Enkephalins and learning and memory: a review of evidence for a site of action outside the blood-brain barrier

Fabrication and Optimization of a Molecularly Imprinted Carbon Fiber Microelectrode for Selective Detection of Met-enkephalin Using Fast-Scan Cyclic Voltammetry

Methionine-enkephalin (Met-Enk) is an endogenous opioid peptide that is involved in various physiological processes including memory. A technological gap in the understanding of Met-Enk's role in memory is the lack of rapid measurement tools to selectively quantify Met-Enk concentrations in situ. Here, we integrate molecularly imprinted polymers (MIPs) with carbon fiber microelectrodes (CFMs) to selectively detect Met-Enk by using fast-scan cyclic voltammetry (FSCV). We report two MIP conditions that yield 2-fold and 5-fold higher selectivity toward Met-Enk than the tyrosine-containing hexapeptide fragment angiotensin II (3-8). We demonstrate that MIP technology can be combined with FSCV at CFMs to create rapid and selective sensors for Met-Enk. This technology is a promising platform for creating selective sensors for other peptides and biomarkers.

Endogenous Opioids Interfere with Pavlovian Second-Order Fear Conditioning

Second-order classical (Pavlovian) aversive conditioning was used to determine whether endogenous opiates play a role in the acquisition of associative learning. Second-order conditioning avoids confounding drug effects on associative learning with altered responsiveness to unconditioned stimuli (e.g., hyperalgesia). Administration of the prototypical opiate antagonist naloxone (2.0 mg/kg) prior to the second-order training session specifically facilitated associative learning as indicated by greater lick suppression over 3 days of testing. This result suggests that endogenous opiates retard the acquisition of associative learning, which complements previous studies demonstrating an opioid attenuation of memory consolidation.

The distribution of substance P and met-enkephalin in vocal control nuclei among oscine species and its relation to song complexity

Substance P (SP) and methionine-enkephalin (ENK) have been reported to appear in song control nuclei of oscine species. However, it remains unknown whether or not SP and ENK location in song control nuclei is correlated with song behavior. To address this issue, the present study first measured two variables for song complexity, i.e., song repertoire sizes, and syllable repertoire sizes in 11 oscine species. Then, we examined the distribution of SP and ENK in four control nuclei, two in the motor pathway, i.e., HVC and the robust nucleus of arcopallium (RA), and the other two in the forebrain pathway, i.e., Area X and the lateral magnocellular nucleus of the anterior nidopallium (LMAN). Finally, we measured the relative amounts of immunoreactivity for SP and ENK in song control nuclei, and tested whether they were correlated with song complexity. Our results showed that: (1) SP and ENK were broadly distributed in the song control nuclei of studied species. However, SP immunohistochemistry was more robust in comparison with ENK, and SP is generally more abundant in the two song learning nuclei than those in the two song producing ones; (2) SP and ENK staining patterns in song control nuclei did not show any obvious phylogenetic relationship among studied oscine species; (3) there was a significant correlation between the relative amounts of immunoreactivity for SP and the song and syllable repertoire sizes. Our results suggest that SP or ENK might be involved in song behavior, such as birdsong learning or memory.

Estrogen and CCK1 receptor modification of mu-opioid receptor binding in the cortex of female rats

Cholecystokinin (CCK) in the nervous system has effects opposite to those of opioids. However, the mechanism by which CCK opposes the effect of opioids at the receptor or cellular level is still unknown. In the brain, distributions of CCK receptors and opioid receptors have been demonstrated to overlap. The present study was undertaken to determine the mechanism of CCK-opioid interactions in the cortex of ovariectomized rats. Furthermore, because estrogen is a powerful regulator of CCK and opioid activity, we examined whether estrogen state also modulates the interactions of these neuropeptides. mu-Opioid (MOP) receptor binding was examined in cortical membranes that were preincubated with CCK-8S and CCK receptor agonist and antagonist followed with 3H-DAMGO. Pharmacological results revealed that CCK-8S suppressed 3H-DAMGO binding in cortical membranes of ovariectomized rats. The same result was obtained using a CCK1 receptor agonist (JMV-180), whereas a CCK2 receptor agonist (CCK-4) failed to suppress 3H-DAMGO binding. Antagonism of the CCK1 receptor by JMV-179 blocked both CCK-8S and JMV-180 suppression of 3H-DAMGO binding. Furthermore, estrogen treatment to female rats resulted in a suppression of 3H-DAMGO binding in cortical membranes. These results demonstrate an estrogen regulation of the MOP receptor and a protein-protein interaction between CCK1 receptor and MOP receptor.

Cholecystokinin and endogenous opioid peptides: interactive influence on pain, cognition, and emotion

It is well documented that stressful life experiences contribute to the etiology of human mood disorders. Cholecystokinin (CCK) is a neuropeptide found in high concentrations throughout the central nervous system, where it is involved in numerous physiological functions. A role for CCK in the induction and persistence of anxiety and major depression appears to be conspicuous. While increased CCK has been associated with motivational loss, anxiety and panic attacks, an increase in mesocorticolimbic opioid availability has been associated with coping and mood elevation. The close neuroanatomical distribution of CCK with opioid peptides in the limbic system suggests that there may be an opioid-CCK link in the modulation and expression of anxiety or stressor-related behaviors. In effect, while CCK induces relatively protracted behavioral disturbances in both animal and human subjects following stressor applications, opioid receptor activation may change the course of psychopathology. The antagonistic interaction of CCK and opioid peptides is evident in psychological disturbances as well as stress-induced analgesia. There appears to be an intricate balance between the memory-enhancing and anxiety-provoking effects of CCK on one hand, and the amnesic and anxiolytic effects of opioid peptides on the other hand. Potential anxiogenic and mnemonic influences of site-specific mesocorticolimbic CCK and opioid peptide availability, the relative contributions of specific CCK and opioid receptors, as well as the time course underlying neuronal substrates of long-term behavioral disturbances as a result of stressor manipulations, are discussed.

Differential involvement of the mu and kappa opioid receptors in spatial learning

In order to test the role of mu and kappa opioid receptors (Mu opioid receptor (MOR) and Kappa opioid receptor (KOR)) in hippocampal-dependent spatial learning, we analyzed genetically engineered null mutant mice missing the functional MOR or KOR gene. Compared to wild-type mice, the homozygous MOR null mutants exhibited an impairment in the ultimate level of spatial learning as shown in two distinct tasks, the 8-arm radial-maze and the Morris water-maze. Control behaviors were normal. The learning impairment could be associated with the impairment we found in the maintenance of long-term potentiation in mossy fibers in CA3. In comparison, there was no impairment in spatial learning in our KOR mutants or in mossy fibers (mf) in CA3 region long-term potentiation (LTP). Our work suggests that the MOR may play a positive role in learning and memory by increasing LTP in CA3 neurons.

Oestrogen modulates cholecystokinin: opioid interactions in the nervous system

Responses of the nervous system to introceptive and extroceptive inputs depend upon the state of the brain. Oestrogen has the ability to modulate brain state and dramatically alter interactions among neural circuits to influence an organism's responses to given stimuli. Cholecystokinin (CCK) and endogenous opioid peptides (EOP) have a wide and parallel distribution in the nervous system. Their reciprocal interactions regulate a diverse physiology including reproduction, cortical function and nociception. The actions of CCK and EOP are diametrically opposed, in many regions. For example, when opioids inhibit reproductive behaviour or nociception, CCK facilitates. Because oestrogen is a powerful regulator of the expression of CCK and EOP, we examined whether oestrogen-state also modulated the interactions of these neuropeptides. In this paper we present new data and review previous work that demonstrates oestrogen modulation of functional CCK-opioid interactions that regulate reproductive behaviour, cortical function and nociception.

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.

ICI 174,864, a selective delta opioid antagonist, reverses the learning impairment produced by [leu]enkephalin

The role of opioid delta receptors in the learning impairment produced by [leu]enkephalin (LE) in one-way active avoidance conditioning was investigated in mice. LE (30 and 100 micrograms/kg) impaired acquisition of the avoidance response, whereas ICI 174,864 (3.0 mg/kg), a selective delta opioid receptor antagonist, enhanced acquisition. The impairment produced by 100 micrograms/kg LE was completely reversed by 1.0 mg/kg ICI 174,864, a dose of the antagonist that by itself had no effect. Control studies provided evidence that the effects of ICI 174,864 and LE on conditioning cannot be explained by performance variables such as alterations in activity levels or footshock sensitivity. The results suggest that opioid delta receptors play an important role in the modulation of learning, and that the effects of LE on avoidance conditioning are mediated by delta receptors.

Roles of delta and mu opioid receptors in mediating the effects of enkephalins on avoidance conditioning

The effects on one-way active avoidance conditioning of pre-training, systemic administration of the selective mu-receptor agonist [D-Ala2,N-Me-Phe4, Gly-ol]enkephalin (DAGO), and the selective mu-receptor antagonist (D-Phe-Cys-Tyr-D-Trp-Orn-Thr-Pen-Thr-NH2 (CTOP), were determined in Swiss-Webster mice. A low dose of DAGO (0.92 micrograms/kg) moderately enhanced avoidance acquisition, whereas a 100 micrograms/kg dose of CTOP more dramatically impaired acquisition. However, the avoidance-enhancing dose of DAGO significantly increased locomotor activity as measured in a separate group of mice in the avoidance chamber, and the avoidance-impairing dose of CTOP significantly decreased activity. Under these same training conditions, earlier studies (Schulteis et al. 1988; Schulteis and Martinez 1990) demonstrated that enkephalins impaired avoidance learning, and selective delta-receptor antagonists such as ICI 174,864 enhanced learning; in contrast to the present study, both of these effects were dissociated from performance effects such as alterations in locomotor activity. Taken together, the results suggested that the effects of enkephalins were mediated by the delta-, but not mu-, class of opioid receptor.

Role of norepinephrine in mediating stress hormone regulation of long-term memory storage: a critical involvement of the amygdala

There is extensive evidence indicating that the noradrenergic system of the amygdala, particularly the basolateral nucleus of the amygdala (BLA), is involved in memory consolidation. Infusions of norepinephrine or beta-adrenoceptor agonists into the BLA enhance memory for inhibitory avoidance as well as water maze training. Other findings show that alpha 1-adrenoceptor activation also enhances memory for inhibitory avoidance training through an interaction with beta-adrenergic mechanisms. The central hypothesis guiding the research reviewed in this chapter is that stress hormones released during emotionally arousing experiences activate noradrenergic mechanisms in the BLA, resulting in enhanced memory for those events. Findings from experiments using rats have shown that the memory-modulatory effects of the adrenocortical stress hormones epinephrine and glucocorticoids are mediated by influences involving activation of beta-adrenoceptors in the BLA. In addition, both behavioral and microdialysis studies have shown that the noradrenergic system of the BLA also mediates the influences of other neuromodulatory systems such as opioid peptidergic and GABAergic systems on memory storage. Other findings indicate that this stress hormone-induced activation of noradrenergic mechanisms in the BLA regulates explicit/declarative memory storage in other brain regions.

Pentylenetetrazole (PTZ)-induced c-fos expression in the hippocampus of kindled rats is suppressed by concomitant treatment with naloxone

Rats were kindled by repeated injections of pentylenetetrazole (PTZ; 37.5 mg/kg; i.p.) in the presence or absence of the opioid receptor antagonist naloxone. Naloxone (10 mg/kg; i.p.) applied 30 min before each PTZ application had no major effect on the seizure development, although a slight decrease in the seizure expression of fully kindled animals could be observed. In the kindled animals, a pronounced but transient increase in c-fos mRNA level was observed in several brain areas after the injection of PTZ. The magnitude of c-fos induction was related to the seizure stage reached. Detectable c-fos mRNA levels in the cortex were observed in rats showing stage four seizures, whereas the expression of c-fos in the hippocampus required stage five kindled seizures. The induction of c-fos expression in the hippocampus of stage five kindled rats but not in other brain areas was prevented by treatment of naloxone prior to each PTZ application. In contrast, a single injection of naloxone to kindled rats was not sufficient to prevent c-fos mRNA expression in the hippocampus. In addition, a single PTZ application (at the higher dose of 45 mg/kg) to rats that were not kindled also caused c-fos expression in several brain regions, but this was not influenced by naloxone. Assuming that c-fos expression reflects neuronal activity our findings suggest a functional role of endogenous opioid peptides in the development of kindling-induced neuronal excitation in the hippocampus. In addition, the excitation of the hippocampus does not appear to be involved in the seizure activity but may be responsible for the impairment of learning in PTZ-kindled rats which can be prevented by pretreatment with naloxone [A. Becker, G. Grecksch, M. Brosz, Naloxone ameliorates the learning deficit induced by pentylenetetrazole kindling in rats, Eur. J. Neurosci. 6 (1994) 1512-1515].

Time-dependent effects of fructose on the modulation of a reactivated memory

1. A passive-avoidance-to-active-avoidance negative transfer paradigm was used to investigate systematically the time-dependent effects of fructose on reactivated memories in rats. 2. Memory reactivation consisted of re-exposing the rats 24 hr after passive-avoidance conditioning to environmental and learning cues present during training; post-reactivation injections of fructose (100 mg/kg, sc) or saline were followed 24 hr later by active-avoidance (discrimination reversal) conditioning. Fructose or saline was administered in the experimental room 0, 2, 5, or 30 min, or in the colony room 60 min, after reactivation. 3. The results showed a time-dependent decrease in the ability of fructose to modulate a reactivated memory. 4. These results suggest that the time-dependent effects for the modulation of a reactivated memory by fructose (a hexose that does not readily pass the blood-brain barrier) and glucose (a hexose that readily passes the blood-brain barrier) follow similar trends.

Endogenous opioids in frontal cortex of patients with Down syndrome

The main purpose of this study was to investigate differences regarding endogenous opioids in post-mortem frontal cortex of adult patients with Down syndrome (DS), patients with Alzheimer disease (AD) and neurologically healthy persons, respectively, using specific radioimmunoassays. The results of this study show that there is an increase in the levels of leu-enkephalin and dynorphin A in the frontal cortex of patients with DS as compared to the control group. An almost identical increase was also observed when comparing patients with AD to controls. In conclusion, the results of this study suggest a relationship between elevated tissue levels of leuenkephalin and dynorphin A in cerebral cortex and cognitive impairments in patients with DS and AD.

Memory retrieval enhancement by kappa opioid agonist and mu, delta antagonists

The present study sought to identify specific opioid receptor subtypes involved in the modulation of reactivation of amnesic or forgotten memory traces by use of a one-trial inhibitory avoidance training procedures in mice. The effects of naloxone, ICI 174,864 (mu and delta opioid receptor antagonists, respectively) and dynorphin (kappa agonist) were investigated. The results indicated that preretention test administration of naloxone (2 mg/kg) or ICI 174,864 (3 mg/kg) attenuated the amnesia and forgetting as indicated by prolongation of step-through latency. On the other hand, the activation of kappa opioid receptors by dynorphin (1 mg/kg) also showed reactivating effects both after amnesia and forgetting. On the basis of the parallelism of the effects for mu and delta opioid receptor antagonists and kappa agonist, and on the finding that all three opioids demonstrated a different degree of reactivation of amnesic and forgotten memory traces, it was concluded that mu, delta, and kappa opioid receptors contribute to the modulation of amnesia and forgetting by independent mechanisms.

Comparable dose-response functions for the effects of glucose and fructose on memory

A passive avoidance-to-active avoidance negative transfer paradigm was used to investigate in rats the effects of glucose and fructose on recently acquired memories. Immediate post-passive avoidance conditioning injections of glucose, fructose, or saline were followed 48 h later by active avoidance conditioning. Equimolar 10, 32, 100, and 2000 mg/kg sc doses of the two sugars significantly impaired acquisition of the reversal task, whereas 3.2 mg/kg doses of both sugars were without significant effect on subsequent performance and 320 mg/kg doses of both sugars significantly enhanced subsequent performance. The cubic trends for both dose-response functions were statistically significant and did not differ from each other. This is the first demonstration that glucose and fructose affect recently acquired memories in accord with comparable cubic dose-response functions, and that there are doses of both sugars that can enhance memory (as indicated by an increase in the number of trials required to reach criterion on the reversal task) and doses of both sugars that can impair memory (as indicated by a decrease in the number of trials required to reach criterion on the reversal task), compared to saline treatment. The similar cubic dose-response functions for glucose and fructose suggest that their mechanisms of action when they are injected peripherally are similar. In addition, because fructose does not readily pass the blood-brain barrier, the results suggest that these two monosaccharides may act through a common peripheral pathway.

Behavioral effects of systemically administered mu and kappa opioid agonists in the squirrel monkey: peptides versus alkaloids

This study compared the effects of receptor-selective peptide and nonpeptide opioid agonists administered intramuscularly to squirrel monkeys responding under a fixed-interval 3-min schedule of stimulus termination. The mu opioid receptor agonist morphine (0.1-3.0 mg/kg) increased response rate at low doses and decreased it and quarter-life at higher doses. [D-Ala2,N-Me-Phe4,Gly-ol]Enkephalin (DAMGO; 0.3-3.0 mg/kg) reduced quarter-life at the highest dose. The kappa dose. The kappa opioid receptor agonist U50,488H (0.1-1.0 mg/kg) elevated response rate transiently and dose-dependently decreased quarter-life. Dynorphin A(1-13) (0.3-10 mg/kg), a purported endogenous ligand of the kappa opioid receptor, decreased response rate slightly but significantly at 3.0 mg/kg and had no effect on quarter-life. Thus, the behavior of squirrel monkeys was affected by systemically administered peptide as well as by nonpeptide opioid drugs. The two alkaloids were much more effective than the two peptides, presumably because of greater ability to penetrate the blood-brain barrier. Quarter-life was often a more sensitive measure of drug effects than was response rate.

The effects of methionine-enkephalin and its related metabolites upon the duration of the dorsal immobility response in rats

The effects of SC injections of methionine-enkephalin (Met1-5-Enk) and its N-terminal and C-terminal fragments upon the duration of the dorsal immobility response (DIR) over a 60-min time course were investigated. Experiment 1 analyzed the effects of various dosages (0.00-100.0 micrograms/kg) on DIR resulting in a potentiation of the duration in a dose-time course function. The effects of various fragments of Met1-5-Enk (10.0 micrograms/kg) from the N-terminal in Experiment 2 and from the C-terminal in Experiment 3 on the DIR resulted in the potentiation of the duration with the Met2-5-Enk and Met1-3-Enk fragments. All other fragments were not significant. The results were discussed in reference to the processing and metabolism of Met1-5-Enk.

Dynorphin(1-13) impairs memory formation for aversive and appetitive learning in chicks

The opioid peptide dynorphin(1-13) impairs memory formation in chicks (5). We examined whether this occurs for both aversively and appetitively motivated learning. Four-day-old chicks were injected with dynorphin(1-13) into the intermediate medial hyperstriatum ventrale and trained on either a peck avoidance (PA) or an appetitive discrimination (AD) task; 2-day-old chicks were trained on PA. In 2-day-old chicks, dynorphin was amnestic for PA at 0.01, 0.03, or 0.1 mM. In 4-day-old chicks, dynorphin impaired memory formation for PA at 0.1 mM, and for AD training at 0.03 mM. Thus, similar doses of dynorphin impair memory formation for both appetitive and aversive conditioning.

Effects of vagotomy on Leu-enkephalin-induced changes in memory storage processes

When given before or after training, Leu-enkephalin impairs later retention of learning. To replicate these findings, Experiment 1 determined if Leu-enkephalin impairs retention when administered after inhibitory avoidance training. Posttraining injection of 100.0 micrograms/kg of Leu-enkephalin impaired retention relative to saline controls or those receiving a lower dose of this peptide. Since Leu-enkephalin does not cross freely from the blood stream into the brain, this peptide may exert its influence on mnemonic processes by activating peripheral receptors that transmit neural messages to the brain via the vagus nerve. In Experiment 2, 100.0 micrograms/kg Leu-enkephalin impaired retention in unoperated and sham-operated animals although vagotomized animals did not differ significantly from these groups or saline controls. These results suggest that subdiaphragmatic vagotomy may not be sufficient to disrupt the mnemonic effects of Leu-enkephalin. Alternatively, the vagus nerve may be one pathway but not the only pathway by which the activation of peripheral systems may influence the memory storage process.

Experience-dependent regulation of Leu-enkephalin hydrolysis in rat plasma

We examined experience-dependent alterations in the production of individual enkephalin metabolites during Leu-enkephalin hydrolysis in rat plasma in vitro. High performance liquid chromatography separation and electrochemical detection were used to quantify accumulation of the primary N-terminal products of enkephalin hydrolysis, Tyr and Tyr-Gly-Gly. Blood was sampled from rats through indwelling femoral artery catheters before, during, and after active avoidance training or appropriate control treatments. Avoidance training increased Tyr production, as did handling and exposing animals to the novel avoidance chamber without foot-shock training. On the other hand, Tyr-Gly-Gly production was elevated by blood sampling alone, by handling/novelty, and by training, but the effect of training was significantly greater than the effects of either of the other treatments. Interestingly, Tyr-Gly-Gly production was highly correlated (r = -0.885) with a measure of escape performance. Since the enzymes that participate in enkephalin hydrolysis act upon a number of peptides, regulation of enzyme activity may be one mechanism whereby an organism can modulate levels of circulating peptides in response to environmental experiences; this may contribute to the expression of appropriate behavioral responses to those environmental experiences.

Adrenalectomy attenuates the improvement of memory in rats by peripheral application of Des-Tyr-D-Pro4-casomorphin

beta-Casomorphin derivatives without the N-terminal amino acid tyrosine possess memory-improving effects after central and peripheral application. We investigated the significance of adrenal glands for the memory improving effect of the systemically applied beta-casomorphin derivative des-Tyr-D-Pro4CM (Pro-Phe-D-Pro-Gly) in a learning experiment. Seven-week-old rats were adrenalectomized or sham operated. One week after surgery the rats were trained in an active avoidance task in a shuttle box. Five avoidance reactions were taken as learning criterion. After training 10 nmol/kg des-Tyr-D-Pro4CM or saline (10 ml/kg) was subcutaneously applied. There were no differences in acquisition between adrenalectomized and sham-operated rats. The memory retention of sham-operated animals was improved by des-Tyr-D-Pro4CM. In adrenalectomized rats this positive effect could not be observed. The involvement of adrenal glands in the peptide effect during learning and retention is discussed.

Naloxone reduces social locomotor activity in rats

Naloxone, a nonspecific opioid antagonist, has been found to decrease the activity and social behavior of rats tested in pairs but the effects on individual locomotor activity have been equivocal. In the present study, groups of male Long-Evans hooded rats received naloxone (1 or 4 mg/kg, IP) or vehicle alone (isotonic saline) 30 min prior to testing sessions. Individual locomotor activity was measured in two activity boxes (41-cm3) equipped with two infrared photobeams using daily 30-min testing sessions for 5 consecutive days. Following a 1-week washout period (no testing), activity and social attraction (paired distance and contact) were examined in pairs of rats from each group using daily 15-min testing sessions for 4 consecutive days. Locomotor activity and its habituation were not significantly affected by naloxone in rats tested individually. However, both doses of naloxone significantly reduced paired locomotor activity compared to the control group. Measures of social attraction were not significantly affected by naloxone. The present findings suggest that naloxone does not produce nonspecific depressant effects on activity but rather may antagonize opioid release in situational contexts of high arousal (e.g., social activity) with consequent reduction of activity.

Effects of stress on opioid receptor binding in the rat central nervous system

The endogenous opioid peptides are known to play a significant role in the modulation and/or mediation of numerous environmental or experimental stressors. However, the specific opioid peptide(s) and receptor type(s) involved, under what physiologic conditions they are engaged and within which regions of the CNS is not well understood. We therefore examined the effects of both a chronic and an acute stressor-90-h water deprivation and a single 20-min foot shock on opioid receptor binding in 17 specific rat brain nuclei. [3H]DSTLE (Tyr-D-Ser-Gly-Phe-Leu-Thr) and [3H]DAGO(Tyr-D-Gly-Phe-NMe-Phe-Gly-ol) were used to label delta and mu receptors, respectively. Foot shock induced profound antinociception as measured by tail-flick latency which outlasted the stressor by several minutes. However, only the septum responded with a decrease in [3H]DAGO binding to this type of stress-induced analgesia. No other alterations in either [3H]DAGO or [3H]DSTLE binding were seen in response to foot shock. In contrast, water deprivation induced increases in [3H-DAGO] binding in the septum as well as increases in [3H]DSTLE binding in the caudate and accumbens nuclei. Moreover, the presumptive mild stress of handling in the foot shock control group was sufficient to decrease mu or delta receptor binding in seven out of 17 brain regions investigated (including the frontal cortex and olfactory tubercle where both mu and delta binding were increased) when compared to unhandled deprivation control animals. These changes in opioid receptor binding may have been the result of alterations in treatment-induced peptide release, receptor regulation, or interactions with other released neurotransmitter ligand/receptor complexes.(ABSTRACT TRUNCATED AT 250 WORDS)

Potentiation of the dorsal immobility response following intrastriatal injections of enkephalins

The effects of bilateral intrastriatal injections (1.0 microgram/side) of leucine5- and methionine5-enkephalins and their related nonopiate fragments upon three measures of immobility over a time course were investigated. Both leucine5-enkephalin and des-Tyr1-leucine-enkephalin potentiated the duration of the dorsal immobility response (DIR) 15 min postinjection and over a 1-h time course. On the other hand, methionine5-enkephalin and des-Tyr1-methionine-enkephalin potentiated the duration of the DIR at 5 and 15 min. These enkephalins and their fragments had no effect upon vertical cling and bar catalepsy. In a second study, an SC injection of 4 mg/kg naloxone 15 min prior to the central injections blocked the potentiation of the DIR effects of the enkephalins.

[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.

Cocaine enhances one-way avoidance responding in mice

We reported previously that posttraining cocaine injections enhance subsequent performance of an automated jump-up avoidance response and a trough avoidance response in rats. In the present study we examined the species generality of the cocaine enhancement by investigating the effects of posttraining cocaine injection on subsequent performance of a one-way active avoidance response in mice. Cocaine (30 mg/kg, IP) administered to mice immediately following completion of two escape-only trials on day 1 significantly enhanced avoidance response performance on day 2. Neither lidocaine nor cocaine methiodide, when administered in doses equimolar to the effective cocaine dose, altered performance on day 2. These data indicate that cocaine's enhancement of avoidance responding in mice probably is neither peripherally mediated nor attributable to its local anesthetic properties.

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.

Nicotine-induced alterations in peripheral tissue concentrations of native and cryptic Met- and Leu-enkephalin

This study examined the peripheral tissue distribution of native and cryptic Met- and Leu-enkephalin, and regulation of tissue enkephalins by nicotine. Met- and Leu-enkephalin concentrations showed widespread variation in tissue concentration and degree of processing. HPLC characterization of homogenate of spleen revealed that both native and cryptic immunoreactive Met-enkephalin are comprised of two peaks, one representing authentic Met-enkephalin pentapeptide and the other its sulfoxide. Subacute repeated administration of nicotine 0.1 mg/kg ip, six times at 30 min intervals, increased native Met- and Leu-enkephalin in adrenal medulla without affecting cryptic Met- and Leu-enkephalin concentrations, consistent with increased processing of larger peptides to Met- and Leu-enkephalin. Subacute nicotine decreased splenic concentrations of native and cryptic Met-enkephalin and native Leu-enkephalin, consistent with increased release of Met- and Leu-enkephalin from spleen and decreased synthesis of proenkephalin A or inadequate processing of larger peptides to enkephalin pentapeptides in spleen to compensate for the increased release during this period. HPLC characterization revealed that nicotine-induced decrease in native Met-enkephalin in spleen resulted from reductions in both pentapeptide and its sulfoxide. Nicotine also increased native Met-enkephalin in jejunum, decreased cryptic Met-enkephalin in heart atrium, increased native Leu-enkephalin in anterior pituitary and decreased cryptic Leu-enkephalin in jejunum. Nicotine may produce some of its effects through alterations in release of enkephalins from peripheral tissues.

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.

Amygdaloid central nucleus neuronal activity accompanying pavlovian cardiac conditioning: effects of naloxone

Rabbits were treated intravenously with either naloxone-HCl (0.5 mg/kg) or saline vehicle prior to aversive pavlovian conditioning and extinction training; heart rate conditioned responses and concomitant multiple-unit activity in the amygdaloid central nucleus were compared. Multiple-unit activity evoked by the conditioned stimulus increased during conditioning and decreased during extinction in saline-treated rabbits; naloxone treatment attenuated evoked neuronal activity but enhanced bradycardiac conditioned responses. Correlational analysis showed that, in 3 of 8 animals in the saline-treated group, larger increases in multiple-unit activity corresponded to smaller bradycardiac responses. Naloxone treatment did not alter the frequency or magnitude of this relationship, but it did augment the training-induced decrements in evoked neuronal activity at placements that were correlated with bradycardiac response magnitude. These data suggest that conditioned decreases in central nucleus neuronal activity normally may serve to disinhibit vagal mechanisms as conditioned bradycardia develops and that the neural circuits that produce these responses are sensitive to opioid modulation.

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

The effects of the enkephalin metabolites, Tyr, des-Tyr-[Leu]enkephalin (GGFL), and Tyr-Gly-Gly (YGG), on acquisition of an active avoidance task following their IP administration to mice were determined. Neither free Tyr (3.9-390.0 micrograms/kg) nor GGFL (7.1-710.0 micrograms/kg) altered acquisition of the avoidance response. In contrast, 53, but not 16 micrograms/kg, of YGG significantly impaired response acquisition. A 390.0, but not 39.0 micrograms/kg, dose of Tyr decreased locomotor activity levels measured in an open field. Together with previous findings that the enkephalin metabolites Tyr-Gly and Tyr-Gly-Gly-Phe also impair avoidance acquisition, these data indicate that the dipeptide Tyr-Gly is the minimum sequence needed to intefere with acquisition of an active avoidance response. Because the various enkephalin metabolites do not bind to opioid receptors, it is likely that their effects on avoidance acquisition represent a separate class of pharmacological agents whose effects are mediated by a nonopioid receptor mechanism. These results are important to the interpretation of behavioral studies involving peripheral administration of the opioid peptide, [Leu]enkephalin (LE).

Enkephalins interfere with early phases of voluntary ethanol drinking

The relationship between the opiate peptides Leu-enkephalin and [D-Ala2-Met5]enkephalinamide (DAME) and the initial expression and maintenance of ethanol preference was studied in male Wistar rats. Subcutaneous administration of both peptides prior to the first choice test between water and ethanol induced reductions on ethanol intake and subsequently on total fluid intake. Leu-enkephalin treatment also diminished ethanol preference in the day of treatment and in consecutive days. Neither Leu-enkephalin nor DAME treatments modified rats sucrose preference or intake. The results suggest that the enkephalins studied, when administered in the early phases of ethanol preference, interfere with the mechanisms involved in the propensity to drink ethanol.

Administration of leu-enkephalin impairs the acquisition of preference for ethanol

The effects of subcutaneous administration of leu-enkephalin (LEU-E) (10, 100 and 300 micrograms/kg) and LEU-E (100 micrograms/kg) plus naloxone (2.5 mg/kg) on ethanol preference and fluid intake have been investigated in rats. Under our procedural conditions, rats develop ethanol preference through forced ethanol drinking (conditioning session). Preconditioning administration of LEU-E induced a reduction of later ethanol preference. Post-conditioning administration of LEU-E (10 and 100 micrograms/kg) also attenuated the development of ethanol preference. NX antagonized the effects of LEU-E on ethanol preference and fluid consumption in the two experimental procedures used, indicating an involvement of opioid receptors in the LEU-E-induced impairment of the acquisition of ethanol preference.

DPen2-[DPen5]enkephalin, a delta opioid receptor-selective analog of [Leu]enkephalin, impairs avoidance learning in an automated shelf-jump task in rats

Both [Leu]enkephalin and DPen2-[DPen5]enkephalin, a delta opioid receptor selective analog of [Leu]enkephalin, impaired acquisition of an automated shelf-jump response in rats. A similar level of impairment was produced by equimolar doses of the two enkephalins. As is seen for [Leu]enkephalin when tested in a one-way active avoidance task, the dose-response function for the impairment produced by DPen2-[DPen5]enkephalin in the automated shelf-jump task is U-shaped. These results, together with our previous findings that DPen2-[DPen5]enkephalin and [Leu]enkephalin both impair acquisition of a one-way active avoidance response in mice, and that [Leu]enkephalin impairs acquisition of that same response in rats, support our suggestion that delta opioid receptors are implicated in the effects of [Leu]enkephalin on conditioning. In addition, these results indicate that the involvement of delta opioid receptors in acquisition impairment extends to two species of rodents and to two different avoidance conditioning tasks.

Endogenous opiates: 1988

This paper is the eleventh installment in our annual review of the research during the past year involving the endogenous opiate system. It is concerned with nonanalgesic and behavioral studies of the opiate peptides that were published during 1988. 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 activity; locomotor activity; sex, pregnancy, and development; immunology and cancer; and other behavior.

Effects of [D-Ala2] Met-enkephalinamide, a Met-enkephalin analog, on delayed response by squirrel monkeys

Squirrel monkeys were tested on an indirect spatial delayed response task after subcutaneous injections of either physiological saline, 100, or 500 microgram/kg [D-Ala2] methionine enkephalinamide (DAME). During Experiment 1 monkeys completed two-choice delayed response problems with 0-, 6-, 12- and 18- sec delays; DAME significantly enhanced performance at 18-sec delays but not for the shorter delay. During Experiment 2, monkeys performed a nine-choice spatial delayed response task with 0-, 4- and 8-sec delays. In Experiment 2, low but not high doses of DAME impaired performance. Memory functions represented by a bias-free performance measure paralleled percentage correct in both experiments. Therefore, DAME effect, in enhancing and in impairing performance, were not attributable to changes in the relative number of systematic spatial errors (positional win-shift; lose-stay, position perseveration, and position preference).

Plasma uptake and in vivo metabolism of [Leu]enkephalin following its intraperitoneal administration to rats

To understand better how [Leu]enkephalin (LE) acts to modulate learning and memory in rats, the plasma uptake, disappearance, and metabolism of LE were investigated following its intraperitoneal administration. Concentrations of [3H]-LE and its radioactive metabolites were determined by thin layer chromatography in plasma samples withdrawn from rats at various times after injection of peptide. As measured in rats receiving an IP injection of a dose of LE (3 micrograms/kg) that impairs active avoidance conditioning, the LE was very rapidly metabolized, with greater than 95% of plasma [3H] in the form of metabolites by 1 min after injection. Despite this rapid metabolism, low but measurable quantities of intact LE were detectable in plasma at all sampling times. Consistent with a greater potency of D-Ala2-[D-Leu5]enkephalin (DADLE) than of LE in modulating avoidance conditioning, DADLE was less rapidly metabolized than was LE following its IP administration. The metabolism of DADLE and LE in vivo was more rapid than it was in plasma in vitro, suggesting a role for membrane bound enzymes in the metabolism of IP-administered enkephalins. The data demonstrate that, despite a rapid hydrolysis of LE in vivo, sufficient LE is present in plasma following IP administration of a behaviorally active dose to support a role of circulating intact LE in the modulation of avoidance conditioning.

Long-term effects of parity on opioid and nonopioid behavioral and endocrine responses

Parity (number of parturitions) affects the endogenous opioid system. Multiparous lactating rats are less sensitive to the effects of morphine (MOR) on maternal behavior (MB) and analgesia than primiparous lactating rats. In order to determine whether these changes in opiate sensitivity persist beyond the lactational state, the present study compared the sensitivity of ovariectomized nulliparous and nonlactating primiparous rats to MOR's effects on MB (Experiment 1), analgesia (Experiment 2) and prolactin release (Experiment 3) in addition to stress-induced analgesia (Experiment 2). In Experiments 1 and 2 primiparous rats were allowed to give birth and remain with their litter (culled to 6 pups) until weaning. At that time the pups were removed and the dams and age-matched nulliparous rats were ovariectomized. Four weeks later animals were exposed to foster pups daily in order to induce MB (Experiment 1). On day 5 or 6 of full MB the primiparous and nulliparous rats received either saline or one of four doses of MOR (0.625, 1.25, 2.5, or 5.0 mg/kg, SC) and 60 min later MB was assessed. MOR, at the 2.5 mg/kg dose, disrupted MB in a significantly greater percentage of nulliparous as compared to primiparous animals (100% vs. 55%, respectively). In Experiment 2, nulliparous and nonlactating primiparous animals received 2.5 mg/kg of MOR four weeks after ovariectomy. Analgesia was assessed on a tail-flick apparatus 30, 60, 90, 120 and 150 min postinjection. One week later the same animals were exposed to cold-water swims (CWS, 2 degrees C, 3.5 min) and tail-flick latencies were again recorded.(ABSTRACT TRUNCATED AT 250 WORDS)

[3H]naloxone binding in the brain of the domestic chick (Gallus domesticus) determined by in vitro quantitative autoradiography

The distribution of [3H]naloxone binding sites was investigated in the brains of one-day-old domestic chicks using quantitative receptor autoradiography. Among the forebrain regions, the greatest levels of opiate binding were found in hyperstriatum dorsale, hyperstriatum ventrale, hyperstriatum intercalatum supremum and neostriatum. Intermediate levels were found throughout the paleostriatal regions, septum, thalamus, archistriatum, hyperstriatum accessorium and area parahippocampalis whilst in hippocampus and ectostriatum the density of [3H]naloxone binding sites was low. In the hindbrain, high levels of opiate binding were found in optic tectum whereas in cerebellum the density of binding sites was barely above background. The greatest densities of opiate binding appear to coincide with regions found to be involved in sensory processing and memory storage.

Differential effects on active avoidance performance and locomotor activity of two major enkephalin metabolites, tyr-gly-gly and des-tyr-[leu]enkephalin

We examined the effects of two enkephalin metabolites, des-tyr-[leu]enkephalin and tyr-gly-gly, on one-way active avoidance conditioning in mice. These metabolites are products of the two major enkephalin hydrolyzing enzymes in plasma, aminopeptidase and angiotensin converting enzyme. Like [leu]enkephalin from which it may be formed, tyr-gly-gly impaired avoidance acquisition, and its dose-response function for this effect was U-shaped. Also like [leu]enkephalin, tyr-gly-gly did not alter locomotor activity. On the other hand, des-tyr-[leu]enkephalin, at the doses tested, was without effect on avoidance conditioning but produced decreased locomotion. These data suggest that the tyrosine end of the enkephalin molecule may be important for its effects on conditioning. Because of their low opioid potencies, it is unlikely that the behavioral actions of tyr-gly-gly and des-tyr-[leu]enkephalin are mediated through opioid receptors.