Structural model of ρ1 GABAC receptor based on evolutionary analysis: Testing of predicted protein–protein interactions involved in receptor assembly and function

The homopentameric ρ1 GABA_C receptor is a ligand‐gated ion channel with a binding pocket for γ‐aminobutyric acid (GABA) at the interfaces of N‐terminal extracellular domains. We combined evolutionary analysis, structural modeling, and experimental testing to study determinants of GABA_C receptor assembly and channel gating. We estimated the posterior probability of selection pressure at amino acid residue sites measured as ω‐values and built a comparative structural model, which identified several polar residues under strong selection pressure at the subunit interfaces that may form intersubunit hydrogen bonds or salt bridges. At three selected sites (R111, T151, and E55), mutations disrupting intersubunit interactions had strong effects on receptor folding, assembly, and function. We next examined the role of a predicted intersubunit salt bridge for residue pair R158–D204. The mutant R158D, where the positively charged residue is replaced by a negatively charged aspartate, yielded a partially degraded receptor and lacked membrane surface expression. The membrane surface expression was rescued by the double mutant R158D–D204R, where positive and negative charges are switched, although the mutant receptor was inactive. The single mutants R158A, D204R, and D204A exhibited diminished activities and altered kinetic profiles with fast recovery kinetics, suggesting that R158–D204 salt bridge perhaps stabilizes the open state of the GABA_C receptor. Our results emphasize the functional importance of highly conserved polar residues at the protein–protein interfaces in GABA_C ρ1 receptors and demonstrate how the integration of computational and experimental approaches can aid discovery of functionally important interactions.     

New insights into the molecular mechanism of methanol-induced inactivation of Thermomyces lanuginosus lipase: a molecular dynamics simulation study

Methanol intolerance of lipase is a major limitation in lipase-catalysed methanolysis reactions. In this study, to understand the molecular mechanism of methanol-induced inactivation of lipases, we performed molecular dynamics (MD) simulations of Thermomyces lanuginosus lipase (TLL) in water and methanol and compared the observed structural and dynamic properties. The solvent accessibility analysis showed that in methanol, polar residues tended to be buried away from the solvent while non-polar residues tended to be more solvent-exposed in comparison to those in water. Moreover, we observed that in methanol, the van der Waals packing of the core residues in two hydrophobic regions of TLL became weak. Additionally, the catalytically relevant hydrogen bond between Asp²⁰¹ OD2 and His²⁵⁸ ND1 in the active site was broken when enzyme was solvated in methanol. This may affect the stability of the tetrahedral intermediates in the catalytic cycle of TLL. Furthermore, compared to in water, some enzyme surface residues displayed enhanced movement in methanol with higher Cα root-mean-square atomic positional fluctuation values. One of such methanol-affecting surface residues (Ile²⁴¹) was chosen for mutation, and MD simulation of the I241E mutant in methanol was conducted. The structural analysis of the mutant showed that replacing a non-polar surface residue with an acidic one at position 241 contributed to the stabilisation of enzyme structure in methanol. Ultimately, these results, while providing molecular-level insights into the destabilising effect of methanol on TLL, highlight the importance of surface residue redesign to improve the stability of lipases in methanol environments.     

PPEF: A bisbenzimdazole potent antimicrobial agent interacts at acidic triad of catalytic domain of E. coli topoisomerase IA

BackgroundTopoisomerase is a well known target to develop effective antibacterial agents. In pursuance of searching novel antibacterial agents, we have established a novel bisbenzimidazole (PPEF) as potent E. coli topoisomerase IA poison inhibitor.MethodsIn order to gain insights into the mechanism of action of PPEF and understanding protein-ligand interactions, we have produced wild type EcTopo 67 N-terminal domain (catalytic domain) and its six mutant proteins at acidic triad (D111, D113, E115). The DDE motif is replaced by alanine (A) to create three single mutants: D111A, D113A, E115A and three double mutants: D111A-D113A, D113A-E115A and D111A-E115A.ResultsCalorimetric study of PPEF with single mutants showed 10 fold lower affinity than that of wild type EcTopo 67 (7.32 × 10⁶ M⁻¹for wild type, 0.89 × 10⁶ M⁻¹for D111A) and 100 fold lower binding with double mutant D113A-E115A (0.02 × 10⁶ M⁻¹) was observed. The mutated proteins showed different CD signature as compared to wild type protein. CD and fluorescence titrations were done to study the interaction between EcTopo 67 and ligands. Molecular docking study validated that PPEF has decreased binding affinity towards mutated enzymes as compared to wild type.ConclusionThe overall study reveals that PPEF binds to D113 and E115 of acidic triad of EcTopo 67. Point mutations decrease binding affinity of PPEF towards DDE motif of topoisomerase.General significanceThis study concludes PPEF as poison inhibitor of E. coli Topoisomerase IA, which binds to acidic triad of topoisomerase IA, responsible for its function. PPEF can be considered as therapeutic agent against bacteria.     

The Regulation of Surface Charged Residues on the Properties of Cytochrome b5

To understand the roles of negatively surface charged residues, the cytochrome b₅ (Cyt b₅) E48A/D60A mutant was constructed. UV-visible and CD spectra confirmed that the mutation did not cause overall structural changes of the protein. The mutant presents an unexpected high stability toward the thermal and denaturant compared with the wild type Cyt b₅, which shows that these surface charged residues can influence the interactions between the heme b group and the polypeptide chain. Functional properties were clarified through the electron transfer reactions between Cyt b₅ and Cyt c. The driving force of the electron transfer reactions is conservative. Although the association constant of Cyt b₅ E48A/D60A with Cyt c is much lower than that of the wild type Cyt b₅, their electron transfer rate constants do not differ significantly. The results show that these surface charged residues play important roles in regulating both the stability and functional properties of Cyt b₅.     

Factor VIII A3 domain residues 1793–1795 represent a factor IXa-interactive site in the tenase complex

BackgroundFactor (F)VIII functions as a cofactor in the tenase complex responsible for conversion of FX to FXa by FIXa. Earlier studies indicated that one of the FIXa-binding sites is located in residues 1811–1818 (crucially F1816) of the FVIII A3 domain. A putative, three-dimensional structure model of the FVIIIa molecule suggested that residues 1790–1798 form a V-shaped loop, and juxtapose residues 1811–1818 on the extended surface of FVIIIa.AimTo examine FIXa molecular interactions in the clustered acidic sites of FVIII including residues 1790–1798.Methods and resultsSpecific ELISA's demonstrated that the synthetic peptides, encompassing residues 1790–1798 and 1811–1818, competitively inhibited the binding of FVIII light chain to active-site-blocked Glu-Gly-Arg-FIXa (EGR-FIXa) (IC₅₀; 19.2 and 42.9 μM, respectively), in keeping with a possible role for the 1790–1798 in FIXa interactions. Surface plasmon resonance-based analyses demonstrated that variants of FVIII, in which the clustered acidic residues (E1793/E1794/D1793) or F1816 contained substituted alanine, bound to immobilized biotin labeled-Phe-Pro-Arg-FIXa (bFPR-FIXa) with a 1.5–2.2-fold greater K_D compared to wild-type FVIII (WT). Similarly, FXa generation assays indicated that E1793A/E1794A/D1795A and F1816A mutants increased the K_m by 1.6–2.8-fold relative to WT. Furthermore, E1793A/E1794A/D1795A/F1816A mutant showed that the K_m was increased by 3.4-fold and the V_max was decreased by 0.75-fold, compared to WT. Molecular dynamics simulation analyses revealed the subtle changes between WT and E1793A/E1794A/D1795A mutant, supportive of the contribution of these residues for FIXa interaction.ConclusionThe 1790–1798 region in the A3 domain, especially clustered acidic residues E1793/E1794/D1795, contains a FIXa-interactive site.     

Asp30 of Aspergillus oryzae cutinase CutL1 is involved in the ionic interaction with fungal hydrophobin RolA

Aspergillus oryzae hydrophobin RolA adheres to the biodegradable polyester polybutylene succinate-co-adipate (PBSA) and promotes PBSA degradation by interacting with A. oryzae polyesterase CutL1 and recruiting it to the PBSA surface. In our previous studies, we found that positively charged amino acid residues (H32, K34) of RolA and negatively charged residues (E31, D142, D171) of CutL1 are important for the cooperative ionic interaction between RolA and CutL1, but some other charged residues in the triple mutant CutL1-E31S/D142S/D171S are also involved. In the present study, on the basis of the 3D-structure of CutL1, we hypothesized that D30 is also involved in the CutL1–RolA interaction. We substituted D30 with serine and performed kinetic analysis of the interaction between wild-type RolA and the single mutant CutL1-D30S or quadruple mutant CutL1-D30S/E31S/D142S/D171S by using quartz crystal microbalance. Our results indicate that D30 is a novel residue involved in the ionic interaction between RolA and CutL1.     

Presence of an acidic glycoprotein in the serum of arthritic rats: Modulation by capsaicin and curcumin

Voltage-dependent L-type Ca²⁺ channels form highly selective pores for Ca²⁺ ions in the membranes of excitable cells. We investigated the functional role of negatively charged residues, within or near the selectivity region, in ion permeation of a human cardiac L-type Ca²⁺ channel. Glutamates in each of the four repeats, and an aspartate in repeat IV, were substituted with positively charged lysine. Wild-type and mutant Ca²⁺ channels were expressed in Xenopus oocytes. Block by Ca²⁺ and Mg² of inward Li⁺ currents through the channels was used to assess the effects of amino acid substitutions on high-affinity divalent cation binding. The rank order of IC₅₀'s for Ca²⁺ block of I_Li was: E677K > E1086K > E334K > E1387K > D1391K > wild-type. The order of IC₅₀'s for Mg²⁺ block of I_Li indicated differential involvement of the same residues in Mg²⁺ binding: E1387K > E334K > E1086K > E677K > D1391K wild-type. Mutants E1387K and D1391K effectively permeated Ba²⁺, but exhibited a decreased single-channel conductance. The unitary current amplitude carried by Na+, in the absence of external divalent cations, was slightly decreased in the E1387K mutant but not in the D1391K mutant. The results confirm that each of the four glutamates participate unequally in high-affinity Ca²⁺ binding. Additionally, our results indicate that these glutamate residues participate in Mg²⁺ binding. The glutamate at position 1387 may be only peripherally involved in the formation of a high-affinity Ca²⁺ -binding site but is central to a Mg²⁺ binding site accessible from the external side of the pore. The aspartate at position 1391 is most likely located just external to the selectivity region. (Mol Cell Biochem 166: 125-134, 1997)     

E75、R78和D82是影响大肠埃希氏菌FtsZ自身组装及其与MreB相互作用的重要氨基酸

【目的】探索大肠埃希氏菌Escherichia coli FtsZ突变体FtsZ~(E75A)、FtsZ~(R78G)和FtsZ~(D82A)对FtsZ自身组装和FtsZ-MreB相互作用的影响。【方法】利用常规分子克隆和定点突变技术,构建FtsZ及其突变体表达载体,亲和纯化得到相应的目标蛋白;通过同源重组构建QN6(ftsZ::yfp-cat)、QN7(ftsZ~(E75A)::yfp-cat)、QN8(ftsZ~(R78G)::yfp-cat)和QN9(ftsZ~(D82A)::yfp-cat)菌株;利用活细胞成像技术观察FtsZ及其突变体的胞内定位模式;免疫沉淀和细菌双杂交实验检测FtsZ/FtsZ*-FtsZ*或FtsZ/FtsZ*-MreB间的相互作用;光扫描检测定点突变对FtsZ组装特性的影响。【结果】FtsZ~(E75A)、FtsZ~(R78G)和FtsZ~(D82A)突变体的功能活性降低、各突变体在E.coli内不能正确的定位和形成功能性Z环;FtsZ/FtsZ*-FtsZ*单体间的相互作用减弱或消失,FtsZ*-MreB相互作用破坏;FtsZ突变体体外聚合效率降低。【结论】FtsZ E75、R78和D82是影响FtsZ正确组装和功能及FtsZ-MreB相互作用的重要氨基酸。     

Crystal structures of LacD from Staphylococcus aureus and LacD.1 from Streptococcus pyogenes: insights into substrate specificity and virulence gene regulation

Staphylococcus aureus LacD, a Class I tagatose-1,6-bisphosphate (TBP) aldolase, shows broadened substrate specificity by catalyzing the cleavage of 1,6-bisphosphate derivatives of d-tagatose, d-fructose, d-sorbose, and d-psicose. LacD.1 and LacD.2 are two closely-related Class I TBP aldolases in Streptococcus pyogenes. Here we have determined the crystal structures of S. aureus LacD and S. pyogenes LacD.1. Monomers of both enzymes are folded into a (β/α)₈ barrel and two monomers associate tightly to form a dimer in the crystals. The structures suggest that the residues E189 and S300 of rabbit muscle Class I fructose-1,6-bisphosphate (FBP) aldolase are important for substrate specificity. When we mutated the corresponding residues of S. aureus LacD, the mutants (L165E, L275S, and L165E/L275S) showed enhanced substrate specificity toward FBP.

Structured summary

lacDbinds to lacD by X-ray crystallography(View interaction)lacD1binds to lacD1 by X-ray crystallography(View interaction)     

Exploration of green integrated approach for effluent treatment through mass culture and biofuel production from unicellular alga,Acutodesmus obliquus RDS01

Abstract

This study deals with the open pond (OP) pilot scale treatment of cassava effluent and enhancement of Ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBisCO) enzyme through CO₂ utilization by the microalga, Acutodesmus obliquus RDS01. The cassava effluent treatment (ET) revealed maximum reduction of ammonia (96.8%), calcium (94.6%), chloride (95.2%), chlorine (98.5%), inorganic phosphate (94.6%), magnesium (96.8%), nitrate (96.89%), organic carbon (95.9%), organic phosphorus (96.3%), potassium (97.9%), sodium (97.1%), and sulfate (95.4%) on 15^th day using A. obliquus. The microalga produced highest RuBisCO enzyme activity (90%), CO₂ utilization efficiency (95%), biomass (8.9 gL^?1), lipid (176.65?mg mL^?1), carbohydrate (96.78?mg mL^?1), biodiesel (4.1?mL g^?1), and bioethanol (3.7?mL g^?1) during OP treatment. The isolated RuBisCO gene (rbcL) was used to construct the protein model by homology modeling. The microalgal-lipid content was analyzed through thin layer chromatography, the biodiesel produced was analyzed using Fourier-transform infrared spectroscopy and gas chromatography mass spectrometry (GCMS). The bioethanol production was confirmed by high performance liquid chromatography and GCMS analyses. A. obliquus produced of 98.75% biodiesel and 96.83% bioethanol in the OP pilot scale treatment A. obliquus. Overall, the microalga A. obliquus could act as an effective CO₂ capturing and bioremediation agent in the cassava ET, and also for the biodiesel and bioethanol can be produced.     

The Z-Conformation of Poly(dA-dT) · Poly(dA-dT) in Solution as Studied by Ultraviolet Resonance Raman Spectroscopy

Abstract

Poly(dA-dT) poly(dA-dT) structures in aqueous solutions with high NaCl concentrations and in the presence of Ni²⁺ ions have been studied with resonance Raman spectroscopy (RRS). In low water activity the effects of added 95 mM NiCl₂ in solution stabilize the syn geometry of the purines and reorganize the water distribution via local interactions of Ni-water charged complexes with the adenine N7 position. It is shown that RRS provides good marker bands for a left-handed helix: i) a purine ring breathing mode around 630 cm″^?1coupled to the deoxyribose vibration in the syn geometry, ii) a 1300-1340 cm^?1 region characterizing local chemical interactions of the Ni²⁺ ions with the adenien N7 position, iii) lines at about 1483-and 1582 cm^?1 correlated to the anti/syn reorientation of the adenine residues on B-Z structure transition, iv) marker bands of the thymidine carbonyl group couplings at 1680-and 1733 cm^?1 due to the disposition of the thymidine residues in the Z helix specific geometry. Hence poly(dA-dT) poly(dA-dT) can adopt a Z form in solution. The Z form observed in alternate purine-pyrimidine sequences does not require G-C base pairs.     

Cytochrome P450 52A3: Modelling of 3D Structure and Surface Mutations

Abstract

Earlier W.-H. Schunck et al. [1] have prepared a water soluble enzymatically active fragment of cytochrome P450 52A3 (CYP52A3) which is lack of 66 amino acid residues, existed as a dimer in aqueous solution. Now we propose 3D structure of the fragment, which is based on multiple sequence alignment of the CYP52A3 with its homologues proteins of known 3D structure: CYP101, 102, 107A1 and 108. The structural model have been optimised and used as a prototype for computer simulation of point mutations. These mutations should bring some changes in the surface properties, interfering dimer formation. For this aim the point of 22 hydrophobic amino acid residues have been sequentially replaced with that of charged amino acids (GLU, ASP, ARG and LYS). The scoring of “mutants” was conducted based on the changes of protein surface hydrophobicity and protein-solvent interaction energy. An analysis of the surface hydrophobicity and protein-solvent interactions permit to select most sensitive three sites (171, 352 and particularly 164 amino acid residues). The dimerization of the following “mutant” fragments must be investigated experimentally.     

Photoproduction of hydrogen by sulfur-deprived <Emphasis Type="Italic">C. reinhardtii</Emphasis> mutants with impaired Photosystem II photochemical activity

Photoproduction of H₂ was examined in a series of sulfur-deprived Chlamydomonas reinhardtii D1-R323 mutants with progressively impaired PSII photochemical activity. In the R323H, R323D, and R323E D1 mutants, replacement of arginine affects photosystem II (PSII) function, as demonstrated by progressive decreases in O₂-evolving activity and loss of PSII photochemical activity. Significant changes in PSII activity were found when the arginine residue was replaced by negatively charged amino acid residues (R323D and R323E). However, the R323H (positively charged or neutral, depending on the ambient pH) mutant had minimal changes in PSII activity. The R323H, R323D, and R323E mutants and the pseudo-wild-type (pWt) with restored PSII function were used to study the effects of sulfur deprivation on H₂-production activity. All of these mutants exhibited significant changes in the normal parameters associated with the H₂-photoproduction process, such as a shorter aerobic phase, lower accumulation of starch, a prolonged anaerobic phase observed before the onset of H₂-production, a shorter duration of H₂-production, lower H₂ yields compared to the pWt control, and slightly higher production of dark fermentation products such as acetate and formate. The more compromised the PSII photochemical activity, the more dramatic was the effect of sulfur deprivation on the H₂-production process, which depends both on the presence of residual PSII activity and the amount of stored starch.     

长双歧杆菌N-乙酰氨基己糖1-位激酶的活性位点

【目的】研究长双歧杆菌(Bifidobacterium longum)JCM1217的N-乙酰氨基己糖1-位激酶(Nacetylhexosamine 1-kinase,Nah K)中对催化活性有影响的位点。【方法】利用点突变试剂盒,获得Nah K的4个位点的共10种单点突变体表达菌株。诱导表达并纯化野生型和突变体酶,用DNS法和NADH偶联的微孔板分光光度法检测野生型及突变体酶的最适p H和最适Mg~(2+)浓度,并测定酶促反应动力学参数。【结果】D208A、D208N、D208E和I24A四种突变体的催化活性几乎丧失。突变体H31A、H31V、F247A和I24V的最适p H由野生型的7.5变为7.0,突变体H31A和F247A的最适Mg~(2+)浓度由野生型的5 mmol/L变为10 mmol/L。反应动力学参数测定结果表明,突变体F247Y对底物Glc NAc/Gal NAc及ATP的催化活性均高于野生型。【结论】通过定点突变,确定了对Nah K催化活性有影响的4个位点,并且获得了一个催化效率提高的突变体(F247Y),为进一步对Nah K进行分子改造奠定了一定基础。     

Relative substrate affinities of wild-type and mutant forms of the Escherichia coli sugar transporter GalP determined by solid-state NMR

Solid-state nuclear magnetic resonance (SSNMR) spectroscopy is used for the first time to examine the relative substrate-binding affinities of mutant forms of the Escherichia coli sugar transporter GalP in membrane preparations. The SSNMR method of ¹³C cross-polarization magic-angle spinning (CP-MAS) is applied to five site-specific mutants (W56F, W239F, R316W, T336Y and W434F), which have a range of different sugar-transport activities compared to the wild-type protein. It is shown that binding of the substrate D-glucose can be detected independently of sugar transport activity using SSNMR, and that the NMR peak intensities for uniformly ¹³C-labelled glucose are consistent with wild-type GalP and the mutants having different affinities for the substrate. The W239F and W434F mutants showed binding affinities similar to that of the wild-type protein, whereas the affinity of glucose-binding to the W56F mutant was reduced. The R316W mutant showed no detectable binding; this position corresponds to the second basic residue in the highly conserved (R/K)XGR(R/K) motif in the major facilitator superfamily of transport proteins and to a mutation in human GLUT1 found in individuals with GLUT1-deficiency syndrome. The T336Y mutant also showed no detectable binding; this mutation is likely to have perturbed helix structure or packing to an extent that conformational changes in the protein are hindered. The effects of the mutations on substrate-binding are discussed with reference to the putative positions of the residues in a 3D homology model of GalP based on the X-ray crystal structure of the E. coli glycerol-3-phosphate transporter GlpT.     

Surface interactions in the complex between cytochrome f and the E43Q/D44N and E59K/E60Q plastocyanin double mutants as determined by 1H-NMR chemical shift analysis

A combination of site-directed mutagenesis and NMR chemical shift perturbation analysis of backbone and side-chain protons has been used to characterize the transient complex of the photosynthetic redox proteins plastocyanin and cytochrome f. To elucidate the importance of charged residues on complex formation, the complex of cytochrome f and E43Q/D44N or E59K/E60Q spinach plastocyanin double mutants was studied by full analysis of the (1)H chemical shifts by use of two-dimensional homonuclear NMR spectra. Both mutants show a significant overall decrease in chemical shift perturbations compared with wild-type plastocyanin, in agreement with a large decrease in binding affinity. Qualitatively, the E43Q/D44N mutant showed a similar interaction surface as wild-type plastocyanin. The interaction surface in the E59K/E60Q mutant was distinctly different from wild type. It is concluded that all four charged residues contribute to the affinity and that residues E59 and E60 have an additional role in fine tuning the orientation of the proteins in the complex.     

Probing enzyme–substrate interactions at the catalytic subsite of Leuconostoc mesenteroides sucrose phosphorylase with site-directed mutagenesis: the roles of Asp49 and Arg395

Abstract

Sucrose phosphorylase is a bacterial α-transglucosidase that catalyses glucosyl transfer from sucrose to phosphate, releasing d-fructose and α-d-glucose 1-phosphate as the product of the first (enzyme glucosylation) and second (enzyme deglucosylation) step of the enzymatic reaction, respectively. The transferred glucosyl moiety of sucrose is accommodated at the catalytic subsite of the phosphorylase through a network of charged hydrogen bonds whereby a highly conserved residue pair of Asp and Arg points towards the equatorial hydroxyl at C₄. To examine the role of this ‘hyperpolar’ binding site for the substrate 4-OH, we have mutated Asp⁴⁹ and Arg³⁹⁵ of Leuconostoc mesenteroides sucrose phosphorylase individually to Ala (D49A) and Leu (R395L), respectively, and also prepared an ‘uncharged’ double mutant harbouring both site-directed substitutions. The efficiency for enzyme glucosylation from sucrose was massively decreased in purified preparations of D49A (10⁷-fold) and R395L (10⁵-fold) as compared to wild-type enzyme. The double mutant was not active above the detection limit. Enzyme deglucosylation to phosphate proceeded relatively efficient in D49A as well as R395L, about 500-fold less than in the wild-type phosphorylase. Substrate inhibition by phosphate and a loss in selectivity for reaction with phosphate as compared to water were new features in the two mutants. Asp⁴⁹ and Arg³⁹⁵ are both essential in the catalytic reaction of L. mesenteroides sucrose phosphorylase.     

Alteration of coenzyme specificity in halophilic NAD(P) glucose dehydrogenase by site-directed mutagenesis

Structural analysis of glucose dehydrogenase from Haloferax mediterranei revealed that the adenosine 2′-phosphate of NADP⁺ was stabilized by the side chains of Arg207 and Arg208. To investigate the structural determinants for coenzyme specificity, several mutants involving residues Gly206, Arg207 and Arg208 were engineered and kinetically characterized. The single mutants G206D and R207I were less efficient with NADP⁺ than the wild type, and the double and triple mutants G206D/R207I and G206D/R207I/R208N showed no activity with NADP⁺.In the single mutant G206D, the relation k_cat/K_NAD⁺ was 1.6 times higher than in the wild type, resulting in an enzyme that preferred NAD⁺ over NADP⁺. The single mutation was sufficient to modify coenzyme specificity, whereas other dehydrogenases usually required more than one or two mutations to change coenzyme specificity. However, the highest reaction rates were reached with the double mutant G206D/R207I and with coenzyme NAD⁺, where the k_cat was 1.6 times higher than the k_cat of the wild-type enzyme with NADP⁺. However, catalytic efficiency with NAD⁺ was lower, as the K_m value for coenzyme was 77 times higher than the wild type with NADP⁺.     

Functional aberration of myofibrils by cardiomyopathy-causing mutations in the coiled-coil region of the troponin-core domain

Two cardiomyopathy-causing mutations, E244D and K247R, in human cardiac troponin T (TnT) are located in the coiled-coil region of the Tn-core domain. To elucidate effects of mutations in this region on the regulatory function of Tn, we measured Ca²⁺-dependent ATPase activity of myofibrils containing various mutants of TnT at these residues. The results confirmed that the mutant E244D increases the maximum ATPase activity without changing the Ca²⁺-sensitivity. The mutant K247R was shown for the first time to have the effect similar to the mutant E244D. Furthermore, various TnT mutants (E244D, E244M, E244A, E244K, K247R, K247E, and K247A) showed various effects on the maximum ATPase activity while the Ca²⁺-sensitivity was unchanged. Molecular dynamics simulations of the Tn-core containing these TnT mutants suggested that the hydrogen-bond network formed by the side chains of neighboring residues around residues 244 and 247 is important for Tn to function properly.     

Identification of glutamate residues important for catalytic activity of Bacillus stearothermophilus leucine aminopeptidase II

Each of four conserved glutamate residues of Bacillus stearothermophilus leucine aminopeptidase II (BsLAPII) was replaced with aspartate, lysine, and leucine respectively by site-directed mutagenesis. The over-expressed wild-type and mutant enzymes were purified to homogeneity by nickel-chelate chromatography and the molecular mass of the subunit was determined to be 44.5 kDa by SDS-PAGE. The specific activity for the Glu-316 and Glu-340 mutants was completely abolished, while Glu-249 mutants showed comparable activity to that of the wild-type BsLAPII. Compared with the wild-type enzyme, the E250D and E250L mutant enzymes retained less than 18% of the enzyme activity and exhibited a dramatic decrease in the value of k _cat/K _m. These observations indicate that Glu-250, Glu-316, and Glu-340 residues are critical for the catalytic activity of BsLAPII.