An absolute requirement of fructose 1,6-bisphosphate for the Lactobacillus casei L-lactate dehydrogenase activity induced by a single amino acid substitution

Lactobacillus casei allosteric L-lactate dehydrogenase (L-LDH) absolutely requires fructose 1,6-bisphosphate [Fru(1,6)P2] for its catalytic activity under neutral conditions, but exhibits marked catalytic activity in the absence of Fru(1,6)P(2) under acidic conditions through the homotropic activation effect of substrate pyruvate. In this enzyme, a single amino acid replacement, i.e. that of His205 conserved in the Fru(1,6)P(2)-binding site of certain allosteric L-LDHs of lactic acid bacteria with Thr, did not induce a marked loss of the activation effect of Fru(1,6)P(2) or divalent metal ions, which are potent activators that improve the activation function of Fru(1,6)P(2) under neutral conditions. However, this replacement induced a great loss of the Fru(1,6)P(2)-independent activation effect of pyruvate or pyruvate analogs under acidic conditions, consequently indicating an absolute Fru(1,6)P(2) requirement for the enzyme activity. The replacement also induced a significant reduction in the pH-dependent sensitivity of the enzyme to Fru(1,6)P(2), through a slight decrease and increase of the Fru(1,6)P(2) sensitivity under acidic and neutral conditions, respectively, indicating that His205 is also largely involved in the pH-dependent sensitivity of L.casei L-LDH to Fru(1,6)P(2). The role of His205 in the allosteric regulation of the enzyme is discussed on the basis of the known crystal structures of L-LDHs.     

Site-directed mutagenesis identifies catalytic residues in the active site of Escherichia coli phosphofructokinase.

Six active site mutants of Escherichia coli phosphofructokinase have been constructed and characterized using steady-state kinetics. All but one of the mutants (ES222) have significantly lower maximal activity, implicating these residues in the catalytic process. Replacement of Asp127, the key catalytic residue in the forward reaction with Glu, results in an enzyme with wild-type cooperative and allosteric behavior but severely decreased Fru6P binding. Replacement of the same residue with Tyr abolishes cooperativity while retaining sensitivity to allosteric inhibition and activation. Thus, this mutant has uncoupled homotropic from heterotropic allostery. Mutation of Asp103 to Ala results in an enzyme which retains wild-type Fru6P-binding characteristics with reduced activity. GDP, which allosterically activates the wild-type enzyme, acts as a mixed inhibitor for this mutant. Mutation of Thr125 to Ala and Asp129 to Ser produces mutants with impaired Fru6P binding and decreased cooperativity. In the presence of the activator GDP, both these mutants display apparent negative cooperativity. In addition, ATP binding is now allosterically altered by GDP. These results extend the number of active site residues known to participate in the catalytic process and help to define the mechanisms behind catalysis and homotropic and heterotropic allostery.     

Biosynthesis of bacterial glycogen. Determination of the amino acid changes that alter the regulatory properties of a mutant Escherichia coli ADP-glucose synthetase

The ADP-glucose synthetase of Escherichia coli K12 mutant 618 has a higher apparent affinity for the activator, fructose 1,6-P2 and a lower apparent affinity for the inhibitor, 5'-AMP, than the normal enzyme. The structural gene, glgC, of the mutant enzyme has been cloned and sequenced (Lee, Y. M., Kumar, A., and Preiss, J. (1987) Nucleic Acids Res. 15, 10603). Substitutions in the mutant enzyme were amino acid residues 296 (Lys to Glu) and 336 (Gly to Asp). Single mutant enzymes, Glu296 and Asp336, were constructed using oligonucleotide-directed mutagenesis. The Glu296 enzyme had the same allosteric kinetic constants as the wild type enzyme. The Asp336 enzyme was catalytically defective. Thus, the mutations at 296 and at 336 separately could not account for the allosteric alterations of the mutant enzyme. A hybrid glgC gene was prepared from genes of wild type and mutant 618 glgC using DNA recombinant techniques. The C-terminal portion of mutant 618 containing Glu296 and Asp336, combined with the N-terminal portion of wild type enzyme, showed allosteric and substrate kinetics similar to mutant 618 enzyme. Thus, alteration of the normal allosteric properties in mutant 618 are due to changes of both Lys296 to Glu and Gly336 to Asp.     

干酪乳杆菌L-乳酸脱氢酶在大肠杆菌中的表达、纯化及酶学性质

L-乳酸脱氢酶(L-lactate dehydrogenase,L-LDH)是发酵生产L-乳酸中催化丙酮酸转化成L-乳酸的关键酶。以干酪乳杆菌G-02(Lactobacillus casei G-02)基因组DNA为模板,克隆得到L-LDH基因(ldhL),经序列分析后将其连接到表达载体pET-28a(+)上,构建成重组质粒pET-ldhL转化到大肠杆菌BL21(DE3)中,实现ldhL基因的表达。30°C加入IPTG诱导表达后,经镍柱亲和层析纯化的重组蛋白样品通过SDS-PAGE分析,约在40 kD处出现显著的特异性条带。对表达的L-LDH生物学特异性研究显示:重组L-LDH的比酶活为1 722 U/mg,最适反应温度为40°C-45°C;果糖-1,6-二磷酸(FBP)为别构激活剂,使最适pH向中性方向偏移(pH为6.6-6.8),Mn2+可拓宽最适酶活pH范围;Mn2+、Ca2+和Mg2+对L-LDH有激活作用,而Zn2+对L-LDH有抑制作用。     

cDNA sequence and kinetic properties of human lung fructose(1, 6)bisphosphatase

A cDNA encoding fructose(1,6)bisphosphatase was isolated from total human lung RNA. The cDNA contained an open reading frame encoding 337 amino acids. The determined nucleotide sequence of the lung cDNA was significantly different from muscle cDNA and slightly differed from human liver cDNA in a single mutation (Gly-336 for Ala-336) and a T for C substitution in position 648. The human lung fructose(1, 6)bisphosphatase [Fru(1,6)Pase] was isolated and its kinetic parameters were compared with liver and muscle isoenzymes. Values of kcat for the lung Fru(1,6)Pase were lower than for the liver and muscle enzyme. Like the liver isoenzyme, lung Fru(1,6)Pase is significantly less inhibited by AMP than the muscle enzyme. The values of I0.5 were 9.5, 9.8, and 0.3 microM for the liver, lung, and muscle enzyme, respectively. The lung enzyme was slightly more sensitive to fructose(2,6)bisphosphate [Fru(2,6)P2] inhibition than the liver enzyme. Ki was 75 microM for the lung and 96 microM for the liver enzyme. The synergistic effect of AMP and Fru(2,6)P2 on the lung and liver Fru(1,6)Pase was also observed. In the presence of AMP the corresponding values of Ki for Fru(2,6)P2 were 16 microM for the lung and 10 microM for the liver enzyme.     

The cooperative binding of fructose-1,6-bisphosphate to yeast pyruvate kinase.

The cooperative binding of the allosteric activator fructose-1,6-bisphosphate [Fru(1,6)P2] to yeast pyruvate kinase was investigated by equilibrium dialysis and fluorescence quench titration. The results show that yeast pyruvate kinase binds four molecules of Fru(1,6)P2 per tetramer and the observed fluorescence quench follows the binding of the ligand and not the cooperative T to R state transition. Additionally it is shown that the binding of Fru(1,6)P2 to yeast pyruvate kinase is compatible with the model of cooperativity that has been proposed and incorporates an intermediate state, R', with properties between those of the T and R states.     

Purification of the fructose 1,6-bisphosphate-dependent lactate dehydrogenase from Streptococcus uberis and an investigation of its existence in different forms.

The fructose 1,6-bisphosphate [Fru(1,6)P2]-dependent lactate dehydrogenase in cells of Streptococcus uberis N.C.D.O. 2039 was purified by a procedure that included chromatography on DEAE-cellulose and Blue Sepharose CL-6B in phosphate buffers. The enzyme appeared to interact with Blue Sepharose through NADH-binding sites. The homogeneous enzyme had catalytic properties that were generally similar to those of other Fru(1,6)P2-dependent lactate dehydrogenases, and it had no catalytic activity in the absence of Fru(1,6)P2. Its existence in different forms, depending on conditions, was investigated by ultracentrifugation, analytical gel filtration and activity measurements. It consisted of subunits with Mr 35,900 +/- 500 and, in the presence of adequate concentrations of Fru(1,6)P2, phosphate or NADH, it existed as a tetramer, whereas when these ligands were in lower concentrations or absent, the subunits were in a concentration-dependent association-dissociation equilibrium. Dissociation occurred slowly and inactivated the enzyme, and although added ligands reversed the dissociation, the lost activity was at best only partly restored. An exception occurred when dissociation was caused by a decrease in temperature, in which case the lost activity was fully restored at the original temperature. The tetramer also lost activity at certain ligand concentrations without dissociating. The results together indicated the presence on the enzyme of two classes of binding site for both Fru(1,6)P2 and NADH, and the likelihood that phosphate bound at the same sites as Fru(1,6)P2. Two different ligands together were much more effective at preventing inactivation and dissociation than was expected from their effectiveness when present separately. It was concluded that tetrameric forms of the enzyme rather than the enzyme in association-dissociation equilibrium were involved in the regulation of its activity in vivo.     

Identification of catalytic and substrate-binding site residues in Bacillus cereus ATCC7064 oligo-1,6-glucosidase.

Three active site residues (Asp199, Glu255, Asp329) and two substrate-binding site residues (His103, His328) of oligo-1,6-glucosidase (EC 3.2.1.10) from Bacillus cereus ATCC7064 were identified by site-directed mutagenesis. These residues were deduced from the X-ray crystallographic analysis and the comparison of the primary structure of the oligo-1,6-glucosidase with those of Saccharomyces carlsbergensis alpha-glucosidase, Aspergillus oryzae alpha-amylase and pig pancreatic alpha-amylase which act on alpha-1,4-glucosidic linkages. The distances between these putative residues of B. cereus oligo-1,6-glucosidase calculated from the X-ray analysis data closely resemble those of A. oryzae alpha-amylase and pig pancreatic alpha-amylase. A single mutation of Asp199-->Asn, Glu255-->Gln, or Asp329-->Asn resulted in drastic reduction in activity, confirming that three residues are crucial for the reaction process of alpha-1,6-glucosidic bond cleavage. Thus, it is identified that the basic mechanism of oligo-1,6-glucosidase for the hydrolysis of alpha-1,6-glucosidic linkage is essentially the same as those of other amylolytic enzymes belonging to Family 13 (alpha-amylase family). On the other hand, mutations of histidine residues His103 and His328 resulted in pronounced dissimilarity in catalytic function. The mutation His328-->Asn caused the essential loss in activity, while the mutation His103-->Asn yielded a mutant enzyme that retained 59% of the k0/Km of that for the wild-type enzyme. Since mutants of other alpha-amylases acting on alpha-1,4-glucosidic bond linkage lost most of their activity by the site-directed mutagenesis at their equivalent residues to His103 and His328, the retaining of activity by His103-->Asn mutation in B. cereus oligo-1,6-glucosidase revealed the distinguished role of His103 for the hydrolysis of alpha-1,6-glucosidic bond linkage.     

Individual metal ligands play distinct functional roles in the zinc sensor Staphylococcus aureus CzrA

Recent studies on metalloregulatory proteins suggest that coordination number/geometry and metal ion availability in a host cytosol are key determinants for biological specificity. Here, we investigate the contribution that individual metal ligands of the alpha5 sensing site of Staphylococcus aureus CzrA (Asp84, His86, His97', and His100') make to in vitro metal ion binding affinity, coordination geometry, and allosteric negative regulation of DNA operator/promoter region binding. All ligand substitution mutants exhibit significantly reduced metal ion binding affinity (K(Me)) by > or =10(3) M(-1). Substitutions of Asp84 and His97 give rise to non-native coordination geometries upon metal binding and are non-functional in allosteric coupling of metal and DNA binding (DeltaG(coupling) approximately 0 kcal mol(-1)). In contrast, His86 and His100 could be readily substituted with potentially liganding (Asp, Glu) and poorly liganding (Asn, Gln) residues with significant native-like tetrahedral metal coordination geometry retained in these mutants, leading to strong functional coupling (DeltaG(coupling) > or = +3.0 kcal mol(-1)). 1H-(15)N heteronuclear single quantum coherence (HSQC) spectra of wild-type and mutant CzrAs reveal that all H86 and H100 substitution mutants undergo 4 degrees structural switching on binding Zn(II), while D84N, H97N and H97D CzrAs do not. Thus, only those variant CzrAs that retain some tetrahedral coordination geometry characteristic of wild-type CzrA upon metal binding are capable of driving 4 degrees structural conformational changes linked to allosteric regulation of DNA binding in vitro, irrespective of the magnitude of K(Me).     

Spontaneous chemical reversion of an active site mutation: deamidation of an asparagine residue replacing the catalytic aspartic acid of glutamate dehydrogenase

A mutant (D165N) of clostridial glutamate dehydrogenase (GDH) in which the catalytic Asp is replaced by Asn surprisingly showed a residual 2% of wild-type activity when purified after expression in Escherichia coli at 37 degrees C. This low-level activity also displayed Michaelis constants for substrates that were remarkably similar to those of the wild-type enzyme. Expression at 8 degrees C gave a mutant enzyme preparation 1000 times less active than the first preparation, but progressively, over 2 weeks' incubation at 37 degrees C in sealed vials, this enzyme regained 90% of the specific activity of wild type. This suggested that the mutant might undergo spontaneous deamidation. Mass spectrometric analysis of tryptic peptides derived from D165N samples treated in various ways showed (i) that the Asn is in place in D165N GDH freshly prepared at 8 degrees C; (ii) that there is a time-dependent reversion of this Asn to Asp over the 2-week incubation period; (iii) that detectable deamidation of other Asn residues, in Asn-Gly sequences, mainly occurred in sample workup rather than during the 2-week incubation; (iv) that there is no significant deamidation of other randomly chosen Asn residues in this mutant over the same period; and (v) that when the protein is denatured before incubation, no deamidation at Asn-165 is detectable. It appears that this deamidation depends on the residual catalytic machinery of the mutated GDH active site. A literature search indicates that this finding is not unique and that Asn may not be a suitable mutational replacement in the assessment of putative catalytic Asp residues by site-directed mutagenesis.     

Different sensitivities of mutants and chimeric forms of human muscle and liver fructose-1,6-bisphosphatases towards AMP

AMP is an allosteric inhibitor of human muscle and liver fructose-1,6-bisphosphatase (FBPase). Despite strong similarity of the nucleotide binding domains, the muscle enzyme is inhibited by AMP approximately 35 times stronger than liver FBPase: I0.5 for muscle and for liver FBPase are 0.14 microM and 4.8 microM, respectively. Chimeric human muscle (L50M288) and chimeric human liver enzymes (M50L288), in which the N-terminal residues (1-50) were derived from the human liver and human muscle FBPases, respectively, were inhibited by AMP 2-3 times stronger than the wild-type liver enzyme. An amino acid exchange within the N-terminal region of the muscle enzyme towards liver FBPase (Lys20-->Glu) resulted in 13-fold increased I0.5 values compared to the wild-type muscle enzyme. However, the opposite exchanges in the liver enzyme (Glu20-->Lys and double mutation Glu19-->Asp/Glu20-->Lys) did not change the sensitivity for AMP inhibition of the liver mutant (I0.5 value of 4.9 microM). The decrease of sensitivity for AMP of the muscle mutant Lys20-->Glu, as well as the lack of changes in the inhibition by AMP of liver mutants Glu20-->Lys and Glu19-->Asp/Glu20-->Lys, suggest a different mechanism of AMP binding to the muscle and liver enzyme.     

Phosphofructokinase type 1 kinetics, isoform expression, and gene polymorphisms in cancer cells

Kinetic analysis of PFK-1 from rodent AS-30D, and human HeLa and MCF-7 carcinomas revealed sigmoidal [fructose 6-phosphate, Fru6P]-rate curves with different V(m) values when varying the allosteric activator fructose 2,6 bisphosphate (Fru2,6BP), AMP, Pi, NH(4)(+), or K(+). The rate equation that accurately predicted this behavior was the exclusive ligand binding concerted transition model together with non-essential hyperbolic activation. PFK-1 from rat liver and heart also exhibited the mixed cooperative-hyperbolic kinetic behavior regarding activators. Lowering pH induced decreased affinity for Fru6P, Fru2,6BP, citrate, and ATP (as inhibitor); as well as decreased V(m) and increased content of inactive (T) enzyme forms. High K(+) prompted increased (Fru6P) or decreased (activators) affinities; increased V(m); and increased content of active (R) enzyme forms. mRNA expression analysis and nucleotide sequencing showed that the three PFK-1 isoforms L, M, and C are transcribed in the three carcinomas. However, proteomic analysis indicated the predominant expression of L in liver, of M in heart and MCF-7 cells, of L>M in AS-30D cells, and of C in HeLa cells. PFK-1M showed the highest affinities for F6P and citrate and the lowest for ATP (substrate) and F2,6BP; PFK-1L showed the lowest affinity for F6P and the highest for F2,6BP; and PFK-1C exhibited the highest affinity for ATP (substrate) and the lowest for citrate. Thus, the present work documents the kinetic signature of each PFK-1 isoform, and facilitates the understanding of why this enzyme exerts significant or negligible glycolysis flux-control in normal or cancer cells, respectively, and how it regulates the onset of the Pasteur effect.     

Identification of Catalytic and Substrate-binding Site Residues in Bacillus cereus ATCC7064 Oligo-1,6-glucosidase

Three active site residues (Asp199, Glu255, Asp329) and two substrate-binding site residues (His103, His328) of oligo-1,6-glucosidase (EC 3.2.1.10) from Bacillus cereus ATCC7064 were identified by site-directed mutagenesis. These residues were deduced from the X-ray crystallographic analysis and the comparison of the primary structure of the oligo-1,6-glucosidase with those of Saccharomyces carlsbergensis α-glucosidase, Aspergillus oryzae α-amylase and pig pancreatic α-amylase which act on α-1,4-glucosidic linkages. The distances between these putative residues of B. cereus oligo-1,6-glucosidase calculated from the X-ray analysis data closely resemble those of A. oryzae α-amylase and pig pancreatic α-amylase. A single mutation of Asp199→Asn, Glu255→Gln, or Asp329→Asn resulted in drastic reduction in activity, confirming that three residues are crucial for the reaction process of α-1,6-glucosidic bond cleavage. Thus, it is identified that the basic mechanism of oligo-1,6-glucosidase for the hydrolysis of α-1,6-glucosidic linkage is essentially the same as those of other amylolytic enzymes belonging to Family 13 (α-amylase family). On the other hand, mutations of histidine residues His103 and His328 resulted in pronounced dissimilarity in catalytic function. The mutation His328→Asn caused the essential loss in activity, while the mutation His103→Asn yielded a mutant enzyme that retained 59% of the κ₀/K_m of that for the wild-type enzyme. Since mutants of other α-amylases acting on α-1,4-glucosidic bond linkage lost most of their activity by the site-directed mutagenesis at their equivalent residues to His103 and His328, the retaining of activity by Hisl03→Asn mutation in B. cereus oligo-1,6-glucosidase revealed the distinguished role of His103 for the hydrolysis of α-1,6-glucosidic bond linkage.     

Charged residues on a flap-loop structure of Lactococcus lactis prolidase play critical roles in allosteric behavior and substrate inhibition

Allosteric behavior and substrate inhibition are unique characteristics of Lactococcus lactis prolidase. We hypothesized that charged residues (Asp36, His38, Glu39, and Arg40), present on one loop essential for catalysis, interact with residues in or near the active site to impart these unique characteristics. Asp36 has a predominant role in the allosteric behavior, as demonstrated through the non-allosteric behavior of the D36S mutant enzyme. In contrast, a double mutant (D36E/R293K) maintained the allostery, indicating that this aspartic acid residue interacts with Arg293, previously shown to be critical in the allostery. Substitution of His38 drastically reduced the substrate inhibition, and substrate specificity of the mutant at Asp36 or His38 showed the influence of these residues to the substrate specificity. These findings confirm the importance of the loop in the enzymatic reaction mechanism and suggest the existence of conformational changes of the loop structure between open and closed states. A variety of mutations at Glu39 and Arg40 showed that these residues influence roles of the loop in the enzyme reaction. On the basis of these results and combined with observations of molecular models of this prolidase, we concluded that Asp36 and His38 interact with the residues in the active site to generate an allosteric subsite and a pseudo-S(1)' site, which are responsible for the allosteric behavior and substrate inhibition.     

Molecular characterization of a phosphoenolpyruvate carboxylase from a thermophilic cyanobacterium, Synechococcus vulcanus with unusual allosteric properties

A gene for phosphoenolpyruvate carboxylase (PEPC) was isolated from a thermophilic cyanobacterium, Synechococcus vulcanus, by screening a genomic DNA library using the coding region of Anacystis nidulans 6301 PEPC as a probe. The S. vulcanus PEPC gene (SvPEPC) had an open reading frame for a polypeptide of 1,011 amino acid residues with a calculated molecular mass of 116.4 kDa. SvPEPC was expressed in E. coli BL21 Codonplus (DE3), using pET32a as a vector. The purified recombinant SvPEPC protein with a tag showed a single band of 120 kDa on SDS-PAGE. The enzyme forms homotetramer as judged by gel filtration. SvPEPC retained full activity even after incubation at 50 degrees C for 60 min or exposure to 0.5 M guanidine-HCl at 30 degrees C for 20 h, being more stable than C4-form PEPC from Zea mays (ZmPEPC(C4)). SvPEPC activity showed a sharp optimum temperature of 42 degrees C at pH 7.5 and an optimum pH of 9.0 at 30 degrees C. The enzyme, unlike most plant PEPCs, was predominantly activated by fructose 1,6-bisphosphate (Fruc-1,6-P(2)), and slightly stimulated by 3-phosphoglycerate (3-PGA), glucose 6-phosphate (Gluc-6-P), glucose 1-phosphate, Glu and Gln. Acetyl-CoA known as a strong activator of most bacterial PEPCs but not of plant PEPCs, showed no effect on the enzyme activity. SvPEPC was more sensitive to the inhibition by Asp at higher pH (9.0) than lower pH (7.0), contrary to Coccochloris peniocystis PEPC and plant PEPCs. I(0.5) for Asp was increased about 2-fold by Gluc-6-P while markedly decreased by Fruc-1,6-P(2), Glu and Gln about 3- to 4-fold. The regulation mechanism of SvPEPC is not readily interpretable by conventional allosteric models.     

蛇肌果糖1，6－二磷酸酯酶果糖2，6－二磷酸和底物抑制的结合部位

在果糖１,６—二磷酸酯酶中果糖２,６—二磷酸可能与底物抑制的作用方式不同,因为蛇肌果糖１,６－二磷酸酯酶ｐＨ９．２的活性受到果糖２,６－二磷酸的抑制,而不受高浓度底物的影响。Ｋ＋能增强果糖２,６—二磷酸对酶活性抑制,并能较大程度地解除过量底物的抑制。快反应流基修饰酶不再受较低浓度果糖２,６—二磷酸的抑制,但高浓度果糖２,６—二磷酸仍能抑制酶活性,其ＩＣ５０增大４０倍。修饰酶受底物抑制的阈值不变。为胰蛋白酶或枯草杆菌蛋白酶限制性酶解的果糖１,６—二磷酸酯酶受过量底物和果糖２,６—二磷酸抑制的行为也不相同。以上结果可能提示在蛇肌果糖１,６—二磷酸酯酸中存在既有别于ＡＭＰ,又有别于过量底物的结合部位。     

A single amino acid substitution deregulates a bacterial lactate dehydrogenase and stabilizes its tetrameric structure

We have engineered a variant of the lactate dehydrogenase enzyme from Bacillus stearothermophilus in which arginine-173 at the proposed regulatory site has been replaced by glutamine. Like the wild-type enzyme, this mutant undergoes a reversible, protein-concentration-dependent subunit assembly, from dimer to tetramer. However, the mutant tetramer is much more stable (by a factor of 400) than the wild type and is destabilized rather than stabilized by binding the allosteric regulator, fructose 1,6-biphosphate (Fru-1,6-P2). The mutation has not significantly changed the catalytic properties of the dimer (Kd NADH, Km pyruvate, Ki oxamate and kcat), but has weakened the binding of Fru-1,6-P2 to both the dimeric and tetrameric forms of the enzyme and has almost abolished any stimulatory effect. We conclude that the Arg-173 residue in the wild-type enzyme is directly involved in the binding of Fru-1,6-P2, is important for allosteric communication with the active site, and, in part, regulates the state of quaternary structure through a charge-repulsion mechanism.     

Steady-state fluorescence of Escherichia coli phosphofructokinase reveals a regulatory role for ATP.

We have investigated the effects of ligands and effectors on the intrinsic fluorescence of Escherichia coli phosphofructokinase (PFK). We have found that the substrate fructose 6-phosphate (Fru6P) or the allosteric activator ADP can quench the fluorescence up to 35%. The response is hyperbolic with Ks[Fru6P] of 20 microM and Ks[ADP] of 13 microM. The allosteric inhibitor phosphoenolpyruvate (PEP) converts the hyperbolic response with respect to Fru6P to a sigmoidal response. AMP-PNP, a nonhydrolyzable analogue of ATP, also inhibits the Fru6P fluorescence response. PFK mutant KA213, which is insensitive to effectors, has a decreased fluorescence response with respect to ADP, and PEP does not convert the Fru6P response to sigmoidicity. However, its fluorescence response with respect to Fru6P is decreased by ATP or AMP-PNP. Taken together, these results suggest that, in the absence of effectors or ligands, E. coli PFK exists in a state with high affinity for Fru6P ("R" state). This state can be altered to a low affinity ("T" state) by PEP binding to the allosteric site or by ATP binding to the enzyme.     

The C1-C2 interface residue lysine 50 of pig kidney fructose-1, 6-bisphosphatase has a crucial role in the cooperative signal transmission of the AMP inhibition.

To understand the mechanism of signal propagation involved in the cooperative AMP inhibition of the homotetrameric enzyme pig-kidney fructose-1,6-bisphosphatase, Arg49 and Lys50 residues located at the C1-C2 interface of this enzyme were replaced using site-directed mutagenesis. The mutant enzymes Lys50Ala, Lys50Gln, Arg49Ala and Arg49Gln were expressed in Escherichia coli, purified to homogeneity and the initial rate kinetics were compared with the wild-type recombinant enzyme. The mutants exhibited kcat, Km and I50 values for fructose-2,6-bisphosphate that were similar to those of the wild-type enzyme. The kinetic mechanism of AMP inhibition with respect to Mg2+ was changed from competitive (wild-type) to noncompetitive in the mutant enzymes. The Lys50Ala and Lys50Gln mutants showed a biphasic behavior towards AMP, with total loss of cooperativity. In addition, in these mutants the mechanism of AMP inhibition with respect to fructose-1,6-bisphosphate changed from noncompetitive (wild-type) to uncompetitive. In contrast, AMP inhibition was strongly altered in Arg49Ala and Arg49Gln enzymes; the mutants had > 1000-fold lower AMP affinity relative to the wild-type enzyme and exhibited no AMP cooperativity. These studies strongly indicate that the C1-C2 interface is critical for propagation of the cooperative signal between the AMP sites on the different subunits and also in the mechanism of allosteric inhibition of the enzyme by AMP.     

Kinetics of activation of L-lactate dehydrogenase from Streptococcus faecalis by fructose 1,6-bisphosphate and by metal ions

The lactate dehydrogenase from Streptococcus faecalis is activated either by fructose 1,6-bisphosphate or by divalent cations such as Mn2+ or Co2+. With both types of activator, a lag is observed before attainment of the steady state rate of pyruvate reduction if the activator is added to the enzyme at the same time as the substrates. This lag can be largely abolished by preincubation of enzyme with activator before mixing with substrates. For fructose 1,6-bisphosphate (Fru(1,6)P2) as the activator, the rate constant for the lag phase showed a linear dependence on activator concentration but was independent of enzyme concentration. This suggests that binding of fructose 1,6-bisphosphate induces a conformational change in the enzyme which leads to increased activity, without association of enzyme subunits or dimers. With Co2+ as activator, the rate constant for the lag phase showed a hyperbolic dependence on Co2+ concentration and was also dependent on enzyme concentration. This suggests that activation by Co2+, in contrast to that by Fru(1,6)P2, involves association of enzyme dimers, followed by ligand binding.