Fluorescence decay time distribution analysis of cyclic enkephalin analogues; influence of solvent and Leu configuration in position 5 on conformation.

Lifetime distribution analysis were performed to study the influence of Leu configuration in position 5 on changes of the peptide chain of cyclic analogues of enkephalins containing a fluorescence donor and acceptor in different solvents. The configuration change of Leu5 in all the analogues of enkephalins studied which contain donor-acceptor pairs has no apparent influence on Trp lifetime distributions. In contrast, there is a significant solvent effect on the shape of lifetime distribution.     

Modulating effect of enkephalins on hemopoieis under stress

The influence of enkephalins on the medullary hemopoiesis has been studied during stress reaction in noninbred mice. It was shown that leu-enkephalin administration suppressed, while met-enkephalin injection stimulated granulocyto- and erythropoiesis during immobilization stress.     

Reserpine Increases Chromaffin Cell Enkephalin Stores Without a Concomitant Decrease in Other Proenkephalin-Derived Peptides

Reserpine increases the levels of enkephalins in adrenal medullary chromaffin cells; however, the origin of the newly apparent pentapeptides has been the subject of debate, because no increase in the levels of proenkephalin mRNA has been observed. The present study was performed for determining if the reserpine-induced increase in context of enkephalins was derived from processing of preexisting fragments of proenkephalin. Bovine chromaffin cell enkephalins and larger enkephalin-containing peptides were separated by reversed-phase HPLC and identified by approximate molecular weight, elution with peptide standards, and enkephalin sequences contained. Treatment of the cells with reserpine increased the levels of enkephalins and of enkephalin-containing peptides of up to approximately 3 kilo-daltons without reducing the levels of larger enkephalin-containing peptides. Similar results were obtained with another catecholamine-depleting drug, tetrabenazine. In contrast, treatment of chromaffin cells with theophylline or forskolin increased the levels of both enkephalins and enkephalin-containing peptides of all sizes. The results suggest that new synthesis of proenkephalin is required for the effects of reserpine, although proenkephalin processing is also altered by this drug.     

The effect of N-terminal acetylation and the inhibition activity of acetylated enkephalins on the aminopeptidase M-catalyzed hydrolysis of enkephalins.

High performance liquid chromatography and high performance liquid chromatography/electrospray ionization-mass spectrometry were used to study the effect of N-terminal acetylation and the inhibition activity of acetylated enkephalins on the aminopeptidase M (EC 3.4.11.2)-catalyzed hydrolysis of methionine (Met-enk) and leucine enkephalins (Leu-enk). Acetylation imparts a significant enhancement in the proteolytic stability of these two peptides. After 30 min of the reaction, < 10% of both acetylated enkephalins was hydrolyzed. In an 8-h incubation period, only a maximum of 54% acetylated (Ac)-Met-enk and 38% Ac-Leu-enk was hydrolyzed. Vmax and Km [infil] for the degradation of Ac-Met-enk were 1.4 nmol/min/50 ng and 2.2 mM, respectively. The corresponding values for the reaction of Ac-Leu-enk were 0.5 nmol/min/50 ng and 0.9 mM. Also, the aminopeptidase M activity on Met-enk can be inhibited in the presence of Ac-Met-enk, which acts as a mixed-type inhibitor with the inhibition constant (K(i)) of I x 10(-3) M.     

Are NPY and enkephalins costored in the same noradrenergic neurons and vesicles?

Separate studies show that NPY and enkephalins are widely distributed in peripheral noradrenergic neurons. In the present study, the subcellular costorage and release in response to intense sympathetic stimulation and reserpine at near therapeutic doses (0.05 mg/kg every other day) were examined. In young pig arteries and vas deferens, enkephalin and D beta H immunofluorescence show consistent but not total overlap. Also NPY is colocalized with D beta H in many fibers but with VIP (nonnoradrenergic) in others. Ultrastructural immunogold labeling indicates that individual terminals contain large dense cored vesicles (LDVs) which store either NPY or enkephalins, even though costorage of both peptides occurs. Some LDVs costore NPY and VIP, especially in the middle cerebral artery and in the lamina propria of vas deferens. Acute CNS ischemia depletes enkephalins and norepinephrine in all tissues analyzed without parallel loss of NPY. Reserpine depletes norepinephrine 70-85% but does not deplete NPY or enkephalins. The latter is in contrast to commonly used high doses known to produce nonspecific, detergent-like effects. In fact, low doses of reserpine induce a time-dependent new synthesis and processing of NPY precursor peptides in vas deferns. Contrasting effects of reserpine on NPY and enkephalin contents, new synthesis and apparent processing, and a differential response to acute CNS ischemia were found in every tissue studied. Activation of precursor neuropeptide processing occurred immediately upon intense sympathetic stimulation in most tissues. Dual localization of NPY in noradrenergic and nonnoradrenergic fibers and differences in subcellular LDV storage help explain why enkephalin correlates better than NPY with norepinephrine loss in response to acute CNS ischemia. Furthermore, the costorage of NPY and enkephalins in distinct subpopulations of noradrenergic fibers, which varies according to tissue, is likely to be under separate CNS control.     

Modulating effect of opioid peptides on hemopoiesis in stress

The influence of leu-enkephalin and dalargin on the blood system was studied during immobilization stress in mice. The early transmitted reactions of the peripheral blood were shown to decrease upon single drug infusions after immobilization. At later terms the activation of bone marrow hematopoiesis was not registered in mice receiving opioid peptides in contrast to the control animals. It correlates with drug-induced decrease in the mitotic activity of bone-marrow cells. Suppressive effect of opioids on hematopoiesis during stress was connected with their decreasing effect on corticosteroid level in the animal plasma. The latter can suggest indirect influence of enkephalins on bone marrow hematopoiesis in immobilization stress.     

Simulated microgravity enhances cerebral artery vasoconstriction and vascular resistance through endothelial nitric oxide mechanism

Growing evidence suggests that cardiac enkephalins and their receptors are involved in ischemic preconditioning (IPC). Because there is no evidence for vesicular storage of small bioactive enkephalins in the heart, studies were designed to test the hypothesis that ischemia depletes cardiac enkephalins and that IPC preserves the same enkephalins by accelerating their processing from the larger proenkephalin precursor (PEP) pool. The precursors and two bioactive representatives, Met-enkephalin (ME) and Met-enkephalin-Arg-Phe (MEAP), were separated by size-exclusion chromatography and quantified by radioimmunoassay. Isolated perfused rat hearts were prepared and exposed to global ischemia. After 30 min of global ischemia and 40 min of reflow, the PEP pool was reduced (from 17.99 +/- 1.52 to 14.20 +/- 2.38 pmol/g wet wt), MEAP increased by 53%, and ME declined by 68%. The sum of the two smaller peptides was unchanged (9.78 +/- 0.83 vs. 9.33 +/- 2.81). Thus the total enkephalin peptide content was not altered (27.77 +/- 1.69 vs. 24.10 +/- 4.75). Peptide distribution after ischemia and reflow was also unaltered by pretreatment with peptidase inhibitors. However, when the hearts were preconditioned, the PEP pool remained significantly lower and both of the bioactive peptides, MEAP and ME, were elevated (+49% and +86%, respectively). The decline in the PEP pool was prevented by peptidase inhibition and the rise in MEAP was exaggerated. In separate protocols, synthetic enkephalins (ME, MEAP, and Leu-enkephalin) were added to the coronary inflow before 30 min of global ischemia and throughout the subsequent reflow. The added enkephalins (10(-8) M) had no inotropic effect on baseline function but completely prevented the mechanical dysfunction observed in untreated controls during reflow. Thus IPC appears to increase available bioactive enkephalins (MEAP + ME) within the heart by enhancing synthesis of precursors and their subsequent processing from the PEP pool.     

Semicarbazide Substitution Enhances Enkephalins Resistance to Ace Induced Hydrolysis

In our previous study on [Met5]-enkephalin analogues, [Met5]-enkephalin semicarbazide was found as a new enkephalin amide that produces antinociception even in ACE (Angiotensin Converting Enzyme) exposure in vivo. In the present work we examined the corresponding [Leu5]-enkephalin derivatives to confirm the influence of semicarbazide substitution. To prevent the enkephalins biodegradation animals were pretreated with a mixture of peptidase inhibitors. As assessed by tail-flick test no significant difference was detected between the produced antinociception by the [Leu5]-enkephalin derivatives. Based on our results both semicarbazide and ethylamide groups could preserve the provided analgesia after captopril (ACE inhibitor) omission from the peptidase inhibitors mixture. This work confirms that semicarbazide substitution on enkephalins yields ACE resistance antinociceptive peptides, nevertheless it may necessarily not enhance the peptides analgesic potencies.     

Brain enkephalin distribution is unaltered by hypophysectomy

Methionine (met) and leucine (leu)-enkephalin were measured by radioimmunoassay in 16 brain regions removed by microdissection in intact rats. In hypophysectomized rats the regional concentrations of the enkephalins was not altered. Brain enkephalins do not appear to be derived from pituitary endorphins.     

Interaction on the antinociceptive effect between neurotensin and enkephalins or tuftsin

The aim of this paper was to study the interaction between neurotensin and both enkephalins or its synthetic analogue D-Ala2-metenkephalinamide, or tuftsin, on the antinonciceptive effect of these peptides in mice after intracisternal injection. Antinociception was measured by the hot-plate method. It was shown that neurotensin antagonized evidently the antinociceptive effect of enkephalins and their analogue. On the contrary, neurotensin and tuftsin were agonists in induction of analgesia. It is concluded that neurotensin modulates in an opposite way the function of the enkephalinergic neurons and the central action of tuftsin.     

Tetraethylammonium facilitates the stimulation-evoked loss of the enkephalins from the myenteric plexus of guinea-pig ileum

The effects of electrical field stimulation on the contents of [Met]enkephalin and [Leu]enkephalin were determined in myenteric plexus-longitudinal muscle preparations of the guinea-pig small intestine. Cycloheximide (0.1 mM) was present in all experiments to prevent de nouveau biosynthesis. The two enkephalins were separated by high performance liquid chromatography and assayed on the mouse vas deferens. Stimulation with submaximal pulses (50 mA, 0.5 ms) at a frequency of 10 Hz caused maximal losses of about 35% of [Met]enkephalin and [Leu]enkephalin after 3 h (108000 pulses). The plot of log (enkephalin content) against number of pulses was steeper during the first 30 min than during the later periods. Tetraethylammonium bromide (TEA, 10 mM) increased the [Met]enkephalin and [Leu]enkephalin contents of the non-stimulated preparations by about 50%. When the preparations were stimulated in the presence of TEA at 50 mA and 1 Hz, the plots of loss of enkephalins against number of pulses were linear until the maximum of about 50% was reached. Compared with stimulation in the absence of TEA, the rate constant was 8 times greater for [Leu]enkephalin and 20 times greater for [Met]enkephalin. The absolute losses per pulse were about 13 times greater for [Leu]enkephalin and 27 times greater for [Met]enkephalin than in the absence of TEA. In the presence of bacitracin and a mixture of dipeptides, the enzymatic degradation of the enkephalins was sufficiently suppressed to cause an overflow of 30-60% of the enkephalins lost from their stores into the perifusing Krebs solution. Until it is possible to determine the preformed precursors, which are present in large quantities, the kinetics relationship between these precursors and the enkephalins cannot be investigated. A similar dilemma exists for the relationship between "released' enkephalins and the losses from their stores.     

Postsynaptic inhibitory effects of Met- and Leu-enkephalin on endocrine and adjacent neurones in the preoptic-septal region of the guinea pig

Iontophoretic application of enkephalins induced inhibitory effects on unit activity of endocrine and adjacent neurones in the preoptic-septal region. Antagonism or lack of antagonism of these effects by naloxone indicated an action of enkephalins through different opiate receptors. Inhibitory effects of enkephalins were obtained during iontophoretic application of Mg2+, showing that these opioid peptides acted postsynaptically. Because enkephalin acts on endocrine neurones, these opioid peptides might be involved in the control of gonadotrophic hormone release by acting on cell bodies of LH-RH neurones.     

Lateral olivocochlear neurons contain both enkephalin and dynorphin immunoreactivities: immunocytochemical co-localization studies

Antibodies to methionine enkephalin and to dynorphin B were used in an immunocytochemical study examining co-containment of enkephalins and dynorphins in olivocochlear neurons in the guinea pig lateral superior olive. Two methods of sequential co-localization were employed: one using primary antibodies from different species, the second using elution of antibodies. Co-localization of enkephalin-like and dynorphin-like immunoreactivities was found in lateral olivocochlear neurons, suggesting co-containment of enkephalins and dynorphins in this projection pathway from the lateral superior olive to the organ of Corti.     

Opioid peptide content of the brain and blood of rats under immobilization stress

A study was made of the influence of acute and repeated immobilization on the content of immunoreactive metenkephalin (ME), leu-enkephalin (LE) and beta-endorphine (beta-E) in different regions of rat brain and that of beta-E in rat blood. Acute immobilization for 30 min led to a decrease in the content of the enkephalins in the hypothalamus. Meanwhile 150-min immobilization caused a remarkable increase in the opioid concentration in the hypothalamus and of the enkephalins in the pituitary. At the same time the beta-E content in the pituitary dropped to 38% of the control (P less than 0.001), that in the blood was twice as increased (P less than 0.05). Repeated immobilization for 7 days abolished these changes in the hypothalamus and pituitraty. The next day following immobilization for 39 days the content of LE and beta-E in the hypothalamus, medulla oblongata, midbrain and blood plasma was noticeably lowered. However, after successive immobilization it rose to the control level. The data obtained are discussed in the light of the involvement of opiate systems in the realization of antinociceptive and emotional effects of stress.     

Selective inhibition of synaptosomal proline uptake by leucine and methionine enkephalins

The high affinity, sodium-dependent uptake of proline by rat brain synaptosomes was inhibited by the opioid pentapeptides, Leu-enkephalin and Met-enkephalin. The synaptosomal uptake of other putative neurotransmitter amino acids including glutamic acid, aspartic acid, gamma-aminobutyric acid, and taurine was not altered in the presence of enkephalins. The uptake of a neuroinactive amino acid, leucine, was also unaffected by enkephalins. The extent of proline uptake was half-maximal at a Leu-enkephalin concentration of 1 microM. Both the initial rate of transport and the overall capacity for proline accumulation were reduced. The effect of the enkephalins was vectorial since carrier-mediated efflux of proline was not altered in the presence of enkephalins. Morphine and the opioid peptides, dynorphin and beta-endorphin, were without effect on proline uptake. The inhibition of proline uptake by enkephalins was not diminished by prior incubation of the synaptosomal preparation with naloxone; however, the inhibition was attenuated by 1-butanol. The des-tyrosyl fragments of the enkephalins were as inhibitory as the intact pentapeptides. A modified enkephalin ([D-Ser2]Leu-enkephalin-Thr) with selective affinity for the delta subclass of enkephalin receptor was effective in inhibiting proline uptake. On the basis of the selectivity of these effects, we propose that there is a specific population of nerve endings in the cerebral cortex that contains both a proline-transport system and binding sites for Leu- and Met-enkephalin and furthermore, that these binding sites may be related to the putative delta receptor.     

The peroxidase-catalyzed oxidation of enkephalins.

In vitro experiments are reported showing that Leu-enkephalin and Metenkephalin, in the presence of hydrogen peroxide, can be oxidized by horseradish peroxidase. The products formed are strongly fluorescent and characterized by absorption peaks with maxima at 290 nm and 315 nm. The effects of substrate and enzyme concentrations on the oxidation rate of enkephalins are described. Amino acid analysis of the hydrolysates from peroxidase-treated enkephalins provides evidence for the presence of dityrosine. The data suggest that the oxidation leads to the production of enkephalin dimers with a linkage between the N-terminal tyrosine residues. Data are also obtained indicating that enkephalins function as hydrogen donors for mammalian peroxidases.     

Effects of enkephalins on perfusion pressure in isolated hindlimb preparations

A series of studies were conducted to determine the effects of leucine-(leu-) enkephalin and methionine-(met-) enkephalin on perfusion pressure. These experiments utilized isolated perfused femoral arterial preparations in pentobarbital-anesthetized cats. The enkephalins were administered intraarterially into the femoral artery and changes in perfusion pressure recorded. Leu-enkephalin in doses of 1 μg to 320 μg produced significant dose-dependent decreases in perfusion pressure (4.0 ± 1.3% with 1 μg to 19.1 ± 2.1% with 320 μg). Similar declines in perfusion pressure (5.2 ± 2.4% with 1 μg to 21.7 ± 4.1% with 320 μg) were observed following the administration of met-enkephalin. Pretreatment with naloxone (3 mg/kg) antagonized the effects of both enkephalins. Diphenhydramine (2 mg/kg) effectively antagonized the leu-enkephalin elicited decline in perfusion pressure but blocked the effects of met-enkephalin only at lower agonist doses. Propranolol treatment (4 mg/kg) did not alter the pressure responses to either enkephalin. The results of the study show that intraarterially administered enkephalins exert a vasodilatory effect on vasculature in skeletal muscle which may be direct, indirect or both. The differential antagonism of the effects of the two enkephalins suggest that the two opioids act through different receptors or multiple receptors.     

Structural alterations of enkephalins in the presence of GM1 ganglioside micelles

The enkephalins are endogenous neurotransmitters and bind with high affinity at the delta-receptor. Gangliosides, the major glycans of nerve cells, known to interact both with receptors and ligands on the cell surface, have been implicated to modulate the actions of opioid receptors by allosteric regulation (Wu, G.; Lu, Z. H.; Wei, T. J.; Howells, R. D.; Christoffers, K.; Leeden R. W. Ann NY Acad Sci 1998, 845, 126-138). We have studied the interactions between enkephalins and monosialylated ganglioside GM1 using NMR spectroscopy and fluorescence. The structural models of enkephalins in the presence of GM1 micelles were generated using two-dimensional (1)H-ROESY experiments along with restrained molecular dynamics simulations. We report a conformational alteration of enkephalins in the presence of GM1 micelles.     

Anxiety- and depressive-like responses and c-<Emphasis Type="Italic">fos</Emphasis> activity in preproenkephalin knockout mice: Oversensitivity hypothesis of enkephalin deficit-induced posttraumatic stress disorder

The present study used the preproenkephalin knockout (ppENK) mice to test whether the endogenous enkephalins deficit could facilitate the anxiety- and depressive-like symptoms of posttraumatic stress disorder (PTSD). On Day 1, sixteen wildtype (WT) and sixteen ppENK male mice were given a 3 mA or no footshock treatment for 10 seconds in the footshock apparatus, respectively. On Days 2, 7, and 13, all mice were given situational reminders for 1 min per trial, and the freezing response was assessed. On Day 14, all mice were tested in the open field test, elevated plus maze, light/dark avoidance test, and forced swim test. Two hours after the last test, brain tissues were stained to examine c-fos expression in specific brain areas. The present results showed that the conditioned freezing response was significant for different genotypes (ppENK vs WT). The conditioned freezing effect of the ppENK mice was stronger than those of the WT mice. On Day 14, the ppENK mice showed more anxiety- and depressive-like responses than WT mice. The magnitude of Fos immunolabeling was also significantly greater in the primary motor cortex, bed nucleus of the stria terminalis-lateral division, bed nucleus of the stria terminalis-supracapsular division, paraventricular hypothalamic nucleus-lateral magnocellular part, central nucleus of the amygdala, and basolateral nucleus of the amygdala in ppENK mice compared with WT mice. In summary, animals with an endogenous deficit in enkephalins might be more sensitive to PTSD-like aversive stimuli and elicit stronger anxiety and depressive PTSD symptoms, suggesting an oversensitivity hypothesis of enkephalin deficit-induced PTSD.     

Is there an interaction between catecholamines and enkephalins in the inferior mesenteric ganglion of the cat?

The authors attempted to block the effects of enkephalins in the lower mesenteric ganglion of the cat by injection of Nalorphin--the antagonist to morphine. In the ganglion they observed an accumulation of catecholamines in nerve cells, nerve terminals and SIF cells. The inhibitory action of enkephalins to catecholamines secretion from nerve cells was assumed.