Mutational analysis of the interaction between active site residues and the loop region in mammalian purple acid phosphatases.

Mammalian purple acid phosphatases (PAPs) can be divided into two groups, which exhibit distinct spectroscopic and kinetics properties: PAPs that consist of a single 36 kDa polypeptide, and PAPs that have undergone limited proteolysis to give two fragments with masses of 16 and 20 kDa, respectively. Proteolysis results in an increase in enzymatic activity, an increase in the optimal pH for activity, and a change in the g(z)() value of the characteristic EPR spectrum of the mixed-valence binuclear iron center. It has been proposed that these changes are due to the loss of interactions between Asp146 in an exposed loop region and active site residues upon proteolysis. In the present study, site-directed mutagenesis of Asp146 in recombinant rat bone PAP (recRPAP) has confirmed this hypothesis. Conversion of Asp146 into Ala, which eliminates the interaction of the side chain with the active site, resulted in an enzyme with properties typical of PAPs isolated in proteolytically cleaved forms. The Asp146Asn and Asp146Glu mutants were also prepared and examined to assess the effects of altered electrostatic interactions and side-chain length. Limited proteolysis of all three mutant enzymes with cathepsin L resulted in a significant increase in catalytic activity. Thus, although the interaction between Asp146 and (an) active site residue(s) is the major factor responsible for the low catalytic activity of uncleaved PAPs, other interactions are also important. Since both p-nitrophenyl phosphate and osteopontin, a potential in vivo substrate, show the same level of activation, the observed increase in catalytic activity upon proteolysis is likely to be due to electrostatic rather than steric effects. EPR spectra of FeZn-recRPAP before and after cleavage by cathepsin L suggest that cleavage primarily affects the divalent metal site. The observation that pK(es,1) is also sensitive to changes at the divalent site is consistent with the proposal that the nucleophilic hydroxide is that bridging the divalent and trivalent metals.

Tartrate-resistant purple acid phosphatase is synthesized as a latent proenzyme and activated by cysteine proteinases.

Purple acid phosphatases (PAPs) are binuclear acid metallohydrolases also referred to as tartrate-resistant acid phosphatases (TRAPs) or type 5 acid phosphatases. The cDNA sequences of TRAP/PAP enzymes from different species and organs indicate that these enzymes are translated as monomeric polypeptides of approx. 35 kDa, contrasting with the predominantly two-subunit structure observed in purified enzyme preparations. In the present study we have compared certain structural and enzyme-kinetic properties of recombinant rat PAP (monomeric) with those of the native rat bone TRAP/PAP enzyme (two-subunit), and examined effects on these parameters by cleaving the monomeric recombinant PAP with the serine proteinase trypsin or the cysteine proteinases papain or cathepsin B. Cleavage with trypsin resulted in a moderate activation of the recombinant enzyme and shifted the pH optimum to a slightly more basic value (5.0-5.5). Cleavage with papain resulted in complete activation and conferred similar properties to those of the bone PAP variant with regard to pH optimum (5.5-6.0) and sensitivity to reducing agents, as well as in the sizes of the subunits. Substrate specificity studies showed that the two-subunit bone PAP was considerably more active than the monomeric recombinant rat PAP towards a variety of serine-, threonine- and tyrosine-phosphorylated substrates. Of these substrates, bovine milk osteopontin seemed to be the most readily dephosphorylated substrate. In conclusion, the results suggest that the monomeric form of PAP represent a latent proenzyme with low enzymic activity towards both tyrosine- and serine/threonine-containing phosphorylated substrates. Besides being implicated in the catabolism of the extracellular matrix, members of the cysteine proteinase family might also exert a regulatory role in degradative processes involving the PAP enzymes by converting the newly synthesized PAPs to enzymically active and microenvironmentally regulated species.

Comparative studies of rat recombinant purple acid phosphatase and bone tartrate-resistant acid phosphatase.

The tartrate-resistant acid phosphatase (TRAP) of rat osteoclasts has been shown to exhibit high (85-94%) identity at the amino acid sequence level with the purple acid phosphatase (PAP) from bovine spleen and with pig uteroferrin. These iron-containing purple enzymes contain a binuclear iron centre, with a tyrosinate-to-Fe(III) charge-transfer transition responsible for the purple colour. In the present study, production of rat osteoclast TRAP could be achieved at a level of 4.3 mg/litre of medium using a baculovirus expression system. The enzyme was purified to apparent homogeneity using a combination of cation-exchange, hydrophobic-interaction, lectin-affinity and gel-permeation chromatography steps. The protein as isolated had a purple colour, a specific activity of 428 units/mg of protein and consisted of the single-chain form of molecular mass 34 kDa, with only trace amounts of proteolytically derived subunits. The recombinant enzyme had the ability to dephosphorylate bone matrix phosphoproteins, as previously shown for bone TRAP. Light absorption spectroscopy of the isolated purple enzyme showed a lambda max at 544 nm, which upon reduction with ascorbic acid changed to 515 nm, concomitant with the transition to a pink colour. EPR spectroscopic analysis of the reduced enzyme at 3.6 K revealed a typical mu-hydr(oxo)-bridged mixed-valent Fe(II)Fe(III) signal with g-values at 1.96, 1.74 and 1.60, proving that recombinant rat TRAP belongs to the family of PAPs. To validate the use of recombinant PAP in substituting for the rat bone counterpart in functional studies, various comparative studies were carried out. The enzyme isolated from bone exhibited a lower K(m) for p-nitrophenyl phosphate and was slightly more sensitive to PAP inhibitors such as molybdate, tungstate, arsenate and phosphate. In contrast with the recombinant enzyme, TRAP from bone was isolated predominantly as the proteolytically cleaved, two-subunit, form. Both the recombinant enzyme and rat bone TRAP were shown to be substituted with N-linked oligosaccharides. A slightly higher apparent molecular mass of the monomeric form and N-terminal chain of bone TRAP compared with the recombinant enzyme could not be accounted for by differential N-glycosylation. Despite differences in specific post-translational modifications, the recombinant PAP should be useful in future studies on the properties and regulation of the mammalian PAP enzyme.