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

The narrow specificity pyroglutamate amino peptidase degrading TRH in rat brain is an ectoenzyme

In order to determine the pathway of extracellular metabolism of the thyrotropin releasing hormone (pyroglu-his-proNH(2)) in brain, the topographical organization of pyroglutamate aminopeptidase II on the plasma membrane was investigated. Its activity was only slightly increased when intact brain synaptosomes were lysed by osmotic shock or detergent treatment. Trypsin treatment of intact synaptosomes destroyed 70-80% of enzyme activity without affecting lactate dehydrogenase. Pyroglutamate aminopeptidase II activity was present in primary cultures of foetal mice cortical cells. It was detected in intact cells, was not released by the cells and its activity was not increased by saponin pretreatment. Trypsin treatment of the cells reduced pyroglutamate aminopeptidase II by 70% but did not affect pyroglutamate aminopeptidase I and lactate dehydrogenase. These data support that brain pyroglutamate aminopeptidase II is an ectoenzyme. They suggest that this enzyme could be responsible for thyrotropin releasing hormone extracellular catabolism in brain.

Regulation of adenohypophyseal pyroglutamyl aminopeptidase II activity by thyrotropin-releasing hormone and phorbol esters

Thyrotropin-releasing hormone (TRH) is inactivated by a narrow specificity ectopeptidase, pyroglutamyl aminopeptidase II (PPII), in the proximity of target cells. In adenohypophysis, PPII is present on lactotrophs. Its activity is regulated by thyroid hormones and 17beta-estradiol. Studies with female rat adenohypophyseal cell cultures treated with 3,3',5'-triiodo-L-thyronine (T3) showed that hypothalamic/paracrine factors, including TRH, can also regulate PPII activity. Some of the transduction pathways involve protein kinase C (PKC) and cyclic adenosine monophosphate (cAMP). The purpose of this study was to determine whether T3 levels or gender of animals used to propagate the culture determine the effects of TRH or PKC. PPII activity was lower in cultures from male rats. In cultures from both sexes, T3 induced the activity. The percentages of decrease due to TRH or PKC were independent of T3 or gender; the percentage of decrease due to cAMP may also be independent of gender. These results suggest that T3 and hypothalamic/paracrine factors may independently control PPII activity in adenohypophysis, in either male or female animals.

[3-Me-His(2)]-TRH combined with dopamine withdrawal rapidly and transiently increases pyroglutamyl aminopeptidase II activity in primary cultures of adenohypophyseal cells

TRH is hydrolyzed by pyroglutamyl aminopeptidase II (PP II), a highly specific ecto-enzyme which is localized on the surface of lactotrophs. To study whether PP II activity may be rapidly regulated during a burst of prolactin secretion, we used an in vitro model in which primary cultures of adenohypophyseal cells were incubated with 500 nM dopamine (DA) for 24 h prior to treatments. We observed a rapid increase of PP II activity when 100 nM [3-Me-His(2)]-TRH, a TRH agonist, was added at removal of DA. PPII activity was maximal after 20 min of treatment and reduced to time 0 activity at 30 min. Dopamine withdrawal alone, slightly and transiently, modified the enzyme activity: an initial activation at 15 min was followed by a transient inhibition at 20 min. The specific contribution of [3-Me-His(2)]-TRH in this paradigm was a transient enhancement of PP II activity. If DA was not removed, [3-Me-His(2)]-TRH was ineffective. These data demonstrate that during in vitro conditions that mimic a suckling episode, adenohypophyseal PP II activity is rapidly and reversibly adjusted.

Human TRH-degrading ectoenzyme cDNA cloning, functional expression, genomic structure and chromosomal assignment

Thyrotropin-Releasing Hormone (TRH) is an important extracellular signal substance that acts as a stimulator of hormone secretion from adenohypophyseal target cells and fulfills many criteria for the function of a neuromodulator/neurotransmitter within the central and peripheral nervous systems. The inactivation of TRH-signals is catalysed by a highly specific ectoenzyme. Here, we characterize the human TRH-degrading ectoenzyme (TRH-DE) by primary sequence, functional expression, genomic structure and chromosomal assignment. By screening a cDNA-library constructed from human lung, 5.7 kb of cDNA were identified. The longest open reading frame predicts a type II integral membrane protein of 117 kDa. The extracellular domain contains the HEXXH + E motif that is characteristic of a certain family of Zn-dependent aminopeptidases. Within this family, the sequences of human and rat TRH-DE reveal an unusual high degree of conservation (96% identical residues). Specific enzymatic activity was observed after transfecting COS-7 cells with human TRH-DE cDNA yielding a Km for TRH hydrolysis of 29.7 microM. Northern blot analysis demonstrated a restricted tissue distribution with highest transcript levels in the brain. Using fluorescent in situ hybridization with the cDNA and a genomic lambda clone, respectively, we localized the TRH-DE gene to the long arm of human chromosome 12. Five independent P1 artificial chromosome clones were required to span the complete cDNA sequence and revealed that it is distributed on 19 exons. Interspecies Southern analysis suggests that the gene is present as a single copy in human, monkey, rat, mouse, dog, bovine, rabbit and chicken DNA. All of these data further the notion that the TRH-DE is not an ordinary enzyme but a specific neuropeptidase that has been highly conserved among species.

Three TRH-like molecules are released from rat hypothalamus in vitro

TRH-like immunoreactivity distinct from TRH is present in various tissues and fluids. In order to determine whether TRH-like molecules are secreted by the hypothalamus, we analyzed tissues and media from hypothalamic slices incubated in Krebs Ringer bicarbonate. Media from basal or high KCl conditions contained 3 TRH-like molecules evidenced by reverse phase high performance liquid chromatography followed by TRH radioimmunoassay. Peak I corresponded to authentic TRH (73% of total immunoreactivity) and peaks II and III had a higher retention time. These additional TRH-like forms were neither detected in hypothalamic tissue nor in tissue or medium from olfactory bulb. Gel filtration analysis of hypothalamic media revealed only one TRH-like peak eluting as TRH, suggesting that the molecular weights of peaks II and III are similar to that of TRH. Peak II retention time was similar to that of pglu-phe-proNH2. We analysed if they could be produced by post secretory metabolism of TRH. Incubation of hypothalamic slices with [3H-Pro]-TRH did not produce radioactive species comigrating with peaks II or III. However, it induced rapid degradation to [3H-Pro]-his-prodiketopiperazine ([3H]-HPDKP). Inhibitor profile suggested that pyroglutamyl aminopeptidase II, but not pyroglutamyl aminopeptidase I, is responsible for [3H]-HPDKP production. These data are consistent with the hypothesis that pyroglutamyl aminopeptidase II is the main aminopeptidase degrading TRH in hypothalamic extracellular fluid. Furthermore, we suggest that the hypothalamus releases additional TRH-like molecules, one of them possibly pglu-phe-proNH2, which may participate in control of adenohypophyseal secretions.

The crystal structure of pyroglutamyl peptidase I from Bacillus amyloliquefaciens reveals a new structure for a cysteine protease

BACKGROUND

The N-terminal pyroglutamyl (pGlu) residue of peptide hormones, such as thyrotropin-releasing hormone (TRH) and luteinizing hormone releasing hormone (LH-RH), confers resistance to proteolysis by conventional aminopeptidases. Specialized pyroglutamyl peptidases (PGPs) are able to cleave an N-terminal pyroglutamyl residue and thus control hormonal signals. Until now, no direct or homology-based three-dimensional structure was available for any PGP.

RESULTS

The crystal structure of pyroglutamyl peptidase I (PGP-I) from Bacillus amyloliquefaciens has been determined to 1.6 A resolution. The crystallographic asymmetric unit of PGP-I is a tetramer of four identical monomers related by noncrystallographic 222 symmetry. The protein folds into an alpha/beta globular domain with a hydrophobic core consisting of a twisted beta sheet surrounded by five alpha helices. The structure allows the function of most of the conserved residues in the PGP-I family to be identified. The catalytic triad comprises Cys144, His168 and Glu81.

CONCLUSIONS

The catalytic site does not have a conventional oxyanion hole, although Cys144, the sidechain of Arg91 and the dipole of an alpha helix could all stabilize a negative charge. The catalytic site has an S1 pocket lined with conserved hydrophobic residues to accommodate the pyroglutamyl residue. Aside from the S1 pocket, there is no clearly defined mainchain substrate-binding region, consistent with the lack of substrate specificity. Although the overall structure of PGP-I resembles some other alpha/beta twisted open-sheet structures, such as purine nucleoside phosphorylase and cutinase, there are important differences in the location and organization of the active-site residues. Thus, PGP-I belongs to a new family of cysteine proteases.

Pyroglutamyl peptidase: an overview of the three known enzymatic forms

Pyroglutamyl peptidase can be classified as an omega peptidase which hydrolytically removes the amino terminal pyroglutamate (pGlu) residue from specific pyroglutamyl substrates. To date, three distinct forms of this enzyme have been identified in mammalian tissues. Type I is typically a cytosolic, cysteine peptidase displaying a broad pyroglutamyl substrate specificity and low molecular mass. Type II has been shown to be a membrane anchored metalloenzyme of high molecular mass with a narrow substrate specificity restricted to the hypothalamic releasing factor, thyrotropin-releasing hormone (TRH, pGlu-His-Pro-NH2). A third pyroglutamyl peptidase activity has also been observed in mammalian serum which displays biochemical characteristics remarkably similar to those of tissue Type II, namely a high molecular mass, sensitivity to metal chelating agents, and a narrow substrate specificity also restricted to TRH. This serum activity has subsequently been designated 'thyroliberinase'. This review surveys the biochemical, enzymatic, and structural properties of this interesting and unique class of peptidases. It also addresses the putative physiological roles which have been ascribed to these enzymes. Pyroglutamyl peptidase activities isolated and characterized from bacterial sources are also reviewed and compared with their mammalian counterparts.

Quantitation and regulation of pyroglutamyl peptidase II messenger RNA levels in rat tissues and GH3 cells

The distribution of the mRNA of the specific thyrotropin-releasing-hormone (TRH)-degrading enzyme pyroglutamyl peptidase II (EC 3.4.19.6) in rat tissues and brain regions and its regulation in rat tissues and in GH3 cells was studied by a reliable and quantitative solution hybridization ribonuclease protection assay. The distribution of pyroglutamyl peptidase II mRNA levels was uneven with the highest level of mRNA found in brain. Within brain the distribution of pyroglutamyl peptidase II mRNA was heterogeneous. A single dose of T3 markedly increased the level of pyroglutamyl peptidase II mRNA in the pituitary (p < 0.01) and in the liver (p < 0.05). In GH3 cells, exposure to T3 at concentrations from 10(-10) to 10(-6) M for time periods of 2-24 h, did not change pyroglutamyl peptidase II mRNA levels. Acute administration of TRH to rats had no effect on pyroglutamyl peptidase II mRNA levels. By contrast, TRH down-regulated pyroglutamyl peptidase II mRNA in GH3 cells. A similar effect was produced in GH3 cells by activators of protein kinase C. These studies reveal fundamental differences in the mechanism of regulation of pyroglutamyl peptidase II mRNA in pituitary and in GH3 cells. Elevation of pyroglutamyl peptidase II mRNA in liver by T3 suggests that this organ is the source of the enzyme in serum.

Multiple hypothalamic factors regulate pyroglutamyl peptidase II in cultures of adenohypophyseal cells: role of the cAMP pathway

In the adenohypophysis, thyrotrophin-releasing hormone (TRH) is inactivated by pyroglutamyl peptidase II (PPII), a TRH-specific ectoenzyme localized in lactotrophs. TRH slowly downregulates surface PPII activity in adenohypophyseal cell cultures. Protein kinase C (PKC) activation mimics this effect. We tested the hypothesis that other hypothalamic factors controlling prolactin secretion could also regulate PPII activity in adenohypophyseal cell cultures. Incubation for 16 h with pituitary adenylate cyclase activator peptide 38 (PACAP; 10(-6) M) decreased PPII activity. Bromocryptine (10(-8) M), a D2 dopamine receptor agonist, or somatostatin (10(-6) M) stimulated enzyme activity and blocked the inhibitory effect of [3-Me-His2]-TRH, a TRH receptor agonist. Bromocryptine and somatostatin actions were suppressed by preincubation with pertussis toxin (400 ng ml(-1)). Because these hypophysiotropic factors transduce some of their effects using the cAMP pathway, we analysed its role on PPII regulation. Cholera toxin (400 ng ml(-1)) inhibited PPII activity. Forskolin (10(-6) M) caused a time-dependent decrease in PPII activity, with maximal inhibition at 12-16 h treatment; ED50 was 10(-7) M. 3-isobutyl-1-methylxanthine or dibutiryl cAMP, caused a dose-dependent inhibition of PPII activity. These data suggest that increased cAMP down-regulates PPII activity. The effect of PACAP was blocked by preincubation with H89 (10(-6) M), a protein kinase A inhibitor, suggesting that the cAMP pathway mediates some of the effects of PACAP. Maximal effects of forskolin and 12-O-tetradecanoylphorbol 13-acetate were additive. PPII activity, therefore, is independently regulated by the cAMP and PKC pathways. Because most treatments inhibited PPII mRNA levels similarly to PPII activity, an important level of control of PPII activity by these factors may be at the mRNA level. We suggest that PPII is subject to 'homologous' and 'heterologous' regulation by elements of the multifactorial system that controls prolactin secretion.

A study of a highly specific pyroglutamyl aminopeptidase type-II from the membrane fraction of bovine brain

Pyroglutamyl aminopeptidase type-II is reported to be a highly specific, membrane-bound neuropeptidase, which has the ability to hydrolytically remove the L-pyroglutamyl residue (pGlu) from the N-terminus of thyrotropin releasing hormone (TRH, pGlu-His-Pro-NH2) and closely related tripeptides or tripeptide amides. The primary aim of this study was to purify this enzyme from bovine brain and to compare its characteristics with those previously reported. Following solubilization from the membrane fraction by limited proteolysis with trypsin, the enzyme was purified approximately 3000-fold with a 24% recovery of activity. A native molecular mass of 214,000 Da was determined for the purified enzyme by gel-filtration chromatography. A pH optimum of 6.8-7.6 was observed for the enzyme, with rapid inactivation occurring below pH 4.0 and above pH 9.2. Optimal enzyme activity was observed at 45 degrees C. On the basis of its inhibition, in a time-dependent manner, by metal complexing agents and its subsequent reactivation in the presence of metal ions, the enzyme was identified as a metallopeptidase. Substrate specificity studies revealed that, with the exception of pGlu-Phe-Pro-NH2, pGlu-7-amino-4-methyl-coumarin and pGlu-beta-naphthylamide, the purified enzyme removes N-terminal pGlu from only tri- and tetrapeptides with a histidine residue in the penultimate position. A number of N-terminal pyroglutamyl peptides of varying length were shown to competitively inhibit the enzyme. Of these, luteinizing hormone releasing hormone (LHRH) and LHRH 1-5, although not substrates for the enzyme, were found to be potent inhibitors, with Ki values of 8 and 11 microM, respectively. The study shows that while bovine brain PAPII shares many of the characteristics of PAPII from other mammalian tissues, its substrate specificity is not as narrow as previously reported.

The development of two fluorimetric assays for the determination of pyroglutamyl aminopeptidase type-II activity

Two fluorimetric assays for the determination of pyroglutamyl aminopeptidase type-II activity have been developed. The assays are based on hydrolysis of the quenched-fluorimetric substrate <Glu-His-Pro-7-amino-4-methylcoumarin. Following the removal of the N-terminal <Glu by pyroglutamyl aminopeptidase type-II, liberation of 7-amino-4-methylcoumarin from the metabolite His-Pro-7-amino-4-methylcoumarin is catalyzed by one of two methods: (i) the addition of partially purified bovine serum dipeptidyl aminopeptidase type-IV or (ii) by incubating the reaction mixture for up to 2 h at 80 degrees C, thus promoting the nonenzymatic cyclization of His-Pro-7-amino-4-methylcoumarin to cyclo His-Pro and free 7-amino-4-methylcoumarin. Pyroglutamyl aminopeptidase type-II from bovine brain is used to establish appropriate assay conditions. These fluorimetric assays offer expeditious alternatives to the existing radiolabeled thyrotropin-releasing hormone assays for the determination of PAPII activity.

Enhancement by streptozotocin-induced diabetes of pancreatic prolyl endopeptidase activity in neonatal rats

The effect of streptozotocin (STZ)-induced diabetes on the concentrations of deamidated TRH (TRH-OH), a metabolite of thyrotropin-releasing hormone (TRH) and prolyl endopeptidase (PE) activity were studied in the pancreas of neonatal rats to determine the contribution of beta-cells to PE activity and TRH-OH levels that we have previously found in this tissue. STZ treatment caused a significant reduction of immunoreactive TRH-OH levels on day-3 and -5 compared to untreated control rats. Reverse-phase high performance liquid chromatography of pooled extracts of 3-day-old normal rat pancreas revealed that about 50% of immunoreactive TRH-OH was found in the fractions representing authentic TRH-OH, whereas the remaining 50% eluted earlier. In STZ treated rats, all of the TRH-OH immunoreactive was associated with this early peak, no authentic TRH-OH could be detected. The specific activity of PE, on the other hand, rose 2.5-fold in diabetic 3-day-old pups (4.06 +/- 0.13 compared with 1.59 +/- 0.83 nmol/min/mg protein, P < 0.01, in controls). This increase declined with age (1.6- and 1.3-fold in 5 day- and 7-day-old pups, respectively). STZ treatment did not change pancreatic PE levels in 20-day-old rats control. Normalization of STZ induced hyperglycemia by sodium metavanadate treatment or by replacement of exogenous insulin did not restore pancreatic PE activity. The enhancement of PE activity following STZ treatment was specific for pancreas tissue. Furthermore, beta cytoxin drugs other than STZ that cause permanent diabetes such as alloxan enhanced PE activity to the same extend. Kinetic studies for PE activity show that Vmax is 3-fold higher in 3-day-old STZ-treated than in rat controls. In contrast, values for Km were comparable in rats of both groups (25 to 34 microM). We then tested whether the decrease of Vmax might have been caused by the presence of an PE inhibiting factor in these preparations. Gel-filtration experiments of pancreatic extracts revealed that the total apparent activity of eluted PE in 3-day-old control rats was 2-fold higher than in the original extract. In contrast, the recovery of eluted PE activity was not increased in the case of STZ-treated 3-day-old and untreated 20-day-old rats. These findings demonstrate that TRH-OH is identified in beta-cells and that an inhibiting factor(s) present in beta-cells appear(s) to be responsible for the unexpected enhancement of PE activity observed in STZ-treated neonatal rats.(ABSTRACT TRUNCATED AT 400 WORDS)

Assessment of the role of TRH in the release of [3H]-dopamine from rat nucleus accumbens-lateral septum slices

We have studied [3H]-dopamine ([3H]-DA) release from rat nucleus accumbens lateral septum slices in response to various paradigms aimed at increasing endogenous or exogenous thyrotropin releasing hormone (TRH) concentrations in the extracellular space. High KCl concentrations significantly enhanced [3H]-DA release by fourfold. TRH (10(-4) or 5 x 10(-4) M) did not affect [3H]-DA release. The release of [3H]-DA was not stimulated by TRH either in the presence of N-1-carboxy-2-phenylethyl (N(im)benzyl)-histidyl-beta naphthylamide, a specific pyroglutamyl peptidase II inhibitor, or that of specific inhibitors of prolyl endopeptidase and pyroglutamyl peptidase I. None of the peptidase inhibitors modified the [3H]-DA release by themselves. These results suggest that the TRH stimulation of [3H]-DA release in vitro observed in previous studies is not due to peptide inactivation but may be due to a nonspecific effect. TRH enhancement of DA release in nucleus accumbens in vivo may not be the result of a direct effect of TRH on DA terminals.

Ontogeny of prolyl endopeptidase, pyroglutamyl peptidase I, TRH, and its metabolites in rat pancreas

We demonstrate that two enzymes, soluble unspecific pyroglutamyl peptidase I and prolyl endopeptidase, able to degrade thyrotropin-releasing hormone (TRH) in vitro were present in pancreas at the early stage of rat development. Specific particulate pyroglutamyl peptidase II remained undetectable during ontogenesis. Pyroglutamyl peptidase I specific activity increased until day 3 and decreased after day 5. Furthermore, prolyl endopeptidase specific activity rose slightly to a peak on postnatal day 20. A good correlation between immunoreactive TRH and deaminated TRH (TRH-OH) was found in the 1st wk after birth. However, His-Pro diketopiperazine (DKP) levels were stable and low during development. We show that hot acidic extraction conditions could artefactually generate His-Pro DKP. In vivo, active site-directed inhibitors of pyroglutamyl peptidase I and prolyl endopeptidase enzymes do not show any TRH-deamidating and/or pyroglutamyl peptidase I pathways in neonatal rat pancreas. The data suggest that these two enzymes are not involved in intra- or extracellular control of TRH levels in neonatal rat pancreas and that pancreatic TRH content appears to be principally regulated by biosynthetic steps. Nevertheless, low levels of endogenous His-Pro DKP and TRH-OH identified in neonatal rat pancreas suggest that TRH or TRH-like peptides may be metabolized in this tissue in intact rats, albeit at low rates.

Ontogenesis of pyroglutamyl peptidase II activity in rat brain, adenohypophysis and pancreas

Pyroglutamyl peptidase II (PPII; E.C. 3.4.19.-) is a highly specific membrane-bound ectoenzyme degrading thyrotropin releasing hormone (TRH). The ontogenesis of this enzyme was measured in rat brain regions, adenohypophysis and pancreas. In hypothalamus PPII activity was maximal at day 8 postnatal, decreasing to adult values at day 45. The postnatal ontogenic patterns in posterior cerebral cortex and hypothalamus were similar. In olfactory bulb, two peaks of activity were observed (3th and 22nd day) while in adenohypophysis it appeared only at day 8, increased to day 30, decreasing thereafter to adult values.

Evidence for pyroglutamyl peptidase I and prolyl endopeptidase activities in the rat insulinoma cell line RINm 5F: lack of relationship with TRH metabolism

Thyrotropin-Releasing hormone (TRH)-degrading pyroglutamyl peptidase I (PGP I) and prolylendopeptidase (PE) activities have been demonstrated in rat insulinoma RINm 5F cell line. These two enzymes catalyze the conversion of TRH to Histydyl-Proline-Diketopiperazine and to acid TRH respectively. After cell fractionation, we found all the PGP I and PE activities in the cytosolic fraction. The membrane-bound PGP II activity is not detectable in the RINm 5F cells. Further investigations on these two cytosolic enzymes show that pyroglutamyl- and proline-containing peptides are inhibitors of each TRH-degrading enzyme. Gel filtration chromatography on Sephadex G100 shows that PGP I and PE activity have an apparent molecular mass of about 18 kDa and 57 kDa, respectively. Kinetic analysis with TRH as substrate, gives a Km of 44 microM and 235 microM, and a Vmax of 1.49 and 8.80 pmol/min/micrograms protein for PGP I and PE, respectively. Immunoreactive TRH, His-Pro-Diketopiperazine and acid TRH levels in the cell line extracts are 2.2 +/- 0.9, 22.5 +/- 11.1 and 28.7 +/- 14.6 pg/1O6 cells, respectively. When cells have been incubated for 2 to 72 hours with a P.E. inhibitor (Z-Gly-Pro-CHN2) at 5 x 10(-7) M, both cell PGP I and PE activities are inhibited. No change in the cellular content of immunoreactive TRH, His-Pro-Diketopiperazine and acid TRH have been observed in treated cells.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Prodrugs of peptides. 6. Bioreversible derivatives of thyrotropin-releasing hormone (TRH) with increased lipophilicity and resistance to cleavage by the TRH-specific serum enzyme

Bioreversible derivatization of TRH (pGlu-His-Pro-NH2) to protect the tripeptide against rapid enzymatic inactivation in the systemic circulation and to improve the lipophilicity of this highly hydrophilic peptide was performed by N-acylation of the imidazole group of the histidine residue with various chloroformates. Whereas TRH was rapidly hydrolyzed at its pGlu-His bond in human plasma by a TRH-specific pyroglutamyl aminopeptidase serum enzyme, the N-alkoxycarbonyl derivatives were resistant to cleavage by the enzyme. On the other hand, these derivatives are readily bioreversible as the parent TRH is formed quantitatively from the derivatives by spontaneous hydrolysis or by plasma esterase-catalyzed hydrolysis. In addition to protecting the parent TRH against rapid inactivation in the circulation and hence potentially prolonging the duration of action of TRH in vivo, the N-alkoxycarbonyl prodrug derivatives were much more lipophilic than TRH as assessed by octanol-buffer partitioning. This property may enhance prodrug penetration of the blood-brain barrier and various other biomembranes compared to the parent peptide.

Degradation of thyrotropin-releasing hormone and luteinising hormone-releasing hormone by enzymes of brain tissue

In this article, the enzymes of brain and associated tissues that can degrade thyrotropin-releasing hormone (TRH) and luteinising hormone-releasing hormone (LH-RH) are reviewed. As both TRH and LH-RH are considered to act as neurotransmitters or neuromodulators in the CNS, attention is paid to the subcellular location of the enzymes described and how their topographies and substrate specificities fit them to playing roles as inactivating agents for TRH and LH-RH or as regulators of intracellular concentrations of TRH and LH-RH. Consideration is also given to enzymes involved in biotransformation of TRH to secondary metabolites that exhibit biological activity and to enzymes involved in the metabolism of secondary metabolites.

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.

Localisation of a particulate luliberin hydrolysing activity in microsomal membranes of guinea pig brain

A particulate luliberin hydrolysing enzyme has been described for guinea pig brain. Examination of subcellular fractions generated under different conditions indicated that particulate luliberin hydrolysing activity was most closely associated with the microsomal marker, rotenone-insensitive NADH cytochrome C reductase. The results obtained indicate that luliberin hydrolysing activity is not associated with synaptosomal membrane preparations and that such luliberin hydrolysing activity as is observed in synaptosomal membranes is probably the result of contamination by microsomes. The enzyme could be released from microsomes by Triton X-100 treatment and the solubilised enzyme was found to be inhibited by puromycin and sulphydryl reagents but to be unaffected by phosphoramidon, captopril, phenylmethyl sulphonyl fluoride and by chelating agents except 1,10-phenanthroline.

Prodrugs of peptides. IV: Bioreversible derivatization of the pyroglutamyl group by N-acylation and N-aminomethylation to effect protection against pyroglutamyl aminopeptidase

Various N-acyl derivatives and N-Mannich bases of the model compound L-pyroglutamyl benzylamide were synthesized to assess their suitability as prodrug forms for the N-terminal pyroglutamyl residue occurring in several peptides, with the aim of improving peptide delivery characteristics. Whereas pyroglutamyl benzylamide was rapidly hydrolyzed by pyroglutamyl aminopeptidase, the N-acyl derivatives and N-Mannich bases (N-aminomethyl derivatives) were totally resistant to cleavage by the enzyme. On the other hand, these derivatives are readily bioreversible, the conversion to the parent pyroglutamyl amide taking place either by spontaneous hydrolysis at physiological pH, as demonstrated for the N-Mannich bases, or by plasma enzymes, as shown for the N-acyl derivatives. The results suggest that by appropriate N-acylation or N-aminomethylation it may be feasible to protect pyroglutamyl-containing peptides against cleavage by pyroglutamyl aminopeptidase and to obtain a release of the parent peptide in the organism, hence improving the delivery characteristics of such peptides.

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.

Neuronal TRH synthesis: developmental and circadian TRH mRNA levels

Peptide biosynthesis within a neuron involves several steps occurring at the soma and during its travel to the nerve terminal, where it accumulates to be released under stimulatory conditions. We have measured hypothalamic TRH and TRH mRNA during ontogeny and circadian cycle and observed that TRH mRNA variations are more prominent than TRH ones. On the basis of these results and in vitro release experiments, we propose a compensatory mechanism working at the nerve terminal which is activated after release.

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.