Inhibition of pyroglutamyl peptidase II synthesis by phorbol ester in the Y-79 retinoblastoma cell

Pyroglutamyl peptidase II (EC 3.4.19.-), a highly specific membrane-bound TRH-degrading enzyme, is inactivated in Y-79 human retinoblastoma cells by exposure to 12-O-tetradecanoyl phorbol-13-acetate (TPA) in a biphasic manner. We have previously demonstrated a rapid decrease in pyroglutamyl peptidase II activity to 10% of the control level within 15 min, which returns to 70% of the control level by 1 h. This decrease results from enzyme phosphorylation by TPA-activated protein kinase-C. We now report a second phase of inactivation after longer exposure of cells to TPA. After 1 h, enzymatic activity slowly and progressively declined. By 7 h, only 15% of control activity remained. Cotreatment of cells with H-7, a protein kinase-C inhibitor, prevented this second phase of inactivation. Immunoblot experiments demonstrated a reduction in the amount of pyroglutamyl peptidase II in Y-79 membranes after long term exposure to TPA. Y-79 cells were labeled with [35S]methionine, and pyroglutamyl peptidase II was immunoprecipitated. A decreased incorporation of [35S]methionine paralleled the decrease in enzyme activity. These studies demonstrate that the second phase of inactivation after exposure to TPA is due to an inhibition of enzyme synthesis.

Rapid inactivation and phosphorylation of pyroglutamyl peptidase II in Y-79 human retinoblastoma cells after exposure to phorbol ester

Pyroglutamyl peptidase II (EC 3.4.19.-), a membrane-bound metalloproteinase, is a highly specific TRH-degrading enzyme. Exposure of Y-79 human retinoblastoma cells to 12-0-tetradecanoyl phorbol 13-acetate (TPA) decreased the activity of this enzyme in a time- and concentration-dependent manner (IC50 5 x 10(-9) M). After 15 min of TPA treatment, only 10% of pyroglutamyl peptidase II activity remained. TPA treatment did not affect the activity of the cytosolic enzyme pyroglutamyl peptidase I (EC 3.4.19.3) or the membrane-bound enzyme dipeptidyl peptidase IV (EC 3.4.19.3). Pretreatment of the cells with the protein kinase C inhibitors H-7 or sphingosine prevented the inactivation of pyroglutamyl peptidase II by TPA. The time course of the TPA-mediated effect paralleled the time course of translocation and activation of protein kinase C in this cell line. Immunoblot analysis demonstrated that inactivation of pyroglutamyl peptidase II was not due to dissociation or internalization of this enzyme molecule. Incubation of TPA-activated Y-79 cell membranes with gamma-[32P]-ATP followed by immunoprecipitation revealed a time-dependent phosphorylation of a 48 kilodalton subunit of pyroglutamyl peptidase II. These studies indicate that the phorbol ester effect is mediated by protein kinase C, and reveal a mechanism of potentiation of the action of TRH at its target sites.

Phosphorylation of the multicatalytic proteinase complex from bovine pituitaries by a copurifying cAMP-dependent protein kinase

The multicatalytic proteinase complex (MPC) constitutes a major nonlysosomal proteolytic system that may play an important role in the processing of biologically active peptides and enzymes, as well as in intracellular metabolism. We report that at least two of its subunits of MW 28,800 (S2) and 27,000 (S3) are phosphorylated by a cAMP-dependent protein kinase (PK-A) that copurifies with the complex isolated from bovine pituitaries. The cAMP-induced phosphorylation was time dependent and inhibited by a PK-A inhibitor. Although not an integral part of the complex, PK-A activity was still present even in 1700-fold-purified and apparently homogeneous preparations by criteria of nondissociating polyacrylamide gel electrophoresis. Furthermore, we present evidence that the copurification of the two enzymes is not species or tissue specific, or dependent on a single method of purification. The copurifying kinase was stimulated 10-fold by cAMP (10 microM) and 2- to 3-fold by a peptide substrate of the MPC, but was unaffected by protein kinase C activators (calcium and a phospholipid mixture). These findings suggest that protein phosphorylation may represent a mechanism for regulating the activity of the multicatalytic proteinase complex.

Metabolism of vasoactive peptides by plasma and purified renal aminopeptidase M

Aminopeptidase M (AmM; EC 3.4.11.2) is a membrane-bound peptidase present on renal brush border and vascular plasma membrane. In the present study, AmM, purified from rabbit kidney cortex, produced a single immunoprecipitin line against AmM antisera, hydrolyzed alanyl-, leucyl- and arginyl-beta-naphthylamides at rates of 5.1 +/- 0.5, 3.9 +/- 0.5 and 2.6 +/- 0.3 mumol/min/mg, respectively, exhibited little or no alpha-glutamyl-, aspartyl- or glycyl-prolyl-naphthylamidase activities (less than or equal to 0.14 mumol/min/mg), and was inhibited by o-phenanthroline, amastatin (IC50 = 400 nM) and bestatin (IC50 = 6 microM). The alanyl-naphthylamidase activity of unfractionated rabbit plasma was found to be identical to purified AmM regarding relative rates of hydrolysis of alanyl-, leucyl- and arginyl-naphthylamides (100:79:42), pH optimum, and inhibition profile. In comparative studies with the purified enzyme, immunoreactive AmM accounted for essentially all of the alanyl-2-naphthylamidase activity of rabbit plasma. N-Terminal metabolism of (Met5)enkephalin by purified renal AmM was 3.92 +/- 0.69 mumol/min/mg, followed by somatostatin (1.25 mumol/min/mg), hepta(5-11)substance P (1.14 +/- 0.13 mumol/min/mg), (Asn1)angiotensin II (1.11 +/- 0.06 mumol/min/mg), angiotensin III (0.45 +/- 0.04 mumol/min/mg) and des(Asp1)-angiotensin I (0.36 +/- 0.04 mumol/min/mg). In contrast, substance P, bradykinin, (Sar1,Ala8)angiotensin II and neurokinin analogs containing modified N-termini (e.g. Ac-Arg) were resistant to hydrolysis by AmM. Peptide degradation was optimal at neutral pH and was inhibited by amastatin (IC50 = 200 nM) and bestatin (IC50 = 5 microM). Apparent Km values ranged from 15.7 +/- 0.4 microM for angiotensin III to 102 +/- 2 microM for (Met5)enkephalin. These data support a significant role for vascular and plasma AmM in the metabolism of circulating vasoactive peptides.

Evaluation of the role of prolyl endopeptidase and pyroglutamyl peptidase I in the metabolism of LHRH and TRH in brain

Intraneuronal peptide regulatory mechanisms are still poorly understood. The cytosolic enzymes prolyl endopeptidase (EC 3.4.21.26) and pyroglutamyl peptidase I (E.C.3.4.19.3) degrade both TRH and LHRH. Previous studies from this laboratory have not supported a role for these enzymes in the control of TRH levels. These studies have now been extended to cell and organ cultures and examine the effects of enzyme inhibition on LHRH. Exposure of dispersed hypothalamic cells or median eminences in culture to Z-Pro-Prolinal and pyroglutamyl diazomethyl ketone, specific inhibitors of prolyl endopeptidase and pyroglutamyl peptidase I respectively, did not change TRH content or recovery of released TRH. In vivo and in vitro treatment with these inhibitors did not modify the content of LHRH or recovery of this peptide upon release from several brain regions except in the olfactory bulb where an unexpected decrease in levels was observed. Olfactory bulb levels of TRH also decreased but only after prolonged in vivo inhibitor treatment. The decrease in olfactory bulb LHRH and TRH could not be accounted for by enzyme induction and is likely due to a non-specific or indirect effect of the inhibitors on the processing of these peptides. These studies demonstrate that levels of LHRH and TRH in brain are not controlled by cytosolic peptidases.

Inhibition of angiotensin III formation by thiol derivatives of acidic amino acids

Angiotensin III is formed by removal of the N-terminal Asp residue of angiotensin II in a reaction catalyzed by glutamyl aminopeptidase (aminopeptidase A EC 3.4.11.7). Thiol derivatives of glutamate and aspartate in which the alpha-COOH group was replaced by -CH2SH were synthesized as inhibitors of glutamyl aminopeptidase. Glutamate thiol was a potent inhibitor of glutamyl aminopeptidase (Ki = 4 x 10(-7) M) but even more potently inhibited microsomal alanyl aminopeptidase (Ki = 2.5 x 10(-7) M). Aspartate thiol (beta-homocysteine) was a less potent but more selective inhibitor of glutamyl aminopeptidase (glutamyl aminopeptidase: Ki = 1.2 x 10(-6) M; microsomal alanyl aminopeptidase: Ki = 7.5 x 10(-6) M). Neither compound inhibited cytosolic leucyl aminopeptidase. Aspartate thiol blocked the conversion of angiotensin II to angiotensin III. These derivatives are more selective than amastatin and may be of value in studies probing the biological significance of angiotensin III.

Pyroglutamyl peptidase II inhibition specifically increases recovery of TRH released from rat brain slices

Pyroglutamyl peptidase II (EC 3.4.19-) is a highly specific membrane-bound thyrotropin releasing hormone (TRH) degrading enzyme. To study the functional significance of pyroglutamyl peptidase II in TRH degradation, we synthesized the reversible inhibitor N-1-carboxy-2-phenylethyl (Nimbenzyl)-histidyl-beta-naphthylamide (CPHNA). CPHNA inhibited the enzyme with a Ki of 8 microM, but had no effect no TRH receptors or no prolyl endopeptidase (EC 3.4.21.26). It weakly inhibited cytosolic pyroglutamyl peptidase I (EC 3.4.19.3). CPHNA at a concentration of 10(-4) M increased both the basal and potassium stimulated recovery of TRH released from hypothalamic slices by approximately two-fold. An even higher recovery was observed in slices from brain regions with relatively high levels of pyroglutamyl peptidase II. CPHNA had no effect on the basal recovery of gamma-aminobutyric acid or Met-enkephalin released from brain slices but decreased the potassium stimulated recovery of both Metenkephalin and gamma-aminobutyric acid. These data further support the involvement of pyroglutamyl peptidase II in the extracellular inactivation of brain TRH.

Sodium butyrate induces pyroglutamyl peptidase I and decreases thyrotropin-releasing hormone receptors in GH3 cells

The effect of sodium butyrate treatment on TRH-degrading enzymes and TRH receptors in GH3 cells was investigated. The specific activity of pyroglutamyl peptidase I (EC 3.4.19.3) was increased by exposure to sodium butyrate in a time- and concentration-dependent manner, whereas the specific activity of prolyl endopeptidase (EC 3.4.21.26) was unchanged. The maximal effect occurred at a concentration of 1 mM sodium butyrate and 16 h after exposure. The increase was reversible upon removal of sodium butyrate from the cell culture. Cycloheximide totally blocked the stimulation, indicating that the increase was due to new protein synthesis. Sodium butyrate had no effect on pyroglutamyl peptidase I activity in the AtT-20 cell line. [methyl-3H]TRH binding to intact GH3 cells was reduced to 70% of the control value when cells were exposed to 1 mM sodium butyrate for 8 h. A maximal decrease in binding to 40% of the control value occurred after 16 h of exposure. The Kd of [methyl-3H]TRH binding was not changed. Sodium butyrate altered GH3 cell morphology, but the morphological changes occurred after alterations of pyroglutamyl peptidase I activity and [methyl-3H]TRH-binding sites. Other agents known to alter GH3 cell morphology had no effect on pyroglutamyl peptidase I activity. These results indicate that sodium butyrate can in some respects mimic the action of T3 on GH3 cells. Moreover, they provide further evidence that the activity of pyroglutamyl peptidase I, but not prolyl endopeptidase, is subject to regulation in the GH3 cell.

Regulation of thyrotropin releasing hormone degrading enzymes in rat brain and pituitary by L-3,5,3'-triiodothyronine

The effect of treatment with L-3,5,3'-triiodothyronine (T3) on the levels of pyroglutamyl peptidase I and pyroglutamyl peptidase II in rat brain regions, pituitary, and serum was studied. Pyroglutamyl peptidase I cleaves pyroglutamyl peptides such as thyrotropin releasing hormone (TRH), luteinizing hormone releasing hormone, neurotensin, and bombesin, whereas pyroglutamyl peptidase II appears to be specific for TRH. Acute administration of T3 did not affect pyroglutamyl peptidase I in any of the regions studied, whereas pyroglutamyl peptidase II was significantly elevated in frontal cortex and pituitary. Treatment with T3 for 10 or 14 days significantly elevated pyroglutamyl peptidase I in pituitary, hypothalamus, olfactory bulb, hippocampus, and thalamus. Chronic T3 treatment elevated pyroglutamyl peptidase II in frontal cortex and in serum. These studies demonstrate regulation of neuropeptide degrading enzymes by thyroid hormones in vivo. This regulation may play a role in the negative feedback control of thyroid status by T3.

Occurrence of pyroglutamyl peptidase II, a specific TRH degrading enzyme in rabbit retinal membranes and in human retinoblastoma cells

Pyroglutamyl peptidase II, a highly specific thyrotropin releasing hormone (TRH)-degrading enzyme is found in highest concentration in brain where it is localized to synaptic membranes. Retina contains relatively high concentrations of both immunoreactive TRH and TRH receptors. We report that the specific activity of pyroglutamyl peptidase II in rabbit retinal membranes exceeds that of all non-CNS tissues thus far studied. Nine clonal cell lines were screened for this enzymatic activity. The specific activity of pyroglutamyl peptidase II in Y79 retinoblastoma cells was greater than the highest activity found in other cell lines by approximately one order of magnitude. These studies further support a functional relationship between pyroglutamyl peptidase II and TRH and identify a cell line suitable for studies on the regulation of this enzyme.

Intracerebroventricular infusion of inhibitors of endopeptidase-24.11 ('enkephalinase') increases the spontaneous firing frequency of an identifiable set of cells in the substantia nigra

The effect of inhibitors of the membrane-bound metalloendopeptidase-24.11 ('enkephalinase') on the activity of electrophysiologically identifiable neurons in the substantia nigra is described. Dopaminergic and non-dopaminergic cells were examined. Cells were classified by their responses to striatal stimulation. Only those cells in which the stimulation evoked excitation (alone or mixed with inhibition) responded to the inhibitors. Those cells in which the evoked response was only inhibition did not respond to the drugs. Infusion of 1 mumol of N-[1-(R,S)-carboxy-2-phenyl-ethyl]Phe-pAB (CPAB), 1 or 2 mumol of N-[1-(R,S)-carboxy-3-phenylpropyl]Phe-pAB (CPPAB) into the lateral ventricle produced statistically significant increases (pre- to post-drug treatment) in the spontaneous activity of cells exhibiting excitatory evoked responses: average increases were 33.3%. The increase in spontaneous activity reached an apparent maximum 20 min after the end of the infusion. The increased firing frequency was shown to result from the inhibition of the enzyme, rather than a non-specific effect, as the infusion of 2 mumol of N-[1-(R,S)-carboxy-2-phenyl-ethyl]Leu-pAB, an inhibitor structurally related to CPAB and CPPAB yet two orders of magnitude less potent, was without effect on the activity of nigral neurons. The inhibition of the enzyme by 1 mumol CPAB was verified through in vitro assay. We hypothesize that inhibition of the enzyme enhances peptide-modulated (tachykinin and/or enkephalin) excitation in select neurons of the substantia nigra.

Regulation of a thyrotropin-releasing hormone-degrading enzyme in GH3 cells: induction of pyroglutamyl peptidase I by 3,5,3'-triiodothyronine

The effect of exposure of GH3 cells to T3 on the TRH-degrading enzymes pyroglutamyl peptidase I (EC 3.4.19.3) and prolyl endopeptidase (EC 3.4.21.26) was studied. T3 produced a dose-dependent increase in the specific activity of pyroglutamyl peptidase I after 3 days of exposure. The EC50 for T3 was 5 X 10(-10) M. The specific activity of prolyl endopeptidase was unaffected by exposure to T3. The increase in pyroglutamyl peptidase I activity was dependent upon the time of exposure of the cells to this hormone. A maximal effect occurred at 72 h. The stimulation of pyroglutamyl peptidase I by T3 was totally blocked by cycloheximide, indicating that this enzyme is induced in GH3 cells by T3. The effect of T3 on the two TRH-degrading enzymes was also studied in the ACTH-secreting cell line AtT20. T3 had no effect on these enzymes in the AtT20 cell, suggesting that the effect of T3 on pyroglutamyl peptidase I may be cell specific. These studies indicate that the induction of pyroglutamyl peptidase I by T3 may contribute to the negative feedback regulation of T3 levels.

Specific inhibitors of pyroglutamyl peptidase I and prolyl endopeptidase do not change the in vitro release of TRH or its content in rodent brain

Pyroglutamyl diazomethyl ketone and N-benzyloxycarbonyl prolyl prolinal, specific inhibitors of pyroglutamyl peptidase I and prolyl endopeptidase respectively, were used to study the possible role of these enzymes in the regulation of thyrotropin releasing hormone turnover. In vitro thyrotropin releasing hormone release by male rat hypothalamic slices was studied. Combined in vitro treatment with 10(-5)M of both inhibitors totally inhibited both enzymatic activities. The treatment did not affect basal or 56 mM K+ induced thyrotropin releasing hormone release or thyrotropin releasing hormone levels in slices. Repeated combined intraperitoneal injections of the two inhibitors for up to 12 hours produced a 70%-95% reduction in mouse brain pyroglutamyl peptidase I specific activity and a 65%-85% reduction in prolyl endopeptidase specific activity. Thyrotropin releasing hormone levels were unaffected by this treatment in all regions tested. The data suggest that these two enzymes are not involved in the intra- or extracellular control of thyrotropin releasing hormone levels in brain or hypophysis.

Neuropeptide-specific peptidases: does brain contain a specific TRH-degrading enzyme?

The particulate fraction of brain homogenates contains an enzyme that cleaves the pyroglutamyl-histidyl bond of thyrotropin-releasing hormone (TRH) but is clearly distinct from the more widely distributed pyroglutamyl peptidase (EC 3.4.19.3). This particulate enzyme is highly localized to brain where it is found on synaptosomal membranes. It exhibits an unusual degree of substrate specificity. For example, it does not cleave the pyroglutamyl-histidyl bond of luteinizing hormone-releasing hormone (LHRH) or the pyroglutamyl histidyl bond of the chromogenic substrate pyroglutamyl-histidyl-2-naphthylamide. Evidence is reviewed supporting the possibility that this enzyme, first detected in serum and originally referred to as "thyroliberinase", may be the first neuropeptide-specific peptidase to be characterized.

Delineation of a particulate thyrotropin-releasing hormone-degrading enzyme in rat brain by the use of specific inhibitors of prolyl endopeptidase and pyroglutamyl peptide hydrolase

The degradation of thyrotropin-releasing hormone in rat brain homogenates was studied in the presence of N-benzyloxycarbonyl-prolyl-prolinal and pyroglutamyl diazomethyl ketone, specific and potent active-site-directed inhibitors of prolyl endopeptidase and pyroglutamyl peptide hydrolase, respectively. Substantial TRH degradation was observed, suggesting the presence of another thyrotropin-releasing hormone-degrading enzyme(s). Reports of a thyrotropin-releasing hormone-degrading enzyme with narrow specificity that cleaves the pGlu-His bond of this tripeptide led us to develop a coupled assay using pGlu-His-Pro-2NA as the substrate to measure this activity. Cleavage of the pGlu-His bond of this substrate under conditions in which pyroglutamyl peptide hydrolase is not expressed occurred in the particulate fraction of a rat brain homogenate. This particulate pyroglutamyl-peptide cleaving enzyme was not inhibited by pyroglutamyl diazomethyl ketone but was inhibited by metal chelators such as EDTA and o-phenanthroline. The particulate pyroglutamyl-peptide cleaving enzyme was found predominantly in the brain. Activity in brain regions varied widely with highest levels present in cortex and hippocampus and very low levels in pituitary. The data suggest that degradation of thyrotropin-releasing hormone by the particulate fraction of a brain homogenate is catalyzed mainly by an enzyme that cleaves the pGlu-His bond of thyrotropin-releasing hormone but is distinct from pyroglutamyl peptide hydrolase.

Evidence for regulation of a thyrotropin-releasing hormone degradation pathway in GH3 cells

GH3 cells, cloned from a rat anterior pituitary tumor, synthesize and secrete PRL in response to TRH. One of the pathways of TRH degradation is removal of the N-terminal pyroglutamyl residue catalyzed by pyroglutamyl peptide hydrolase (PPH; EC 3.4.11.8). We recently described the synthesis and properties of 5-oxoprolinal, a specific and potent (Ki = 26 nM) inhibitor of PPH. The effect of long term exposure of GH3 cells to 5-oxoprolinal on PPH activity was studied by incubating cells with inhibitor for 3 days, harvesting, washing to remove inhibitor, and assaying for PPH. Unexpectedly, we found a marked (300%) increase in PPH activity. This effect was dependent on the concentration of 5-oxoprolinal (EC50 = 10(-7) M) and was time dependent, with a rapid increase in enzyme activity occurring during the first 24 h. Cycloheximide did not block the increase. The results suggest that the activity of PPH in GH3 cells is subject to complex regulatory mechanisms.

The effect of inhibitors of prolyl endopeptidase and pyroglutamyl peptide hydrolase on TRH degradation in rat serum

The identity of the enzymes catalyzing the degradation of thyrotropin releasing hormone (TRH) in rat serum was investigated by the use of specific inhibitors of prolyl endopeptidase and pyroglutamyl peptide hydrolase. These inhibitors did not protect TRH from degradation, but o-phenanthroline afforded significant protection. The participation of "thyroliberinase", a metalloenzyme which cleaves TRH at the pyroglutamyl-His bond was implied. A coupled assay using the chromogenic substrate pyroglutamyl-His-Pro-2-naphthylamide and excess diaminopeptidase IV was developed to specifically quantitate "thyroliberinase" activity. Rat serum catalyzed the degradation of 67.5 nmoles substrate/ml serum/h. The data indicate that TRH is degraded in rat serum predominantly by "thyroliberinase" and that prolyl endopeptidase and pyroglutamyl peptide hydrolase do not contribute significantly to this process.

Pyroglutamyl diazomethyl ketone: potent inhibitor of mammalian pyroglutamyl peptide hydrolase

Pyroglutamyl peptide hydrolase (EC 3.4.11.8), a cysteine protease, cleaves the N-terminal pyroglutamyl residue from pyroglutamyl peptides such as thyrotropin releasing hormone. Pyroglutamyl diazomethyl ketone was synthesized as an active site directed inhibitor. Preincubation of the partially purified bovine brain enzyme with nanomolar concentrations of inhibitor produced rapid inactivation. Inhibitor concentrations five orders of magnitude higher did not inactivate other exo- and endopeptidases. A dose of 0.1 mg/kg administered intraperitoneally to mice totally inactivated the enzyme in all tissues studied including brain. Pyroglutamyl diazomethyl ketone should be of value in studies on the physiological role of this enzyme in the metabolism of pyroglutamyl-containing peptides.

5-Oxoprolinal: transition-state aldehyde inhibitor of pyroglutamyl-peptide hydrolase

Pyroglutamyl-peptide hydrolase (EC 3.4.11.8) removes the N-terminal pyroglutamyl residue from pyroglutamyl-containing peptides such as thyrotropin-releasing hormone (TRH), luteinizing hormone-releasing hormone (LH-RH), neurotensin, and bombesin. The aldehyde analogue of pyroglutamate, 5-oxoprolinal, was synthesized as an active site directed transition-state inhibitor of the enzyme. 5-Oxoprolinal was found to be a potent (Ki = 26 nM) and specific competitive inhibitor of pyroglutamyl-peptide hydrolase. Other aldehydes tested inhibited the enzyme only weakly or not at all. 5-Oxoprolinal blocked the degradation of LH-RH by purified pyroglutamyl-peptide hydrolase. The inhibitor, when injected into mice, inhibited the enzyme after 10 and 30 min. 5-Oxoprolinal should be of value in studies probing the biological significance of pyroglutamyl-peptide hydrolase.

Inhibitors of an enkephalin degrading membrane-bound metalloendopeptidase: analgesic properties and effects on striatal enkephalin levels

Intraperitoneal administration of N-[1-(R,S)-carboxy-2-phenylethyl-Phe-p-aminobenzoate, synthesized in this laboratory as a potent inhibitor of membrane-bound metalloendopeptidase (EC 3.4.24.11) caused a prolonged but weak analgesic effect on rats as measured by the tail flick test. It also caused a transitory but significant increase in striatal [Leu5]- and [Met5]enkephalin levels 3 h, after administration. Analogs of the inhibitor in which the phenylalanyl residue was replaced by an alanyl or glycyl residue also elicited prolonged analgesic responses although their inhibitory potencies were 75 and more than 1500 times lower respectively. The glycine containing derivative did not alter striatal enkephalin levels 3 h, after administration. The data suggest that inhibition of the metalloendopeptidase decreases the rate of degradation of endogenous enkephalins, however the analgesic properties of the inhibitors do not seem to be related to their inhibitory potencies. Factors other than changes in striatal enkephalin levels may contribute to the analgesic effect of the three N-carboxyphenylethyl derivatives.

Peptide-degrading enzymatic activities in GH3 cells and rat anterior pituitary homogenates

The activities of a number of peptide-degrading enzymes were compared in homogenates of GH3 cells and rat anterior pituitaries. The enzymes studied were prolyl endopeptidase (EC 3.4.21.26), a soluble metalloendopeptidase, pyroglutamyl peptide hydrolase (EC 3.4.11.8), a multicatalytic protease complex, cathepsin B (EC 3.4.22.1), cathepsin D (EC 3.4.23.5), aminopeptidase (EC 3.4.11.2), and a membrane-bound neutral metalloendopeptidase (EC 3.4.24.11). Specific substrates were used to measure the activities, and active-site-directed inhibitors were used to verify the identities of the enzymes studied. Of the two lysosomal enzymes studied, cathepsin B, the enzyme with the highest activity in both preparations, had 5 times the activity in GH3 cell homogenates as in anterior pituitary homogenates. Cathespin D had a somewhat higher activity in the anterior pituitary homogenates than in the GH3 cell homogenates. Soluble metalloendopeptidase and prolyl endopeptidase, both cytoplasmic enzymes, had about twice the activity in GH3 cell homogenates as in anterior pituitary homogenates. Membrane-bound neutral metalloendopeptidase in the GH3 cell homogenates had 25% of the activity of the anterior pituitary homogenates. Of the two TRH-degrading enzymes, the activity of prolyl endopeptidase in GH3 cell homogenates was about 25 times higher than that of pyroglutamyl peptide hydrolase. Since the secretory function of the pituitary is in part controlled by neuropeptides, the knowledge of the enzyme profiles of the GH3 cells and the anterior pituitary should be of value in studying the metabolism of neuropeptides and peptide hormones in these systems.

Prolyl endopeptidase: inhibition in vivo by N-benzyloxycarbonyl-prolyl-prolinal

The activity of prolyl endopeptidase in homogenates of mouse tissues was determined 30 min after intraperitoneal injection of N-benzyloxycarbonyl-prolyl-prolinal (1.25 mg/kg), a potent transition state analog inhibitor (K1 = 14 nM) of prolyl endopeptidase (EC 3.4.21.26). A more than 85% decrease of enzyme activity was obtained in all tissues. The in vivo degradation of potential prolyl endopeptidase substrates was studied by following the release of sulfamethoxazole from N-benzyloxycarbonylglycyl-prolyl-sulfamethoxazole, a model synthetic substrate of the enzyme. When this substrate was given intraperitoneally, its enzymatic degradation was blocked after administration of the inhibitor in a dose- and time-dependent manner, indicating inhibition of the enzyme in vivo. Of interest is the long duration of the inhibition. After a relatively low inhibitor dose (5 mg/kg) significant inhibition was seen in most tissues even after 6 h. The brain was particularly sensitive to the effect of the inhibitor. Since prolyl endopeptidase readily degrades many proline-containing neuropeptides, the inhibitor should be of value in studies on the role of the enzyme in neuropeptide metabolism.

Prolyl endopeptidase

Prolyl endopeptidase (E.C. 3.4.21.26) an enzyme previously called post proline cleaving enzyme, TRH-deamidase or kininase B, may play a role in neuropeptide metabolism. This enzyme, highly active in brain and other tissues, catabolizes proline-containing peptides such as substance P, neurotensin, luteinizing hormone-releasing hormone, thyrotropin releasing hormone, bradykinin and angiotensin II. The structure of beta-neo-endorphin suggests that this opioid peptide is formed by the action of prolyl endopeptidase on a precursor of higher molecular weight. Formation of two biologically active fragments of substance P also requires the action of this enzyme. This review summarizes the current knowledge of the biochemistry of this enzyme, and its potential significance for neuropeptide physiology and pharmacology.

Inhibition of rabbit brain prolyl endopeptidase by n-benzyloxycarbonyl-prolyl-prolinal, a transition state aldehyde inhibitor

Prolyl endopeptidase cleaves peptide bonds on the carboxyl side of proline residues within a peptide chain. The enzyme readily degrades a number of neuropeptides including substance P, neurotensin, thyrotropin-releasing hormone, and luteinizing hormone-releasing hormone. The finding that the enzyme is inhibited by benzyloxycarbonyl-prolyl-proline, with a Ki of 50 microM, prompted the synthesis of benzyloxycarbonyl-prolyl-prolinal as a potential transition state analog inhibitor. Rabbit brain prolyl endopeptidase was purified to homogeneity for these studies. The aldehyde was found to be a remarkably potent inhibitor of prolyl endopeptidase with a Ki of 14 nM. This Ki is more than 3000 times lower than that of the corresponding acid or alcohol. By analogy with other transition state inhibitors, it can be assumed that binding of the prolinal residue to the S1 subsite and the formation of a hemiacetal with the active serine of the enzyme greatly contribute to the potency of inhibition. The specificity of the inhibitor is indicated by the finding that a variety of proteases were not affected at concentrations 150 times greater than the Ki for prolyl endopeptidase. The data indicate that benzyloxycarbonyl-prolyl-prolinal is a specific and potent inhibitor of prolyl endopeptidase and that consequently it should be of value in in vivo studies on the physiological role of the enzyme.