of a cold active beta-galactosidase taken from an Antarctic psychrotolerant Planococcus Bacterial isolate. The goal was to modify the active site such that there would be an increase in activity on certain substrates which showed little to no activity with the wild type enzyme. A total of 5 mutant enzymes were constructed with amino acid changes based on an analysis done via homology modeling. All 5 modified enzymes were assayed using 14 different nitrophenol substrates. In most cases there was a loss of activity on substrates that showed activity with the wild type enzymes. None of the expected activity was observed with any of the mutants, possibly in part due to a decrease in hydrogen bonding between the active site and the substrates. With the substrates p-nitrophenyl-β-d-galacturonide and p-nitrophenyl-α-d-glucopyranoside we saw increased activity. With one of the mutants we measured a 320% increase in activity on p-nitrophenyl-β-d-galacturonide. Two other mutants showed activity on p-nitrophenyl-α-d-glucopyranoside, which showed no activity at all with the wild type enzyme.     

Mutational analysis of Thermus caldophilus GK24 beta-glycosidase: role of His119 in substrate binding and enzyme activity

Three amino acid residues (His119, Glu164, and Glu338) in the active site of Thermus caldophilus GK24 beta- glycosidase (Tca beta-glycosidase), a family 1 glycosyl hydrolase, were mutated by site-directed mutagenesis. To verify the key catalytic residues, Glu164 and Glu338 were changed to Gly and Gln, respectively. The E164G mutation resulted in drastic reductions of both beta-galactosidase and beta-glucosidase activities, and the E338Q mutation caused complete loss of activity, confirming that the two residues are essential for the reaction process of glycosidic linkage hydrolysis. To investigate the role of His119 in substrate binding and enzyme activity, the residue was substituted with Gly. The H119G mutant showed 53-fold reduced activity on 5 mM p-nitrophenyl beta-Dgalactopyranoside, when compared with the wild type; however, both the wild-type and mutant enzymes showed similar activity on 5 mM p-nitrophenyl beta-D-glucopyranoside at 75degreeC. Kinetic analysis with p-nitrophenyl beta-D-galactopyranoside revealed that the kcat value of the H119G mutant was 76.3-fold lower than that of the wild type, but the Km of the mutant was 15.3-fold higher than that of the wild type owing to the much lower affinity of the mutant. Thus, the catalytic efficiency (kcat/Km) of the mutant decreased to 0.08% to that of the wild type. The kcat value of the H119G mutant for p-nitrophenyl beta- D-glucopyranoside was 5.1-fold higher than that of the wild type, but the catalytic efficiency of the mutant was 2.5% of that of the wild type. The H119G mutation gave rise to changes in optima pH (from 5.5-6.5 to 5.5) and temperature (from 90 degrees C to 80-85 degrees C). This difference of temperature optima originated in the decrease of H119G's thermostability. These results indicate that His119 is a crucial residue in beta- galactosidase and beta-glucosidase activities and also influences the enzyme's substrate binding affinity and thermostability.     

Regulation of cellulases and xylanases from a derepressed mutant of Cellulomonas flavigena growing on sugar-cane bagasse in continuous culture

When the wild type Cellulomonas flavigena was grown on glycerol, xylose or cellobiose, it produced basal levels of carboxymethyl-cellulase (CMCase), filter-paperase (FPase) and xylanase activities. By comparison, a catabolic derepressed mutant strain of the same organism produced markedly higher levels of these enzymes when grown on the same carbon sources. Sugar-cane bagasse induced both the wild type and the mutant strain to produce three- to eight-time higher levels of FPase and xylanase than was observed with xylose or cellobiose. Continuous culture was used to determine the minimal cellobiose or glucose concentrations that repress the enzyme synthesis in both strains. 2.5 g l(-1) glucose repressed FPase and xylanases from wild type, while 1.6 times more glucose was needed to repress the same activities in the PN-120 strain. In the same way, twofold more cellobiose was needed to reduce by 75% the CMCase and xylanase activities in the mutant compared to the wild type. The FPase in the presence of 4 g l(-1) cellobiose did not change in the same strain. Therefore, its derepressed and feedback resistant characters of PN-120 mutant are evident. On the other hand, isoelectrofocused crude extracts of mutant and wild strains induced by sugar-cane bagasse, did not show differences in protein patterns, however, the Schiffs staining was more intense in the PN-120 than in the wild strain. These results point out that the mutational treatment did not apparently change the extracellular proteins from mutant PN-120 and this could affect their regulation sites, since derepressed and feed-back resistant enzymes may be produced.     

rpoS基因插入突变对铜绿假单胞菌两个吩嗪合成基因簇的调控

【目的】为了研究铜绿假单胞菌rpoS基因对吩嗪(Phenazine)合成基因簇phz1和phz2的调控方式与机制。【方法】采用抗庆大霉素基因(gentamycin resistance cassette,aacC1)插入失活的策略构建了rpoS基因突变株PA-SG;同时利用lacZ的翻译融合表达载体pME6015,构建了phz1′-′lacZ和phz2′-′lacZ翻译融合表达载体pMEZ1和pMEZ2。采用电转化法分别将pMEZ1、pMEZ2和pME6015导入铜绿假单胞菌突变株PA-SG和野生株PAO1,用Miller法检测融合β-半乳糖苷酶活性。【结果】在KMB或PPM培养基中,pMEZ1在突变株PA-SG中的表达均增强,为野生株的4-5倍;而pMEZ2在突变株PA-SG中的表达均降低,野生株是突变株的2-3倍。【结论】由此推测,铜绿假单胞菌rpoS基因对两个不同吩嗪合成基因簇的调控作用具有特异性,在一定程度上,rpoS负调控phz1,正调控phz2。     

Altered prephenate dehydratase in phenylalanine-excreting mutants of Brevibacterium flavum.

The regulatory properties of three key enzymes in the phenylalanine biosynthetic pathway, 3-deoxy-D-arabino-heptulosonate 7-phosphate synthetase (DAHP synthetase) [EC 4.1.2.15], chorismate mutase [EC 5.4.99.5], and prephenate dehydratase [prephenate hydro-lyase (decarboxylating), EC 4.2.1.51] were compared in three phenylalanine-excreting mutants and the wild strain of Brevibacterium flavum. Regulation of DAHP synthetase by phenylalanine and tyrosine in these mutants did not change at all, but the specific activities of the mutant cell extracts increased 1.3- to 2.8-fold, as reported previously (1). Chorismate mutase activities in both the wild and the mutant strains were cumulatively inhibited by phenylalanine and tyrosine and recovered with tryptophan, while the specific activities of the mutants increased 1.3- to 2.8-fold, like those of DAHP synthetase. On the other hand, the specific activities of prephenate dehydratase in the mutant and wild strains were similar, when tyrosine was present. While prephenate dehydratase of the wild strain was inhibited by phenylalanine, tryptophan, and several phenylalanine analogues, the mutant enzymes were not inhibited at all but were activated by these effectors. Tyrosine activated the mutant enzymes much more strongly than the wild-type enzyme: in mutant 221-43, 1 mM tyrosine caused 28-fold activation. Km and the activation constant for tyrosine were slightly altered to a half and 6-fold compared with the wild-type enzyme, respectively, while the activation constants for phenylalanine and tryptophan were 500-fold higher than the respective inhibition constants of the wild-type enzyme. The molecular weight of the mutant enzyme was estimated to be 1.2 x 10(5), a half of that of the wild-type enzyme. The molecular weight of the mutant enzyme was estimated to be 1.2 X 10(5) a half of that of the wild type enzyme, while in the presence of tyrosine, phenylalanine, or tryptophan, it increased to that of the wild-type enzyme. Immediately after the mutant enzyme had been activated by tyrosine and then the tyrosine removed, it still showed about 10-fold higher specific activity than before the activation by tyrosine. However, on standing in ice the activity gradually fell to the initial level before the activation by tyrosine. Ammonium sulfate promoted the decrease of the activity. On the basis of these results, regulatory mechanisms for phenylalanine biosynthesis in vivo as well as mechanisms for the phenylalanine overproduction in the mutants are discussed.     

Chorismate mutase and 3-deoxy-D-arabino-heptulosonate 7-phosphate synthase of the methylotrophic actinomycete Amycolatopsis methanolica.

Chorismate mutase (CM) and 3-deoxy-D-arabino-heptulosonate 7-phosphate (DAHP) synthase (DS) are key regulatory enzymes in L-Phe and L-Tyr biosynthesis in Amycolatopsis methanolica. At least two CM proteins, CMIa and CMIb, are required for the single chorismate mutase activity in the wild type. Component CMIa (a homodimeric protein with 16-kDa subunits) was purified to homogeneity (2,717-fold) and kinetically characterized. The partially purified CMIb preparation obtained also contained the single DS (DSI) activity detectable in the wild type. The activities of CMIa and CMIb were inhibited by both L-Phe and L-Tyr. DSI activity was inhibited by L-Trp, L-Phe, and L-Tyr. A leaky L-Phe-requiring auxotroph, mutant strain GH141, grown under L-Phe limitation, possessed additional DS (DSII) and CM (CMII) activities. Synthesis of both CMII and DSII was repressed by L-Phe. An ortho-DL-fluorophenylalanine-resistant mutant of the wild type (strain oFPHE83) that had lost the sensitivity of DSII and CMII synthesis to L-Phe repression was isolated. DSII was partially purified (a 42-kDa protein); its activity was strongly inhibited by L-Tyr. CMII was purified to homogeneity (93.6 fold) and characterized as a homodimeric protein with 16-kDa subunits, completely insensitive to feedback inhibition by L-Phe and L-Tyr. The activity of CMII was activated by CMIb; the activity of CMII plus CMIb was again inhibited by L-Phe and L-Tyr. A tightly blocked L-Phe- plus L-Tyr-requiring derivative of mutant strain GH141, GH141-19, that had lost both CMIa and CMII activities was isolated.(ABSTRACT TRUNCATED AT 250 WORDS)     

In Vivo Complementation Between Wild-Type and Mutant β-Galactosidase in Escherichia coli

A comparison of the specific activity of wild-type beta-galactosidase synthesized in a lacZ(-)/lacZ(+) heterogenote has shown that there is 60% more activity in the heterogenote's enzyme than can be accounted for by wild-type subunits alone. It is concluded that wild type beta-galactosidase subunits can complement mutant subunits.     

Effect of mutations in the qa gene cluster of Neurospora crassa on the enzyme catabolic dehydroquinase.

Catabolic dehydroquinase, which functions in the inducible quinic acid catabolic pathway of Neurospora crassa, has been purified from wild type (74-A) and three mutants in the qa gene cluster. The mutant strains were: 105c, a temperature-sensitive constitutive mutant in the qa-1 regulatory locus; M-16, a qa-3 mutant deficient in quinate dehydrogenase activity; and 237, a leaky qa-2 mutant which possess very low levels of catabolic dehydroquinase activity. The enzymes purified from strains 74-A, 105c, and M-16 are identical with respect to behavior during purification, specific activity, electrophoretic behavior, stability, molecular weight, subunit structure, immunological cross-reactivity, and amino acid content. The mutant enzyme from strain 237 is 1,500-fold less active and appears to have a slightly different amino acid content. It is identical by a number of the other criteria listed above and is presumed to be a mutant at or near the enzyme active site. These data demonstrate that the qa-1 gene product is not involved in the posttranslational expression of enzyme activity. The biochemical identity of catabolic dehydroquinase isolated from strains 105c and M-16 with that from wild type also demonstrates that neither the inducer, quinic acid, nor other enzymes encoded in the qa gene cluster are necessary for the expression of activity. Therefore the combined genetic and biochemical data on the qa system continue to support the hypothesis that the qa-1 regulatory protein acts as a positive initiator of qa enzyme synthesis.     

Site-specific mutagenesis of lysine-204, tyrosine-224, tyrosine-228, and histidine-307 of porcine kidney D-amino acid oxidase and the implications as to its catalytic function

In order to evaluate the possible contributions of Lys-204, Tyr-224, Tyr-228, and His-307 in porcine kidney D-amino acid oxidase [EC 1.4.3.3] (DAO) to its catalytic function, we constructed four point mutant cDNAs encoding enzymes possessing Glu-204, Phe-224, Phe-228, and Leu-307 by oligonucleotide-directed in vitro mutagenesis. The four mutant cDNAs and the wild type cDNA could be expressed in vitro with similar efficiencies and about 200 ng of each enzyme protein was produced from 5 micrograms of the respective capped RNA. The electrophoretic mobilities of the in vitro synthesized mutant enzymes on SDS-polyacrylamide gel were almost identical with that of the wild type DAO, and the molecular weight was calculated to be 38,000. The Glu-204 and Phe-224 mutant DAOs showed comparable enzyme activities to that of the wild type enzyme, and were inhibited strongly by sodium benzoate, a potent competitive inhibitor of DAO. The kinetic parameters of the two mutant DAOs were also comparable to those of the wild type DAO. On the other hand, the Phe-228 and Leu-307 mutant DAOs showed no detectable activity. The results indicate that Tyr-228 and His-307 play important roles as to the constitution of the active site or participate in the reaction directly, while Lys-204 and Tyr-224 are not essential in the enzyme reaction.     

Glucokinase thermolability and hepatic regulatory protein binding are essential factors for predicting the blood glucose phenotype of missense mutations

To better understand how glucokinase (GK) missense mutations associated with human glycemic diseases perturb glucose homeostasis, we generated and characterized mice with either an activating (A456V) or inactivating (K414E) mutation in the gk gene. Animals with these mutations exhibited alterations in their blood glucose concentration that were inversely related to the relative activity index of GK. Moreover, the threshold for glucose-stimulated insulin secretion from islets with either the activating or inactivating mutation were left- or right-shifted, respectively. However, we were surprised to find that mice with the activating mutation had markedly reduced amounts of hepatic GK activity. Further studies of bacterially expressed mutant enzymes revealed that GK(A456V) is as stable as the wild type enzyme, whereas GK(K414E) is thermolabile. However, the ability of GK regulatory protein to inhibit GK(A456V) was found to be less than that of the wild type enzyme, a finding consistent with impaired hepatic nuclear localization. Taken together, this study indicates that it is necessary to have knowledge of both thermolability and the interactions of mutant GK enzymes with GK regulatory protein when attempting to predict in vivo glycemic phenotypes based on the measurement of enzyme kinetics.