Activity and spectroscopic properties of the Escherichia coli glutamate 1-semialdehyde aminotransferase and the putative active site mutant K265R.

Glutamate 1-semialdehyde aminotransferase (glutamate 1-semialdehyde 2,1-aminomutase; EC 5.4.3.8; GSA-AT) catalyzes the transfer of the amino group on carbon 2 of glutamate 1-semialdehyde (GSA) to the neighboring carbon 1 to form delta-aminolevulinic acid (ALA). To gain insight into the mechanism of this enzyme, possible intermediates were tested with purified enzyme and the reaction sequence was followed spectroscopically. While 4,5-dioxovaleric acid (DOVA) was efficiently converted to ALA by the pyridoxamine 5'-phosphate (PMP) form of the enzyme, 4,5-diaminovaleric acid (DAVA) was a substrate for the pyridoxal 5'-phosphate (PLP) form of GSA-AT. Thus, both substances are reaction intermediates. The purified enzyme showed an absorption spectrum with a peak around 338 nm. Addition of PLP led to increased absorption at 338 nm and a new peak around 438 nm. Incubation of the purified enzyme with PMP resulted in an additional absorption peak at 350 nm. The reaction of the PLP and PMP form of the enzyme with GSA allowed the detection of a series of peaks which varied in their intensities in a time-dependent manner. The most drastic changes to the spectrum that were observed during the reaction sequence were at 495 and 540 nm. Some of the detected absorption bands during GSA-AT catalysis were previously described for several other aminotransferases, indicating the relationship of the mechanisms. The reaction of the PMP form of the enzyme with DOVA resulted in a similar spectrum as described above, while the spectrum for the conversion of DAVA by the PLP form of the enzyme indicated a different mechanism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mutation of amino acids in the alpha 1,3-fucosyltransferase motif affects enzyme activity and Km for donor and acceptor substrates

Alpha 1,3-fucosyltransferases (FucT) share a conserved amino acid sequence designated the alpha 1,3 FucT motif that has been proposed to be important for nucleotide sugar binding. To evaluate the importance of the amino acids in this motif, each of the alpha 1,3 FucT motif amino acids was replaced with alanine (alanine scanning mutagenesis) in human FucT VI, and the resulting mutant proteins were analyzed for enzyme activity and kinetically characterized in those cases in which the mutant protein had sufficient activity. Two of the mutant proteins were inactive, six had less than 1% of wild-type activity, and four had approximately 10-50% of wild-type enzyme activity. Three of the mutant proteins with significant enzyme activity had substantially larger Km (5 to 15 times) for GDP-fucose than FucT VI wild-type enzyme. The fourth mutant protein with significant enzyme activity (S249A) had a Km at least 10 times larger than wild-type FucT VI for the acceptor substrate, with only a slightly larger (2-3 times) Km for GDP-fucose. Thus mutation of any of the amino acids within the alpha 1,3 FucT motif to Ala affects alpha 1,3-FucT activity, and substitution of Ala for some of the alpha 1,3 FucT motif amino acids results in proteins with altered kinetic constants for both the acceptor and donor substrates. Secondary structure prediction suggests a helix-loop-helix fold for the alpha 1,3 FucT motif, which can be used to rationalize the effects of mutations in terms of 3D structure.     

Gabaculine-resistant glutamate 1-semialdehyde aminotransferase of Synechococcus. Deletion of a tripeptide close to the NH2 terminus and internal amino acid substitution

Glutamate 1-semialdehyde aminotransferase (GSA-AT) is the last enzyme in the C5 pathway converting glutamate into the tetrapyrrole precursor delta-aminolevulinate in plants, algae, and several bacteria. Sequence analysis of the genes encoding GSA-AT in barley, Synechococcus, and Escherichia coli revealed 50-70% similarity in the primary structures of the proteins. The enzyme is inhibited rapidly by gabaculine when added in approximately stoichiometric amounts with the enzyme. A gabaculine-tolerant Synechococcus strain, GR6, was found to produce a GSA-AT less sensitive to the inhibitor. Accordingly, the mutant gene was isolated and sequenced. In comparison with the wild-type gene it contains a deletion of nine nucleotides (position 12-20) and a guanine to adenine substitution (position 743). This resulted in the loss of the amino acids serine, proline, and phenylalanine (position 5-7) close to the NH2 terminus of the enzyme and an exchange of Met-248 for isoleucine in the middle of the polypeptide chain. Wild-type and mutant GSA-AT were expressed in E. coli and purified close to homogeneity. Although the specific activity of the mutant GSA-AT was only one-fifth of the wild type, it displayed a 100-fold increased resistance to gabaculine. Peaks in the absorption spectrum of the purified recombinant GSA-ATs at 335 and 417 nm are typical of a transaminase containing a B6 cofactor. Incubation with substrate and with inhibitor induced spectral changes characteristic of other gabaculine-sensitive, B6-requiring enzymes.     

Crystal structure of glutamate-1-semialdehyde aminotransferase from Bacillus subtilis with bound pyridoxamine-5'-phosphate

Glutamate-1-semialdehyde aminotransferase (GSA-AT), also named glutamate-1-semialdehyde aminomutase (GSAM), a pyridoxamine-5′-phosphate (PMP)/pyridoxal-5′-phosphate (PLP) dependent enzyme, catalyses the transamination of the substrate glutamate-1-semialdehyde (GSA) to the product 5-Aminolevulinic acid (ALA) by an unusual intramolecular exchange of amino and oxo groups within the catalytic intermediate 4,5-diaminovalerate (DAVA). This paper presents the crystal structure of GSA-AT from Bacillus subtilis (GSA-AT_Bsu) in its PMP-bound form at 2.3 Å resolution. The structure was determined by molecular replacement using the Synechococcus GSAM (GSAM_Syn) structure as a search model. Unlike the previous reported GSAM/GSA-AT structures, GSA-AT_Bsu is a symmetric homodimer in the PMP-bound form, which shows the structural symmetry at the gating loop region with open state, as well as identical cofactor (PMP) binding in each monomer. This observation of PMP in combination with an “open” lid supports one characteristic feature for this enzyme, as the catalyzed reaction is believed to be initiated by PMP. Furthermore, the symmetry of GSA-AT_Bsu structure challenges the previously proposed negative cooperativity between monomers of this enzyme.     

Expression of a Brassic napus glutamate 1-semialdehyde aminotransferase in Escherichia coli and characterization of the recombinant protein

Glutamate 1-semialdehyde aminotransferase (GSA-AT) is a key regulatory enzyme, which converts glutamate 1-semialdehyde (GSA) to 5-aminolevulinic acid (ALA) in chlorophyll biosynthesis. ALA is the universal precursor for the synthesis of chlorophyll, heme, and other tetrapyrroles. To study the regulation of chlorophyll biosynthesis in Brassica napus, two cDNA clones of GSA-AT were isolated for genetic manipulation. A SalI-XbaI fragment from one of the two cDNA clones of GSA-AT was used for recombinant protein expression by inserting it at the 3' end of a calmodulin-binding-peptide (CBP) tag of the pCaln vector. The CBP tagged recombinant protein, expressed in Escherichia coli, was purified to apparent homogeneity in a one step purification process using a calmodulin affinity column. The purified CBP tagged GSA-AT is biologically active and has a specific activity of 16.6 nmol/min/mg. Cleavage of the CBP tag from the recombinant protein with thrombin resulted in 9.2% loss of specific activity. However, removal of the cleaved CBP tag from the recombinant protein solution resulted in 60% loss of specific activity, suggesting possible interactions between the recombinant protein and the CBP tag. The enzyme activity of the CBP tagless recombinant protein, referred as TR-GSA-AT hereafter, was not affected by the addition of pyridoxamine 5' phosphate (PMP). Addition of glutamate and pyridoxal 5' phosphate (PLP) to the TR-GSA-AT enhanced the enzyme activity by 3-fold and 3.6-fold, respectively. Addition of both glutamate and PLP increased the enzyme activity by 4.6-fold. Similar to the GSA-AT of B. napus, the active TR-GSA-AT is a dimeric protein of 88 kDa with 45.5 kDa subunits. As the SalI-XbaI fragment encodes a biologically active GSA-AT that has the same molecular mass as the native GSA-AT, it is concluded that the SalI-XbaI fragment is the coding sequence of GSA-AT. The highly active polyclonal antibodies generated from TR-GSA-AT were used for the detection of GSA-AT of B. napus.     

Physical and kinetic interactions between glutamyl-tRNA reductase and glutamate-1-semialdehyde aminotransferase of Chlamydomonas reinhardtii

In plants, algae, and most bacteria, the heme and chlorophyll precursor 5-aminolevulinic acid (ALA) is formed from glutamate in a three-step process. First, glutamate is ligated to its cognate tRNA by glutamyl-tRNA synthetase. Activated glutamate is then converted to a glutamate 1-semialdehyde (GSA) by glutamyl-tRNA reductase (GTR) in an NADPH-dependent reaction. Subsequently, GSA is rearranged to ALA by glutamate-1-semialdehyde aminotransferase (GSAT). The intermediate GSA is highly unstable under physiological conditions. We have used purified recombinant GTR and GSAT from the unicellular alga Chlamydomonas reinhardtii to show that GTR and GSAT form a physical and functional complex that allows channeling of GSA between the enzymes. Co-immunoprecipitation and sucrose gradient ultracentrifugation results indicate that recombinant GTR and GSAT enzymes specifically interact. In vivo cross-linking results support the in vitro results and demonstrate that GTR and GSAT are components of a high molecular mass complex in C. reinhardtii cells. In a coupled enzyme assay containing GTR and wild-type GSAT, addition of inactive mutant GSAT inhibited ALA formation from glutamyl-tRNA. Mutant GSAT did not inhibit ALA formation from GSA by wild-type GSAT. These results suggest that there is competition between wild-type and mutant GSAT for binding to GTR and channeling GSA from GTR to GSAT. Further evidence supporting kinetic interaction of GTR and GSAT is the observation that both wild-type and mutant GSAT stimulate glutamyl-tRNA-dependent NADPH oxidation by GTR.     

Characterization of glutamate-1-semialdehyde aminotransferase of Synechococcus. Steady-state kinetic analysis.

Synechococcus glutamate-1-semialdehyde aminotransferase was expressed in large amounts in transformed cells of Escherichia coli. The resulting purified enzyme has an absorption spectrum characteristic of B6-containing enzymes and could be converted to the pyridoxal-phosphate form with excess dioxovalerate (O2Val), and back to the pyridoxamine-phosphate form with diaminovalerate (A2Val). Both enzyme forms are similarly active in the conversion of glutamate 1-semialdehyde (GSA) to 5-aminolevulinate (ALev), suggesting that A2Val and O2Val are intermediates. Initial rates of ALev synthesis at various fixed concentrations of GSA followed typical Michaelis-Menten kinetics (Km of GSA for the pyridoxamine-phosphate form of GSA aminotransferase = 12 microM, kcat = 0.23 s-1). In submicromolar amounts A2Val stimulates ALev synthesis, and in a series of concentrations with various fixed concentrations of GSA, gives a family of parallel lines in Lineweaver-Burk plots (Km for A2Val = 1.0 microM). On the other hand, O2Val gives competitive inhibition of the pyridoxamine-phosphate form of GSA-aminotransferase and mixed-type inhibition of the pyridoxal-phosphate form (Ki for O2Val = 1.4 mM). In general the kinetics were typical of ping-pong bi-bi mechanisms in which A2Val is the second substrate (intermediate) and O2Val is an alternative first substrate. There is no compelling evidence that O2Val accepts an amino group at its C5 position resulting in the direct formation of ALev, or the reverse involving the apparent formation of O2Val from ALev. These results are consistent with the hypothesis that the mechanism of GSA aminotransferase mimics that of other aminotransferases and that A2Val is the intermediate.     

Purification and Characterization of Glutamate 1-Semialdehyde Aminotransferase from Barley Expressed in Escherichia coli

The immediate precursor in the synthesis of tetrapyrroles is Δ-aminolevulinate (ALA). ALA is synthesized from glutamate in higher plants, algae, and certain bacteria. Glutamate 1-semialdehyde aminotransferase (EC 5.4.3.8) (GSA-AT), the third enzyme involved in this metabolic pathway, catalyzes the transamination of GSA to form ALA. The gene encoding this aminotransferase has previously been isolated from barley (Hordeum vulgare) and inserted into an Escherichia coli expression vector. We describe herein the purification of this recombinant barley GSA-AT expressed in Escherichia coli. Coexpression of GroEL and GroES is required for isolation of active aminotransferase from the soluble protein fraction of Escherichia coli. Purified GSA-AT exhibits absorption maxima characteristic of vitamin B₆-containing enzymes. GSA-AT is primarily in the pyridoxamine form when isolated and can be interconverted between this and the pyridoxal form by addition of 4,5-dioxovalerate and 4,5-diaminovalerate. The conversion of GSA to ALA under steady-state conditions exhibited typical Michaelis-Menten kinetics. Values for K_m (d,l-GSA) and k_cat were determined to be 25 micromolar and 0.11 per second, respectively, by nonlinear regression analysis. Stimulation of ALA synthesis by increasing concentrations of d,l-GSA at various fixed concentrations of 4,5-diaminovalerate supports the hypothesis that 4,5-diaminovalerate is the intermediate in the synthesis of ALA.     

Structural role of serine 127 in the NADH-binding site of human NADH-cytochrome b5 reductase

Serine 127 of human NADH-cytochrome b5 reductase was replaced by proline and alanine by site-directed mutagenesis. The former mutation has been found in the genes of patients with hereditary deficiency of the enzyme. Both the mutant enzymes (Ser-127----Pro mutant and Ser-127----Ala mutant) were overproduced in Escherichia coli and purified to homogeneity. The two purified mutant enzymes showed indistinguishable spectral properties which differed from those of the wild-type enzyme. The mutant enzymes showed higher molecular extinction coefficients at 462 nm than that of the wild-type enzyme. Quenching of FAD fluorescence in these mutant enzymes was significantly less than that in the wild-type enzyme. Furthermore, circular dichroism spectra of the mutant enzymes were different, in both the visible and ultraviolet regions, from that of the wild-type enzyme. The spectra of the mutant enzymes in the visible region were restored to almost the same spectrum as the wild type upon reduction with NADH. Ser-127----Pro mutant and Ser-127----Ala mutant showed very low Kcat/Km (NADH) values (5 x 10(7) and 3.5 x 10(7) s-1 M-1, respectively) with cytochrome b5 as an electron acceptor, than that of the wild-type enzyme (Kcat/Km (NADH) = 179 x 10(7) s-1 M-1), while the Kcat/Km (cytochrome b5) value for each enzyme was similar. The mutant enzymes were less thermostable than the wild-type enzyme. These results indicate that serine 127 plays an important role to maintain the structure of the NADH-binding site in the enzyme.     

Replacement of lysine 269 by arginine in Escherichia coli tryptophan indole-lyase affects the formation and breakdown of quinonoid complexes

Lysine 269 in Escherichia coli tryptophan indole-lyase (tryptophanase) has been changed to arginine by site-directed mutagenesis. The resultant K269R mutant enzyme exhibits kcat values about 10% those of the wild-type enzyme with S-(o-nitrophenyl)-L-cysteine, L-tryptophan, and S-benzyl-L-cysteine, while kcat/Km values are reduced to 2% or less. The pH profile of kcat/Km for S-benzyl-L-cysteine for the mutant enzyme exhibits two pK alpha values which are too close to separate, with an average value of 7.6, while the wild-type enzyme exhibits pK alpha values of 6.0 and 7.8. The pK alpha for the interconversion of the 335 and 412 nm forms of the K269R enzyme is 8.3, while the wild-type enzyme exhibits a pK alpha of 7.4. Steady-state kinetic isotope effects on the reaction of [alpha-2H]S-benzyl-L-cysteine with the K269R mutant enzyme (Dkcat = 2.0; D(kcat/Km) = 3.9) are larger than those of the wild-type enzyme (Dkcat = 1.4; D(kcat/Km) = 2.9). Rapid scanning stopped-flow kinetic studies demonstrate that the K269R mutant enzyme does not accumulate quinonoid intermediates with L-alanine, L-tryptophan, or S-methyl-L-cysteine, but does form quinonoid absorption peaks in complexes with S-benzyl-L-cysteine and oxidolyl-L-alanine, whereas wild-type enzyme forms prominent quinonoid bands with all these amino acids. Single wavelength stopped-flow kinetic studies demonstrate that the alpha-deprotonation of S-benzyl-L-cysteine is 6-fold slower in the K269R mutant enzyme, while the intrinsic deuterium kinetic isotope effect is less for the K269R enzyme (Dk = 4.2) than for the wild-type (Dk = 7.9). The decay of the K269R quinonoid intermediate in the presence of benzimidazole is 7.1-fold slower than that of the wild-type enzyme. These results demonstrate that Lys-269 plays a significant role in the conformational changes or electrostatic effects obligatory to the formation and decomposition of the quinonoid intermediate, although it is not an essential basic residue.     

The role of Lys272 in the pyridoxal 5-phosphate active site of Synechococcus glutamate-1-semialdehyde aminotransferase.

Glutamate-1-semialdehyde (GSA) aminotransferase catalyzes transfer of the C2 amino group of glutamate 1-semialdehyde to the C1 position to yield the tetrapyrrole precursor 5-aminolevulinate. Based on spectrophotometric and steady-state data, GSA aminotransferase is a B6-containing enzyme which uses a ping-pong bi-bi mechanism described for other aminotransferases. A putative active-site lysine at position 272 of Synechococcus GSA aminotransferase was replaced by Arg, Ile or Glu, and genes encoding the corresponding three site directed mutants were expressed in Escherichia coli. The catalytic competence of the resulting enzymes was determined. The similarity of the absorbance spectra of pyridoxal-P-treated forms of Lys272----Arg, Lys272----Ile, Lys272----Glu with free pyridoxal-P indicates that enzyme-bound pyridoxal-P does not form an internal aldimine in in these three site-directed mutants. Whereas Lys----Ile and Lys----Glu form only stable ketimines and aldimines with GSA and its analogues, addition of these compounds to the pyridoxamine-P and pyridoxal-P forms of Lys----Arg induces slow spectral changes, indicating the catalysis of a half-reaction with GSA, 4,5-dioxovalerate and 4,5-diaminovalerate. 5-Aminolevulinate apparently binds with both coenzyme forms of Lys272----Arg, however significant tautomeric rearrangement is only observed with the pyridoxal-P form. It is suggested that Lys272 is the covalent pyridoxal-P-binding site and that this catalytically active lysine residue channels the overall transamination reaction towards 5-aminolevulinate. The second-half reaction (4,5-diaminovalerate in equilibrium with 5-aminolevulinate) is possibly supported by the formation of an internal aldimine which correctly positions the C4 amino group of 4,5-diaminovalerate relative to the enzyme-bound pyridoxal-P.     

Restriction of Chlorophyll Synthesis Due to Expression of Glutamate 1-Semialdehyde Aminotransferase Antisense RNA Does Not Reduce the Light-Harvesting Antenna Size in Tobacco

The formation of 5-aminolevulinate is a key regulatory step in tetrapyrrole biosynthesis. In higher plants, glutamate 1-semialdehyde aminotransferase (GSA-AT) catalyzes the last step in the sequential conversion of glutamate to 5-aminolevulinate. Antisense RNA synthesis for GSA-AT leads to reduced GSA-AT protein levels in tobacco (Nicotiana tabacum L.) plants. We have used these transgenic plants for studying the significance of chlorophyll (Chl) availability for assembly of the light-harvesting apparatus. To avoid interfering photoinhibitory stress, plants were cultivated under a low photon flux density of 70 [mu]mol photons m-2 s-1. Decreased GSA-AT expression does not seem to suppress other enzymic steps in the Chl pathway, indicating that reduced Chl content in transgenic plants (down to 12% of the wild-type level) is a consequence of reduced GSA-AT activity. Chl deficiency correlated with a drastic reduction in the number of photosystem I and photosystem II reaction centers and their surrounding antenna on a leaf area basis. Different lines of evidence from the transgenic plants indicate that complete assembly of light-harvesting pigment-protein complexes is given preference over synthesis of new reaction center/core complexes, resulting in fully assembled photosynthetic units with no reduction in antenna size. Photosynthetic oxygen evolution rates and in vivo Chl fluorescence showed that GSA-AT antisense plants are photochemically competent. Thus, we suggest that under the growth conditions chosen during this study, plants tend to maintain their light-harvesting antenna size even under limited Chl supply.     

Cloning of tomato (Lycopersicon esculentum Mill.) arginine decarboxylase gene and its expression during fruit ripening.

Extracts of soybean (Glycine max) root nodules and greening etiolated leaves catalyzed radiolabeled delta-aminolevulinic acid (ALA) formation from 3,4-[3H]glutamate but not from 1-[14C]glutamate. Nevertheless, those tissue extracts expressed the activity of glutamate 1-semialdehyde (GSA) aminotransferase, the C5 pathway enzyme that catalyzes ALA synthesis from GSA for tetrapyrrole formation. A soybean nodule cDNA clone that conferred ALA prototrophy, GSA aminotransferase activity, and glutamate-dependent ALA formation activity on an Escherichia coli GSA aminotransferase mutant was isolated. The deduced product of the nodule cDNA shared 79% identity with the GSA aminotransferase expressed in barley leaves, providing, along with the complementation data, strong evidence that the cDNA encodes GSA aminotransferase. GSA aminotransferase mRNA and enzyme activity were expressed in nodules but not in uninfected roots, indicating that the Gsa gene is induced in the symbiotic tissue. The Gsa gene was strongly expressed in leaves of etiolated plantlets independently of light treatment and, to a much lesser extent, in leaves of mature plants. We conclude that GSA aminotransferase, and possibly the C5 pathway, is expressed in a nonphotosynthetic plant organ for nodule heme synthesis and that Gsa is a regulated gene in soybean.     

Glutamate 1-semialdehyde aminotransferase: anomalous enantiomeric reaction and enzyme mechanism.

Glutamate 1-semialdehyde aminotransferase (GSA-AT) catalyzes near 50% conversion of the racemic mixture of GSA to 5-aminolevulinate (ALA), indicating quantitative use of the L-glutamate-derived natural (S)-enantiomer as substrate. This enzymic reaction has been extensively studied with (R,S)-GSA because it is readily purified in high yields following ozonolysis of racemic 4-vinyl-4-aminobutyric acid. However upon addition of (R,S)-GSA, GSA-aminotransferase is converted to the pyridoxal-P or internal aldimine form (418 nm) and not rapidly cycled back to the original pyridoxamine-P, as predicted by the rate of product (ALA) accumulation. Addition of the putative intermediate, (R,S)-4,5-diaminovalerate (DAVA), eliminates this rapid conversion of the enzyme by (R,S)-GSA to the internal aldimine and stimulates initial rates of ALA synthesis (2-3-fold) and results in corresponding increases in apparent equilibrium concentrations of ALA. These results indicate that DAVA is rate limiting and suggest anomalous reactivity of (R)-GSA. Steady-state and spectral kinetic experiments with individual purified enantiomers confirm anomalous reactivity of (R)-GSA: in the case of (S)-GSA, spectral changes are lesser in amplitude and at least 1 or 2 orders of magnitude more rapid. Only (S)-GSA yielded significant amounts of ALA. Since (R)-GSA is an apparent substrate in the first half-reaction, the resulting (R)-DAVA is either inactive or a poor substrate in the second half-reaction.     

Kinetic consequences of site-specific mutation of Glu-239----Gln in E. coli aspartate transcarbamylase: comparison with catalytic subunits and Phe-240 mutant enzyme

The kinetic characteristics of E. coli aspartate transcarbamylase, altered by site-specific mutagenesis of Glu-239----Gln, have been determined by equilibrium isotope-exchange kinetics and compared to the wild-type system. In wild-type enzyme, residue Glu-239 helps to stabilize the T-state structure by multiple bonding interactions with Tyr-165 and Lys-164 across the c1-c4 subunit interface; upon conversion to the R-state, these bonds are re-formed within c-chains. Catalysis of both the [14C]Asp in equilibrium C-Asp and [32P]ATP in equilibrium Pi exchanges by mutant enzyme occurs at rates comparable to those for wild-type enzyme. Saturation with different reactant/product pairs produced kinetic patterns consistent with strongly preferred order binding of carbamyl-P prior to Asp and carbamyl-Asp release before Pi. The kinetics for the Gln-239 mutant enzyme resemble those observed for catalytic subunits (c3), namely a R-state enzyme (Hill coefficient nH = 1.0) and Km (Asp) approximately equal to 6 mM. The Glu-239----Gln mutation appears to destablize both the T- and R-states, whereas the Tyr-240----Phe mutation destablizes only the T-state.     

Structural and functional role of the amino-terminal region of porcine cytosolic aspartate aminotransferase. Catalytic and structural properties of enzyme derivatives truncated on the amino-terminal side

In porcine cytosolic aspartate aminotransferase, a dimeric enzyme, the amino-terminal region anchoring onto the neighboring subunit is linked to the adjoining floppy peptide segment (residues 12-47), an integral part of the small domain whose facile movement upon substrate binding is a striking "induced fit" feature of this enzyme. To assess the contribution by the amino-terminal region to small domain movement and protein stability, a series of enzyme derivatives truncated on the amino-terminal side (residues 1-9) was prepared by using oligonucleotide-directed in vitro mutagenesis. Deletion of residues 1-3 showed no effect on catalytic activity and heat stability. Del 1-5 mutant enzyme with an extra methionine at position 5 showed only 43% of the kappa cat value (in the overall transamination) of the wild-type enzyme. Further deletion up to residue 9 resulted in a slight decrease in kappa cat values. Del 1-9 mutant enzyme still retained a kappa cat value of 33% that of wild-type enzyme. Km values for aspartate and 2-oxoglutarate increased sharply upon deletion of residues 1-9. Accordingly, Del 1-9 mutant enzyme showed a striking decrease in the kappa cat/Km value, to only 2% of that for the wild-type enzyme. Deletion of amino-terminal residues 1-9 resulted also in a large decrease in thermostability and in an enhanced susceptibility to limited proteolysis by protease 401, which is known to cleave at Leu20 of the wild-type enzyme. These findings indicate that an increase in the conformational freedom of the floppy segment (residues 12-47) would occur upon the loss of most of the anchorage region, thereby presenting an entropic barrier to conformational changes that facilitate substrate binding with high affinity.     

Isolation of a Bacillus stearothermophilus mutant exhibiting increased thermostability in its restriction endonuclease.

A procedure was developed for the selection of spontaneous mutants of Bacillus stearothermophilus NUB31 that are more efficient than the wild type in the restriction of phage at elevated temperatures. Inactivation studies revealed that two mutants contained a more thermostable restriction enzyme and one mutant contained three times more enzyme than the wild type. The restriction endonucleases from the wild type and one of the mutants were purified to apparent homogeneity. The mutant enzyme was more thermostable than the wild-type enzyme. The subunit molecular weight, amino acid composition, N-terminal and C-terminal amino acid residues, tryptic peptide map, and catalytic properties of the two enzymes were determined. The two enzymes have similar catalytic properties, but the molecular size of the mutant enzyme is approximately 6 to 7 kilodaltons larger than that of the wild-type enzyme. The mutant enzyme contains 54 additional amino acid residues, of which 26 to 28 are aspartate/asparagine, 8 to 15 are glutamate/glutamine, and 8 to 9 are tyrosine residues. The two enzymes contained similar amounts of the other amino acids, identical N-terminal residues, and different C-terminal residues. Tryptic peptide analyses revealed a high degree of homology between the two enzymes. The increased thermostability observed in the mutant enzyme appears to have been achieved by a mutation that resulted in the addition of amino acid residues to the wild-type enzyme. A number of mechanisms are discussed that could account for the observed difference between the mutant and wild-type enzymes.     

Role of conserved histidine residues in D-aminoacylase from Alcaligenes xylosoxydans subsp. xylosoxydans A-6

D-Aminoacylase from Alcaligenes xylosoxydans subsp. xylosoxydans A-6 (Alcaligenes A-6) was strongly inactivated by diethylpyrocarbonate (DEPC). An H67N mutant was barely active, with a kcat/Km 6.3 x 10(4) times lower than that of the recombinant wild-type enzyme, while the H67I mutant lost detectable activity. The H67N mutant had almost constant Km, but greatly decreased kcat. These results suggested that His67 is essential to the catalytic event. Both H69N and H69I mutants were overproduced in the insoluble fraction. The kcat/Km of H250N mutant was reduced by a factor of 2.5 x 10(4)-fold as compared with the wild-type enzyme. No significant difference between H251N mutant and wild-type enzymes in the Km and kcat was found. The Zn content of H250N mutant was nearly half of that of wild-type enzyme. These results suggest that the His250 residue might be essential to catalysis via Zn binding.     

Temperature-sensitive inhibition of development in Dictyostelium due to a point mutation in the piaA gene

The Dictyostelium mutant HSB1 is temperature-sensitive for development, undergoing aggregation and fruiting body formation at temperatures below 18 degrees C but not above. In vivo G protein-linked adenylyl cyclase activation is defective in HSB1, and the enzyme is not stimulated in vitro by GTPgammaS; stimulation is restored upon addition of wild-type cytosol. Transfection with the gene encoding the cytosolic regulator PIA rescued the mutant. We excluded the possibility that HSB1 cells fail to express PIA and show that the HSB1 piaA gene harbors a point mutation, resulting in the amino acid exchange G(917)D. Both wild-type and HSB1 cells were also transfected with the HSB1 piaA gene. The piaA(HSB1) gene product displayed a partial inhibitory effect on wild-type cell development. We hypothesize that PIA couples the heterotrimeric G protein to adenylyl cyclase via two binding sites, one of which is altered in a temperature-sensitive way by the HSB1 mutation. When overexpressed in the wild-type background, PIA(HSB1) competes with wild-type PIA via the nonmutated binding site, resulting in dominant-negative inhibition of development. Expression of GFP-fused PIA shows that PIA is homogeneously distributed in the cytoplasm of chemotactically moving cells.