Only tyrosine-containing metabolites of [Leu]enkephalin impair active avoidance conditioning in mice

Variation in the analgesic activity of opioid peptide fragments in correlation with the amino acidic sequence

Short fragments of typical or atypical opioid peptides, lacking the whole four amino acid sequence of the enkephalin motif, can preserve a significant percentage of the analgesic activity of the original peptides. This paper investigates the importance of the amino-acidic sequence of minimum structure typical opioid peptides for the analgesic activity. Different groups of rats were treated with 1) Gly-Tyr, 0.5 mg/rat i.t., 2) Tyr-Gly, 0.5 mg/rat i.t., 3) Tyr-Gly-Gly, 0.5 mg/rat i.t., 4) Gly-Gly-Phe-Leu, 0.5 mg/rat i.t., 5) Leu-enkephalin, 0.5 mg/rat i.t.. The analgesic effect of the tested substances was appreciated through the nociceptive threshold for thermal (plantar test) and mechanical nociception (algesimetric test). Fragments of typical opioid peptides elicited antinociceptive activity only when a tyrosine residue was present at the N-terminal end of the amino-acidic sequence. The presence of Nterminal tyrosine provides affinity for the opioid receptors and significant analgesic activity. The intensity of the antinociceptive effect was directly proportional with the length of the amino-acidic sequence. The inhibition of the analgesic effect by previous administration of naloxone proves that this effect is mediated through the opioid system.

Inhibition of neprilysin by thiorphan (i.c.v.) causes an accumulation of amyloid β and impairment of learning and memory

An accumulation of amyloid beta peptide (Abeta) due to an imbalance between anabolism and catabolism triggers Alzheimer's disease (AD). Neprilysin is a rate-limiting peptidase, which participates in the catabolism of Abeta in brain. We investigated whether rats continuously infused with thiorphan, a specific inhibitor for neprilysin, into the cerebral ventricle cause cognitive dysfunction, with an accumulation of Abeta in the brain. Thiorphan-infused rats displayed significant cognitive dysfunction in the ability to discriminate in the object recognition test and spatial memory in the water maze test, but not in other hippocampus-dependent learning and memory tasks. Thiorphan infusion also elevated the Abeta40 level in the insoluble fraction of the cerebral cortex, but not that of the hippocampus. There was no significant difference in the nicotine-stimulated release of acetylcholine in the hippocampus between vehicle- and thiorphan-infused rats. These results indicate that continuous infusion of thiorphan into the cerebral ventricle causes cognitive dysfunction by raising the level of Abeta in the cerebral cortex, and suggest that a reduction of neprilysin activity contribute to the deposition of Abeta and development of AD.

Inhibition of Neprilysin by Infusion of Thiorphan into the Hippocampus Causes an Accumulation of Amyloid β and Impairment of Learning and Memory

An imbalance between anabolism and catabolism causes an accumulation of amyloid beta-peptide (Abeta), which is a proposed trigger of the onset of Alzheimer's disease. Neprilysin is a rate-limiting peptidase that participates in the catabolism of Abeta in the brain. We examined whether rats continuously infused with thiorphan, a specific neprilysin inhibitor, into the hippocampus develop cognitive impairments through accumulation of Abeta. Thiorphan infusion elevated hippocampal Abeta40 and Abeta42 levels in the insoluble but not the soluble fraction. Thiorphan-infused rats displayed cognitive impairments in the ability to discriminate in the object recognition test, associative learning in the conditioned fear learning test, and spatial memory in the water maze test, tasks that depend on the hippocampus. These cognitive abilities in the battery of behavioral tasks inversely correlated with insoluble Abeta contents in the hippocampus. The nicotine-stimulated release of acetylcholine in the hippocampus of thiorphan-infused rats was significantly lower than that in vehicle-infused rats. These results indicate that continuous infusion of thiorphan into the hippocampus causes cognitive dysfunction and reduces cholinergic activity by raising the level of Abeta in the hippocampus and suggest that a reduction of neprilysin activity contributes to the deposition of Abeta and development of Alzheimer's disease.

Modulation of delayed-type hypersensitivity responses in hairless guinea pigs by peptides derived from enkephalin

Although opioid peptides such as methionine (met)-enkephalin have been previously shown to enhance or suppress immune responses, few studies in animal models have addressed the immunomodulatory activity of their metabolic derivatives. Hairless (IAF/HA-HO) guinea pigs immunized with Freund's complete adjuvant containing Mycobacterium tuberculosis and repeatedly skin tested with purified protein derivative of tuberculin (PPD) display high levels of stable delayed-type hypersensitivity (DTH) to PPD. Met-enkephalin (YGGFM) and two of its metabolites (YGG, YG) enhanced and accelerated PPD-elicited DTH inflammatory reactions when injected together with elicitor in these animals. At 24 h, 5 x 10(-3) pmol met-enkephalin significantly enhanced DTH responses by 30% over PPD alone, while 5 x 10(-5) pmol of YGG and 5 x 10(-9) pmol of YG significantly enhanced these responses by 62 and 32%, respectively. At much higher doses (5 x 10(3) pmol), met-enkephalin and its metabolites significantly suppressed DTH reactions by 25-32%. Tyrosine and glycine had no effect on PPD-elicited DTH. All DTH reactions (control, enhanced, suppressed) displayed typical perivascular mononuclear cell infiltrates. We conclude that the immunoactivity of met-enkephalin resides in its first two amino acids and suggest that cleavage of enkephalin molecules to YG occurs in serum and/or on the cell surface.

Peripheral modulation of learning and memory: enkephalins as a model system

Extensive research on the effects of enkephalins on conditioning is reviewed and used as the basis for a model of peripheral modulation of learning and memory. An overall theme emphasized throughout our discussion is that these peptides can influence the strength with which a memory is acquired and stored by acting outside the blood-brain barrier. This assertion is supported by research on the behavioral effects of systemically administered enkephalins and opioid antagonists, the rapid hydrolysis of circulating enkephalins in vivo, and the limited ability of these peptides to penetrate the blood-brain barrier. A consideration of the extensive distribution of enkephalins throughout peripheral autonomic systems leads to the proposal that enkephalins may act to modulate learning and memory by altering peripheral autonomic function; autonomic afferents may then communicate with the memory trace in the CNS through a central modulatory pathway outlined herein. Evidence that some stressful experiences may lead to increases in circulating enkephalins also is discussed. The sites of action of these circulating enkephalins may involve peripheral autonomic sites, or additionally may involve the circumventricular organs. As a further regulatory mechanism, circulating enkephalin levels may be controlled by experience-dependent alterations of the activity of enzyme systems that participate in their breakdown. Finally, it is emphasized that the mechanisms of enkephalin action postulated herein may be applicable to the actions of other peripheral hormones, peptides, and neurotransmitters that participate in the modulation of learning and memory storage processes.

[Leu]enkephalin and its metabolite, Tyr-Gly-Gly, impair active avoidance retention

The current study examined the effects of [leu]enkephalin and its metabolite, Tyr-Gly-Gly, given immediately posttraining on active avoidance performance measured 24 h later. Initial experiments revealed that, in comparison to zero or one training trials, providing mice with two training trials significantly increased active avoidance performance measured 24 h later; this enabled us to examine the effects on retention of peptides administered immediately after the two training trials. It was found that Tyr-Gly-Gly (16 and 53 micrograms/kg) and [leu]enkephalin (30 and 100 micrograms/kg) administered in this fashion both significantly impaired retention; the dose-response functions for both peptides were U-shaped. Since the effects of enkephalins are most likely mediated by opioid delta-receptors, and Tyr-Gly-Gly has little or no activity at opioid receptors, the effects of the parent peptide(s) and metabolite are presumably pharmacologically distinct.

Uptake and metabolism of [3H]-Leu-enkephalin following either its intraperitoneal or subcutaneous administration to mice

The uptake and metabolism of 30 micrograms/kg [3H]-Leu-enkephalin ([3H]-LE) following either intraperitoneal (IP) or subcutaneous (SC) administration to Swiss Webster mice was examined. Uptake of [3H] was rapid, with peak levels of radioactivity in plasma observed at 5 or 10 min following IP or SC peptide injection, respectively. The majority (80-99% +/- 0.8) of plasma radioactivity at all postinjection plasma collection time points was in the form of tyrosine-containing enkephalin metabolites, indicating a substantial and rapid in vivo hydrolysis rate for exogenously administered LE. Leu-enkephalin is metabolized in vivo faster than previously reported in vitro in mouse plasma. However, despite this extensive hydrolysis, levels of intact LE remaining in plasma following its systemic administration are within or above endogenous LE plasma levels.

Enkephalin hydrolysis by mouse plasma in vitro

Hydrolysis of [Leu]- and [Met]enkephalin was determined in samples of pooled whole mouse plasma in vitro by using HPLC-ECD to measure accumulation of Tyr-containing metabolites. More Tyr-Gly-Gly accumulated from [Met]enkephalin than from [Leu]enkephalin hydrolysis, and [Met]enkephalin's half-life in mouse plasma was approximately half that of [Leu]enkephalin. Comparisons of metabolite formation in the presence versus the absence of inhibitors with high selectivity for various peptidases demonstrated that a bestatin-sensitive aminopeptidase, presumably aminopeptidase M, as well as enkephalinase and angiotensin converting enzyme, participate in the hydrolysis of enkephalin in mouse plasma.

Endogenous opiates: 1990

This paper, an examination of works published during 1990, is thirteenth in a series of our annual reviews of the research involving the behavioral, nonanalgesic, effects of the endogenous opiate peptides. The specific topics this year include stress; tolerance and dependence, eating; drinking; gastrointestinal, renal, and hepatic functions; mental illness; learning, memory, and reward; cardiovascular responses; respiration and thermoregulation; seizures and other neurological disorders; electrical-related activity; locomotor activity; sex, pregnancy, development, and aging; immunological responses; and other behavior.

Further characterization of the in vitro hydrolysis of [Leu]- and [Met]enkephalin in rat plasma: HPLC-ECD measurement of substrate and metabolite concentrations

Hydrolysis of [Leu]- and [Met]enkephalin was determined in whole rat plasma in vitro by using HPLC-ECD to measure Tyr, Tyr-Gly and Tyr-Gly-Gly formation. Although [Leu]- and [Met]enkephalin did not differ in Tyr or Tyr-Gly accumulation, the amount of Tyr-Gly-Gly resulting from [Met]enkephalin hydrolysis was greater than that resulting from [Leu]enkephalin hydrolysis, and [Met]enkephalin's half-life in plasma was slightly shorter than that of [Leu]enkephalin. By comparing metabolite formation in the presence and absence of peptidase inhibitors with high selectivity for their respective enzymes, these studies demonstrated that aminopeptidase M and angiotensin converting enzyme are the major peptidases that hydrolyze enkephalins in rat plasma.

Hydrolysis of [Leu]enkephalin by chick brain in vitro

Using high-performance liquid chromatography with electrochemical detection to measure substrate disappearance and metabolite accumulation following addition of [Leu]enkephalin to samples prepared from chick brain in vitro, the following were found: 1. [Leu]enkephalin hydrolysis by whole forebrain homogenates is almost solely attributable to aminopeptidase MII activity. 2. [Leu]enkephalin hydrolysis by whole forebrain P2 membrane fractions is attributable to both aminopeptidase MII and dipeptidyl carboxypeptidase activity. 3. Differences are apparent in both [Leu]enkephalin disappearance and Tyr-Gly-Gly accumulation in P2 membrane fractions, but not in homogenate fractions, prepared from several regions of the chick brain.