Prostatic Acid Phosphatase Is Expressed in Peptidergic and Nonpeptidergic Nociceptive Neurons of Mice and Rats

Thiamine monophosphatase (TMPase, also known as Fluoride-resistant acid phosphatase or FRAP) is a classic histochemical marker of small- to medium-diameter dorsal root ganglia (DRG) neurons and has primarily been studied in the rat. Previously, we found that TMPase was molecularly identical to Prostatic acid phosphatase (PAP) using mice. In addition, PAP was expressed in a majority of nonpeptidergic, isolectin B4-binding (IB4⁺) nociceptive neurons and a subset of peptidergic, calcitonin gene-related peptide-containing (CGRP⁺) nociceptive neurons. At the time, we were unable to determine if PAP was present in rat DRG neurons because the antibody we used did not cross-react with PAP in rat tissues. In our present study, we generated a chicken polyclonal antibody against the secretory isoform of mouse PAP. This antibody detects mouse, rat and human PAP protein on western blots. Additionally, this antibody detects PAP in mouse and rat small- to medium-diameter DRG neurons and axon terminals in lamina II of spinal cord. In the rat, 92.5% of all PAP⁺ cells bind the nonpeptidergic marker IB4 and 31.8% of all PAP⁺ cells contain the peptidergic marker CGRP. Although PAP is found in peptidergic and nonpeptidergic neurons of mice and rats, the percentage of PAP⁺ neurons that express these markers differs between species. Moreover, PAP⁺ axon terminals in the rat partially overlap with Protein kinase Cγ (PKCγ⁺) interneurons in dorsal spinal cord whereas PAP⁺ axon terminals in the mouse terminate dorsal to PKCγ⁺ interneurons. Collectively, our studies highlight similarities and differences in PAP localization within nociceptive neurons of mice and rats.     

Recombinant Mouse PAP Has pH-Dependent Ectonucleotidase Activity and Acts through A1-Adenosine Receptors to Mediate Antinociception

Prostatic acid phosphatase (PAP) is expressed in nociceptive neurons and functions as an ectonucleotidase. When injected intraspinally, the secretory isoforms of human and bovine PAP protein have potent and long-lasting antinociceptive effects that are dependent on A₁-adenosine receptor (A₁R) activation. In this study, we purified the secretory isoform of mouse (m)PAP using the baculovirus expression system to determine if recombinant mPAP also had antinociceptive properties. We found that mPAP dephosphorylated AMP, and to a much lesser extent, ADP at neutral pH (pH 7.0). In contrast, mPAP dephosphorylated all purine nucleotides (AMP, ADP, ATP) at an acidic pH (pH 5.6). The transmembrane isoform of mPAP had similar pH-dependent ectonucleotidase activity. A single intraspinal injection of mPAP protein had long-lasting (three day) antinociceptive properties, including antihyperalgesic and antiallodynic effects in the Complete Freund''s Adjuvant (CFA) inflammatory pain model. These antinociceptive effects were transiently blocked by the A₁R antagonist 8-cyclopentyl-1, 3-dipropylxanthine (CPX), suggesting mPAP dephosphorylates nucleotides to adenosine to mediate antinociception just like human and bovine PAP. Our studies indicate that PAP has species-conserved antinociceptive effects and has pH-dependent ectonucleotidase activity. The ability to metabolize nucleotides in a pH-dependent manner could be relevant to conditions like inflammation where tissue acidosis and nucleotide release occur. Lastly, our studies demonstrate that recombinant PAP protein can be used to treat chronic pain in animal models.     

Cytochemical study of macrophage lysosomal inorganic trimetaphosphatase and acid phosphatase

Cytochemical investigations have associated acid inorganic trimetaphosphatase (TMPase) activity with the lysosomes of certain cell types. We have used the modified staining technique of Berg to show that this enzyme activity is present in normal mononuclear phagocytes and macrophage cell lines. We have found this enzyme activity to be present in murine RAW264 macrophages, in human U937 macrophages, in normal human blood monocytes, and in guinea pig peritoneal macrophages. All of the RAW264 and U937 macrophages showed intense TMPase activity. Many of the human monocytes and most of the guinea pig macrophages were labeled by this method. The reaction product was associated with the lysosomes of these cell types. The lysosomal staining-pattern was similar to that of acid phosphatase. Differences with regard to Golgi staining were noted. This indicates that TMPase is a lysosomal enzyme of mammalian macrophages. The distinction between TMPase and acid phosphatase activity has been demonstrated by measuring the pH optimum of each enzyme. Using substrates identical to those of the ultrastructural cytochemistry, we show that the pH optimum of TMPase is 4.0 and that of acid phosphatase is 5.0. The enzymatic activities are therefore ultrastructurally and biochemically distinct. Following phagocytosis of latex, yeast (Saccharomyces cerevisiae), or Corynebacterium parvum, TMPase has been found to be associated with phagosomes. This enzyme may take part in the degradation of phagocytosed materials, particularly microorganisms which contain inorganic polyphosphates and metaphosphates.     

Thiamine monophosphatase: a genuine marker for transganglionic regulation of primary sensory neurons

Thiamine monophosphatase (TMPase) has been selectively localized in small dorsal root ganglion cells and in their central and peripheral terminals. Light microscopic localization of TMPase, and its alterations due to transganglionic effects, are identical with those of fluoride-resistant acid phosphatase (FRAP), but are not contaminated by the ubiquitous lysosomal reaction inevitable in trivial acid phosphatase-stained sections. TMPase is inhibited by 0.1 mM NaF, which is slightly less than the concentration needed to inhibit FRAP (0.2-0.4 mM). It is assumed that TMPase and FRAP are identical enzymes. In the perikaryon of small dorsal root ganglion cells, TMPase is located in the cisterns of the endoplasmic reticulum and in the Golgi apparatus. The central terminals of these cells are scalloped (sinusoid) axon terminals, surrounded by membrane-bound TMPase activity. Central terminals outline substantia gelatinosa Rolandi throughout the spinal cord, as well as the analogous nucleus spinalis trigemini in the medulla. TMPase-active central terminals outline "faisceau de la corne postérieure" in the sacral cord, as well as Lissauer's tract in the thoracic, upper lumbar, and sacral segments, and the paratrigeminal nucleus and the terminal (sensory) nucleus of the ala cinerea in the brainstem. Peripheral terminals displaying TMPase activity are fine nerve plexuses of C fibers. The TMPase activity of the central terminals disappears after dorsal rhizotomy in the course of Wallerian degeneration, and is depleted in the course of transganglionic degenerative atrophy (after transection of the related peripheral sensory nerve). TMPase is an outstanding genuine marker for the study of transganglionic regulation in Muridae.     

Role of phosphatidic acid phosphatase 2a in uptake of extracellular lipid phosphate mediators

Phosphatidic acid (PA) phosphatase 2a (PAP2a) is an integral membrane glycoprotein that hydrolyzes a number of structurally related lipid phosphate substrates when presented in mixed phospholipid and detergent micelles. The physiological substrate specificity and functions of this enzyme are unclear. Using reconstitution studies we demonstrate that PAP2a hydrolyses both PA and LysoPA substrates in a lipid bilayer. To investigate the activity of PAP2a against cellular substrates we generated HEK293 cell variants stably overexpressing the enzyme. Although one of these lines exhibited a 27-fold increase in PAP2 activity measured in vitro, levels of PA were not significantly reduced in comparison with control cells. Cell surface labeling and activity measurements demonstrate that a portion of the enzyme was localized to the cell surface. Pagano and Longmuir (J. Biol. Chem. 260 (1985) 1909) described the rapid uptake of PA by cultured cells, but the mechanisms and proteins involved were not identified. We found that overexpression of PAP2a was accompanied by a 2.1-fold increase in uptake of a fluorescent PA analog but that uptake of other phospholipids and diacylglycerols was unaltered. The increase in lipid uptake was completely dependent on PAP activity and unaffected by endocytosis inhibitors. Our results indicate that PAP2a is a cell surface enzyme that plays an active role in the hydrolysis and uptake of lipids from the extracellular space.     

The HIF-2alpha dependent induction of PAP and adenosine synthesis regulates glioblastoma stem cell function through the A2B adenosine receptor

Glioblastomas are lethal tumors characterized by malignant proliferation and recurrence promoted partly by glioblastoma stem cells (GSCs). GSCs are known to be regulated by hypoxia, but the mechanisms involved in this regulation are not fully understood. We now demonstrate that hypoxia-inducible factor HIF2α and prostatic acid phosphatase (PAP) are preferentially expressed in hypoxic GSCs in comparison with non-stem tumor cells and normal neural stem cells and that PAP is regulated by HIF2α. Targeting PAP in hypoxic GSCs inhibits self-renewal and proliferation in vitro and attenuates tumor initiation potential of GSCs in vivo. Using specific adenosine receptor antagonists, we further find that the pro-proliferative role of PAP is stemmed from stimulated A2B adenosine receptors. Moreover, selective blockage of A2B receptor or knockdown of PAP or A2B on hypoxic GSCs results in significant reduction of phosphorylation of Akt and Erk-1/2. Our results demonstrate that PAP may play a pro-proliferative role in hypoxic GSCs with a HIF2α-induction pattern, which may be ascribed to stimulated A2B receptors and activated Akt and Erk-1/2 pathways. Therefore, we propose that these identified molecular regulators of GSCs in the hypoxic niche might represent promising targets for antiglioblastoma therapies.     

AMP is an adenosine A1 receptor agonist

Numerous receptors for ATP, ADP, and adenosine exist; however, it is currently unknown whether a receptor for the related nucleotide adenosine 5'-monophosphate (AMP) exists. Using a novel cell-based assay to visualize adenosine receptor activation in real time, we found that AMP and a non-hydrolyzable AMP analog (deoxyadenosine 5'-monophosphonate, ACP) directly activated the adenosine A(1) receptor (A(1)R). In contrast, AMP only activated the adenosine A(2B) receptor (A(2B)R) after hydrolysis to adenosine by ecto-5'-nucleotidase (NT5E, CD73) or prostatic acid phosphatase (PAP, ACPP). Adenosine and AMP were equipotent human A(1)R agonists in our real-time assay and in a cAMP accumulation assay. ACP also depressed cAMP levels in mouse cortical neurons through activation of endogenous A(1)R. Non-selective purinergic receptor antagonists (pyridoxalphosphate-6-azophenyl-2',4'-disulfonic acid and suramin) did not block adenosine- or AMP-evoked activation. Moreover, mutation of His-251 in the human A(1)R ligand binding pocket reduced AMP potency without affecting adenosine potency. In contrast, mutation of a different binding pocket residue (His-278) eliminated responses to AMP and to adenosine. Taken together, our study indicates that the physiologically relevant nucleotide AMP is a full agonist of A(1)R. In addition, our study suggests that some of the physiological effects of AMP may be direct, and not indirect through ectonucleotidases that hydrolyze this nucleotide to adenosine.     

Prostatic acid phosphatase, a neglected ectonucleotidase

Two recent papers reveal that the soluble and secreted prostatic acid phosphatase, an enzyme that has long served as a diagnostic marker for prostate cancer, has a membrane-bound splice variant. This enzyme exhibits ecto-5′-nucleotidase activity, is widely distributed, and implicated in the formation of chronic pain. While prostatic acid phosphatase hydrolyzes phosphomonoesters other than 5′-nucleoside monophosphates these novel data suggest that, in addition to ecto-5′-nucleotidase and the alkaline phosphatases, prostatic acid phosphatase must be taken into account in future studies on extracellular adenosine production.     

A novel mammalian lithium-sensitive enzyme with a dual enzymatic activity, 3'-phosphoadenosine 5'-phosphate phosphatase and inositol-polyphosphate 1-phosphatase.

We report the molecular cloning in Rattus norvegicus of a novel mammalian enzyme (RnPIP), which shows both 3'-phosphoadenosine 5'-phosphate (PAP) phosphatase and inositol-polyphosphate 1-phosphatase activities. This enzyme is the first PAP phosphatase characterized at the molecular level in mammals, and it represents the first member of a novel family of dual specificity enzymes. The phosphatase activity is strictly dependent on Mg2+, and it is inhibited by Ca2+ and Li+ ions. Lithium chloride inhibits the hydrolysis of both PAP and inositol-1,4-bisphosphate at submillimolar concentration; therefore, it is possible that the inhibition of the human homologue of RnPIP by lithium ions is related to the pharmacological action of lithium. We propose that the PAP phosphatase activity of RnPIP is crucial for the function of enzymes sensitive to inhibition by PAP, such as sulfotransferase and RNA processing enzymes. Finally, an unexpected connection between PAP and inositol-1,4-bisphosphate metabolism emerges from this work.     

The expression of phosphatidic acid phosphatase 2a, which hydrolyzes lipids to generate diacylglycerol, is regulated by p73, a member of the p53 family

p73, a p53-related gene, is essential for a development of animals, while p53 is important for tumor formation. And little is known about the target genes specifically regulated by p73. Identifying the specific targets of p73 is important to understand the physiological roles of p73. To identify the genes specifically regulated by p73, we conducted serial analysis of gene expression to quantitatively evaluate messenger RNA populations. We found that the gene for phosphatidic acid phosphatase 2a (PAP2a), an enzyme that hydrolyzes lipids to generate diacylglycerol, was specifically upregulated by ectopic production of p73beta. The promoter region of this gene contains an element that is functionally responsive to p73beta. And the quantity of PAP2a protein was upregulated by ectopic production of p73beta. These results suggest that the expression of PAP2a is directly regulated by p73.     

Clinical behaviour of prostatic specific antigen and prostatic acid phosphatase: a comparative study

We assayed prostatic specific antigen (PSA) and prostatic acid phosphatase (PAP) serum levels in 1383 patients using a double antibody radioimmunoassay (RIA) I125. Establishing the upper normal limit in 10 ng/ml PSA and 2.5 ng/ml for PAP, the false positive results were only 1.9 and 5.1 percent in men with non-prostatic benign or malignant pathology and respectively 0 and 2.2 percent in women. We detected false positive levels for these two tumoral markers in 3.5 and 4.7 percent of patients with non-complicated benign prostatic hypertrophy, 64.8 and 19.2 percent in complicated benign prostatic hypertrophy, 24 and 16 percent in acute prostatitis and 3.3 percent in chronic prostatitis. The sensitivity in patients with prostate cancer was 87.2 percent for PSA and 64.1 percent for PAP, and there was a better correlation with PSA than PAP for tumoral spread and histological grading. Finally, clinical efficacy was higher with PSA and was no better when both markers were assayed.     

Intra-articular hyaluronan (hyaluronic acid) and hylans for the treatment of osteoarthritis: mechanisms of action

Although the predominant mechanism of intra-articular hyaluronan (hyaluronic acid) (HA) and hylans for the treatment of pain associated with knee osteoarthritis (OA) is unknown, in vivo, in vitro, and clinical studies demonstrate various physiological effects of exogenous HA. HA can reduce nerve impulses and nerve sensitivity associated with the pain of OA. In experimental OA, this glycosaminoglycan has protective effects on cartilage, which may be mediated by its molecular and cellular effects observed in vitro. Exogenous HA enhances chondrocyte HA and proteoglycan synthesis, reduces the production and activity of proinflammatory mediators and matrix metalloproteinases, and alters the behavior of immune cells. Many of the physiological effects of exogenous HA may be a function of its molecular weight. Several physiological effects probably contribute to the mechanisms by which HA and hylans exert their clinical effects in knee OA.     

Mice Deficient in Transmembrane Prostatic Acid Phosphatase Display Increased GABAergic Transmission and Neurological Alterations

Prostatic acid phosphatase (PAP), the first diagnostic marker and present therapeutic target for prostate cancer, modulates nociception at the dorsal root ganglia (DRG), but its function in the central nervous system has remained unknown. We studied expression and function of TMPAP (the transmembrane isoform of PAP) in the brain by utilizing mice deficient in TMPAP (PAP^−/− mice). Here we report that TMPAP is expressed in a subpopulation of cerebral GABAergic neurons, and mice deficient in TMPAP show multiple behavioral and neurochemical features linked to hyperdopaminergic dysregulation and altered GABAergic transmission. In addition to increased anxiety, disturbed prepulse inhibition, increased synthesis of striatal dopamine, and augmented response to amphetamine, PAP-deficient mice have enlarged lateral ventricles, reduced diazepam-induced loss of righting reflex, and increased GABAergic tone in the hippocampus. TMPAP in the mouse brain is localized presynaptically, and colocalized with SNARE-associated protein snapin, a protein involved in synaptic vesicle docking and fusion, and PAP-deficient mice display altered subcellular distribution of snapin. We have previously shown TMPAP to reside in prostatic exosomes and we propose that TMPAP is involved in the control of GABAergic tone in the brain also through exocytosis, and that PAP deficiency produces a distinct neurological phenotype.     

Subcellular localization and properties of pyridoxal phosphate phosphatases of human polymorphonuclear leukocytes and their relationship to acid and alkaline phosphatase

Using a novel fluorimetric assay for pyridoxal phosphate phosphatase, human polymorphonuclear leucocytes were found to exhibit both acid an alkaline activities. The neutrophils were homogenised in isotonic sucrose and subjected to analytical subcellular fractionation by sucrose density gradient centrigfugation. The alkaline pyridoxal phosphate phosphatase showed a very similar distribution to alkaline phosphatase an was located solely to the phosphasome granules. Fractionation experiments on neutrophils treated with isotonic sucrose containing digitonin and inhibitor studies with diazotised sulphanilic acid and levamisole further confirmed that both enzyme activities had similar locations and properties. Acid pyridoxal phosphate phosphatase activity was located primarily to the tertiary granule with a partial azurophil distribution. Fractionation studies on neutrophils homogenised in isotonic sucrose containing digitonin and specific inhibitor studies showed that acid pyridoxal phosphate phosphatase and acid phosphatase were not the result of a single enzyme activity, Neutrophils were isolated from control subjects, patients with chronic granulocytic leukaemia and patients in the third trimester of pregnancy. The specific activities (munits/mg protein) of alkaline pyridoxal phosphate phosphatase an alkaline phosphatase varied widely in the three groups and the alterations occurred in a parallel manner. The specific activities of acid pyridoxal phosphate phosphatase and of acid phosphatase were similar in the three groups. These results, together with the fractionation experiments and inhibition studies strongly suggest that pyridoxal phosphate is a physiological substrate for neutrophil alkaline phosphatase.     

Plastidic phosphatidic acid phosphatases identified in a distinct subfamily of lipid phosphate phosphatases with prokaryotic origin

Plastidic phosphatidic acid phosphatase (PAP) dephosphorylates phosphatidic acid to yield diacylglycerol, which is a precursor for galactolipids, a primary and indispensable component of photosynthetic membranes. Despite its functional importance, the molecular characteristics and phylogenetic origin of plastidic PAP were unknown because no potential homologs have been found. Here, we report the isolation and characterization of plastidic PAPs in Arabidopsis that belong to a distinct lipid phosphate phosphatase (LPP) subfamily with prokaryotic origin. Because no homolog of mammalian LPP was found in cyanobacteria, we sought an LPP ortholog in a more primitive organism, Chlorobium tepidum, and its homologs in cyanobacteria. Arabidopsis had five homologs of cyanobacterial LPP, three of which (LPP gamma, LPP epsilon 1, and LPP epsilon 2) localized to chloroplasts. Complementation of yeast Delta dpp1 Delta lpp1 Delta pah1 by plastidic LPPs rescued the relevant phenotype in vitro and in vivo, suggesting that they function as PAPs. Of the three LPPs, LPP gamma activity best resembled the native activity. The three plastidic LPPs were differentially expressed both in green and nongreen tissues, with LPP gamma expressed the highest in shoots. A knock-out mutant for LPP gamma could not be obtained, although a lpp epsilon 1 lpp epsilon 2 double knock-out showed no significant changes in lipid composition. However, lpp gamma homozygous mutant was isolated only under ectopic overexpression of LPP gamma, suggesting that loss of LPP gamma may cause lethal effect on plant viability. Thus, in Arabidopsis, there are three isoforms of plastidic PAP that belong to a distinct subfamily of LPP, and LPP gamma may be the primary plastidic PAP.     

Molecular cloning and sequence analysis of cDNA encoding human prostatic acid phosphatase

lambda gt11 clones encoding human prostatic acid phosphatase (PAP) (EC 3.1.3.2) were isolated from human prostatic cDNA libraries by immunoscreening with polyclonal antisera. Sequence data obtained from several overlapping clones indicated that the composite cDNAs contained the complete coding region for PAP, which encodes a 354-residue protein with a calculated molecular mass of 41,126 Da. In the 5'-end, the cDNA codes for a signal peptide of 32 amino acids. Direct protein sequencing of the amino-terminus of the mature protein and its proteolytic fragments confirmed the identity of the predicted protein sequence. PAP has no apparent sequence homology to other known proteins. However, both the cDNA clones coding for human placental alkaline phosphatase and PAP have an alu-type repetitive sequence about 900 nucleotides downstream from the coding region in the 3'-untranslated region. Two of our cDNA clones differed from others at the 5'-ends. RNA blot analysis indicated mRNA of 3.3 kb. We are continuing to study whether acid phosphatases form a gene family as do alkaline phosphatases.     

Transganglionic regulation of the primary sensory neuron

Central terminals of the primary sensory neurons depend on the integrity of the retrograde transport mechanism within the peripheral axon. Whenever retrograde transport is impaired (either by injury or by blockade induced by perineural application of microtubule inhibitors) central terminals undergo transganglionic degenerative atrophy (TDA), characterized by depletion of substance P, somatostatin, FRAP (fluoride resistant acid phosphatase), TMPase (thiamine monophosphatase) and lectin-binding fucose-terminated glyco-conjugates. The TDA is essentially a failure of the central terminals to bind the above genuine marker substances. TDA-inflicted central terminals undergo a slowly proceeding ultrastructural deterioration, accompanied by derangement of the dorsal root potential, reflecting decreased functional activity of synaptic transmission between first and second-order cells. One of the important trophic substances carried by retrograde axoplasmic transport to dorsal root ganglion cells is nerve growth factor (NGF); blockade of NGF transport results in TDA; conversely, locally applied NGF delays or prevents TDA.     

Voltage sensitive phosphoinositide phosphatases of Xenopus: their tissue distribution and voltage dependence

Voltage-sensitive phosphatases (VSPs) are unique proteins in which membrane potential controls enzyme activity. They are comprised of the voltage sensor domain of an ion channel coupled to a lipid phosphatase specific for phosphoinositides, and for ascidian and zebrafish VSPs, the phosphatase activity has been found to be activated by membrane depolarization. The physiological functions of these proteins are unknown, but their expression in testis and embryos suggests a role in fertilization or development. Here we investigate the expression pattern and voltage dependence of VSPs in two frog species, Xenopus laevis and Xenopus tropicalis, that are well suited for experimental studies of these possible functions. X. laevis has two VSP genes (Xl-VSP1 and Xl-VSP2), whereas X. tropicalis has only one gene (Xt-VSP). The highest expression of these genes was observed in testis, ovary, liver, and kidney. Our results show that while Xl-VSP2 activates only at positive membrane potentials outside of the physiological range, Xl-VSP1 and Xt-VSP phosphatase activity is regulated in the voltage range that regulates sperm-egg fusion at fertilization.