Comparative modelling of human PHOSPHO1 reveals a new group of phosphatases within the haloacid dehalogenase superfamily

PHOSPHO1 is a recently identified phosphatase whose expression is upregulated in mineralizing cells and is implicated in the generation of inorganic phosphate for matrix mineralization, a process central to skeletal development. The enzyme is a member of the haloacid dehalogenase (HAD) superfamily of magnesium-dependent hydrolases. However, the natural substrate(s) is as yet unidentified and to date no structural information is known. We have identified homologous proteins in a number of species and have modelled human PHOSPHO1 based upon the crystal structure of phosphoserine phosphatase (PSP) from Methanococcus jannaschii. The model includes the catalytic Mg(2+) atom bound via three conserved Asp residues (Asp32, Asp34 and Asp203); O-ligands are also provided by a phosphate anion and two water molecules. Additional residues involved in PSP-catalysed hydrolysis are conserved and are located nearby, suggesting both enzymes share a similar reaction mechanism. In PHOSPHO1, none of the PSP residues that confer the enzyme's substrate specificity (Arg56, Glu20, Met43 and Phe49) are conserved. Instead, we propose that two fully conserved Asp residues (Asp43 and Asp123), not present in PSPs contribute to substrate specificity in PHOSPHO1. Our findings show that PHOSPHO1 is not a member of the subfamily of PSPs but belongs to a novel, closely related enzyme group within the HAD superfamily.     

Site-directed mutations and kinetic studies show key residues involved in alkylammonium interactions and reveal two sites for phosphorylcholine in Pseudomonas aeruginosa phosphorylcholine phosphatase

Pseudomonas aeruginosa phosphorylcholine phosphatase (PchP) catalyzes the hydrolysis of phosphorylcholine (Pcho) to produce choline and inorganic phosphate. PchP belongs to the haloacid dehalogenase superfamily (HAD) and possesses the three characteristic motifs of this family: motif I ((31)D and (33)D), motif II ((166)S), and motif III ((242)K, (261)G, (262)D and (267)D), which fold to form the catalytic site that binds the metal ion and the phosphate moiety of Pcho. Based on comparisons to the PHOSPHO1 and PHOSPHO2 human enzymes and the choline-binding proteins of Gram-(+) bacteria, we selected residues (42)E and (43)E and the aromatic triplet (82)YYY(84) for site-directed mutagenesis to study the interactions with Pcho and p-nitrophenylphosphate as substrates of PchP. Because mutations in (42)E, (43)E and the three tyrosine residues affect both the substrate affinity and the inhibitory effect produced by high Pcho concentrations, we postulate that two sites, one catalytic and one inhibitory, are present in PchP and that they are adjacent and share residues.     

The functional co-operativity of tissue-nonspecific alkaline phosphatase (TNAP) and PHOSPHO1 during initiation of skeletal mineralization.

Phosphatases are recognized to have important functions in the initiation of skeletal mineralization. Tissue-nonspecific alkaline phosphatase (TNAP) and PHOSPHO1 are indispensable for bone and cartilage mineralization but their functional relationship in the mineralization process remains unclear. In this study, we have used osteoblast and ex-vivo metatarsal cultures to obtain biochemical evidence for co-operativity and cross-talk between PHOSPHO1 and TNAP in the initiation of mineralization. Clones 14 and 24 of the MC3T3-E1 cell line were used in the initial studies. Clone 14 cells expressed high levels of PHOSPHO1 and low levels of TNAP and in the presence of β-glycerol phosphate (βGP) or phosphocholine (P-Cho) as substrates and they mineralized their matrix strongly. In contrast clone 24 cells expressed high levels of TNAP and low levels of PHOSPHO1 and mineralized their matrix poorly. Lentiviral Phospho1 overexpression in clone 24 cells resulted in higher PHOSPHO1 and TNAP protein expression and increased levels of matrix mineralization. To uncouple the roles of PHOSPHO1 and TNAP in promoting matrix mineralization we used PHOSPHO1 (MLS-0263839) and TNAP (MLS-0038949) specific inhibitors, which individually reduced mineralization levels of Phospho1 overexpressing C24 cells, whereas the simultaneous addition of both inhibitors essentially abolished matrix mineralization (85%; P<0.001). Using metatarsals from E15 mice as a physiological ex vivo model of mineralization, the response to both TNAP and PHOSPHO1 inhibitors appeared to be substrate dependent. Nevertheless, in the presence of βGP, mineralization was reduced by the TNAP inhibitor alone and almost completely eliminated by the co-incubation of both inhibitors. These data suggest critical non-redundant roles for PHOSPHO1 and TNAP during the initiation of osteoblast and chondrocyte mineralization.     

Design,synthesis and evaluation of benzoisothiazolones as selective inhibitors of PHOSPHO1

We report the discovery and characterization of a series of benzoisothiazolone inhibitors of PHOSPHO1, a newly identified soluble phosphatase implicated in skeletal mineralization and soft tissue ossification abnormalities. High-throughput screening (HTS) of a small molecule library led to the identification of benzoisothiazolones as potent and selective inhibitors of PHOSPHO1. Critical structural requirements for activity were determined, and the compounds were subsequently derivatized and measured for in vitro activity and ADME parameters including metabolic stability and permeability. On the basis of its overall profile the benzoisothiazolone analogue 2q was selected as MLPCN probe ML086.     

Structural and functional characterization of the c-terminal domain of the ecdysteroid phosphate phosphatase from bombyx mori reveals a new enzymatic activity

Here, we present the crystal structure of the ecdysone phosphate phosphatase (EPPase) phosphoglycerate mutase (PGM) homology domain, the first structure of a steroid phosphate phosphatase. The structure reveals an alpha/beta-fold common to members of the two histidine (2H)-phosphatase superfamily with strong homology to the Suppressor of T-cell receptor signaling-1 (Sts-1 PGM) protein. The putative EPPase PGM active site contains signature residues shared by 2H-phosphatase enzymes, including a conserved histidine (His80) that acts as a nucleophile during catalysis. The physiological substrate ecdysone 22-phosphate was modeled in a hydrophobic cavity close to the phosphate-binding site. EPPase PGM shows limited substrate specificity with an ability to hydrolyze steroid phosphates, the phospho-tyrosine (pTyr) substrate analogue para-nitrophenylphosphate ( pNPP) and pTyr-containing peptides and proteins. Altogether, our data demonstrate a new protein tyrosine phosphatase (PTP) activity for EPPase. They suggest that EPPase and its closest homologues can be grouped into a distinct subfamily in the large 2H-phosphatase superfamily of proteins.     

Chromosomal localization of the chicken and mammalian orthologues of the orphan phosphatase PHOSPHO1 gene

PHOSPHO1 is a recently identified phosphatase expressed at high levels in the chicken growth plate and which may be involved in generating inorganic phosphate for skeletal matrix mineralization. Using a degenerate RT-PCR approach a fragment of human PHOSPHO1 was cloned. This enabled the identification of the human orthologue on HSA17q21, and the mouse orthologue on a region of MMU11 that exhibits conservation of synteny with HSA17q21. Chicken PHOSPHO1 was mapped by SSCP analysis to position 44 cM on GGA27, adjacent to the HOXB@ (44 cM) and COL1A1 (36 cM) loci. Comparison of genes on GGA27 with their orthologues on the preliminary draft of the human genome identifies regions of conserved synteny equivalent to 25 Mb on HSA17q21.2-23.3 and approximately 20 Mb on GGA27 in which the gene order appears to be conserved. Mapping of the PHOSPHO1 genes to regions of HSA17q21.3, MMU11 and GGA27 that exhibit conservation of synteny provides strong evidence that they are orthologous.     

Site-directed mutational analysis of active site residues in the acetate kinase from Methanosarcina thermophila

Acetate kinase catalyzes the magnesium-dependent transfer of the gamma-phosphate of ATP to acetate. The recently determined crystal structure of the Methanosarcina thermophila enzyme identifies it as a member of the sugar kinase/Hsc70/actin superfamily based on the fold and the presence of five putative nucleotide and metal binding motifs that characterize the superfamily. Residues from four of these motifs in M. thermophila acetate kinase were selected for site-directed replacement and analysis of the variants. Replacement of Asp(148) and Asn(7) resulted in variants with catalytic efficiencies less than 1% of that of the wild-type enzyme, indicating that these residues are essential for activity. Glu(384) was also found to be essential for catalysis. A 30-fold increase in the magnesium concentration required for half-maximal activity of the E384A variant relative to that of the wild type implicated Glu(384) in magnesium binding. The kinetic analysis of variants and structural data is consistent with nonessential roles for active site residues Ser(10), Ser(12), and Lys(14) in catalysis. The results are discussed with respect to the acetate kinase catalytic mechanism and the relationship to other sugar kinase/Hsc70/actin superfamily members.     

Defining the active site of Schizosaccharomyces pombe C-terminal domain phosphatase Fcp1

Fcp1 is an essential protein serine phosphatase that dephosphorylates the C-terminal domain (CTD) of RNA polymerase II. By testing the effects of serial N- and C-terminal deletions of the 723-amino acid Schizosaccharomyces pombe Fcp1, we defined a minimal phosphatase domain spanning amino acids 156-580. We employed site-directed mutagenesis (introducing 24 mutations at 14 conserved positions) to locate candidate catalytic residues. We found that alanine substitutions for Arg(223), Asp(258), Lys(280), Asp(297), and Asp(298) abrogated the phosphatase activity with either p-nitrophenyl phosphate or CTD-PO(4) as substrates. Structure-activity relationships were determined by introducing conservative substitutions at each essential position. Our results, together with previous mutational studies, highlight a constellation of seven amino acids (Asp(170), Asp(172), Arg(223), Asp(258), Lys(280), Asp(297), and Asp(298)) that are conserved in all Fcp1 orthologs and likely comprise the active site. Five of these residues (Asp(170), Asp(172), Lys(280), Asp(297), and Asp(298)) are conserved at the active site of T4 polynucleotide 3'-phosphatase, suggesting that Fcp1 and T4 phosphatase are structurally and mechanistically related members of the DXD phosphotransferase superfamily.     

Mutagenic analysis of functional residues in putative substrate-binding site and acidic domains of vacuolar H+-pyrophosphatase

Vacuolar H(+)-translocating inorganic pyrophosphatase (V-PPase) uses PP(i) as an energy donor and requires free Mg(2+) for enzyme activity and stability. To determine the catalytic domain, we analyzed charged residues (Asp(253), Lys(261), Glu(263), Asp(279), Asp(283), Asp(287), Asp(723), Asp(727), and Asp(731)) in the putative PP(i)-binding site and two conserved acidic regions of mung bean V-PPase by site-directed mutagenesis and heterologous expression in yeast. Amino acid substitution of the residues with alanine and conservative residues resulted in a marked decrease in PP(i) hydrolysis activity and a complete loss of H(+) transport activity. The conformational change of V-PPase induced by the binding of the substrate was reflected in the susceptibility to trypsin. Wild-type V-PPase was completely digested by trypsin but not in the presence of Mg-PP(i), while two V-PPase mutants, K261A and E263A, became sensitive to trypsin even in the presence of the substrate. These results suggest that the second acidic region is also implicated in the substrate hydrolysis and that at least two residues, Lys(261) and Glu(263), are essential for the substrate-binding function. From the observation that the conservative mutants K261R and E263D showed partial activity of PP(i) hydrolysis but no proton pump activity, we estimated that two residues, Lys(261) and Glu(263), might be related to the energy conversion from PP(i) hydrolysis to H(+) transport. The importance of two residues, Asp(253) and Glu(263), in the Mg(2+)-binding function was also suggested from the trypsin susceptibility in the presence of Mg(2+). Furthermore, it was found that the two acidic regions include essential common motifs shared among the P-type ATPases.     

Four conserved cytoplasmic sequence motifs are important for transport function of the Leishmania inositol/H(+) symporter

The protozoan Leishmania donovani has a myo-inositol/proton symporter (MIT) that is a member of a large sugar transporter superfamily. Active transport by MIT is driven by the proton electrochemical gradient across the parasite membrane, and MIT is a prototype for understanding the function of an active transporter in lower eukaryotes. MIT contains two duplicated 6- or 7-amino acid motifs within cytoplasmic loops, which are highly conserved among 50 members of the sugar transporter superfamily and are designated A(1), A(2) ((V)(D/E)(R/K)PhiGR(R/K)), and B(1) (PESPRPhiL), B(2) (VPETKG). In particular, the three acidic residues within these motifs, Glu(187)(B(1)), Asp(300)(A(2)), and Glu(429)(B(2)) in MIT, are highly conserved with 96, 78, and 96% amino acid identity within the analyzed members of this transporter superfamily ranging from bacteria, archaea, and fungi to plants and the animal kingdom. We have used site-directed mutagenesis in combination with functional expression of transporter mutants in Xenopus oocytes and overexpression in Leishmania transfectants to investigate the significance of these three acidic residues in the B(1), A(2), and B(2) motifs. Alteration to the uncharged amides greatly reduced MIT transport function to 23% (E187Q), 1.4% (D300N), and 3% (E429Q) of wild-type activity, respectively, by affecting V(max) but not substrate affinity. Conservative mutations that retained the charge revealed a less pronounced effect on inositol transport with 39% (E187D), 16% (D300E) and 20% (E429D) remaining transport activity. Immunofluorescence microscopy of oocyte cryosections confirmed that MIT mutants were expressed on the oocyte surface in similar quantity to MIT wild type. The proton uncouplers carbonylcyanide-4-(trifluoromethoxy) phenylhydrazone and dinitrophenol inhibited inositol transport by 50-70% in the wild type as well as in E187Q, D300N, and E429Q, despite their reduced transport activities, suggesting that transport in these mutants is still proton-coupled. Furthermore, temperature-dependent uptake studies showed an increased Arrhenius activation energy for the B(1)-E187Q and the B(2)-E429Q mutants, which supports the idea of an impaired transporter cycle in these mutants. We conclude that the conserved acidic residues Glu(187), Asp(300), and Glu(429) are critical for transport function of MIT.     

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).     

Amino acid residues forming the active site of arylsulfatase A. Role in catalytic activity and substrate binding

Arylsulfatase A belongs to the sulfatase family whose members carry a Calpha-formylglycine that is post-translationally generated by oxidation of a conserved cysteine or serine residue. The formylglycine acts as an aldehyde hydrate with two geminal hydroxyls being involved in catalysis of sulfate ester cleavage. In arylsulfatase A and N-acetylgalactosamine 4-sulfatase this formylglycine was found to form the active site together with a divalent cation and a number of polar residues, tightly interconnected by a net of hydrogen bonds. Most of these putative active site residues are highly conserved among the eukaryotic and prokaryotic members of the sulfatase family. To analyze their function in binding and cleaving sulfate esters, we substituted a total of nine putative active site residues of human ASA by alanine (Asp29, Asp30, Asp281, Asn282, His125, His229, Lys123, Lys302, and Ser150). In addition the Mg2+-complexing residues (Asp29, Asp30, Asp281, and Asn282) were substituted conservatively by either asparagine or aspartate. In all mutants Vmax was decreased to 1-26% of wild type activity. The Km was more than 10-fold increased in K123A and K302A and up to 5-fold in the other mutants. In all mutants the pH optimum was increased from 4.5 by 0.2-0.8 units. These results indicate that each of the nine residues examined is critical for catalytic activity, Lys123 and Lys302 by binding the substrate and the others by direct (His125 and Asp281) or indirect participation in catalysis. The shift in the pH optimum is explained by two deprotonation steps that have been proposed for sulfate ester cleavage.     

Identification of acceptor substrate binding subsites +2 and +3 in the amylomaltase from Thermus thermophilus HB8

Glycoside hydrolase family 77 (GH77) belongs to the alpha-amylase superfamily (Clan H) together with GH13 and GH70. GH77 enzymes are amylomaltases or 4-alpha-glucanotransferases, involved in maltose metabolism in microorganisms and in starch biosynthesis in plants. Here we characterized the amylomaltase from the hyperthermophilic bacterium Thermus thermophilus HB8 (Tt AMase). Site-directed mutagenesis of the active site residues (Asp293, nucleophile; Glu340, general acid/base catalyst; Asp395, transition state stabilizer) shows that GH77 Tt AMase and GH13 enzymes share the same catalytic machinery. Quantification of the enzyme's transglycosylation and hydrolytic activities revealed that Tt AMase is among the most efficient 4-alpha-glucanotransferases in the alpha-amylase superfamily. The active site contains at least seven substrate binding sites, subsites -2 and +3 favoring substrate binding and subsites -3 and +2 not, in contrast to several GH13 enzymes in which subsite +2 contributes to oligosaccharide binding. A model of a maltoheptaose (G7) substrate bound to the enzyme was used to probe the details of the interactions of the substrate with the protein at acceptor subsites +2 and +3 by site-directed mutagenesis. Substitution of the fully conserved Asp249 with a Ser in subsite +2 reduced the activity 23-fold (for G7 as a substrate) to 385-fold (for maltotriose). Similar mutations reduced the activity of alpha-amylases only up to 10-fold. Thus, the characteristics of acceptor subsite +2 represent a main difference between GH13 amylases and GH77 amylomaltases.     

The fully conserved Asp residue in conserved sequence region I of the alpha-amylase family is crucial for the catalytic site architecture and activity

The alpha-amylase family is a large group of starch processing enzymes [Svensson, B. (1994) Plant Mol. Biol. 25, 141-157]. It is characterized by four short sequence motifs that contain the seven fully conserved amino acid residues in this family: two catalytic carboxylic acid residues and four substrate binding residues. The seventh conserved residue (Asp135) has no direct interactions with either substrates or products, but it is hydrogen-bonded to Arg227, which does bind the substrate in the catalytic site. Using cyclodextrin glycosyltransferase as an example, this paper provides for the first time definite biochemical and structural evidence that Asp135 is required for the proper conformation of several catalytic site residues and therefore for activity.     

Probing a putative active site of the catalytic subunit of pyruvate dehydrogenase phosphatase 1 (PDP1c) by site-directed mutagenesis

The catalytic subunit of pyruvate dehydrogenase phosphatase 1 (PDP1c) is a magnesium-dependent protein phosphatase that regulates the activity of mammalian pyruvate dehydrogenase complex. Based on the sequence analysis, it was hypothesized that PDP1c is related to the mammalian magnesium-dependent protein phosphatase type 1, with Asp54, Asp347, and Asp445 contributing to the binuclear metal-binding center, and Asn49 contributing to the phosphate-binding sites. In this study, we analyzed the functional significance of these amino acid residues using a site-directed mutagenesis. It was found that substitution of each of these residues had a significant impact on PDP1c activity toward the protein substrate. The activities of Asp54, Asp347, and Asp445 mutants were decreased more than 1000-fold. The activity of Asn49 mutant was 2.5-fold lower than the activity of wild-type PDP1c. The decrease in activity of Asp54 and Asp347 came about, most likely, as a result of impaired magnesium binding. Unexpectedly, it was found that the Asp445 mutant bound Mg(2+) ions similarly to the wild-type enzyme. Accordingly, the Asp445 mutant was found to be active with the artificial substrate p-nitrophenyl phosphate (pNPP). Asp54 and Asp347 mutants did not demonstrate any appreciable activity with pNPP. Together, these observations strongly suggest that Asn49, Asp54, and Asp347 are important for the catalysis of the phosphatase reaction, contributing to the phosphate- and metal-binding centers of PDP1c. In contrast, Asp445 is not required for catalysis. The exact role of Asp445 remains to be established, but indirect evidence suggests that it might be involved in the control of interactions between PDP1c and the protein substrate pyruvate dehydrogenase.     

Mutational analysis of Cvab, an ABC transporter involved in the secretion of active colicin V

CvaB is the central membrane transporter of the colicin V secretion system that belongs to an ATP-binding cassette superfamily. Previous data showed that the N-terminal and C-terminal domains of CvaB are essential for the function of CvaB. N-terminal domain of CvaB possesses Ca(2+)-dependent cysteine proteolytic activity, and two critical residues, Cys32 and His105, have been identified. In this study, we also identify Asp121 as being the third residue of the putative catalytic triad within the active site of the enzyme. The Asp121 mutants lose both their colicin V secretion activity and N-terminal proteolytic activity. The adjacent residue Pro122 also appears to play a critical role in the colicin V secretion. However, the reversal of the two residues D121P - P122D results in loss of activity. Based on molecular modeling and protein sequence alignment, several residues adjacent to the critical residues, Cys32 and His105, were also examined and characterized. Site-directed mutagenesis of Trp101, Asp102, Val108, Leu76, Gly77, and Gln26 indicate that the neighboring residues around the catalytic triad affect colicin V secretion. Several mutated CvaB proteins with defective secretion were also tested, including Asp121 and Pro122, and were found to be structurally stable. These results indicate that the residues surrounding the identified catalytic triad are functionally involved in the secretion of biologically active colicin V.     

A conserved amino acid motif (R-X-G-R-R) in the Glut1 glucose transporter is an important determinant of membrane topology.

The Glut1 glucose transporter is one of over 300 members of the major facilitator superfamily of membrane transporters. These proteins are extremely diverse in substrate specificity and differ in their transport mechanisms. The two most common features shared by many members of this superfamily are the presence of 12 predicted transmembrane segments and an amino acid motif, R-X-G-R-R, present at equivalent positions within the cytoplasmic loops joining transmembrane segments 2-3 and 8-9. The structural and functional roles of the arginine residues within these motifs in Glut1 were investigated by expression of site-directed mutant transporters in Xenopus oocytes followed by analyses of intrinsic transport activity and the membrane topology of mutant glycosylation-scanning reporter Glut1 molecules. Substitution of lysine residues for the cluster of 3 arginine residues in each of the 2 cytoplasmic pentameric motifs of Glut1 revealed no absolute requirement for arginine side chains at any of the 6 positions for transport of 2-deoxyglucose. However, removal of the 3 positive charges at either site by substitution of glycines for the arginines completely abolished transport activity as the result of a local perturbation in the membrane topology in which the cytoplasmic loop was aberrantly translocated into the exoplasm along with the two flanking transmembrane segments. Substitution of lysines for the arginines had no affect on membrane topology. We conclude that the positive charges in the R-X-G-R-R motif form critical local cytoplasmic anchor points involved in determining the membrane topology of Glut1. These data provide a simple explanation for the presence of this conserved amino acid motif in hundreds of functionally diverse membrane transporters that share a common predicted membrane topology.