The interaction between residues 62 and 193 play a key role in activity and structural stability of arginine kinase

The purpose of this study is to clarify that the amino acid residues (Asp62 and Arg193) are responsible for the activity and stability of arginine kinase (AK). The amino acid residues Asp62 (D62) and Arg193 (R193) are strictly conserved in monomeric AKs and form an ion pair in the transition state analogue complex. In this research, we replaced D62 with glutamate (E) or glycine (G) and R193 with lysine (K) or glycine (G). The mutants of D62E and R193K retained almost 90% of the wild-type activity, whereas D62G and R193G had a pronounced loss in activity. A detailed comparison was made between the physic-chemical properties and conformational changes of wild-type AK and the mutants by means of ultraviolet (UV) difference and fluorescence spectra. The results indicated that the conformation of all of the mutants had been changed and the stability in a urea solution was also reduced. We speculated that the hydrogen bond and electrostatic interactions formed between residues 62 and 193 play a key role in stabilizing the structure and mediating the synergism in substrate binding of arginine kinase from greasyback shrimp (Metapenaeus ensis).     

Evidence that amino-acid residues are responsible for substrate synergism of locust arginine kinase

A series of mutants were constructed to investigate the amino-acid residues responsible for the synergism in substrate binding of arginine kinase (AK). AK contains a pair of highly conserved amino acids (Y75 and P272) that form a hydrogen bond. In the locust (Locusta migratoria manilensis) AK, mutants in two highly conserved sites can cause pronounced loss of activity, conformational changes and distinct substrate synergism alteration. The Y75F and Y75D mutants showed strong synergism (Kd/Km=6.2-13.4), while in single mutants, P272G and P272R, and a double mutant, Y75F/P272G, the synergism was almost completely lost (Kd/Km=1.1-1.4). Another double mutant, Y75D/P272R, had characteristics similar to those of the wild-type enzyme. All these results suggest that the amino-acid residues 75 and 272 play an important role in regulating the synergism in substrate binding of AK. Fluorescence spectra showed that all mutants except Y75D/P272R displayed a red shift to different degrees. All the results provided direct evidence that there is a subtle relationship between the synergism in substrate binding and the conformational change.     

Role of Amino Acid Residues on the GS Region of Stichopus Arginine Kinase and Danio Creatine Kinase

Stichopus arginine kinase (AK) is a unique enzyme in that it evolved not from the AK gene but from the creatine kinase (CK) gene: the entire amino acid sequence is homologous with other CKs apart from the guanidine specificity region (GS region), which is identical in structure to that of AK. Ten independent mutations were introduced around the GS region in Stichopus AK. When an insertion or deletion was introduced near the GS region, the Vmax of the mutant enzyme was dramatically decreased to less than 0.1% of the wild type, suggesting that the length of the GS region is crucial for the recognition of the guanidine substrate. Replacement of Phe63 and Leu65 to Gly in the Stichopus enzyme caused a remarkable increase in the Kmarg. This indicates that Phe63 and Leu65 are associated with the arginine substrate-binding affinity. The hydrogen bond formed between the Asp62 and Arg193 residues is thought to play a key role in stabilizing the closed substrate-bound structure of AK. Mutants that eliminated this hydrogen bond had a considerably decreased Vmax, accompanied by a threefold increase in Kmarg. It is noted that the value of the Kmarg of the mutants became very close to the Kdarg value of the wild type. Six independent mutations were introduced in the GS region of Danio M-CK. Almost equivalent values of Kmcr and Kdcr in all of the mutants indicated that a typical synergism was completely lost. The results suggested that the Ile69 to Gly mutant, displaying a high Kmcr and a low Vmax, plays an important role in creatine-binding. This is consistent with the observation that in the structure of Torpedo CK, Ile69 provides a hydrophobic pocket to optimize creatine-binding.     

Two-domain arginine kinase from the deep-sea clam Calyptogena kaikoi--evidence of two active domains

The cDNA and deduced amino acid sequences for arginine kinase (AK) from the deep-sea clam Calyptogena kaikoi have been determined revealing an unusual two-domain (2D) structure with molecular mass of 80 kDa, twice that of normal AK. The amino acid sequences of both domains contain most of the residues thought to be required for substrate binding found in the horseshoe crab Limulus polyphemus AK, a well studied system for which several X-ray crystal structures exist. However, two highly conserved residues, D62 and R193, that form a salt bridge thereby stabilizing the substrate-bound structure have been replaced by G and N in domain 1, and G and P in domain 2, respectively. The present effort probes whether both domains of Calyptogena AK are catalytically competent. Recombinant constructs of the wild-type enzyme of both single domains, and of selected mutants of the Calyptogena AK have been expressed as fusion proteins with the maltose-binding protein. The wild-type two-domain enzyme (2D[WT]) had high AK activity (k(cat)=23 s(- 1), average value of the two domains), and the single domain 2 (D2[WT]) showed 1.5-times higher activity (k(cat)=38 s(- 1)) than the wild-type 2D[WT]. Interestingly, the single domain 1 (D1[WT]) showed only a very low activity (k(cat) approximately 0.016 s(- 1)). Introduction of a Y68A mutation in both domains virtually abolished catalytic activity. On the other hand, significant residual activity was observed (k(cat)=2.8 s(- 1)), when the Y68A mutation was introduced only into domain 2 of the two-domain enzyme. A similar mutation in domain 1 of the two-domain enzyme reduced activity to a much lower extent (k(cat)=11.1 s(- 1)). Although the domains of this "contiguous" dimeric AK each have catalytic capabilities, the presence of domain 2 strongly influences the stability and activity of domain 1.     

Kinetic properties and structural characteristics of an unusual two-domain arginine kinase of the clam Corbicula japonica

Arginine kinase (AK) from the clam Corbicula japonica is a unique enzyme in that it has an unusual two-domain structure with molecular mass of 80 kDa. It lacks two functionally important amino acid residues, Asp-62 and Arg-193, which are conserved in other 40 kDa AKs and are assumed to be key residues for stabilizing the substrate-bound structure. K m arg and Vmax values for the recombinant two-domain AK were determined. These values were close to those of usual 40 kDa AKs, although Corbicula AK lacks the functionally important Asp-62 and Arg-193. Domain 2 of Corbicula AK was separated from the two-domain enzyme and was expressed in Escherichia coli. Domain 2 still exhibited activity. However, kinetic parameters for domain 2 appeared to be slightly, but significantly, different from those of two-domain AK. Thus, it is likely that the formation of the contiguous dimer alters the kinetic properties of its constituent domains significantly. Comparison of K d arg and K m arg for two-domain AK and its domain 2 showed that the affinity of the enzyme for arginine is greater in the presence of substrate ATP than in its absence. Presumably this difference is correlated with the large structural differences in the enzyme in the presence or absence of substrate, namely open and closed structures. We expressed three mutants of Corbicula AK domain 2 (His-60 to Gly or Arg, Asp-197 to Gly), and determined their K m arg and Vmax values. The affinity for the substrate arginine in mutant enzymes was reduced considerably, accompanied by a decrease in Vmax. These results suggest that His-60 and Asp-197 affect the substrate binding system, and are consistent with the hypothesis that a hydrogen bond is formed between His-60 and Asp-197 in Corbicula AK as a substitute for the Asp-62 and Arg-193 bond in normal AKs.     

Two-domain arginine kinases from the clams Solen strictus and Corbicula japonica: exceptional amino acid replacement of the functionally important D(62) by G

Arginine kinases (AKs) isolated from the adductor muscle of the clams Solen strictus and Corbicula japonica have relative molecular masses of 80 kDa as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) in contrast to the 40 kDa AKs found in Mollusca and Arthropoda. The cDNAs encoding Solen and Corbicula AKs have open reading frames of 2175 nucleotides (724 amino acid protein) and 2172 nucleotides (723 amino acid protein), respectively. The amino acid sequence clearly indicates that Solen and Corbicula AKs have a two-domain structure: the first-domain includes residues 1-363 and the second-domain includes residue 364 to the end. There is approximately 60% inter-domain amino acid identity. It is clear that gene-duplication and subsequent fusion occurred in the immediate ancestor of the clams Solen, Corbicula, and Pseudocardium. During substrate binding, it is proposed that AK undergoes a substrate-induced conformational change and that the hydrogen bond between D(62) and R(193) stabilizes the substrate-bound structure. However, in Solen and Corbicula two-domain AKs, D(62) is replaced by a G, and R(193) by A, S, or D. Consequently, the two-domain AKs can not form the stabilizing hydrogen bond. Nevertheless, the enzyme activity of Corbicula AK is comparable to those of other molluscan 40 kDa AKs. We assumed that the substrate-bound structure of the two-domain AK is stabilized not by the hydrogen bond between D(62) and R(193) but by the bond between H(60) and D(197), characteristic of the unusual two-domain AKs. This explains why D(62) and R(193), which remain highly conserved in other AKs, have undergone amino acid replacements in Solen and Corbicula AKs.     

Role of amino-acid residue 95 in substrate specificity of phosphagen kinases

The purpose of this study is to elucidate the mechanisms of guanidine substrate specificity in phosphagen kinases, including creatine kinase (CK), glycocyamine kinase (GK), lombricine kinase (LK), taurocyamine kinase (TK) and arginine kinase (AK). Among these enzymes, LK is unique in that it shows considerable enzyme activity for taurocyamine in addition to its original target substrate, lombricine. We earlier proposed several candidate amino acids associated with guanidine substrate recognition. Here, we focus on amino-acid residue 95, which is strictly conserved in phosphagen kinases: Arg in CK, Ile in GK, Lys in LK and Tyr in AK. This residue is not directly associated with substrate binding in CK and AK crystal structures, but it is located close to the binding site of the guanidine substrate. We replaced amino acid 95 Lys in LK isolated from earthworm Eisenia foetida with two amino acids, Arg or Tyr, expressed the modified enzymes in Escherichia coli as a fusion protein with maltose-binding protein, and determined the kinetic parameters. The K95R mutant enzyme showed a stronger affinity for both lombricine (Km=0.74 mM and kcat/Km=19.34 s(-1) mM(-1)) and taurocyamine (Km=2.67 and kcat/Km=2.81), compared with those of the wild-type enzyme (Km=5.33 and kcat/Km=3.37 for lombricine, and Km=15.31 and kcat/ Km=0.48for taurocyamine). Enzyme activity of the other mutant, K95Y, was dramatically altered. The affinity for taurocyamine (Km=1.93 and kcat/Km=6.41) was enhanced remarkably and that for lombricine (Km=14.2 and kcat/Km=0.72) was largely decreased, indicating that this mutant functions as a taurocyamine kinase. This mutant also had a lower but significant enzyme activity for the substrate arginine (Km=33.28 and kcat/Km=0.01). These results suggest that Eisenia LK is an inherently flexible enzyme and that substrate specificity is strongly controlled by the amino-acid residue at position 95.     

Elucidation of active site residues of Arabidopsis thaliana flavonol synthase provides a molecular platform for engineering flavonols

Arabidopsis thaliana flavonol synthase (aFLS) catalyzes the production of quercetin, which is known to possess multiple medicinal properties. aFLS is classified as a 2-oxoglutarate dependent dioxygenase as it requires ferrous iron and 2-oxoglutarate for catalysis. In this study, the putative residues for binding ferrous iron (H221, D223 and H277), 2-oxoglutarate (R287 and S289) and dihydroquercetin (H132, F134, K202, F293 and E295) were identified via computational analyses. To verify the proposed roles of the identified residues, 15 aFLS mutants were constructed and their activities were examined via a spectroscopic assay designed in this study. Mutations at H221, D223, H277 and R287 completely abolished enzymes activities, supporting their importance in binding ferrous iron and 2-oxoglutarate. However, mutations at the proposed substrate binding residues affected the enzyme catalysis differently such that the activities of K202 and F293 mutants drastically decreased to approximately 10% of the wild-type whereas the H132F mutant exhibited approximately 20% higher activity than the wild-type. Kinetic analyses established an improved substrate binding affinity in H132F mutant (Km: 0.027+/-0.0028 mM) compared to wild-type (Km: 0.059+/-0.0063 mM). These observations support the notion that aFLS can be selectively mutated to improve the catalytic activity of the enzyme for quercetin production.     

The study of the bacteriophage T5 deoxynucleoside monophosphate kinase active site by site-directed mutagenesis

The amino acid residues essential for the enzymatic activity of bacteriophage T5 deoxyribonucleoside monophosphate kinase were determined using a computer model of the enzyme active site. By site-directed mutagenesis, cloning, and gene expression in E. coli, a series of proteins were obtained with single substitutions of the conserved active site amino acid residues—S13A, D16N, T17N, T17S, R130K, K131E, Q134A, G137A, T138A, W150F, W150A, D170N, R172I, and E176Q. After purification by ion exchange and affine chromatography electrophoretically homogeneous preparations were obtained. The study of the enzymatic activity with natural acceptors of the phosphoryl group (dAMP, dCMP, dGMP, and dTMP) demonstrated that the substitutions of charged amino acid residues of the NMP binding domain (R130, R172, D170, and E176) caused nearly complete loss of enzymatic properties. It was found that the presence of the OH-group at position 17 was also important for the catalytic activity. On the basis of the analysis of specific activity variations we assumed that arginine residues at positions 130 and 172 were involved in the binding to the donor γ-phosphoryl and acceptor α-phosphoryl groups, as well as the aspartic acid residue at position 16 of the ATP-binding site (P-loop), in the binding to some acceptors, first of all dTMP. Disproportional changes in enzymatic activities of partially active mutants, G137A, T138A, T17N, Q134A, S13A, and D16N, toward different substrates may indicate that different amino acid residues participate in the binding to various substrates.     

Cooperativity in the two-domain arginine kinase from the sea anemone Anthopleura japonicus

cDNAs of the two-domain arginine kinase (AK) (contiguous dimer; denoted by 2D/WT) and its separated domains 1 and 2 (denoted by D1/WT and D2/WT) from the sea anemone Anthopleura japonicus, were cloned into the plasmid pMAL, and recombinant enzymes were expressed in E. coli as MBP fusion proteins. The kinetic parameters kcat, Ka and Kia, were determined for all three AKs. All three enzymes showed distinct AK activity, and had high affinity for arginine (Ka Arg=0.25-0.48 mM). The catalytic efficiency, calculated by kcat/Ka ArgKia ATP, of the 2D/WT enzyme (182 mM(-2)s(-1), the value for one active 40 kDa domain) was two- to three-times higher than values for either D1/WT or D2/WT (80.2 and 86.4mM(-2)s(-1), respectively), suggesting the presence of domain-domain interactions (cooperativity) in the contiguous dimer. The Kia/Ka values of the three enzymes ranged from 0.88 to 1.32, indicating that there is no strong synergism in substrate binding, as seen in typical AKs. Asp62 and Arg193, which are conserved in most AKs and play a key role in stabilizing the substrate-bound structure, are also conserved in the two domains of Anthopleura AK. We replaced Asp62 in D2/WT with Glu or Gly. The catalytic efficiency and Kia/Ka for the D62E mutant were comparable to those of D2/WT, but catalytic efficiency for the D62G mutant was decreased to 13% of that of the D2/WT with a significantly increased value of Kia/Ka (1.92), indicating that Asp62 plays an important role in the expression of AK activity.     

NMR analysis of site-specific mutants of yeast phosphoglycerate kinase. An investigation of the triose-binding site

Site-specific mutants of yeast phosphoglycerate kinase have been produced in order to investigate the roles of the 'basic-patch' residues, arginine 168 and histidine 170. The fully-conserved residue, arginine 168, has been replaced with a lysine (R168K) and a methionine (R168M) residue, while the non-conserved histidine 170 has been replaced with an aspartate (H170D). Comparison of the 500-MHz 1H-NMR spectra of the mutant proteins with that of wild-type phosphoglycerate kinase shows that the overall fold of the mutants remains essentially unaltered from that of the native enzyme. Results of NOE experiments indicate that there are only very minor changes in structure in the vicinity of the mutations. These mutations have also led to firm sequence-specific resonance assignments to histidines 62, 167 and 170. NMR studies of 3-phosphoglycerate binding show that decreasing the positive charge in the sequence 168-170 reduces the binding of this substrate (by about 15-fold and 4-fold for mutants R168M and H170D respectively). Mutant R168K binds 3-phosphoglycerate with an affinity about twofold less than that of the native enzyme. Significantly, the activity of mutant H170D, measured at saturating substrate concentrations, is unchanged from that of the wild-type enzyme. This indicates that this residue is not of major importance in the binding or reaction of 3-phosphoglycerate. The observation is in agreement with results obtained for the wild-type enzyme, which indicate that 3-phosphoglycerate interacts most strongly with histidine 62 and least strongly with histidine 170, as would be predicted from the X-ray crystal structure. Substitution of positively charged arginine 168 with neutral methionine (or positively charged lysine) does not cause a detectable change in the pKa values of the neighbouring histidine groups, in as much as they remain below 3. The results reported here indicate that the observed reduction in catalytic efficiency relates less to direct electrostatic effects than to the mutants' inability to undergo 3-phosphoglycerate-induced conformational changes.     

The role of Arg-96 in Danio rerio creatine kinase in substrate recognition and active center configuration

In creatine kinases (CKs), the amino acid residue-96 is a strictly conserved arginine. This residue is not directly associated with substrate binding, but it is located close to the binding site of the substrate creatine. On the other hand, the residue-96 is known to be involved in expression in the substrate specificity of various other phosphagen (guanidino) kinases, since each enzyme has a specific residue at this position: arginine kinase (Tyr), glycocyamine kinase (Ile), taurocyamine kinase (His) and lombricine kinase (Lys). To gain a greater understanding of the role of residue-96 in CKs, we replaced this residue in zebra fish Danio rerio cytoplasmic CK with other 19 amino acids, and expressed these constructs in Escherichia coli. All the twenty recombinant enzymes, including the wild-type, were obtained as soluble form, and their activities were determined in the forward direction. Compared with the activity of wild-type, the R96K mutant showed significant activity (8.3% to the wild-type), but 10 mutants (R96Y, A, S, E, H, T, F, C, V and N) showed a weak activity (0.056–1.0%). In the remaining mutants (R96Q, G, M, P, L, W, D and I), the activity was less than 0.05%. Our mutagenesis studies indicated that Arg-96 in Danio CK can be substituted for partially by Lys, but other replacements caused remarkable loss of activity. From careful inspection of the crystal structures (transition state analog complex (TSAC) and open state) of Torpedo cytoplasmic CK, we found that the side chain of R96 forms hydrogen bonds with A339 and D340 only in the TSAC structure. Based on the assumption that CKs consist of four dynamic domains (domains 1–3, and fixed domain), the above hydrogen bonds act to link putative domains 1 and 3 in TSAC structure. We suggest that residue-96 in CK and equivalent residues in other phosphagen kinases, which are structurally similar, have dual roles: (1) one involves in distinguishing guanidino substrates, and (2) the other plays a key role in organizing the hydrogen-bond network around residue-96 which offers an appropriate active center for the high catalytic turnover. The mode of development of the network appears to be unique each phosphagen kinase, reflecting evolution of each enzyme.     

Mutagenesis of lysine 62, asparagine 64, and conserved region 1 reduces the activity of human ecto-ATPase (NTPDase 2)

The human ecto-ATPase (NTPDase 2) contains conserved motifs including five apyrase conserved regions (ACRs) and four conserved regions (CRs) as well as conserved lysine and arginine residues that are also present in other cell surface E-NTPDases. Some of the positively charged amino acids may be involved in ATP binding. The protein also contains six potential N-linked glycosylation sites. Results obtained with seven lysine and six arginine mutants indicate the importance of K62 that is located in CR1, K182, which is downstream of ACR3, and R155, which immediately follows CR3. Mutation of asparagine at the six potential N-linked glycosylation sites individually to glutamine established the importance of N64 in CR1 and N443 in ACR5 in protein function and expression. Mutation of N64, which is conserved in all cell surface NTPDases, results in the expression of an unstable protein, the activity of which is only manifested in the presence of concanavalin A. Both K62 and N64 reside in CR1 that is conserved in all cell surface NTPDases. In the sequence of the CR1 of human ecto-ATPase, 58WPADKENDTGIV69, 65DTG67 is similar to the phosphate-binding motif (DXG) in ACR1 and 4. The D65A and G67A mutants have reduced protein expression and activity. Mutations of other residues in CR1 to alanine led to partial to complete loss of protein expression and activity except for P59. The alanine mutants of the three acidic amino acid residues, D61, E63, and D65, all have decreased affinity for divalent ions. D61 can be substituted by glutamate, but E63 appears to be invariable. Taken together, these results indicate that CR1, which follows ACR1 in the cell surface NTPDases, is an essential structural element in these enzymes.     

Modification of SR-PSOX functions by multi-point mutations of basic amino acid residues

SR-PSOX can function as a scavenger receptor, a chemokine and an adhesion molecule, and it could be an interesting player in the formation of atherosclerotic lesions. Our previous studies demonstrated that basic amino acid residues in the chemokine domain of SR-PSOX are critical for its functions. In this study the combinations of the key basic amino acids in the chemokine domain of SR-PSOX have been identified. Five combinations of basic amino acid residues that may form conformational motif for SR-PSOX functions were selected for multi-point mutants. The double mutants of K61AR62A, R76AK79A, R82AH85A, and treble mutants of R76AR78AK79A, R78AR82AH85A were successfully constructed by replacing the combinations of two or three basic amino acid residues with alanine. After successful expression of these mutants on the cells, the functional studies showed that the cells expressing R76AK79A and R82AH85A mutants significantly increased the activity of oxLDL uptake compared with that of wild-type SR-PSOX. Meanwhile, the cells expressing R76AK79A mutant also dramatically enhanced the phagocytotic activity of SR-PSOX. However, the cells expressing the construct of combination of R78A mutation in R76AK79A or R82AH85A could abolish these effects. More interestingly, the adhesive activities were remarkably down regulated in the cells expressing the multi-point mutants respectively. This study revealed that some conformational motifs of basic amino acid residues, especially R76 with K79 in SR-PSOX, may form a common functional motif for its critical functions. R78 in SR-PSOX has the potential action to stabilize the function of oxLDL uptake and bacterial phagocytosis. The results obtained may provide new insight for the development of drug target of atherosclerosis.     

Identification of arginine residues important for the activity of Escherichia coli signal peptidase I

Escherichia coil signal peptidase I (leader peptidase, SPase I) is an integral membrane serine protease that catalyzes the cleavage of signal (leader) peptides from pre-forms of membrane or secretory proteins. We previously demonstrated that E. coil SPase I was significantly inactivated by reaction with phenylglyoxal with concomitant modification of three to four of the total 17 arginine residues in the enzyme. This result indicated that several arginine residues are important for the optimal activity of the enzyme. In the present study, we have constructed 17 mutants of the enzyme by site-directed mutagenesis to investigate the role of individual arginine residues in the enzyme. Mutation of Arg127, Arg146, Arg198, Arg199, Arg226, Arg236, Arg275, Arg282, and Arg295 scarcely affected the enzyme activity in vivo and in vitro. However, the enzymatic activity toward a synthetic substrate was significantly decreased by replacements of Arg77, Arg222, Arg315, or Arg318 with alanine/lysine. The kcat values of the R77A, R77K, R222A, R222K, R315A, R318A, and R318K mutant enzymes were about 5.5-fold smaller than that of the wild-type enzyme, whereas the Km values of these mutant enzymes were almost identical with that of the wild-type. Moreover, the complementing abilities in E. Arg222, Arg315, coil IT41 were lost completely when Arg77, or Arg318 was replaced with alanine/lysine. The circular dichroism spectra and other enzymatic properties of these mutants were comparable to those of the wild-type enzyme, indicating no global conformational changes. However, the thermostability of R222A, R222K, R315A, and R318K was significantly lower compared to the wild type. Therefore, Arg77, Arg222, Arg315, and Arg318 are thought to be important for maintaining the proper and stable conformation of SPase I.     

"Catch 222," the effects of symmetry on ligand binding and catalysis in R67 dihydrofolate reductase as determined by mutations at Tyr-69

R67 dihydrofolate reductase (R67 DHFR) catalyzes the transfer of a hydride ion from NADPH to dihydrofolate, generating tetrahydrofolate. The homotetrameric enzyme provides a unique environment for catalysis as both ligands bind within a single active site pore possessing 222 symmetry. Mutation of one active site residue results in concurrent mutation of three additional symmetry-related residues, causing large effects on binding of both ligands as well as catalysis. For example, mutation of symmetry-related tyrosine 69 residues to phenylalanine (Y69F), results in large increases in Km values for both ligands and a 2-fold rise in the kcat value for the reaction (Strader, M. B., Smiley, R. D., Stinnett, L. G., VerBerkmoes, N. C., and Howell, E. E. (2001) Biochemistry 40, 11344-11352). To understand the interactions between specific Tyr-69 residues and each ligand, asymmetric Y69F mutants were generated that contain one to four Y69F mutations. A general trend observed from isothermal titration calorimetry and steady-state kinetic studies of these asymmetric mutants is that increasing the number of Y69F mutations results in an increase in the Kd and Km values. In addition, a comparison of steady-state kinetic values suggests that two Tyr-69 residues in one half of the active site pore are necessary for NADPH to exhibit a wild-type Km value. A tyrosine 69 to leucine mutant was also generated to approach the type(s) of interaction(s) occurring between Tyr-69 residues and the ligands. These studies suggest that the hydroxyl group of Tyr-69 is important for interactions with NADPH, whereas both the hydroxyl group and hydrophobic ring atoms of the Tyr-69 residues are necessary for proper interactions with dihydrofolate.     

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.     

Lysine-21 of Leuconostoc mesenteroides glucose 6-phosphate dehydrogenase participates in substrate binding through charge-charge interaction.

Leuconostoc mesenteroides glucose 6-phosphate dehydrogenase (G6PD) was isolated in high yield and purified to homogeneity from a newly constructed strain of Escherichia coli which lacks its own glucose 6-phosphate dehydrogenase gene. Lys-21 is one of two lysyl residues in the enzyme previously modified by the affinity labels pyridoxal 5'-phosphate and pyridoxal 5'-diphosphate-5'-adenosine, which are competitive inhibitors of the enzyme with respect to glucose 6-phosphate (LaDine, J.R., Carlow, D., Lee, W.T., Cross, R.L., Flynn, T.G., & Levy, H.R., 1991, J. Biol. Chem. 266, 5558-5562). K21R and K21Q mutants of the enzyme were purified to homogeneity and characterized kinetically to determine the function of Lys-21. Both mutant enzymes showed increased Km-values for glucose 6-phosphate compared to wild-type enzyme: 1.4-fold (NAD-linked reaction) and 2.1-fold (NADP-linked reaction) for the K21R enzyme, and 36-fold (NAD-linked reaction) and 53-fold (NADP-linked reaction) for the K21Q enzyme. The Km for NADP+ was unchanged in both mutant enzymes. The Km for NAD+ was increased 1.5- and 3.2-fold, compared to the wild-type enzyme, in the K21R and K21Q enzymes, respectively. For the K21R enzyme the kcat for the NAD- and NADP-linked reactions was unchanged. The kcat for the K21Q enzyme was increased in the NAD-linked reaction by 26% and decreased by 30% in the NADP-linked reaction from the values for the wild-type enzyme. The data are consistent with Lys-21 participating in the binding of the phosphate group of the substrate to the enzyme via charge-charge interaction.     

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.