Serge Turcaud

Antidepressant-type effects of endogenous enkephalins protected by systemic RB 101 are mediated by opioid δ and dopamine D1 receptor stimulation

The role of endogenous enkephalins in behavioural control in mice was investigated by i.v. injection of RB 101 (N-[(R,S)-2-benzyl-3[(S)(2-amino-4- methylthio)butyl dithio]-1-oxopropyl]-L-phenylalanine benzyl ester). RB 101 is a recently reported systemically active mixed inhibitor prodrug of the two enzymes which metabolize the enkephalins neutral endopeptidase 24.11 and aminopeptidase N. RB 101 (2.5-10 mg/kg) induced a dose-dependent long-lasting hyperlocomotion and attenuated the conditioned suppression of motility in mice placed in an environment where they had received footshocks 24 h before. In addition, RB 101 decreased the duration of immobility in the forced swim test. All these actions of RB 101 were antagonized by the selective delta antagonist, naltrindole, supporting the preferential involvement of delta opioid receptors in these enkephalin-controlled behavioural responses. The effects induced by RB 101 were also suppressed by prior administration of the selective dopamine D1 antagonist, SCH 23390, but not by the D2 antagonist, sulpiride. Attenuation of the conditioned suppression of motility was associated with increased striatal dihydroxyphenylacetic acid (DOPAC)/dopamine (DA) and homovanillic acid (HVA)/DA ratios, both effects being antagonized by naltrindole. This latter compound is also efficient to inhibit the effect of imipramine in the mouse forced swim test. Taken together, these results support the occurrence of tonic and phasic controls of mood-related behaviour by endogenous enkephalins through delta and D1 receptor stimulation and suggest a possible future use of these mixed inhibitors as new antidepressants.

In vivo occupation of mouse brain opioid receptors by endogenous enkephalins: blockade of enkephalin degrading enzymes by RB 101 inhibits [3H]diprenorphine binding

With the aim of possibly studying the local activity of brain enkephalinergic pathways by autoradiography and positron emission tomography, preliminary competition experiments of [3H]diprenorphine binding in mouse brain were carried out after i.v. administration of the first systemically-active mixed inhibitor of enkephalin degrading enzymes RB 101 (N(R,S)-2-benzyl-3[(S)-(2-amino-4-methylthiobutyldithio]-1-oxoprop yl]- L-phenylalanine benzyl ester). Although devoid of affinity for the opioid binding sites, RB 101 inhibited the [3H]diprenorphine binding to the opioid receptors in a dose-dependent manner. This effect, very likely due to an RB 101-induced increase in extracellular levels of enkephalins, reached a plateau at a dose of 10 mg/kg, where almost 30% displacement was observed. Intravenous administration of either 5 or 20 mg/kg of RB 101 in mice submitted to warm-swim stress led to an additional [3H]diprenorphine displacement, which reached 45% compared to unstressed controls. This ceiling effect could account for the reported minimal morphine-like side effects induced by mixed inhibitors. A large increase in endogenous enkephalin levels induced by RB 101, associated or not with stress, was also indirectly demonstrated by the analgesic responses elicited by i.v. injection of the mixed inhibitor. This effect was blocked by naloxone but not by the delta antagonist naltrindole (NTI), supporting a preferential implication of mu receptors in supraspinal analgesia. Taken together, these results suggest that RB 101 could be used to determine the precise in vivo localization of enkephalinergic pathways recruited by various stimuli.

Antinociceptive response induced by mixed inhibitors of enkephalin catabolism in peripheral inflammation

&NA; RB101 (Symbol is a recently developed full inhibitor of the enkephalin‐catabolizing enzymes able to cross the blood‐brain barrier, whereas RB38A ((Symbol) is as potent as RB101 but almost unable to enter the brain. In this study, we have investigated the effects of systemic administration of morphine, RB101 and RB38A on nociception induced by pressure on inflamed peripheral tissues. Antinociceptive test was performed between 4 and 5 days after injection into the rat left hindpaw of Freunds complete adjuvant to produce localized inflammation. Morphine (1, 2 and 4 mg/kg i.v.) induced antinociception in inflamed paws at all the doses used, and only at the highest dose in non‐inflamed paws. RB101 (10 and 20 mg/kg i.v.) induced an antinociceptive response only in the inflamed paws. RB38A, also induced an antinociceptive effect in the inflamed paws, but only at the highest dose (20 mg/kg i.v.). The responses induced by morphine and the inhibitors of enkephalin catabolism were antagonized by the systemic administration of naloxone (1 mg/kg) or methylnaloxonium (2 mg/kg) which acts essentially outside the brain. Central injection (i.c.v.) of methylnaloxonium (2 &mgr;g) blocked the effect of morphine only in non‐inflamed paws, and slightly decreased the response induced by RB101 on inflamed paws. These results indicate that the endogenous opioid peptides, probably enkephalins, are important in the peripheral control of nociception from inflamed tissues. Symbol. No caption available Symbol. No caption available

Repeated systemic administration of the mixed inhibitor of enkephalin-degrading enzymes, RB101, does not induce either antinociceptive tolerance or cross-tolerance with morphine

The potent analgesic responses elicited by systemic administration of RB101, N-[(R,S)-2-benzyl-3[(S)(2-amino-4-methylthio)butyldithio]-1-oxopro pyl]- 1-oxopropyl]-L-phenylalanine benzyl ester, a prodrug able to inhibit enkephalin-degrading enzymes completely after in vivo bioactivation, has made it possible to investigate the development of antinociceptive tolerance after chronic potentiation of endogenous enkephalins. The ED50 values of RB101 obtained 10 min after i.v. injection were not significantly different in mice treated for 4 days with i.p. administered vehicle (ED50 = 9.50 (6.37-14.15) mg/kg), or with 80 mg/kg of RB101 twice daily (ED50 = 9.50 (5.86-15.39) mg/kg). In contrast, a parallel rightwards shift of the dose-response curves, corresponding to a significant 1.92 (1.49-2.52)-fold decrease in analgesic potency, was observed after i.v. administration of morphine in mice chronically treated with morphine (3 mg/kg, twice daily for 4 days) (ED50 = 3.10 (2.52-3.81) mg/kg) vs. saline (ED50 = 1.60 (1.22-2.09) mg/kg). No tolerance to RB101 was observed even after a longer period (8 days) of chronic treatment with the prodrug. Moreover, no cross-tolerance between morphine and RB101 appeared to occur since the ED50 values obtained after i.v. administration of RB101 were not significantly different in mice chronically pretreated with vehicle (ED50 = 9.50 (6.37-14.15) mg/kg) or with morphine (ED50 = 10.00 (6.62-15.10) mg/kg). The analgesic effect of RB101 observed in morphine-tolerant mice was antagonized by prior injection of naloxone, but not naltrindole (delta-selective antagonist), supporting a preferential involvement of mu-opioid receptors in the antinociceptive effect of RB101, at least in mice in the hot-plate test.(ABSTRACT TRUNCATED AT 250 WORDS)

Pain-suppressive effects on various nociceptive stimuli (thermal, chemical, electrical and inflammatory) of the first orally active enkephalin-metabolizing enzyme inhibitor RB 120

&NA; RB 101 (N‐((R,S)‐2‐benzyl‐3[(S)(2‐amino‐4‐methylthio)butyldithio]‐1‐oxopropyl)‐l‐phenylalanine benzyl ester) is a full inhibitor of the enkephalin‐catabolizing enzymes, which induces strong naloxone‐reversible antinociceptive responses after i.v. or i.p. administration, but is only slightly active after oral administration. Chemical modifications were introduced on this compound, resulting in molecules such as RB 120 (N‐((S)‐2‐benzyl‐3[(S)(2‐amino‐4‐methylthio)butyldithio]‐1‐oxopropyl)‐l‐alanine benzyl ester), which was selected for a complete study, after oral administration, in various assays commonly used to select analgesics: mouse hot plate test, rat tail‐flick test, electrical stimulation of the tail in rats, paw pressure test on inflamed paws in rats, acetic acid‐induced writhing test and the formalin test in mice. RB 120 induced potent dose‐dependent antinociceptive responses in all these tests after oral administration. The differences in antinociceptive effects induced by RB 120 in the various assays is probably related to the amount of enkephalins released and to the efficiency of peptidase inactivation in particular brain regions implicated in the control of a given nociceptive input. The goal of discovering orally active analgesics endowed with a potency similar to that of morphine but devoid of its major side‐effects, seems now to have been reached with mixed neutral endopeptidase/aminopeptidase N (NEP/APN) inhibitors, although these compounds have yet to be evaluated in clinical trials.

Opposite role of CCKA and CCKB receptors in the modulation of endogenous enkephalin antidepressant-like effects

Systemic administration of RB 101, a complete inhibitor of the enkephalin degrading enzymes, has been reported to induce naltrindole-reversed anti-depressant-like effects in the conditioned suppression of motility (CSM) test in mice. The selective CCKB antagonist L-365,260 also elicits the same naltrindole-blocked responses on CSM. The aim of this study was therefore to investigate the possible modulation of RB 101 induced behavioral responses by activation or blockade of CCK receptors. Thus, the effects induced by RB 101 administered alone or associated with an ineffective dose of a selective CCKB agonist (BC 264), a CCKB antagonist (L-365,260) or a CCKA antagonist (L-364,718), were evaluated on the CSM in mice. RB 101 alone decreased the stress-induced loss of motility, as previously reported. The antidepressant-like effect of RB 101 was potentiated by L-365,260, and suppressed by BC 264 and to a lesser extent by L-364,718. The facilitatory effect induced by L-365,260 on RB 101 responses was blocked by the delta selective antagonist naltrindole. All these effects occurred only in shocked animals. The present results suggest that the activation of CCKA and CCKB receptors by endogenous CCK, could play an opposite role in the control of behavioral responses induced by endogenous enkephalins. Delta opioid receptors seem to be selectively involved in this interaction.

Thio-derived disulfides as potent inhibitors of botulinum neurotoxin type B: implications for zinc interaction

Botulinum neurotoxin type B causes the inhibition of acetylcholine release at the neuromuscular junction resulting in a flaccid paralysis designated botulism. This occurs through the cleavage of synaptobrevin, an intracellular critical component of neurotransmitter exocytosis, by the zinc-metallopeptidase activity of the smallest subunit of the toxin. Blocking the proteolytic activity may present an attractive approach to treat botulism as to date there is no efficient specific drug therapy available. We have therefore recently described a series of beta-amino-thiol derived pseudotripeptides able of inhibiting the toxin at low (10(-8) M) concentration. In this study, binding characteristics of the proteins active site are explored through various structural modifications of the thiol functionality which was supposed to be a key structural constituent for effective zinc-ion chelation. Surprisingly, sulfanyl-derivatives such as symmetric disulfides were shown to be better inhibitors than their thiol-counterparts, the most potent compound displaying a Ki value of 3.4 nM.

Partial Protection against Botulinum B Neurotoxin-Induced Blocking of Exocytosis by a Potent Inhibitor of Its Metallopeptidase Activity

Clostridium botulinum neurotoxins (BoNTs) cause botulism, which is characterized by a flaccid paralysis, through inhibition of acetylcholine release by peripheral cholinergic nerve terminals. This is due to the zinc metallopeptidase activity of the neurotoxin, cleaving one component (synaptobrevin for BoNT/B) of the exocytosis machinery. Yet, there are no specific agents able to control the peptidase‐related effects of BoNT/B. We recently developed the first compounds to inhibit this enzymatic activity in the nanomolar range. Here we report that two of our best inhibitors prevent the BoNT/B‐induced cleavage of native synaptobrevin on synaptic vesicles, and partially inhibit the suppression of [3H]noradrenaline release from synaptosomes that is caused by BoNT/B. These results were obtained at micromolar concentrations, consistent with the measured inhibitory potency of these inhibitors on the native toxin. These compounds provide a new way to possibly prevent and/or to control the neurotoxin effects of botulinum.

Assessment of physical dependence after continuous perfusion into the rat jugular vein of the mixed inhibitor of enkephalin-degrading enzymes, RB 101

We investigated if continuous activation of opioid receptors by their endogenous ligands could lead to the development of physical dependence. Catheters were implanted for chronic i.v. drug administration in rats and connected to an infusion pump. On the fifth day of perfusion, the severity of naloxone (5 mg/kg s.c.)-precipitated withdrawal was evaluated. Large behavioral changes and body weight losses were observed in rats chronically treated with morphine (0.17 mg/120 microliters/h). In contrast, only one withdrawal symptom (tremor) was significant in rats treated with the mixed inhibitor of enkephalin-degrading enzymes, RB 101 (1.20 mg/120 microliters/h). Morphine and RB 101 were perfused at doses which give same analgesic responses 6 h after the start of perfusion. This lack of physical dependence after drastic conditions of administration emphasizes the potential clinical interest of systemically active mixed inhibitors as new analgesics.

Novel approaches in the development of new analgesics

A recently developed series of highly selective and systemically active delta-agonists such as Tyr-X-Gly-Phe-Leu-Thr(OtBu), with X = D.Ser (OtBu) in BUBU and X = D.Cys(StBu) in BUBUC, and complete inhibitors of enkephalin metabolism (Kelatorphan, RB 38 A, PC 12) have enabled the major role played by mu-opioid receptors in supraspinal analgesia to be demonstrated. This is in agreement with the results of in vivo mu-receptor occupancy measured by taking into account the cross-reactivity of the delta-ligands for mu-sites. In contrast, mu and delta binding sites seem to act independently to control pain at the spinal level. Strong analgesic effects, especially in arthritic rats, can also be obtained by complete protection of tonically or phasically released endogenous enkephalins with mixed inhibitors such as RB38A. Chronic icv administration of the mu agonist DAGO, led to a severe naloxone precipitated withdrawal syndrome whilst a weak dependence was seen with the delta agonist, DSTBULET or with RB 38 A. Moreover, mixed inhibitors did not induce any significant respiratory depression. All these data emphasize the interest in developing delta-agonists and mixed inhibitors with appropriate bioavailability for clinical evaluation.