Key residues of loop 3 in the interaction with the interface residue at position 14 in triosephosphate isomerase from Trypanosoma brucei

Cysteine 14 is an interface residue that is fundamental for the catalysis and stability of homodimeric triosephosphate isomerase from Trypanosoma brucei (TbTIM). Its side chain is surrounded by a deep pocket of 11 residues that are part of loop 3 of the adjacent monomer. Mutation of this residue to serine (producing single mutant C14S) yields a wild-type-like enzyme that is resistant to the action of sulfhydryl reagents methylmethane thiosulfonate (MMTS) and 5,5-dithiobis(2-nitrobenzoate) (DTNB). This mutant enzyme was a starting point for probing by cysteine scanning the role of four residues of loop 3 in the catalysis and stability of the enzyme. Considering that the conservative substitution of either serine or alanine with cysteine would minimally alter the structure and properties of the environment of the residue in position 14, we made double mutants C14S/A69C, C14S/S71C, C14S/A73C, and C14S/S79C. Three of these double mutants were similar in their kinetic parameters to wild-type TbTIM and the single mutant C14S, but double mutant C14S/A73C showed a greatly reduced k cat. All enzymes had similar CD spectra, but all mutants had thermal stabilities lower than that of wild-type TbTIM. Intrinsic fluorescence was also similar for all enzymes, but the double mutants bound up to 50 times more 1-anilino-8-naphthalene sulfonate (ANS) and were susceptible to digestion with subtilisin. The double mutants were also susceptible to inactivation by sulfhydryl reagents. Double mutant C14S/S79C exhibited the highest sensitivity to MMTS and DTNB, bound a significant amount of ANS, and had the highest sensitivity to subtilisin. Thus, the residues at positions 73 and 79 are critical for the catalysis and stability of TbTIM, respectively.     

Elucidation of information encoded in tryptophan 140 of staphylococcal nuclease

We investigated the role of W140 in the folding of Staphylococcal nuclease. For this purpose, we constructed the 19 possible substitution mutations at residue 140. Only three mutants, W140F, W140H, and W140Y, adopted native-like structures under physiological conditions and showed native-like enzymatic activities. In contrast, the other 16 mutants took on compact unfolded structures under physiological conditions and the enzymatic activities of these mutants were decreased to approximately 70% of wild-type levels. These 16 mutants maintained substrate-induced foldability. These results strongly indicate that the side-chain information encoded by residue 140 is essential to maintain a stable native structure, and that this residue must be an aromatic side chain. The order of thermal stability was wild type > W140H > W140F = W140Y. Therefore, the five-membered nitrogen-containing ring of the indole is thought to bear the essential information. In the crystal structure of staphylococcal nuclease, the five-membered ring is at the local center of the C-terminal cluster through hydrophobic interactions. This cluster plays a key role in the interaction connecting the C-terminal region and the N-terminal beta-core. Mutants other than W140H, W140F, and W140Y lost the ability to form the local core, which caused the loss of the long-range interactions between the C-terminal and N-terminal regions. Inhibitor or substrate binding to these mutants compensates for the lack of long-range interactions generated by W140.     

Crosstalk between the subunits of the homodimeric enzyme triosephosphate isomerase

Homodimeric triosephosphate isomerase (TIM) from Trypanosoma cruzi (TcTIM) and T. brucei (TbTIM) are markedly similar in amino acid sequence and three-dimensional structure. In their dimer interfaces, each monomer has a Cys15 that is surrounded by loop3 of the adjoining subunit. Perturbation of Cys15 by methylmethane thiosulfonate (MMTS) induces abolition of catalysis and structural changes. In the two TIMs, the structural arrangements of their Cys15 are almost identical. Nevertheless, the susceptibility of TcTIM to MMTS is nearly 100-fold higher than in TbTIM. To ascertain the extent to which the characteristics of the interface Cys depend on the dynamics of its own monomer or on those of the adjacent monomer, we studied MMTS action on mutants of TcTIM that had the interface residues of TbTIM, and hybrids that have only one interfacial Cys15 (C15ATcTIM-wild type TbTIM). We found that the solvent exposure of the interfacial Cys depends predominantly on the characteristics of the adjoining monomer. The maximal inhibition of activity induced by perturbation of the sole interface Cys in the C15ATcTIM-TbTIM hybrid is around 60%. Hybrids formed with C15ATcTIM monomers and catalytically inert TbTIM monomers (E168DTbTIM) were also studied. Their activity drops by nearly 50% when the only interfacial Cys is perturbed. These results in conjunction with those on C15ATcTIM-wild type TbTIM hybrid indicate that about half of the activity of each monomer depends on the integrity of each of the two Cys15-loop3 portions of the interface. This could be another reason of why TIM is an obligatory dimer.     

Probing the role of the fully conserved Cys126 in triosephosphate isomerase by site-specific mutagenesis--distal effects on dimer stability

Cys126 is a completely conserved residue in triosephosphate isomerase that is proximal to the active site but has been ascribed no specific role in catalysis. A previous study of the C126S and C126A mutants of yeast TIM reported substantial catalytic activity for the mutant enzymes, leading to the suggestion that this residue is implicated in folding and stability [Gonzalez-Mondragon E et al. (2004) Biochemistry 43, 3255-3263]. We re-examined the role of Cys126 with the Plasmodium falciparum enzyme as a model. Five mutants, C126S, C126A, C126V, C126M, and C126T, were characterized. Crystal structures of the 3-phosphoglycolate-bound C126S mutant and the unliganded forms of the C126S and C126A mutants were determined at a resolution of 1.7-2.1 ?. Kinetic studies revealed an approximately five-fold drop in k(cat) for the C126S and C126A mutants, whereas an approximately 10-fold drop was observed for the other three mutants. At ambient temperature, the wild-type enzyme and all five mutants showed no concentration dependence of activity. At higher temperatures (> 40 °C), the mutants showed a significant concentration dependence, with a dramatic loss in activity below 15 μM. The mutants also had diminished thermal stability at low concentration, as monitored by far-UV CD. These results suggest that Cys126 contributes to the stability of the dimer interface through a network of interactions involving His95, Glu97, and Arg98, which form direct contacts across the dimer interface.     

Effects of mutations of conserved Lys-155 and Thr-156 residues in the phosphate-binding glycine-rich sequence of the F1-ATPase beta subunit of Escherichia coli.

beta Lys-155 in the glycine-rich sequence of the beta subunit of Escherichia coli F1-ATPase has been shown to be near the gamma-phosphate moiety of ATP by affinity labeling (Ida, K., Noumi, T., Maeda, M., Fukui, T., and Futai, M. (1991) J. Biol. Chem. 266, 5424-5429). For examination of the roles of beta Lys-155 and beta Thr-156, mutants (beta Lys-155-->Ala, Ser, or Thr; beta Thr-156-->Ala, Cys, Asp, or Ser; beta Lys-155/beta Thr-156-->beta Thr-155/beta Lys-156; and beta Thr-156/beta Val-157-->beta Ala-156/beta Thr-157) were constructed, and their properties were studied extensively. The beta Ser-156 mutant was active in ATP synthesis and had approximately 1.5-fold higher membrane ATPase activity than the wild type. Other mutants were defective in ATP synthesis, had < 0.1% of the membrane ATPase activity of the wild type, and showed no ATP-dependent formation of an electrochemical proton gradient. The mutants had essentially the same amounts of F1 in their membranes as the wild type. Purified mutant enzymes (beta Ala-155, beta Ser-155, beta Ala-156, and beta Cys-156) showed low rates of multisite (< 0.02% of the wild type) and unisite (< 1.5% of the wild type) catalyses. The k1 values of the mutant enzymes for unisite catalysis were lower than that of the wild type: not detectable with the beta Ala-156 and beta Cys-156 enzymes and 10(2)-fold lower with the beta Ala-155 and beta Ser-155 enzymes. The beta Thr-156-->Ala or Cys enzyme showed an altered response to Mg2+, suggesting that beta Thr-156 may be closely related to Mg2+ binding. These results suggest that beta Lys-155 and beta Thr-156 are essential for catalysis and are possibly located in the catalytic site, although beta Thr-156 could be replaced by a serine residue.     

Rett syndrome-causing mutations in human MeCP2 result in diverse structural changes that impact folding and DNA interactions

Most cases of Rett syndrome (RTT) are caused by mutations in the methylated DNA-binding protein, MeCP2. Here, we have shown that frequent RTT-causing missense mutations (R106W, R133C, F155S, T158M) located in the methylated DNA-binding domain (MBD) of MeCP2 have profound and diverse effects on its structure, stability, and DNA-binding properties. Fluorescence spectroscopy, which reports on the single tryptophan in the MBD, indicated that this residue is strongly protected from the aqueous environment in the wild type but is more exposed in the R133C and F155S mutations. In the mutant proteins R133C, F155S, and T158M, the thermal stability of the domain was strongly reduced. Thermal stability of the wild-type protein was increased in the presence of unmethylated DNA and was further enhanced by DNA methylation. DNA-induced thermal stability was also seen, but to a lesser extent, in each of the mutant proteins. Circular dichroism (CD) of the MBD revealed differences in the secondary structure of the four mutants. Upon binding to methylated DNA, the wild type showed a subtle but reproducible increase in alpha-helical structure, whereas the F155S and R106W did not acquire secondary structure with DNA. Each of the mutant proteins studied is unique in terms of the properties of the MBD and the structural changes induced by DNA binding. For each mutation, we examined the extent to which the magnitude of these differences correlated with the severity of RTT patient symptoms.     

Site-directed mutagenesis of rat liver NAD(P)H: quinone oxidoreductase: roles of lysine 76 and cysteine 179.

We previously reported the expression of a full-length cDNA complementary to a rat liver NAD(P)H:quinone oxidoreductase (EC 1.6.99.2) mRNA in Escherichia coli (Q. Ma, R. Wang, C. S. Yang, and A. Y. H. Lu, 1990, Arch. Biochem. Biophys. 283, 311-317). Since cysteine residues have been suggested to be important for the catalysis of flavoproteins and a lysine residue at position 76 in NAD(P)H:quinone oxidoreductase has been proposed to be involved in electron transfer of the enzyme, we investigated the roles of lysine 76 and cysteine 179 of this enzyme in catalysis by site-directed mutagenesis. Mutant cDNA clones replacing lysine 76 with valine (K76V) and cysteine 179 with alanine (C179A) were generated by a procedure based on the polymerase chain reaction. The mutant enzymes were expressed in E. coli. The cytosolic activities of the K76V and C179A mutants were 50 and 25% of that of the wild type (DTD), due to lower levels of the mutant proteins as shown by immunoblot analysis. The mutant proteins were purified to apparent homogeneity. The purified K76V and C179A mutant enzymes maintained full activities of 2,6-dichlorophenolindophenol (DCIP) reduction compared with that of the wild type. The mutant enzymes exhibited kinetic parameters for DCIP, NADH, and NADPH similar to those of DTD except that, with K76V, the Km for NADPH was doubled. Both mutant proteins contained two molecules of FAD per enzyme molecule. Dicumarol inhibited K76V and C179A mutant activities to greater than 90% at a concentration of 10(-7) M. Heat stability studies showed that C179A was much more sensitive to inactivation at 37 degrees C than both the wild-type and K76V enzymes. It is concluded from this study that lysine 76 and cysteine 179 are not essential in catalysis and in the binding of FAD, DCIP, and dicumarol. However, lysine residue 76 appears to play a role in NADPH binding and cysteine residue 179 is important in maintaining the stability of the enzyme.     

Altered intersubunit interactions in crystal structures of catalytically compromised ribulose-1,5-bisphosphate carboxylase/oxygenase

Substitution of Leu290 by Phe (L290F) in the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase from the unicellular green alga Chlamydomonas reinhardtii causes a 13% decrease in CO(2)/O(2) specificity and reduced thermal stability. Genetic selection for restored photosynthesis at the restrictive temperature identified an Ala222 to Thr (A222T) substitution that suppresses the deleterious effects of the original mutant substitution to produce a revertant enzyme with improved thermal stability and kinetic properties virtually indistinguishable from that of the wild-type enzyme. Because the mutated residues are situated approximately 19 A away from the active site, they must affect the relative rates of carboxylation and oxygenation in an indirect way. As a means for elucidating the role of such distant interactions in Rubisco catalysis and stability, we have determined the crystal structures of the L290F mutant and L290F/A222T revertant enzymes to 2.30 and 2.05 A resolution, respectively. Inspection of the structures reveals that the mutant residues interact via van der Waals contacts within the same large subunit (intrasubunit path, 15.2 A Calpha-Calpha) and also via a path involving a neighboring small subunit (intersubunit path, 18.7 A Calpha-Calpha). Structural analysis of the mutant enzymes identified regions (residues 50-72 of the small subunit and residues 161-164 and 259-264 of the large subunit) that show significant and systematically increased atomic temperature factors in the L290F mutant enzyme compared to wild type. These regions coincide with residues on the interaction paths between the L290F mutant and A222T suppressor sites and could explain the temperature-conditional phenotype of the L290F mutant strain. This suggests that alterations in subunit interactions will influence protein dynamics and, thereby, affect catalysis.     

Role of hydrogen bonding in the active site of human manganese superoxide dismutase

The side chain of Gln143, a conserved residue in manganese superoxide dismutase (MnSOD), forms a hydrogen bond with the manganese-bound solvent and is critical in maintaining catalytic activity. The side chains of Tyr34 and Trp123 form hydrogen bonds with the carboxamide of Gln143. We have replaced Tyr34 and Trp123 with Phe in single and double mutants of human MnSOD and measured their catalytic activity by stopped-flow spectrophotometry and pulse radiolysis. The replacements of these side chains inhibited steps in the catalysis as much as 50-fold; in addition, they altered the gating between catalysis and formation of a peroxide complex to yield a more product-inhibited enzyme. The replacement of both Tyr34 and Trp123 in a double mutant showed that these two residues interact cooperatively in maintaining catalytic activity. The crystal structure of Y34F/W123F human MnSOD at 1.95 A resolution suggests that this effect is not related to a conformational change in the side chain of Gln143, which does not change orientation in Y34F/W123F, but rather to more subtle electronic effects due to the loss of hydrogen bonding to the carboxamide side chain of Gln143. Wild-type MnSOD containing Trp123 and Tyr34 has approximately the same thermal stability compared with mutants containing Phe at these positions, suggesting the hydrogen bonds formed by these residues have functional rather than structural roles.     

The effect of specific proline residues on the kinetic stability of the triosephosphate isomerases of two trypanosomes

The effect of specific residues on the kinetic stability of two closely related triosephosphate isomerases (from Trypanosoma cruzi, TcTIM and Trypanosoma brucei, TbTIM) has been studied. Based on a comparison of their β‐turn occurrence, we engineered two chimerical enzymes where their super secondary β‐loop‐α motifs 2 ((βα)₂) were swapped. Differential scanning calorimetry (DSC) experiments showed that the (βα)₂ motif of TcTIM inserted into TbTIM (2Tc) increases the kinetic stability. On the other hand, the presence of the (βα)₂ motif of TbTIM inserted into TcTIM (2Tb) gave a chimerical protein difficult to purify in soluble form and with a significantly reduced kinetic stability. The comparison of the contact maps of the (βα)₂ of TbTIM and TcTIM showed differences in the contact pattern of residues 43 and 49. In TcTIM these residues are prolines, located at the N‐terminal of loop‐2 and the C‐terminal of α‐helix‐2. Twelve mutants were engineered involving residues 43 and 49 to study the effect over the unfolding activation energy barrier (E_A). A systematic analysis of DSC data showed a large decrease on the E_A of TcTIM (ΔE_A ranging from 468 to 678 kJ/mol) when the single and double proline mutations are present. The relevance of Pro43 to the kinetic stability is also revealed by mutation S43P, which increased the free energy of the transition state of TbTIM by 17.7 kJ/mol. Overall, the results indicate that protein kinetic stability can be severely affected by punctual mutations, disturbing the complex network of interactions that, in concerted action, determine protein stability. Proteins 2017; 85:571–579. © 2016 Wiley Periodicals, Inc.     

Role of a glutamate bridge spanning the dimeric interface of human manganese superoxide dismutase

The function in the structure, stability, and catalysis of the interfaces between subunits in manganese superoxide dismutase (MnSOD) is currently under scrutiny. Glu162 in homotetrameric human MnSOD spans a dimeric interface and forms a hydrogen bond with His163 of an adjacent subunit which is a direct ligand of the manganese. We have examined the properties of two site-specific mutants of human MnSOD in which Glu162 is replaced with Asp (E162D) and Ala (E162A). The X-ray crystal structures of E162D and E162A MnSOD reveal no significant structural changes compared with the wild type other than the removal of the hydrogen bond interaction with His163 in E162A MnSOD. In the case of E162D MnSOD, an intervening solvent molecule fills the void created by the mutation to conserve the hydrogen bond interaction between His163 and residue 162. These mutants retain their tetrameric structure and their specificity for manganese over iron. Each has catalytic activity in the disproportionation of superoxide that is typically 5-25% of that of the wild-type enzyme and a level of product inhibition greater by approximately 2-fold. Differential scanning calorimetry indicates that the hydrogen bond between Glu162 and His163 contributes to the stability of MnSOD, with the major unfolding transition occurring at 81 degrees C for E162A compared to 90 degrees C for wild-type MnSOD. These results suggest that Glu162 at the tetrameric interface in human MnSOD supports stability and efficient catalysis and has a significant role in regulating product inhibition.     

Derivatization of the interface cysteine of triosephosphate isomerase from Trypanosoma brucei and Trypanosoma cruzi as probe of the interrelationship between the catalytic sites and the dimer interface

In the interface of homodimeric triosephosphate isomerase from Trypanosoma brucei (TbTIM) and Trypanosoma cruzi (TcTIM), one cysteine of each monomer forms part of the intersubunit contacts. The relatively slow derivatization of these cysteines by sulfhydryl reagents induces progressive structural alterations and abolition of catalysis [Garza-Ramos et al. (1998) Eur. J. Biochem. 253, 684-691]. Derivatization of the interface cysteine by 5, 5-dithiobis(2-nitrobenzoate) (DTNB) and methylmethane thiosulfonate (MMTS) was used to probe if events at the catalytic site are transmitted to the dimer interface. It was found that enzymes in the active catalytic state are significantly less sensitive to the thiol reagents than in the resting state. Maximal protection against derivatization of the interface cysteine by thiol reagents was obtained at near-saturating substrate concentrations. Continuous recording of derivatization by DTNB showed that catalysis hinders the reaction of sulfhydryl reagents with the interface cysteine. Therefore, in addition to intrinsic structural barriers, catalysis imposes additional impediments to the action of thiol reagents on the interface cysteine. In TcTIM, the substrate analogue phosphoglycolate protected strongly against DTNB action, and to a lesser extent against MMTS action; in TbTIM, phosphoglycolate protected against the effect of DTNB, but not against the action of MMTS. This indicates that barriers of different magnitude to the reaction of thiol reagents with the interface cysteine are induced by the events at the catalytic site. Studies with a Cys14Ser mutant of TbTIM confirmed that all the described effects of sulfhydryl reagents on the trypanosomal enzymes are a consequence of derivatization of the interface cysteine.     

Critical role of the cysteine 323 residue in the catalytic activity of human glutamate dehydrogenase isozymes

The role of residue C323 in catalysis by human glutamate dehydrogenase isozymes (hGDH1 and hGDH2) was examined by substituting Arg, Gly, Leu, Met, or Tyr at C323 by cassette mutagenesis using synthetic human GDH isozyme genes. As a result, the Km of the enzyme for NADH and alpha-ketoglutarate increased up to 1.6-fold and 1.1-fold, respectively. It seems likely that C323 is not responsible for substrate-binding or coenzyme-binding. The efficiency (kcat/Km) of the mutant enzymes was only 11-14% of that of the wild-type isozymes, mainly due to a decrease in kcat values. There was a linear relationship between incorporation of [14C]p-chloromercuribenzoic acid and loss of enzyme activity that extrapolated to a stoichiometry of one mol of [14C] incorporated per mol of monomer for wild type hGDHs. No incorporation of [14C]p-chloromer-curibenzoic acid was observed with the C323 mutants. ADP and GTP had no effect on the binding of p-chloromercuribenzoic acid, suggesting that C323 is not directly involved in allosteric regulation. There were no differences between the two hGDH isozymes in sensitivities to mutagenesis at C323. Our results suggest that C323 plays an important role in catalysis by human GDH isozymes.     

Role of invariant tyrosines in a crustacean mu-class glutathione S-transferase from shrimp Litopenaeus vannamei: site-directed mutagenesis of Y7 and Y116

Y6 and Y115 are key amino acids involved in enzyme-substrate interactions in mu-class glutathione S-transferase (GST). They provide electrophilic assistance and stabilize substrates through their hydroxyl groups. Two site-directed mutants (Y7F and Y116F) and the wild-type shrimp GSTs were expressed in Escherichia coli, and the steady-state kinetic parameters were determined using CDNB as the second substrate. The mutants were modeled based on a crystal structure of a mu-class GST to obtain further insights about the changes at the active site. The Y116F mutant had an increase in kcat contrary to Y7F compared to the wild type. Molecular modeling showed that the shrimp GST has a H108 residue that may contribute to compensate and lead to a less deleterious change when conserved tyrosine residues are mutated. This work indicates that shrimp GST is a useful model to understand the catalysis mechanisms in this critical enzyme.     

Probing the dynamics of a mobile loop above the active site of L1, a metallo-beta-lactamase from Stenotrophomonas maltophilia, via site-directed mutagenesis and stopped-flow fluorescence spectroscopy

A structural feature shared by the metallo-beta-lactamases is a flexible loop of amino acids that extends over their active sites and that has been proposed to move during the catalytic cycle of the enzymes, clamping down on substrate. To probe the movement of this loop (residues 152-164), a site-directed mutant of metallo-beta-lactamase L1 was engineered that contained a Trp residue on the loop to serve as a fluorescent probe. It was necessary first, however, to evaluate the contribution of each native Trp residue to the fluorescence changes observed during the catalytic cycle of wild-type L1. Five site-directed mutants of L1 (W39F, W53F, W204F, W206F, and W269F) were prepared and characterized using metal analyses, CD spectroscopy, steady-state kinetics, stopped-flow fluorescence, and fluorescence titrations. All mutants retained the wild-type tertiary structure and bound Zn(II) at levels comparable with wild type and exhibited only slight (<10-fold) decreases in k(cat) values as compared with wild-type L1 for all substrates tested. Fluorescence studies revealed a single mutant, W39F, to be void of the fluorescence changes observed with wild-type L1 during substrate binding and catalysis. Using W39F as a template, a Trp residue was added to the flexile loop over the active site of L1, to generate the double mutant, W39F/D160W. This double mutant retained all the structural and kinetic characteristics of wild-type L1. Stopped-flow fluorescence and rapid-scanning UV-visible studies revealed the motion of the loop (k(obs) = 27 +/- 2 s(-1)) to be similar to the formation rate of a reaction intermediate (k(obs) = 25 +/- 2 s(-1)).     

Effects of Phe-to-Trp mutation and fluorotryptophan incorporation on the solution structure of cardiac troponin C, and analysis of its suitability as a potential probe for in situ NMR studies

19F NMR spectroscopy is potentially a powerful tool for probing protein properties in situ. However, results obtained using this technique are relevant only if the 19F probe offers minimal perturbation to the surrounding environment. In this paper, we examine the effect of 5-fluorotryptophan (5fW) incorporation on the three-dimensional structure of cardiac troponin-C (cTnC), with the intention of developing a 19F-labeled TnC for use in in situ 19FNMR. We find that, in general, 5fW does not perturb the structure of the protein significantly. Replacement of residue Phe 153 with 5fW produces no noticeable change in protein conformation. However, replacement of residue Phe 104 with 5fW produces a folding behavior that is dependent on the Escherichia coli strain used to express the mutant. The orientations of the indole rings in these mutants are such that the Trp residue adopts a chi2 of approximately 90 degrees in the F104W mutant and approximately -100 degrees in the F153W mutant. Using results from 19F-1H heteronuclear NOE experiment, we show the replacement of L-Trp with 5fW at these positions does not change the orientation of the indole ring and the spread of the 5fW side-chain dihedral angles increases moderately for the F104(5fW) mutant and not at all for the F153(5fW) mutant. Based on these structures, we conclude that the substitution of Phe by 5fW at these two positions has minimal effects on the structure of cTnC and that the 5fW indole rings in both mutants have well defined orientation, making the two mutants viable candidates for use in in situ 19F NMR spectroscopy.     

Structural and functional roles of highly conserved serines in human lipoprotein lipase. Evidence that serine 132 is essential for enzyme catalysis

The structure of human lipoprotein lipase was recently deduced from its cDNA sequence. It contains 8 serine residues (residues 45, 132, 143, 172, 193, 244, 251, and 363) that are absolutely conserved in both lipoprotein lipase and hepatic lipase across all species studied. The high homology between lipoprotein lipase, hepatic lipase, and pancreatic lipase suggests that the catalytic functions of these enzymes share a common mechanism and that one of the 8 conserved serines in human lipoprotein lipase must play a catalytic role as does serine 152 in the case of pancreatic lipase (Winkler, F. K., D'Arcy, A., and Hunziker, W. Nature 343, 771-774). We expressed wild-type and site-specific mutants of human lipoprotein lipase in COS cells in vitro. We produced two to four substitution mutants involving each of the 8 serines and assayed a total of 22 mutants for both enzyme activity and the amount of immunoreactive enzyme mass produced. Immunoreactive lipase was detected in all cases. With the exception of Ser132, for each of the 8 serine mutants we studied, at least one of several mutants at each position showed detectable enzyme activity. All three substitution mutants at Ser132, Ser----Thr, Ser----Ala, and Ser----Asp, were totally inactive. Ser132 occurs in the consensus sequence Gly-Xaa-Ser-Xaa-Gly present in all serine proteinases and in human pancreatic lipase. The x-ray crystallography structure of human pancreatic lipase suggests that the analogous serine residue in human pancreatic lipase, Ser152, is the nucleophilic residue essential for catalysis. Our biochemical data strongly support the conclusion that Ser132 in human lipoprotein lipase is the crucial residue required for enzyme catalysis. The observed specific activities of the variants involving the other seven highly conserved serines in human lipoprotein lipase are consistent with the interpretation that this enzyme has a three-dimensional structure very similar to that of human pancreatic lipase.     

A non-active site residue, cysteine 69, of glutathione S-transferase ADGSTD3-3 has a role in stability and catalytic function

The Cys69 residue of an Anopheles dirus glutathione S-transferase isoform (adGSTD3-3), was characterized to elucidate its contribution in both catalysis and structural support. Nine mutants were generated at this position by replacing the residue with polar, non-polar and charged residues. The polar residues changed the Vm of the enzymes. With non-polar residues, the enzymes were unable to fold and were expressed in the insoluble inclusion form. With charged residues, the soluble enzyme yields were only 3% of the wild type protein. Molecular dynamics simulation also was performed to understand the changes in the enzyme structure. These findings are additional evidence of the importance of structural residues that affect the enzymatic properties such as Vm, Km and enzyme specificity.     

Kinetic and physical characterisation of recombinant wild-type and mutant human protoporphyrinogen oxidases

The effects of various protoporphyrinogen oxidase (PPOX) mutations responsible for variegate porphyria (VP), the roles of the arginine-59 residue and the glycines in the conserved flavin binding site, in catalysis and/or cofactor binding, were examined. Wild-type recombinant human PPOX and a selection of mutants were generated, expressed, purified and partially characterised. All mutants had reduced PPOX activity to varying degrees. However, the activity data did not correlate with the ability/inability to bind flavin. The positive charge at arginine-59 appears to be directly involved in catalysis and not in flavin-cofactor binding alone. The K(m)s for the arginine-59 mutants suggested a substrate-binding problem. T(1/2) indicated that arginine-59 is required for the integrity of the active site. The dominant alpha-helical content was decreased in the mutants. The degree of alpha-helix did not correlate linearly with T(1/2) nor T(m) values, supporting the suggestion that arginine-59 is important for catalysis at the active site. Examination of the conserved dinucleotide-binding sequence showed that substitution of glycine in codon 14 was less disruptive than substitutions in codons 9 and 11. Ultraviolet melting curves generally showed a two-state transition suggesting formation of a multi-domain structure. All mutants studied were more resistant to thermal denaturation compared to wild type, except for R168C.     

H(+)-ATPase gamma subunit of Escherichia coli. Role of the conserved carboxyl-terminal region

Cloned uncG genes (wild-type or in vitro mutagenized) for the Escherichia coli gamma subunit were introduced into the uncG mutant Gln-14----end), and the functions of the mutant subunits were studied. The F1's with Ala-283----end and Thr-277----end mutant gamma subunits had 63 and 14% of the wild-type ATPase activity, respectively, and mutants with these subunits showed reduced growth by oxidative phosphorylation, indicating that the 10 residues at the carboxyl terminus (286th residue) are important, but dispensable, for catalysis. On the other hand, F1 with a Gln-269----end gamma subunit was inactive. Replacement of conserved residues (Gln-269, Thr-273, or Glu-275) between Gln-269 and Leu-276 gave enzymes with significantly reduced ATPase activity (2-41% of that of the wild-type) and lower ATP-driven proton conduction. Thus these residues are required for the normal catalytic activity of F1, although they are not absolutely essential. Membranes with amino acid replacements (Thr-277----end, Gln-269----Leu, or Glu-275----Lys) and the frameshift mutation (downstream of Thr-277) had about 15% of the wild-type ATPase activity, but showed different degrees of ATP-dependent H+ translocation and growth yield by oxidative phosphorylation, suggesting that the gamma subunit, especially its carboxyl-terminal region, functions in coupling between catalysis and H+ translocation.