Effect of metal ions on the activity of the catalytic domain of calcineurin

Calcineurin (CN) is a heterodimer, composed of a catalytic subunit (CNA) and a regulatory subunit (CNB). There are four functional domains present in CNA, which are catalytic domain (CNa), CNB-binding domain (BBH), CaM-binding domain (CBH) and autoinhibitory domain (AI). It has been shown previously that the in vitro activity of calcineurin is relied primarily on the binding of metal ions. Mn2+ and Ni2+ are the most crucial cation-activators for this enzyme. In order to determine which domain(s) in CN is functionally regulated by metal ions, the rat CNA alpha subunit and its catalytic domain (CNa) were cloned and expressed in E. coli. The effects of Mn2+, Ni2+ and Mg2+ on the catalytic activity of these purified proteins were examined. Our results demonstrate that all the metal ions tested in this study activated either CNA or CNa. However, the activation degree of CNa by the metal ions was much higher than that of CNA. In term of different metal ions, the activating extents to CNA and CNa were different. To CNA, the activating order from high to low was Mg2+ > > Ni2+ > Mn2+, but Mn2+ > Ni2+ > > Mg2+ to CNa. No effect of CaM/Ca2+ and CNB/Ca2+ on the activity of CNa was observed in our experiments. Moreover, a weak interaction (or untight coordination binding) between metal ions and the enzyme molecule was also identified. These results suggest that the activation of these enzymes by the exogenous metal ions might be via both regulating fragment of CNA (including BBH, CBH and AI) and catalytic domain (CNa), and mainly via regulating fragment to CNA and mainly via catalytic domain to CNa. The activating extents of metal ions via catalytic domain were higher than that via regulating fragment. The results obtained in this study should be very useful for understanding the molecular mechanism underlying the interaction between calcineurin and metal ions, especially Mn2+, Ni2+ and Mg2+.     

The beta12-beta13 loop is a key regulatory element for the activity and properties of the catalytic domain of protein phosphatase 1 and 2B

The molecular architectures of the catalytic core of protein phosphatase 1 (PP1) and protein phosphatase 2B (PP2B) are similar, and both contain a beta12-beta13 loop that consists of non-conserved residues. A truncation mutant containing the PP2B catalytic domain has previously been constructed in our laboratory, and designated CNAa. In this study, the PP1 catalytic subunit (PP1c) and CNAa, as well as mutants with the corresponding loops exchanged, were investigated using multiple substrates. Deletion of the beta12-beta13 loop from Y272 to A279 of PP1c or from Y311 to K318 of CNAa resulted in inactive proteins. Loop exchange generated chimeric mutants called PP1-CNAa-loop and CNAa-PP1-loop. The activities and kinetic parameters of the two chimeric mutants were altered in the direction of the enzyme from which its loop was derived. The activity of PP1c or CNAa-PP1-loop was similar whether preincubated with Mn(2+) or not, while CNAa and PP1-CNAa-loop can acquire enhanced activation if preincubated with Mn(2+) for longer periods of time. Intrinsic fluorescence spectra revealed that the three-dimensional structure was altered as a result of exchanging the loops of PP1c and CNAa. In conclusion, the beta12-beta13 loop is one of the key regulatory elements in the catalytic domain for the activity and properties of PP1c and CNAa.     

The regulatory domains of CNA have different effects on the inhibition of CN activity by FK506 and CsA

Calcineurin (CN) is the common receptor for two immunophilin-immunosuppressant complexes, Cyp-CsA and FKBP-FK506. Calcineurin is composed of a catalytic subunit (CNA) and a regulatory subunit (CNB). CNA contains the catalytic domain and three regulatory domains: a CNB-binding domain (BBH, 350-370), a calmodulin- binding domain (CBD, 389-413), and an autoinhibitory domain (AID, 457-482). To investigate the effects of these three regulatory domains on the inhibition of CN by the two drugs we constructed three C-terminal deletion mutants: CNAabc (1-456), CNAab (1-388) and CNAa (1-347). Inhibition of CNA and its derivatives by the two drugs was examined and compared with inhibition by peptides (AID [457-482] and LCBD [389-456], CBD and the extension of the AID were included). Our results show that the BBH is critical for inhibition of CN by Cyp-CsA and FKBP-FK506. The LCBD has no effect and the AID reduces the inhibition of CN by two complexes. In addition, LCBD and AID as autoinhibitors may inhibit enzyme activity via different sites.     

A renewed model of CNA regulation involving its C-terminal regulatory domain and CaM

Calcineurin is composed of a catalytic subunit (CNA) and a regulatory subunit (CNB). CNA contains the catalytic domain and three regulatory domains: a CNB-binding domain (BBH), a C-terminal calmodulin-binding domain (CBD), and an autoinhibitory domain (AID). We constructed a series of mutants of CNA to explore the regulatory role of its C-terminal regulatory domain and CaM. We demonstrated a more precise mechanism of CNA regulation by C-terminal residues 389-511 in the presence of CNB. First, we showed that residues 389-413, which were identified in previous work as constituting a CaM binding domain (CBD), also have an autoinhibiting function. We also found that residues 389-413 were not sufficient for CaM binding and that the CBD comprises at least residues 389-456. In conclusion, two distinct segments of the C-terminal regulatory region (389-511) of CNA inhibit enzyme activity: residues 389-413 interact with the CNB binding helix (BBH), and residues 457-482 with the active center of CNA.     

Preparation and characterization of a single-chain calcineurin-calmodulin complex

Calcineurin (CN), a Ca(2+)/calmodulin (CaM)-dependent serine/threonine protein phosphatase, is a heterodimer composed of a catalytic subunit (CNA) and a regulatory subunit (CNB). The activity of CNA is under the control of two functionally distinct, but structurally similar Ca(2+)-regulated proteins, CaM and CNB. The crystal structure of the holoenzyme reveals that the N-terminus and C-terminus of CNB and the N-terminus of CNA each have a long arm not involved in the active site. We constructed a fusion of the genes of CaM, CNB and CNA in that order using linker primers containing six and ten codons of glycine. A single-chain CaM-CNB-CNA (CBA) complex was expressed and purified to near homogeneity. The single-chain complex was fully soluble, and had biochemical properties and kinetic parameters similar to single-chain CNB-CNA (BA) activated by CaM. It was not regulated by CaM and CNB, but was strongly stimulated by Mn2+, Ni2+ and Mg2+. Intrinsic fluorescence spectroscopy of the complex showed a change in the environment of tryptophan in the presence of Ca2+ and circular dichroism (CD) spectropolarimetry revealed an increase in alpha-helical content. Our findings suggest that fusion of CaM, CNB and CNA does not prevent the structural changes required for their functioning; in particular, CaM within the complex could still interact correctly with CN in the presence of Ca2+.     

Regulation of calcineurin phosphatase activity by its autoinhibitory domain

The Ca(2+)-dependent activation of calcineurin phosphatase activity is regulated by an autoinhibitory element (residues 457-482) located 43 residues COOH-terminal of the calmodulin-binding domain (residues 390-414). Removal of residues 457-482 does not result in full Ca(2+)/calmodulin-independent activity. Full activity in the absence of Ca(2+) requires the removal of residues 420-457. In the present study the presence of additional autoinhibitory elements within residues 420-457 was tested using two calcineurin A subunit COOH-terminal region constructs containing residues 420-511 (AI(420-511)) or 328-511 (AI(328-511)). Using recombinant, Ca(2+)/calmodulin-independent calcineurin, AI(420-511) and AI(328-511) were three- to fourfold more potent inhibitors of calcineurin phosphatase activity than the synthetic calcineurin autoinhibitory peptide(457-482). Calmodulin reversed the inhibition of calcineurin phosphatase activity by AI(328-511) but not AI(420-511). Kinetic studies indicated that AI(420-511) exhibited mixed-type inhibition and that the enzyme/substrate/inhibitor complex is partially active. These results indicate that (i) additional autoinhibitory elements are present within residues 420-457, (ii) calmodulin-binding to the autoinhibitory domain neutralizes the inhibitory function of the 420-457 autoinhibitory segment, (iii) the full-length autoinhibitory domain is a mixed-type inhibitor of calcineurin phosphatase activity, and (iv) the enzyme/substrate/inhibitor complex is partially catalytically active.     

Catalytic cycling in beta-phosphoglucomutase: a kinetic and structural analysis

Lactococcus lactis beta-phosphoglucomutase (beta-PGM) catalyzes the interconversion of beta-d-glucose 1-phosphate (beta-G1P) and beta-d-glucose 6-phosphate (G6P), forming beta-d-glucose 1,6-(bis)phosphate (beta-G16P) as an intermediate. Beta-PGM conserves the core domain catalytic scaffold of the phosphatase branch of the HAD (haloalkanoic acid dehalogenase) enzyme superfamily, yet it has evolved to function as a mutase rather than as a phosphatase. This work was carried out to identify the structural basis underlying this diversification of function. In this paper, we examine beta-PGM activation by the Mg(2+) cofactor, beta-PGM activation by Asp8 phosphorylation, and the role of cap domain closure in substrate discrimination. First, the 1.90 A resolution X-ray crystal structure of the Mg(2+)-beta-PGM complex is examined in the context of previously reported structures of the Mg(2+)-alpha-d-galactose-1-phosphate-beta-PGM, Mg(2+)-phospho-beta-PGM, and Mg(2+)-beta-glucose-6-phosphate-1-phosphorane-beta-PGM complexes to identify conformational changes that occur during catalytic turnover. The essential role of Asp8 in nucleophilic catalysis was confirmed by demonstrating that the D8A and D8E mutants are devoid of catalytic activity. Comparison of the ligands to Mg(2+) in the different complexes shows that a single Mg(2+) coordination site must alternatively accommodate water, phosphate, and the phosphorane intermediate during catalytic turnover. Limited involvement of the HAD family metal-binding loop in Mg(2+) anchoring in beta-PGM is consistent with the relatively loose binding indicated by the large K(m) for Mg(2+) activation (270 +/- 20 microM) and with the retention of activity found in the E169A/D170A double loop mutant. Comparison of the relative positions of cap and core domains in the different complexes indicated that interaction of cap domain Arg49 with the "nontransferring" phosphoryl group of the substrate ligand might stabilize the cap-closed conformation, as required for active site desolvation and alignment of Asp10 for acid-base catalysis. Kinetic analyses of the specificity of beta-PGM toward phosphoryl group donors and the specificity of phospho-beta-PGM toward phosphoryl group acceptors were carried out. The results support a substrate induced-fit mechanism of beta-PGM catalysis, which allows phosphomutase activity to dominate over the intrinsic phosphatase activity. Last, we present evidence that the autophosphorylation of beta-PGM by the substrate beta-G1P accounts for the origin of phospho-beta-PGM in the cell.     

Zinc inhibits calcineurin activity in vitro by competing with nickel

Calcineurin (CN) is a Ca(2+)/calmodulin (CaM)-dependent protein serine/threonine phosphatase that contains Zn(2+) in its catalytic domain and can be stimulated by divalent ions such as Mn(2+) and Ni(2+). In this study, the role of exogenous Zn(2+) in the regulation of CN activity and its relevance to the role of Ni(2+) was investigated. Zn(2+) at a concentration range of 10nM-10 micro M inhibited Ni(2+)-stimulated CN-activity in vitro in a dose-dependent manner and approximately 50% inhibition was attained with 0.25 micro M Zn(2+). Kinetic analysis showed that Zn(2+) inhibited the activity of CN by competing with Ni(2+). Interaction of CN and CaM was not inhibited with Zn(2+) at 10 micro M. Zn(2+) never affected the activity of cAMP phosphodiesterase 1 or myosin light-chain kinase (CaM-dependent enzymes) and rather activated alkaline phosphatase. The present results indicate that Zn(2+) should be a potent inhibitor for CN activity although this ion is essential for CN.     

Characterization of the fragmented forms of calcineurin produced by calpain I

Calcineurin, a calmodulin-stimulated phosphatase from bovine brain, was hydrolyzed by calpain I from human erythrocytes. In the absence of calmodulin, calpain rapidly transformed the 60-kilodalton (kDa) catalytic subunit of calcineurin into a transient 57-kDa fragment and thereafter a 43-kDa limit fragment. In the presence of calmodulin, the 60-kDa subunit was sequentially proteolyzed to a 55-kDa fragment and then a 49-kDa fragment. Upon proteolysis in the absence or presence of calmodulin, the p-nitrophenyl phosphatase activity (assayed in the presence of calmodulin) was increased by 300%. The 43- and the 49-kDa fragments were found to (i) remain associated with the small subunit (17 kDa), (ii) have lost the ability to bind and to be activated by calmodulin, and (iii) have phosphatase activity that was still stimulated by Mn2+ or Ni2+. The 43- + 17-kDa form had similar Km values for various substrates, but the Vmax values were increased compared with the native enzyme. It is proposed that (i) a 43-kDa core segment of the 60-kDa subunit of calcineurin contained the catalytic domain, the small subunit-binding domain, and the metal ion (Mn2+ and (or) Ni2+) binding site; and (ii) two distinct types of inhibitory domains exist near the end(s) of the large subunit, one of which is calmodulin regulated, while the other is calmodulin independent.     

The importance of Loop 7 for the activity of calcineurin

Calcineurin (CN) is a heterodimer composed of a catalytic subunit (CNA) and a regulatory subunit (CNB). Loop 7 lies within the CNA catalytic domain. To investigate the role of Loop 7 in enzyme activity, we systematically examined all its residues by site-directed deletion mutation. Our results show that the Loop 7 residues are important for enzyme activity. Besides deleting residues V314, Y315 or N316, enzyme activity also increased dramatically when residues D313 or K318 were deleted. In contrast, almost all activity was lost when L312 or N317 were deleted. Ni2+ and Mn2+ were effective activators for all active mutants. However, whereas the wild-type enzyme was more efficiently activated by Ni2+ than by Mn2+ with 32P-labeled R(II) peptide as substrate, the reverse was true in all the mutants. We also found that the effect of Loop 7 on enzyme activity was substrate dependent, and involved interactions between Loop 7 residues and the unresolved part of the CN crystal structure near the auto-inhibitory domain and catalytic site.     

General enzymatic screens identify three new nucleotidases in Escherichia coli. Biochemical characterization of SurE, YfbR, and YjjG

To find proteins with nucleotidase activity in Escherichia coli, purified unknown proteins were screened for the presence of phosphatase activity using the general phosphatase substrate p-nitrophenyl phosphate. Proteins exhibiting catalytic activity were then assayed for nucleotidase activity against various nucleotides. These screens identified the presence of nucleotidase activity in three uncharacterized E. coli proteins, SurE, YfbR, and YjjG, that belong to different enzyme superfamilies: SurE-like family, HD domain family (YfbR), and haloacid dehalogenase (HAD)-like superfamily (YjjG). The phosphatase activity of these proteins had a neutral pH optimum (pH 7.0-8.0) and was strictly dependent on the presence of divalent metal cations (SurE: Mn(2+) > Co(2+) > Ni(2+) > Mg(2+); YfbR: Co(2+) > Mn(2+) > Cu(2+); YjjG: Mg(2+) > Mn(2+) > Co(2+)). Further biochemical characterization of SurE revealed that it has a broad substrate specificity and can dephosphorylate various ribo- and deoxyribonucleoside 5'-monophosphates and ribonucleoside 3'-monophosphates with highest affinity to 3'-AMP. SurE also hydrolyzed polyphosphate (exopolyphosphatase activity) with the preference for short-chain-length substrates (P(20-25)). YfbR was strictly specific to deoxyribonucleoside 5'-monophosphates, whereas YjjG showed narrow specificity to 5'-dTMP, 5'-dUMP, and 5'-UMP. The three enzymes also exhibited different sensitivities to inhibition by various nucleoside di- and triphosphates: YfbR was equally sensitive to both di- and triphosphates, SurE was inhibited only by triphosphates, and YjjG was insensitive to these effectors. The differences in their sensitivities to nucleotides and their varied substrate specificities suggest that these enzymes play unique functions in the intracellular nucleotide metabolism in E. coli.     

Function and structure of N-terminal and C-terminal domains of calcineurin B subunit

Calcineurin (CN), a Ca2+/calmodulin-dependent protein phosphatase, plays a critical role in T-cell activation by regulating the activity of NF-AT. CN is a heterodimer consisting of a catalytic subunit (CNA) and a Ca2+-binding regulatory subunit (CNB). CNB is composed of two global domains: the C-terminal domain (DC) and the N-terminal domain (DN), each containing two Ca2+ binding sites. In this study, using purified DN and DC derived from constructed expression systems, we revealed that intact CNB and DC can stimulate the phosphatase activity of CNA, about 2.2 and 1.6 times the phosphatase activity of CNA alone, respectively; DN itself has little effect on the phosphatase activity of CNA. Fluorescence spectroscopy of an ANS-hydrophobic fluorescence probe shows that binding of Ca2+ to CNB, DC or DN leads to exposure of the hydrophobic surface of the proteins and that the hydrophobicity of CNB is the greatest, that of DC is less, and that of DN is the least. The hydrophobic surface of CNB may be an important structural basis for stimulating CN phosphatase activity.     

Mechanism of the phosphatase component of Clostridium thermocellum polynucleotide kinase-phosphatase

Polynucleotide kinase-phosphatase (Pnkp) from Clostridium thermocellum catalyzes ATP-dependent phosphorylation of 5'-OH termini of DNA or RNA polynucleotides and Ni(2+)/Mn(2+)-dependent dephosphorylation of 2',3' cyclic phosphate, 2'-phosphate, and 3'-phosphate ribonucleotides. CthPnkp is an 870-amino-acid polypeptide composed of three domains: an N-terminal module similar to bacteriophage T4 polynucleotide kinase, a central module that resembles the dinuclear metallo-phosphoesterase superfamily, and a C-terminal ligase-like adenylyltransferase domain. Here we conducted a mutational analysis of CthPnkp that identified 11 residues required for Ni(2+)-dependent phosphatase activity with 2'-AMP and 3'-AMP. Eight of the 11 CthPnkp side chains were also required for Ni(2+)-dependent hydrolysis of p-nitrophenyl phosphate. The ensemble of essential side chains includes the conserved counterparts (Asp187, His189, Asp233, Arg237, Asn263, His264, His323, His376, and Asp392 in CthPnkp) of all of the amino acids that form the dinuclear metal-binding site and the phosphate-binding site of bacteriophage lambda phosphatase. Three residues (Asp236, His264, and Arg237) required for activity with 2'-AMP or 3'-AMP were dispensable for Ni(2+)-dependent hydrolysis of p-nitrophenyl phosphate. Our findings, together with available structural information, provide fresh insights to the metallophosphoesterase mechanism, including the roles of His264 and Asp236 in proton donation to the leaving group. Deletion analysis defined an autonomous phosphatase domain, CthPnkp-(171-424).     

Expression and characterization of the catalytic domains of soluble guanylate cyclase: interaction with the heme domain

The catalytic domains (alpha(cat) and beta(cat)) of alpha1beta1 soluble guanylate cyclase (sGC) were expressed in Escherichia coli and purified to homogeneity. alpha(cat), beta(cat), and the alpha(cat)beta(cat) heterodimeric complex were characterized by analytical gel filtration and circular dichroism spectroscopy, and activity was assessed in the absence and presence of two different N-terminal regulatory heme-binding domain constructs. Alpha(cat) and beta(cat) were inactive separately, but together the domains exhibited guanylate cyclase activity. Analysis by gel filtration chromatography demonstrated that each of the approximately 25-kDa domains form homodimers. Heterodimers were formed when alpha(cat) and beta(cat) were combined. Results from circular dichroism spectroscopy indicated that no major structural changes occur upon heterodimer formation. Like the full-length enzyme, the alpha(cat)beta(cat) complex was more active in the presence of Mn(2+) as compared to the physiological cofactor Mg(2+), although the magnitude of the difference was much larger for the catalytic domains than for the full-length enzyme. The K(M) for Mn(2+)-GTP was measured to be 85 +/- 18 microM, and in the presence of Mn(2+)-GTP, the K(D) for the alpha(cat)beta(cat) complex was 450 +/- 70 nM. The N-terminal heme-bound regulatory domain of the beta1 subunit of sGC inhibited the activity of the alpha(cat)beta(cat) complex in trans, suggesting a domain-scale mechanism of regulation by NO. A model in which binding of NO to sGC causes relief of an autoinhibitory interaction between the regulatory heme-binding domain and the catalytic domains of sGC is proposed.     

The modular cellulase CelZ of the thermophilic bacterium Clostridium stercorarium contains a thermostabilizing domain

The non-catalytic region of the Clostridium stercorarium cellulase CelZ (Avicelase I) comprises two protein segments (C and C′) grouped into different subfamilies of cellulose-binding domain (CBD) family III. The C-terminally located family IIIb domain C was identified as a true cellulose-binding domain responsible for anchoring the CelZ enzyme to cellulose. The family IIIc domain C′ immediately adjacent to the catalytic domain was unable to mediate binding to cellulose. A deletion study revealed a lack of independence of this pair of domains: almost the entire C′ domain was required to maintain the catalytic activity and the thermostability of the enzyme.     

The HD domain of the Escherichia coli tRNA nucleotidyltransferase has 2',3'-cyclic phosphodiesterase, 2'-nucleotidase, and phosphatase activities

In all mature tRNAs, the 3'-terminal CCA sequence is synthesized or repaired by a template-independent nucleotidyltransferase (ATP(CTP):tRNA nucleotidyltransferase; EC 2.7.7.25). The Escherichia coli enzyme comprises two domains: an N-terminal domain containing the nucleotidyltransferase activity and an uncharacterized C-terminal HD domain. The HD motif defines a superfamily of metal-dependent phosphohydrolases that includes a variety of uncharacterized proteins and domains associated with nucleotidyltransferases and helicases from bacteria, archaea, and eukaryotes. The C-terminal HD domain in E. coli tRNA nucleotidyltransferase demonstrated Ni(2+)-dependent phosphatase activity toward pyrophosphate, canonical 5'-nucleoside tri- and diphosphates, NADP, and 2'-AMP. Assays with phosphodiesterase substrates revealed surprising metal-independent phosphodiesterase activity toward 2',3'-cAMP, -cGMP, and -cCMP. Without metal or in the presence of Mg(2+), the tRNA nucleotidyltransferase hydrolyzed 2',3'-cyclic substrates with the formation of 2'-nucleotides, whereas in the presence of Ni(2+), the protein also produced some 3'-nucleotides. Mutations at the conserved His-255 and Asp-256 residues comprising the C-terminal HD domain of this protein inactivated both phosphodiesterase and phosphatase activities, indicating that these activities are associated with the HD domain. Low concentrations of the E. coli tRNA (10 nm) had a strong inhibiting effect on both phosphatase and phosphodiesterase activities. The competitive character of inhibition by tRNA suggests that it might be a natural substrate for these activities. This inhibition was completely abolished by the addition of Mg(2+), Mn(2+), or Ca(2+), but not Ni(2+). The data suggest that the phosphohydrolase activities of the HD domain of the E. coli tRNA nucleotidyltransferase are involved in the repair of the 3'-CCA end of tRNA.     

Purification, subunit composition and regulatory properties of the ATP X Mg2+-dependent form of type I phosphoprotein phosphatase from bovine heart

The ATP X Mg2+-dependent phosphoprotein phosphatase has been purified from bovine heart to near-homogeneity. It is a heterodimer (75 kDa) consisting of a catalytic (C) subunit (40 kDa) and a regulatory (R) subunit (35 kDa). The R subunit, which is identical to inhibitor-2, is transiently phosphorylated during activation of the enzyme catalyzed by phosphatase-1 kinase (FA). Maximal activation requires preincubation of the phosphatase with FA and ATP X Mg2+. However, relatively low yet definitively demonstrable basal activity can be expressed by Mg2+ alone (ranging from 3% to 10% of the FA X ATP X Mg activity, depending on the degree of endogenous proteolytic damage of the phosphatase during purification), but not by either FA or ATP alone. Limited trypsinization results in a rapid and total degradation of the R subunit and partial degradation of the 40-kDa C subunit to active proteins of 35-38 kDa. The resulting 'nicked' C subunit of 35-38 kDa is no longer dependent on FA for activation and can be fully activated by Mg2+ (or Mn2+) alone. Endogenous proteolytic damage of the R subunit also results in an increase of activity that can be expressed by M2+ alone with a concomitant decrease of the FA-dependent activation. Although Mn2+ is slightly more effective than Mg2+ in expressing the holoenzyme basal activity, the activation by Mn2+ is only about 60% of that of Mg2+ when FA and ATP are also present. In the activation by adenosine 5'-[gamma-thio]triphosphate (ATP[gamma S]), Co2+ is the most effective cofactor. The activation by ATP[gamma S] X Co2+ is more than 50% of that by ATP X Mg2+. The present studies indicate that Mg2+ is the natural divalent cation for the FA-catalyzed activation in which Mg2+ plays two distinctly different roles: it forms Mg2+ X ATP which serves as a substrate for the kinase; it acts as an essential cofactor for the catalytic function of the phosphatase. The discrepancies between the results obtained by this and other laboratories with respect to the effectiveness of Mg2+ and ATP[gamma S] in the activation of the phosphatase are discussed.     

Mycobacterium tuberculosis isocitrate lyase (MtbIcl): role of divalent cations in modulation of functional and structural properties

Isocitrate lyase (Icl), an enzyme that plays an important role in the regulation of isocitrate flux and anaplerotic replenishment of pool of substrate required for biosynthetic process in Mycobacterium tuberculosis is a potential drug target for the antituberculosis drugs. Divalent cations induce differential effect of activation and inhibition of MtbIcl functional activity. The study for the first time demonstrates that interaction of cations with MtbIcl results in differential modulation of the enzyme structure which is probably the underlying mechanism for differential modulation of functional activity of enzyme by divalent cations. The Mg(2+) and Mn(2+) ions act as activators of the enzyme and in their absence no enzymatic activity was observed. These cations do not induce any significant structural alteration in the enzyme as observed by far-UV CD and solvent denaturation studies using chaotropic salts. However, the thermal denaturation studies demonstrate that they do interact with the noncatalytic alpha/beta barrel core domain of the enzyme and destabilize it. The inhibitors Zn(2+) and Cd(2+) interact directly with the catalytic domain of the enzyme and unfold it as a result of which complete loss of the enzymatic activity is observed in their presence. The results obtained from the studies provide intriguing insight into the possible mechanism of divalent cation-induced changes in structure, function, and stability of MtbIcl.     

Function analysis of conserved amino acid residues in a Mn2+-dependent protein phosphatase, Pph3, from Myxococcus xanthus

The Myxococcus xanthus protein phosphatase Pph3 belongs to the Mg(2+)- or Mn(2+)-dependent protein phosphatase (PPM) family. Bacterial PPMs contain three divalent metal ions and a flap subdomain. Putative metal- or phosphate-ion binding site-specific mutations drastically reduced enzymatic activity. Pph3 contains a cyclic nucleotide monophosphate (cNMP)-binding domain in the C-terminal region, and it requires 2-mercaptoethanol for phosphatase activity; however, the C-terminal deletion mutant showed high activity in the absence of 2-mercaptoethanol. The phosphatase activity of the wild-type enzyme was higher in the presence of cAMP than in the absence of cAMP, whereas a triple mutant of the cNMP-binding domain showed slightly lower activities than those of wild-type, without addition of cAMP. In addition, mutational disruption of a disulphide bond in the wild-type enzyme increased the phosphatase activity in the absence of 2-mercaptoethanol, but not in the C-terminal deletion mutant. These results suggested that the presence of the C-terminal region may lead to the formation of the disulphide bond in the catalytic domain, and that disulphide bond cleavage of Pph3 by 2-mercaptoethanol may occur more easily with cAMP bound than with no cAMP bound.     

Glycerolipid biosynthesis in rat adipose tissue. I. Properties and distribution of glycerophosphate acyltransferase and effect of divalent cations on neutral lipid formation

A sensitive radioactive assay of acyl CoA:sn-glycerol-3-phosphate-O-acyltransferase (EC 2.3.1.15) was developed to study the properties and subcellular distribution of this enzyme in rat epididymal adipose tissue. The esterification of sn-glycerol-3-phosphate was measured in the presence of palmitoyl CoA or palmitate, ATP, CoA, and Mg(2+) at pH 7.5. The presence of glycerophosphate acyltransferase was detected in both mitochondria and microsomes. The product of this reaction was identified as phosphatidate by thin-layer chromatography and dual isotope incorporation studies. Several divalent cations reduced the activity of this enzyme. Although Mg(2+) was not required for the activity of glycerophosphate acyltransferase, its addition to the incubation mixture resulted in an increased formation of neutral lipids at the expense of phosphatidate. This result is explained by an activation of microsomal phosphatidate phosphatase (EC 3.1.3.4). The effect of Mg(2+) was completely abolished by Ni(2+), Co(2+), Mn(2+), and Zn(2+). These studies suggest that the balance between Mg(2+) and several other divalent ions may be important in the regulation of neutral lipid synthesis in adipose tissue.