Low molecular weight, sequence based, collagenase inhibitors selectively block the interaction between collagenase and TIMP (tissue inhibitor of metalloproteinases).

Sequence-based inhibitors of collagenase bearing an hydroxamate group capable of chelating the active site zinc atom were synthesized and tested. The effect of one of these molecules (RP 59794; Ki about 10(-8) M) on the formation of the TIMP: collagenase complex was also tested. RP 59794 blocks complex formation and can partially dissociate established TIMP: collagenase complexes. It exhibits the same stereospecificity in this activity as in its inhibition of collagenase suggesting that TIMP and RP 59794 both interact with the active site region of collagenase.

[Inhibition of synovial collagenase by actinonin. Study of structure/activity relationship]. / Inhibition de la collagénase synoviale par l'actinonine. Etude de relations structure/activité.

Actinonin is a pseudopeptide antibiotic which inhibits collagenase at micromolar concentrations [10]. In this study, Actinonin analogs were tested to investigate "structure/activity" relationships for this class of molecule. The results indicate that distance between the hydroxamate carbonyl group and that of the first amide bond is important, since increasing this distance by a methylene group, decreases inhibition by a factor of 100. The amide bonds of this inhibitor must be in the peptide bond orientation. Different N terminal amide derivatives and different hydrophobic substituents adjacent to the hydroxamate residue, had little effect on inhibitory activity. However, in this series of molecules, two hydrophobic groups separated by an amide bond seem to be necessary for potent inhibition.

Effects of kelatorphan and other peptidase inhibitors on the in vitro and in vivo release of methionine-enkephalin-like material from the rat spinal cord.

The effects of the novel mixed peptidase inhibitor, kelatorphan [N-(R)-3-(N-hydroxyaminocarbonyl-2-benzyl-1-oxopropyl)-L-alanine], were compared to those of a combination of the potent "enkephalinase" inhibitor thiorphan and the nonselective aminopeptidase inhibitor bestatin, on the catabolism of [3H]Met-enkephalin and on the release of endogenous Met-enkephalin by the rat spinal cord in vitro and in vivo. At 20 microM, kelatorphan almost prevented completely the degradation of exogenous [3H] Met-enkephalin by slices of the dorsal zone of the lumbar enlargement. Similarly, the addition of 20 microM kelatorphan to a [3H] Met-enkephalin-containing artificial cerebrospinal fluid superfusing the whole spinal cord of halothane-anesthetized rats efficiently protected the exogenous peptide from enzymatic degradation. In contrast, in the same in vitro and in vivo models, thiorphan (1 microM) or bestatin (20 microM) alone was inactive, and only their combination induced a significant protection of the exogenous peptide. In vitro and in vivo, kelatorphan (20 microM) increased markedly the spontaneous outflow of endogenous Met-enkephalin-like material as well as the peptide overflow due to K+-induced depolarization (in vitro and in vivo) or noxious stimulation (in vivo). Under similar conditions, thiorphan (1 microM) plus bestatin (20 microM) also enhanced the efflux of Met-enkephalin-like material, but generally to a lower extent than kelatorphan. Compared to thiorphan plus bestatin, kelatorphan exerts additional inhibitory effects on dipeptidylaminopeptidase activity and the present results could indicate that this enzyme also may be involved in the inactivation of extracellular Met-enkephalin at the spinal level in rats.

In vitro and in vivo effects of kelatorphan on enkephalin metabolism in rodent brain.

Biologically relevant assays were used to compare the potency of kelatorphan (N-[3(R)-[(hydroxyamino)carbonyl]-2-benzyl-1-oxopropyl]-L-alanine) as inhibitor of the peptidase-induced metabolism of enkephalins to that of bestatin, a non-specific inhibitor of aminopeptidase and thiorphan, a highly potent blocker of the neutral endopeptidase (EC 3.4.24.11) designated as enkephalinase. Kelatorphan almost completely inhibited the formation of the three metabolites [3H]Tyr, [3H]Tyr-Gly and [3H]Tyr-Gly-Gly produced by incubation of [3H][Tyr1,Met5]enkephalin with rat striatal slices. Co-administered with [Met5]enkephalin in mouse brain, kelatorphan was able to prevent by 80% the degradation of the exogenous peptide. Moreover, a mixture of thiorphan (1 microM) and bestatin (20 microM) or kelatorphan alone (20 microM) induced a 2.2 to 2.5-fold increase in endogenous [Met5]enkephalin overflow after evoked depolarization of superfused rat striatal slices. In this assay, kelatorphan was the only compound to increase by 63% the basal level of released [Met5]enkephalin. Kelatorphan was about 100 times less potent than bestatin to inhibit the total rat striatal aminopeptidases, but as efficient (IC50 = 4 X 10(-7) M) as bestatin to inhibit a minor aminopeptidase activity resembling aminopeptidase M. Therefore the reported enhanced analgesic potency of kelatorphan with regard to the association of bestatin and thiorphan is very likely related to its ability to almost completely inhibit enkephalin-degrading enzymes (including the Tyr-Gly releasing peptidase) and to its better selectivity for the biologically relevant aminopeptidase M. Kelatorphan would be a valuable probe, preferable to the association of bestatin and thiorphan, to investigate the physiological functions regulated by a phasic enkephalinergic activity.

New bidentates as full inhibitors of enkephalin-degrading enzymes: synthesis and analgesic properties.

New compounds were designed to fully inhibit the in vitro metabolism of enkephalins, ensured by three different metallopeptidases. For this purpose, bidentate ligands as hydroxamate and N-hydroxy-N-formylamino groups were selected as highly potent metal coordinating agents and introduced on Phe-Gly and Phe-Ala related structures. Compounds corresponding to the general formula HC(O)N(OH)CH2CH(CH2Ph)CONHCH2COOH (compound 7) and HN(OH)C(O)CH2CH(CH2Ph)CONHCH(R)COOH (compound 11, R = H; compound 13, R = CH3) behave as full inhibitors of the three enzymes, with IC50's in the nanomolar range for enkephalinase, from 0.3 microM to 1 nM for dipeptidylaminopeptidase, and in the micromolar range for a biologically relevant aminopeptidase. Two diastereoisomers of the most active inhibitor 13 were separated by HPLC and their stereochemistry was assigned by 1H NMR spectroscopy. Both isomers were efficient as enkephalinase blockers, but only the RS isomer, designated kelatorphan, was able to strongly inhibit aminopeptidase and dipeptidylaminopeptidase. Intracerebroventricular injection in mice of these mixed inhibitors, especially kelatorphan, led to naloxone reversible analgesic responses (hot-plate test) that were slightly better than those produced by a mixture of thiorphan and bestatin, two potent inhibitors of enkephalinase and aminopeptidase, respectively. Kelatorphan was also more efficient in potentiating the analgesia induced by a subanalgesic dose of Met-enkephalin. All these results support a physiological role in pain transmission for enkephalinase and a probably synaptic aminopeptidase M.

Binding of the bidentate inhibitor [3H]HACBO-Gly to the rat brain neutral endopeptidase "enkephalinase".

The synthesis and binding properties to rat brain tissue of the enkephalinase inhibitor [3H] N-[(R,S)-3-hydroxyaminocarbonyl-2-benzyl-1-oxopropyl]-glycine ([3H]HACBO-Gly, 45 Ci/mmole) is reported. [3H]HACBO-Gly binding to membranes from various rat brain tissue is saturable (KD = 0.4 +/- 0.05 nM) and linearly related to the amount of tissue. Non specific binding is less than 15% of total binding at the KD concentration. The regional distribution of [3H]HACBO-Gly binding and enkephalinase activity are closely correlated with highest levels in striatum and substantia nigra. The efficiency of inhibitors of various peptidases (thiorphan, captopril, bestatin ...) to inhibit [3H]HACBO-Gly binding or enkephalinase activity are similar. These results indicate that [3H]HACBO-Gly binds selectively to enkephalinase. This compound should help to clarify the localization of the enzyme in the CNS.

Kelatorphan: a full inhibitor of enkephalin degrading enzymes. Biochemical and pharmacological properties, regional distribution of enkephalinase in rat brain by use of a tritiated derivative.

New potent inhibitors of enkephalin degrading enzymes were obtained by synthesis of compounds bearing a bidentate group. Among these bidentates, Kelatorphan, N-[(R)-3-(N-hydroxy)-carboxamido-2-benzylpropanoyl]-L-alanine, is in vitro a full inhibitor of enkephalinase, dipeptidylaminopeptidase and aminopeptidase. In vivo Kelatorphan (i.c.v. administered in mice) prevents exogenous enkephalin from peptidase degradation. The analgesic effect of Kelatorphan is at least equal to that of the association of bestatin and thiorphan. An analogue of Kelatorphan was tritiated and was used as a specific marker of enkephalinase. Thus the distribution of enkephalinase in rat brain was studied: striatum corpus and substantia nigra were particularly labelled.

Bidentate peptides: highly potent new inhibitors of enkephalin degrading enzymes.

Three series of bidentates bearing an hydroxamic or an N-Acyl-N-hydroxy amino group on structures related to Phe-Gly or Phe-Ala exhibit strong inhibitory potency against purified enkephalinase with IC50 values in the 4 to 15 nM range. As with thiol-containing inhibitors, such as thiorphan, the most active compounds are those in which a methylene spacer separates the benzyl P1' moiety from the Zn coordinating residue. Formation of a bidentate complex with the metal enzyme is clearly demonstrated by a loss of potency of three order of magnitude following the removal of one component of the bidentate group. All the compounds studied are unable to interact with angiotensin converting enzyme (IC50 greater than 10,000 nM). Moreover, compounds of the general formula HONHCO-CH2-CH(CH2 phi)-CONH-CH(R)-COOH belonging to the most active series of enkephalinase blockers (IC50 approximately 4 nM) behave also as highly potent and competitive inhibitors (IC50 approximately 10 nM) of a Tyr-Gly releasing dipeptidylaminopeptidase purified from rat brain. The pure steroisomer [(R)-3-(N-hydroxy)carboxamido-2-benzylpropanoyl]-L-alanine designated kelatorphan, exhibits also a relatively good inhibitory potency against aminopeptidases (IC50 approximately 10 microM) and can be considered as the first virtually complete inhibitor of enkephalin metabolism. This very interesting property of inhibiting all three enzymes of enkephalin metabolism could enhance the required selectivity for a possible clinical use of these inhibitors as new analgesic and psychoactive drugs.

Analgesic effects of kelatorphan, a new highly potent inhibitor of multiple enkephalin degrading enzymes.

Kelatorphan, [(R)-3-(N-hydroxy)-carboxamido-2-benzylpropanoyl]-L-alanine, represents the first virtually complete inhibitor of enkephalins metabolism with KI = 1.4 nM against enkephalinase, KI = 2 nM against the Gly2 -Gly3 cleaving dipeptidylaminopeptidase and KI = 7 microM on aminopeptidase activity. The analgesic effect of [Met5]enkephalin was potentiated 50000 times (ED50 approximately 10 ng) by intracerebroventricular co-administration in mice of kelatorphan (50 micrograms). This effect was significantly higher than that produced by bestatin (50 micrograms) + thiorphan (50 micrograms). Kelatorphan alone was at least two-fold more potent as analgesic than the above mixture of inhibitors.

[Regional distribution of enkephalinase in the rat brain by autoradiography]. / Distribution régionale de l'enképhalinase dans le cerveau du rat par autoradiographie.

The first visualization of enkephalinase (neutral metalloendopeptidase, E.C.3.4.24.11) in rat brain was obtained by autoradiography, using a new tritiated inhibitor: [3H]N-[( R,S )3-(N-hydroxy) carboxamido-2-benzyl propanoyl]glycine (3H-HCBP-Gly). The preliminary analysis of sections clearly showed a discrete localization of enkephalinase in enkephalin enriched regions, such as caudate nucleus, putamen, globus pallidus, and substantia nigra. Moreover 3H-HCBP-Gly binding also occurred in choroid plexus and spinal cord.