Investigating the structure of human RNase H1 by site-directed mutagenesis

In this study we examine for the first time the roles of the various domains of human RNase H1 by site-directed mutagenesis. The carboxyl terminus of human RNase H1 is highly conserved with Escherichia coli RNase H1 and contains the amino acid residues of the putative catalytic site and basic substrate-binding domain of the E. coli RNase enzyme. The amino terminus of human RNase H1 contains a structure consistent with a double-strand RNA (dsRNA) binding motif that is separated from the conserved E. coli RNase H1 region by a 62-amino acid sequence. These studies showed that although the conserved amino acid residues of the putative catalytic site and basic substrate-binding domain are required for RNase H activity, deletion of either the catalytic site or the basic substrate-binding domain did not ablate binding to the heteroduplex substrate. Deletion of the region between the dsRNA-binding domain and the conserved E. coli RNase H1 domain resulted in a significant loss in the RNase H activity. Furthermore, the binding affinity of this deletion mutant for the heteroduplex substrate was approximately 2-fold tighter than the wild-type enzyme suggesting that this central 62-amino acid region does not contribute to the binding affinity of the enzyme for the substrate. The dsRNA-binding domain was not required for RNase H activity, as the dsRNA-deletion mutants exhibited catalytic rates approximately 2-fold faster than the rate observed for wild-type enzyme. Comparison of the dissociation constant of human RNase H1 and the dsRNA-deletion mutant for the heteroduplex substrate indicates that the deletion of this region resulted in a 5-fold loss in binding affinity. Finally, comparison of the cleavage patterns exhibited by the mutant proteins with the cleavage pattern for the wild-type enzyme indicates that the dsRNA-binding domain is responsible for the observed strong positional preference for cleavage exhibited by human RNase H1.     

The role of Leu-190 in the function and stability of adenylate kinase

To elucidate the role of C-terminal region of chicken adenylate kinase (a single polypeptide consisting of 193 amino acid residues) in the catalysis and stability of the enzyme, a series of mutant proteins truncated in the C-terminal region has been prepared by successive replacements of the sense codons by a termination codon via site-directed mutagenesis. Removal of the three C-terminal residues did not affect the apparent Michaelis constants (Km values) for AMP and ATP, although the Vmax values decreased gradually in parallel with the length of the polypeptide chain. A sudden increase in Km values for substrates, in particular for ATP, was observed on removal of one additional residue (Leu-190), the Vmax value also being less than one-half of that of the mutant enzyme with 3 residues shorter than the wild-type enzyme. These results suggest the importance of the highly conservative Leu-190. Therefore, we further prepared the mutant enzymes through replacement of Leu-190 by a variety of other amino acid residues. They all had substantially lower Vmax values and decreased thermostabilities. Their apparent Km values for ATP also changed, whereas those for AMP were affected to a lesser extent. The hydrophobicity of amino acid residues at position 190 was found to positively correlate with the specificity constants (kcat/Km values) for ATP and also with the thermostability of the enzyme. The fluorescence emission of the Trp-190 mutant enzyme was quenched by the addition of ATP. It is suggested that the C-terminal residues, particularly those around Leu-190, are present in a hydrophobic region which may be involved in binding of ATP.     

Expression and characterization of catalytic and regulatory domains of rat tyrosine hydroxylase.

Phenylalanine hydroxylase, tyrosine hydroxylase, and tryptophan hydroxylase constitute a family of tetrahydropterin-dependent aromatic amino acid hydroxylases. Comparison of the amino acid sequences of these three proteins shows that the C-terminal two-thirds are homologous, while the N-terminal thirds are not. This is consistent with a model in which the C-terminal two-thirds constitute a conserved catalytic domain to which has been appended discrete regulatory domains. To test such a model, two mutant proteins have been constructed, expressed in Escherichia coli, purified, and characterized. One protein contains the first 158 amino acids of rat tyrosine hydroxylase. The second lacks the first 155 amino acid residues of this enzyme. The spectral properties of the two domains suggest that their three-dimensional structures are changed only slightly from intact tyrosine hydroxylase. The N-terminal domain mutant binds to heparin and is phosphorylated by cAMP-dependent protein kinase at the same rate as the holoenzyme but lacks any catalytic activity. The C-terminal domain mutant is fully active, with Vmax and Km values identical to the holoenzyme; these results establish that all of the catalytic residues of tyrosine hydroxylase are located in the C-terminal 330 amino acids. The results with the two mutant proteins are consistent with these two segments of tyrosine hydroxylase being two separate domains, one regulatory and one catalytic.     

A Corynebacterium glutamicum rnhA recG double mutant showing lysozyme-sensitivity, temperature-sensitive growth, and UV-sensitivity

Corynebacterium glutamicum mutant KY9707 was originally isolated for lysozyme-sensitivity, and showed temperature-sensitive growth. Two DNA fragments from a wild-type C. glutamicum chromosomal library suppressed the temperature-sensitivity of KY9707. These clones also rescued the lysozyme-sensitivity of KY9707, although partially. One of them encodes a protein of 382 amino acid residues, the N-terminal domain of which was homologous to RNase HI. This gene suppressed the temperature-sensitive growth of an Escherichia coli rnhA rnhB double mutant. We concluded that this gene encodes a functional RNase HI of C. glutamicum and designated it as rnhA. The other gene encodes a protein of 707 amino acid residues highly homologous to RecG protein. The C. glutamicum recG gene complemented the UV-sensitivity of E. coli recG258::kan mutant. KY9707 showed increased UV-sensitivity, which was partially rescued by either the recG or rnhA gene of C. gluamicum. Point mutations were found in both recG and rnhA genes in KY9707. These suggest that temperature-sensitive growth, UV-sensitivity, and probably lysozyme-sensitivity also, of KY9707 were caused by mutations in the genes encoding RNase HI and RecG.     

Heat labile ribonuclease HI from a psychrotrophic bacterium: gene cloning, characterization and site-directed mutagenesis.

The rnhA gene encoding RNase HI from a psychrotrophic bacterium, Shewanella sp. SIB1, was cloned, sequenced and overexpressed in an rnh mutant strain of Escherichia coli. SIB1 RNase HI is composed of 157 amino acid residues and shows 63% amino acid sequence identity to E.coli RNase HI. Upon induction, the recombinant protein accumulated in the cells in an insoluble form. This protein was solubilized and purified in the presence of 7 M urea and refolded by removing urea. Determination of the enzymatic activity using M13 DNA-RNA hybrid as a substrate revealed that the enzymatic properties of SIB1 RNase HI, such as divalent cation requirement, pH optimum and cleavage mode of a substrate, are similar to those of E.coli RNase HI. However, SIB1 RNase HI was much less stable than E.coli RNase HI and the temperature (T(1/2)) at which the enzyme loses half of its activity upon incubation for 10 min was approximately 25 degrees C for SIB1 RNase HI and approximately 60 degrees C for E.coli RNase HI. The optimum temperature for the SIB1 RNase HI activity was also shifted downward by 20 degrees C compared with that of E.coli RNase HI. Nevertheless, SIB1 RNase HI was less active than E.coli RNase HI even at low temperatures. The specific activity determined at 10 degrees C was 0.29 units/mg for SIB1 RNase HI and 1.3 units/mg for E.coli RNase HI. Site-directed mutagenesis studies suggest that the amino acid substitution in the middle of the alphaI-helix (Pro52 for SIB1 RNase HI and Ala52 for E.coli RNase HI) partly accounts for the difference in the stability and activity between SIB1 and E.coli RNases HI.     

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.     

Site-directed mutagenesis of the small subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase from Anacystis nidulans

Using oligonucleotide-directed mutagenesis of the gene encoding the small subunit (rbcS) from Anacystis nidulans mutant enzymes have been generated with either Trp-54 of the small subunit replaced by a Phe residue, or with Trp-57 replaced by a Phe residue, whereas both Trp-54 and Trp-57 have been replaced by Phe residues in a double mutant. Trp-54 and Trp-57 are conserved in all amino acid sequences or the small subunit (S) that are known at present. The wild-type and mutant forms of Rubisco have all been purified to homogeneity. The wild-type enzyme, purified from Escherichia coli is indistinguishable from enzyme similarly purified from A. nidulans in subunit composition, subunit molecular mass and kinetic parameters (Vmax CO2 = 2.9 U/mg, Km CO2 = 155 microM). The single Trp mutants are indistinguishable from the wild-type enzyme by criteria (a) and (b). However, whereas, Km CO2 is also unchanged, Vmax CO2 is 2.5-fold smaller than the value for the wild-type enzyme for both mutants, demonstrating for the first time that single amino acid replacements in the non-catalytic small subunit influence the catalytic rate of the enzyme. The specificity factor tau, which measures the partitioning of the active site between the carboxylase and oxygenase reactions, was found to be invariant. Since tau is not affected by these mutations we conclude that S is an activating not a regulating subunit.     

Stabilization of Escherichia coli ribonuclease HI by strategic replacement of amino acid residues with those from the thermophilic counterpart.

Thermus thermophilus ribonuclease H is exceptionally stable against thermal and guanidine hydrochloride denaturations as compared to Escherichia coli ribonuclease HI (Kanaya, S., and Itaya, M. (1992) J. Biol. Chem. 267, 10184-10192). The identity in the amino acid sequences of these enzymes is 52%. As an initial step to elucidate the stabilization mechanism of the thermophilic RNase H, we examined whether certain regions in its amino acid sequence confer the thermostability. A variety of mutant proteins of E. coli RNase HI were constructed and analyzed for protein stability. In these mutant proteins, amino acid sequences in loops or terminal regions were systematically replaced with the corresponding sequences from T. thermophilus RNase H. Of the nine regions examined, replacement of the amino acid sequence in each of four regions (R4-R7) resulted in an increase in protein stability. Simultaneous replacements of these amino acid sequences revealed that the effect of each replacement on protein stability is independent of each other and cumulative. Replacement of all four regions (R4-R7) gave the most stable mutant protein. The temperature of the midpoint of the transition in the thermal unfolding curve and the free energy change of unfolding in the absence of denaturant of this mutant protein were increased by 16.7 degrees C and 3.66 kcal/mol, respectively, as compared to those of E. coli RNase HI. These results suggest that individual local interactions contribute to the stability of thermophilic proteins in an independent manner, rather than in a cooperative manner.     

Identification of amino acid residues in the catalytic domain of RNase E essential for survival of Escherichia coli: functional analysis of DNase I subdomain

RNase E is an essential Escherichia coli endoribonuclease that plays a major role in the decay and processing of a large fraction of RNAs in the cell. To better understand the molecular mechanisms of RNase E action, we performed a genetic screen for amino acid substitutions in the catalytic domain of the protein (N-Rne) that knock down the ability of RNase E to support survival of E. coli. Comparative phylogenetic analysis of RNase E homologs shows that wild-type residues at these mutated positions are nearly invariably conserved. Cells conditionally expressing these N-Rne mutants in the absence of wild-type RNase E show a decrease in copy number of plasmids regulated by the RNase E substrate RNA I, and accumulation of 5S ribosomal RNA, M1 RNA, and tRNA(Asn) precursors, as has been found in Rne-depleted cells, suggesting that the inability of these mutants to support cellular growth results from loss of ribonucleolytic activity. Purified mutant proteins containing an amino acid substitution in the DNase I subdomain, which is spatially distant from the catalytic site posited from crystallographic studies, showed defective binding to an RNase E substrate, p23 RNA, but still retained RNA cleavage activity-implicating a previously unidentified structural motif in the DNase I subdomain in the binding of RNase E to targeted RNA molecules, demonstrating the role of the DNase I domain in RNase E activity.     

Analysis of the mechanism of the Serratia nuclease using site-directed mutagenesis.

Based on crystal structure analysis of the Serratia nuclease and a sequence alignment of six related nucleases, conserved amino acid residues that are located in proximity to the previously identified catalytic site residue His89 were selected for a mutagenesis study. Five out of 12 amino acid residues analyzed turned out to be of particular importance for the catalytic activity of the enzyme: Arg57, Arg87, His89, Asn119 and Glu127. Their replacement by alanine, for example, resulted in mutant proteins of very low activity, < 1% of the activity of the wild-type enzyme. Steady-state kinetic analysis of the mutant proteins demonstrates that some of these mutants are predominantly affected in their kcat, others in their Km. These results and the determination of the pH and metal ion dependence of selected mutant proteins were used for a tentative assignment for the function of these amino acid residues in the mechanism of phosphodiester bond cleavage by the Serratia nuclease.     

Effects of site-directed mutagenesis of the highly conserved aspartate residues in domain II of farnesyl diphosphate synthase activity.

Comparison of the farnesyl diphosphate (FPP) synthase amino acid sequences from four species with amino acid sequences from the related enzymes hexaprenyl diphosphate synthase and geranylgeranyl diphosphate synthase show the presence of two aspartate rich highly conserved domains. The aspartate motif ((I, L, or V)XDDXXD) of the second of those domains has homology with at least 9 prenyl transfer enzymes that utilize an allylic prenyl diphosphate as one substrate. In order to investigate the role of this second aspartate-rich domain in rat FPP synthase, we mutated the first or third aspartate to glutamate, expressed the wild-type and mutant enzymes in Escherichia coli, and purified them to apparent homogeneity using a single chromatographic step. Approximately 12 mg of homogeneous protein was isolated from 120 mg of crude bacterial extract. The kinetic parameters of the purified wild-type recombinant FPP synthase containing the DDYLD motif were as follows: Vmax = 0.84 mumol/min/mg; GPP Km = 1.0 microM; isopentenyl diphosphate (IPP) Km = 2.7 microM. Substitution of glutamate for the first aspartate (EDYLD) decreased the Vmax by over 90-fold. The Km for IPP increased, whereas the Km for GPP remained the same in this D243E mutant. Substitution of glutamate for the third aspartate (DDYLE) did not result in altered enzyme kinetics in the D247E mutant. These results suggest that the first aspartate in the second domain is involved in the catalysis by FPP synthase.     

Identification of the gene encoding a type 1 RNase H with an N-terminal double-stranded RNA binding domain from a psychrotrophic bacterium

The gene encoding a bacterial type 1 RNase H, termed RBD-RNase HI, was cloned from the psychrotrophic bacterium Shewanella sp. SIB1, overproduced in Escherichia coli, and the recombinant protein was purified and biochemically characterized. SIB1 RBD-RNase HI consists of 262 amino acid residues and shows amino acid sequence identities of 26% to SIB1 RNase HI, 17% to E. coli RNase HI, and 32% to human RNase H1. SIB1 RBD-RNase HI has a double-stranded RNA binding domain (RBD) at the N-terminus, which is commonly present at the N-termini of eukaryotic type 1 RNases H. Gel mobility shift assay indicated that this domain binds to an RNA/DNA hybrid in an isolated form, suggesting that this domain is involved in substrate binding. SIB1 RBD-RNase HI exhibited the enzymatic activity both in vitro and in vivo. Its optimum pH and metal ion requirement were similar to those of SIB1 RNase HI, E. coli RNase HI, and human RNase H1. The specific activity of SIB1 RBD-RNase HI was comparable to that of E. coli RNase HI and was much higher than those of SIB1 RNase HI and human RNase H1. SIB1 RBD-RNase HI showed poor cleavage-site specificity for oligomeric substrates. SIB1 RBD-RNase HI was less stable than E. coli RNase HI but was as stable as human RNase H1. Database searches indicate that several bacteria and archaea contain an RBD-RNase HI. This is the first report on the biochemical characterization of RBD-RNase HI.     

Site-directed mutagenesis of the putative distal helix of peroxygenase cytochrome P450

CYP152A1 is an unusual, peroxygenase enzyme that catalyzes the beta- or alpha-hydroxylation of fatty acids by efficiently introducing an oxygen atom from H2O2 to the fatty acid. To clarify the mechanistic roles of amino acid residues in this enzyme, we have used site-directed mutagenesis of residues in the putative distal helix and measured the spectroscopic and enzymatic properties of the mutant proteins. Initially, we carried out Lys-scanning mutagenesis of amino acids in this region to determine residues of CYP152A1 that might have a mechanistic role. Among the Lys mutants, only P243K gave an absorption spectrum characteristic of a nitrogenous ligand-bound form of a ferric P450. Further investigation of the Pro243 site revealed that a P243H mutant also exhibited a nitrogen-bound form, but that the mutants P243A or P243S did not. On the hydroxylation of myristic acid by the Lys mutants, we observed a large decrease in activity for R242K and A246K. We therefore examined other mutants at amino acid positions 242 and 246. At position 246, an A246K mutant showed a roughly 19-fold lower affinity for myristic acid than the wild type. Replacing Ala246 with Ser decreased the catalytic activity, but did not affect affinity for the substrate. An A246V mutant showed slightly reduced activity and moderately reduced affinity. At position 242, an R242A showed about a fivefold lower affinity than the wild type for myristic acid. The Km values for H2O2 increased and Vmax values decreased in the order of wild type, R242K, and R242A when H2O2 was used; furthermore, Vmax/Km was greatly reduced in R242A compared with the wild type. If cumene hydroperoxide was used instead of H2O2, however, the Km values were not affected much by these substitutions. Together, our results suggest that in CYP152A1 the side chain of Pro243 is located close to the iron at the distal side of a heme molecule; the fatty acid substrate may be positioned near to Ala246 in the catalytic pocket, although Ala246 does not participate in hydrophobic interactions with the substrate; and that Arg242 is a critical residue for substrate binding and H2O2-specific catalysis.     

Site-directed mutagenesis of human aldolase isozymes: the role of Cys-72 and Cys-338 residues of aldolase A and of the carboxy-terminal Tyr residues of aldolases A and B

In order to elucidate the role of particular amino acid residues in the catalytic activity and conformational stability of human aldolases A and B [EC 4.1.2.13], the cDNAs encoding these isoenzyme were modified using oligonucleotide-directed, site-specific mutagenesis. The Cys-72 and/or Cys-338 of aldolase A were replaced by Ala and the COOH-terminal Tyr of aldolases A and B was replaced by Ser. The three mutant aldolases A thus prepared, A-C72A, A-C338A, and A-C72,338A, were indistinguishable from the wild-type enzyme with respect to general catalytic properties, while the replacement of Tyr-363 by Ser in aldolase A (A-Y363S) resulted in decreases of the Vmax of the fructose-1, 6-bisphosphate (FDP) cleavage reaction, activity ratio of FDP/fructose-1-phosphate (F1P), and the Km values for FDP and F1P. The wild-type and all the mutant aldolase A proteins exhibited similar thermal stabilities. In contrast, the mutant aldolase A proteins were more stable than the wild-type enzyme against tryptic and alpha-chymotryptic digestions. Based upon these results it is concluded that the strictly conserved Tyr-363 of human aldolase A is required for the catalytic function with FDP as the substrate, while neither Cys-72 nor Cys-338 directly takes part in the catalytic function although the two Cys residues may be involved in maintaining the correct spatial conformation of aldolase A. Replacement of Tyr-363 by Ser in human aldolase B lowered the Km value for FDP appreciably and also diminished the stability against elevated temperatures and tryptic digestion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Analysis of the DXD motifs in human xylosyltransferase I required for enzyme activity

Human xylosyltransferase I (XT-I) is the initial enzyme involved in the biosynthesis of the glycosaminoglycan linker region in proteoglycans. Here, we tested the importance of the DXD motifs at positions 314-316 and 745-747 for enzyme activity and the nucleotide binding capacity of human XT-I. Mutations of the 314DED316 motif did not have any effect on enzyme activity, whereas alterations of the 745DWD747 motif resulted in reduced XT-I activity. Loss of function was observed after exchange of the highly conserved aspartic acid at position 745 with glycine. However, mutation of Asp745 to glutamic acid retained full enzyme activity, indicating the importance of an acidic amino acid at this position. Reduced substrate affinity was observed for mutants D747G (Km=6.9 microm) and D747E (Km=4.4 microm) in comparison with the wild-type enzyme (Km=0.9 microm). Changing the central tryptophan to a neutral, basic, or acidic amino acid resulted in a 6-fold lower Vmax, with Km values comparable with those of the wild-type enzyme. Despite the major effect of the DWD motif on XT-I activity, nucleotide binding was not abolished in the D745G and D747G mutants, as revealed by UDP-bead binding assays. Ki values for inhibition by UDP were determined to be 1.9-24.6 microm for the XT-I mutants. The properties of binding of XT-I to heparin-beads, the Ki constants for noncompetitive inhibition by heparin, and the activation by protamine were not altered by the generated mutations.     

A Corynebacterium glutamicum rnhA recG Double Mutant Showing Lysozyme- sensitivity,Temperature-sensitive Growth,and UV-Sensitivity

Corynebacterium glutamicum mutant KY9707 was originally isolated for lysozyme-sensitivity, and showed temperature-sensitive growth. Two DNA fragments from a wild-type C. glutamicum chromosomal library suppressed the temperature-sensitivity of KY9707. These clones also rescued the lysozyme-sensitivity of KY9707, although partially. One of them encodes a protein of 382 amino acid residues, the N-terminal domain of which was homologous to RNase HI. This gene suppressed the temperature-sensitive growth of an Escherichia coli rnhA rnhB double mutant. We concluded that this gene encodes a functional RNase HI of C. glutamicum and designated it as rnhA. The other gene encodes a protein of 707 amino acid residues highly homologous to RecG protein. The C. glutamicum recG gene complemented the UV-sensitivity of E. coli recG258::kan mutant. KY9707 showed increased UV-sensitivity, which was partially rescued by either the recG or rnhA gene of C. gluamicum. Point mutations were found in both recG and rnhA genes in KY9707. These suggest that temperature-sensitive growth, UV-sensitivity, and probably lysozyme-sensitivity also, of KY9707 were caused by mutations in the genes encoding RNase HI and RecG.     

Identification of the catalytically important histidine of 3-hydroxy-3-methylglutaryl-coenzyme A reductase.

We identify His381 of Pseudomonas mevalonii 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) reductase as the basic residue functional in catalysis. The catalytic domain of 20 HMG-CoA reductases contains a single conserved histidine (His381 of the P. mevalonii enzyme). Diethyl pyrocarbonate inactivated the P. mevalonii enzyme, and hydroxylamine partially restored activity. We changed His381 to alanine, lysine, asparagine, and glutamine. The mutant proteins were overexpressed, purified to homogeneity, and characterized. His381 mutant enzymes were not inactivated by diethyl pyrocarbonate. All four mutant enzymes exhibited wild-type crystal morphology and chromatographed on substrate affinity supports like wild-type enzyme. The mutant enzymes had low catalytic activity (Vmax 0.06-0.5% that of wild-type enzyme), but Km values approximated those for wild-type enzyme. For wild-type enzyme and mutant enzymes H381A, H381N, and H381Q, Km values at pH 8.1 were 0.45, 0.27, 3.7, and 0.71 mM [(R,S)-mevalonate]; 0.05, 0.03, 0.20, and 0.11 mM [coenzyme A]; 0.22, 0.14, 0.81, and 0.62 mM [NAD+]. Km values at pH 11 for wild-type enzyme and mutant enzyme H381K were 0.32 and 0.75 mM [(R,S)-mevalonate]; 0.24 and 0.50 mM [coenzyme A]; 0.15 and 1.23 mM [NAD+]. Both pK values for the enzyme-substrate complex increased relative to wild-type enzyme (by 1-2.5 pH units for pK1 and by 0.5-1.3 pH units for pK2). For mutant enzyme H381K, the pK1 of 10.2 is consistent with lysine acting as a general base at high pH. His381 of P. mevalonii HMG-CoA reductase, and consequently the histidine of the consensus Leu-Val-Lys-Ser-His-Met-Xaa-Xaa-Asn-Arg-Ser motif of the catalytic domain of eukaryotic HMG-CoA reductases, thus is the general base functional in catalysis.     

Identification of iron ligands in tyrosine hydroxylase by mutagenesis of conserved histidinyl residues.

Tyrosine hydroxylase catalyzes the hydroxylation of tyrosine and other aromatic amino acids using a tetrahydropterin as the reducing substrate. The enzyme is a homotetramer; each monomer contains a single nonheme iron atom. Five histidine residues are conserved in all tyrosine hydroxylases that have been sequenced to date and in the related eukaryotic enzymes phenylalanine and tryptophan hydroxylase. Because histidine has been suggested as a ligand to the iron in these enzymes, mutant tyrosine hydroxylase proteins in which each of the conserved histidines had been mutated to glutamine or alanine were expressed in Escherichia coli. The H192Q, H247Q, and H317A mutant proteins contained iron in comparable amounts to the wild-type enzyme, about 0.6 atoms/sub-unit. In contrast, the H331 and H336 mutant proteins contained no iron. The first three mutant enzymes were active, with Vmax values 39, 68, and 7% that of the wild-type enzyme, and slightly altered V/Km values for both tyrosine and 6-methyltetrahydropterin. In contrast, the H331 and H336 mutant enzymes had no detectable activity. The EPR spectra of the H192Q and H247Q enzymes are indistinguishable from that of wild-type tyrosine hydroxylase, whereas that of the H317A enzyme indicated that the ligand field of the iron had been slightly perturbed. These results are consistent with H331 and H336 being ligands to the active site iron atom.     

Protein thermostabilization requires a fine-tuned placement of surface-charged residues

Using the information from the genome projects, recent comparative studies of thermostable proteins have revealed a certain trend of amino acid composition in which polar residues are scarce and charged residues are rich on the protein surface. To clarify experimentally the effect of the amino acid composition of surface residues on the thermostability of Escherichia coli Ribonuclease HI (RNase HI), we constructed six variants in which five to eleven polar residues were replaced by charged residues (5C, 7Ca, 7Cb, 9Ca, 9Cb and 11C). The thermal denaturation experiments indicated that all of the variant proteins are 3.2-10.1 degrees C in Tm less stable than the wild proteins. The crystal structures of resultant protein variants 7Ca, 7Cb, 9Ca and 11C closely resemble that of E. coli RNase HI in their global fold, and several different hydrogen bonding and ion-pair interactions are formed by the mutations. Comparison of the crystal structures of these variant proteins with that of E. coli RNase HI reveals that thermal destabilization is apparently related to electrostatic repulsion of the charged residues with neighbours. This result suggests that charged residues of natural thermostable proteins are strictly posted on the surface with optimal interactions and without repulsive interactions.