beta-Endorphin: analgesic and receptor binding activity of non-mammalian homologs

Analgesic potencies of turkey, ostrich and des-acetyl salmon beta-endorphins have been measured in the tail-flick test and binding affinities determined by radio-receptor assay. The duration of analgesia and the slope of the dose-response curves generated by these peptides are similar to those elicited by mammalian beta-endorphins. This suggests that they act in vivo and in vitro on the same population of opiate receptors. The ratio of binding to analgesic potencies observed for these peptides varies nearly sixfold. Structure-activity analysis suggests that a basic side-chain at position 9 is required in order to produce a high opiate activity both in vivo and in vitro. A reexamination of the biological activities of camel beta-endorphin shows that the analgesic potency and binding affinity of this peptide are respectively 171 and 2.7 times higher than human beta-endorphin. His-27 and/or Gln-31 may contribute to this increased potency. The dissociation of radioreceptor binding affinity from analgesic potency in these naturally occurring beta-endorphin homologs suggests that either the conditions under which the binding assay is performed mask the true binding potency in the brain or that, once bound to the appropriate receptor, these homologs do not possess equal ability to produce biological effects.     

Inhibition of analgesia by C-terminal deletion analogs of human beta-endorphin

Human beta-endorphin (beta h-EP) analogs of variable chain lengths have been investigated for their potency in inhibiting analgesia induced by beta h-EP or by the potent opiate etorphine. It was found that beta h-EP-(1-28) inhibits the analgesic effect of beta h-EP and etorphine when co-injected intracerebroventricularly into mice. Antagonism by competition at same opioid receptor subtypes is suggested from parallel shifts of the dose-response curve of etorphine or beta h-EP in the presence of increasing doses of beta h-EP-(1-28). On a molar basis, beta h-EP-(1-28) is nearly 10 times more potent than naloxone. The reduction of the chain length from residues 1-28 to 1-27 lowered the antagonist potency while further reduction of the peptide chain led to a complete loss of inhibitory activity. From comparison of the opioid-receptor binding affinity, analgesic activity and antagonist potency, it is concluded that the C-terminus of beta-EP is critical to the biological efficacy of the molecule and that the antagonist activity of C-terminal deletion analogs is probably mediated through residues 27 and 28.     

Influence of N-terminal acetylation and C-terminal proteolysis on the analgesic activity of beta-endorphin.

Removal of one, two and four amino-acid residues from the C-terminus of beta-endorphin ('lipotropin C-Fragment', lipotropin residues 61--91) led to the formation of peptides with progressively decreased analgesic potency; there was no change in the persistence of the analgesic effects. The four C-terminal residues are thus important for the activity of beta-endorphin, but not for the duration of action. Removal of eight amino-acid residues from the N-terminus provided a peptide that had no specific affinity for brain opiate receptors in vitro and was devoid of analgesic properties. The N-terminal sequence of beta-endorphin is therefore necessary for the production of analgesia, whereas the C-terminal residues confer potency. The N alpha-acetyl form of beta-endorphin had no specific affinity for brain opiate receptors in vitro and possessed no significant analgesic properties. Since lipotropin C'-Fragment (lipotropin residues 61--87) and the N alpha-acetyl derivative of beta-endorphin occur naturally in brain and pituitary and are only weakly active or inactive as opiates, it is suggested that proteolysis at the C-terminus and acetylation of the N-terminus of beta-endorphin may constitute physiological mechanisms for inactivation of this potent analgesic peptide.     

Synthesis and receptor binding activity of elephant beta-endorphin, a beta-endorphin homolog with highly potent analgesic activity.

Elephant beta-endorphin and its analog, elephant beta-endorphin(6-31) were synthesized by standard solid phase method. Receptor binding activity showed that elephant beta-endorphin was five to six times more potent than human beta-endorphin in its ability to bind to opiate receptors on rat brain membrane. In a previous study (Wong, C.-L., Wai, M.-K., Cheng, H.-C., Chung, D. & Yamashiro, D (1990) Clinical and Experimental Pharmacology and Physiology 16, 33-37), tail flick test for intracerebroventricularly administered beta-endorphin showed that the antinociceptive potency of elephant beta-endorphin was seven to eight times higher than that of human beta-endorphin in mice. Results from both studies suggest that elephant beta-endorphin was a much more potent antinociceptive agent than human beta-endorphin in tail flick test and its higher analgesic activity might be due to its higher affinity for opiate receptors in the brain.     

Examination of the requirement for an amphiphilic helical structure in beta-endorphin through the design, synthesis, and study of model peptides

In our approach to beta-endorphin modeling, we have proposed that the biological properties of the natural peptide are determined by the combination of three basic structural units: a highly specific opiate recognition sequence at the NH2 terminus (residues 1-5) connected via a hydrophilic peptide link (residues 6-12) to a potential amphiphilic helix in the COOH-terminal residues 13-31. In the alpha-helical conformation the hydrophobic domain twists around the length of the helix and covers almost one-half of its surface. The other distinctive features of the helix include its basicity and the two aromatic residues Phe18 and Tyr27. In contrast to previous models we have studied, peptide 4 is a "negative" model in the sense that it was designed and examined in order to determine how the lack of a well defined amphiphilic structure affects the biological properties of beta-endorphin. For this purpose, peptide 4 retains the three structural units previously postulated for beta-endorphin, but the amino acids of the 13-31 region are arranged in such a way that no definite continuous hydrophobic zone could be formed in an alpha- or pi-helical conformation of this region. In aqueous buffered solutions, peptide 4 showed almost the same amount of alpha-helical structure as beta-endorphin, with a slight tendency toward less helicity in 50% aqueous 2,2,2-trifluoroethanol. In rat brain homogenate, peptide 4 was degraded slightly slower than beta-endorphin, in contrast to the apparently much higher stability of previous models under the same conditions. With regard to opiate receptor binding, peptide 4 was twice as potent as beta-endorphin in mu-receptor assays but half as potent in delta-receptor assays. The opiate potency of peptide 4 on the guinea pig ileum was higher than that of beta-endorphin. In contrast, in the rat vas deferens assay, which is very specific for beta-endorphin, the potency of peptide 4 was very low and could be shown not to be mediated by the same opiate mechanism or by the same opiate receptor. A comparison of these results with those of previous model peptides provides further evidence for the importance of an amphiphilic helical structure in beta-endorphin residues 13-31, which determines the resistance to proteolysis of the natural molecule and contributes to the delta- and mu-opiate receptor interaction. The amphiphilicity of this helical structure must also be essential for high opiate activity on the rat vas deferens (epsilon-receptors), whereas no such structural requirement appears to be necessary for interaction with the opiate receptors on the guinea pig ileum.     

Selective Alterations of Opiate Receptor Subtypes in Mono sodium Glutamate-Treated Rats

Neonatal treatment of rats with monosodium glutamate (MSG) has been demonstrated to destroy cell bodies of neurons in the arcuate nucleus including the brain beta-endorphin (B-END) system. The effects on opiate receptors of the loss of B-END is unknown. Neonatal rats were treated with MSG as previously described. After reaching maturity (7-9 months), MSG-treated rats and litter-matched untreated control rats were decapitated and brains dissected into brain regions. Opiate receptor assays were run with [3H]morphine (mu receptor ligand) and [3H]D-alanine2-D-leucine5 (DADL) enkephalin (delta receptor ligand) for each brain region for both MSG and control rats simultaneously. Scatchard plot analyses showed a selective increase in delta receptors in the thalamus only. No corresponding change in mu receptors in the thalamus was found. The cross-competition IC50 data supported this conclusion, showing a loss in the potency of morphine in displacing [3H]DADL enkephalin in the thalamus of MSG-treated rats. This shift in delta receptors produced an IC50 displacement pattern in thalamus, ordinarily a mu-rich area, similar to that of striatum or cortex, delta-rich areas, again indicating an increase in delta receptors. Similar changes in delta receptors in other brain regions were not found. These results represent one of the few examples of a selective and localized shift in delta with no change in mu sites. Furthermore, the delta increase may reflect an up-regulation of the receptors in thalamus after chronic loss of the endogenous opioid B-END.     

Interaction of iodinated human [D-Ala2]beta-endorphin with opitate receptors.

The interaction of beta-endorphin with opiate receptors was studied by using the radioiodinated, metabolically stable D-Ala2 derivative of human beta-endorphin. This analog binds specifically to rat brain membrane preparations with an apparent Kd of about 2.5 x 10-9 M. The ability of various enkephalin analogs, as well as opiate agonists and antagonists, to inhibit the binding of beta-endorphin clearly demonstrates that this peptide can bind to opiate receptors. However, the effects of various cations on the binding of 125I-[D-Ala2]beta-endorphin are markedly different from those found for enkephalin binding. Sodium ion at physiological concentrations decreases substantially the binding of enkephalins but only slightly decreases endorphin binding, whereas manganese enhances enkephalin binding but has no effect on endorphin binding. Moreover, potassium (100 mM) decreases the binding of beta-endorphin but does not affect enkephalin binding. These results suggest that beta-endorphin and enkephalin bind differently to the same receptor or bind to different receptors with overlapping specificity.     

Opioid pharmacology in the rat hippocampal slice

The ability of several opioids in potentiating the synaptic activation of CA1 pyramidal cells in the rat hippocampal slice were compared. Morphine and the opioid peptides, (D-ala2, D-leu5)-enkephalin (DADL), morphiceptin, beta-endorphin, and Tyr-D-Ser-Gly-Phe-Leu-Thr (DSThr) caused a concentration-dependent, naloxone-reversible shift to the left in the input-output (IO) curve constructed by plotting the population spike as a function of the field EPSP. These opioids then produced an increase in the size of the population spike while leaving the EPSP unaffected. In contrast, the kappa agonist prototype, ethylketazocine, had no effect on the IO curve when perfused in concentrations up to 10 microM. The rank order of potency for the opioids in the CA1 region of the hippocampus was DADL greater than DSThr greater than beta-endorphin greater than morphiceptin greater than morphine much greater than ethylketazocine. Thus, opioids that are more specific for delta opiate receptors were the most potent and mu receptor agonists, the least potent in this action. Taken together with previous studies suggesting that morphine and DADL may interact with a common opiate receptor in the CA1 region, the results are consistent with the notion that these epileptiform effects may be primarily mediated by delta opiate receptors in this area although the potency of morphiceptin indicates that mu receptors play some role in this effect.     

Opioid peptides as intercellular messengers

Opioid peptides are endogenous substances present in central nervous system and various tissues whose actions are mediated by opiate receptors. They belong to two different classes: short peptides like the two pentapeptides enkephalin and substances of higher molecular weight like beta-endorphin. It appears that these various peptides play a messenger role between cells, either as neurotransmitters in the case of enkephalins or as hormones in the case of beta-endorphin.     

Beta-endorphin. Biological activity of analogs containing dermorphin and dynorphin sequences: ileum and vas deferens assays

Biological activity of synthetic beta-endorphin (beta-EP) analogs containing dermorphin or dynorphin-A-(1-13) structure has been investigated using the guinea pig ileum and the vas deferens of the mouse, rat and rabbit. Replacement of NH2-terminal 1-7 segment of camel beta-EP [beta c-EP-(1-7)] with dermorphin caused a great increase in opiate potency of the analog. [Dermorphin (1-7)]-beta c-EP was 120 times more potent than beta c-EP in the guinea pig ileum assay, 49 times more potent in the mouse vas deferens assay; and only 4 times more potent in the rat vas deferens assay. Replacement of NH2-terminal 1-13 segment of human beta-EP [beta h-EP-(1-13)] with dynorphin-A-(1-13) caused an increase in opiate potency in both the guinea pig ileum and rabbit vas deferens assays, a complete loss of potency in the rat vas deferens assay, and no change in the mouse vas deferens assay. In comparison with dynorphin-A-(1-13), the hybrid peptide was less potent in the guinea pig ileum assay as well as in mouse and rabbit vas deferens assay. It is suggested that beta c-EP-(8-31) facilitates the dermorphin moiety to act on opiate mu and delta receptors but not on the epsilon receptor, while beta h-(14-31) reduces the action of dynorphin on mu, delta and kappa receptors.     

beta-Endorphin: radioreceptor binding assay. Relative potency of synthetic analogs with various chain lengths

An assay system is described to measure the specific binding of beta-endorphin to opiate sites (receptors) in rat brain membrane preparations using the tritiated hormone as the primary ligand. By this assay procedure, the radioreceptor activity of beta-endorphin and synthetic analogs with various chain lengths has been determined. The results suggest that both NH2- and COOH-terminal sequences of the molecule are involved in the interaction of beta-endorphin with opiate receptors.     

Biological and physical properties of a beta-endorphin analog containing only D-amino acids in the amphiphilic helical segment 13-31

Our approach to the modeling of beta-endorphin has been based on the proposal that three basic structural units can be distinguished in the natural peptide hormone: a highly specific opiate recognition sequence at the N terminus (residues 1-5) connected via a hydrophilic link (residues 6-12) to a potential amphiphilic helix in the C-terminal residues 13-31. Our previous studies showed the validity of this approach and have demonstrated the importance of the amphiphilic helical structure in the C terminus of beta-endorphin. The present model, peptide 5, has been designed in order to evaluate further the requirements of the amphiphilic secondary structure as well as to determine the importance of this basic structural element as compared to more specific structural features which might occur in the C-terminal segment. For these reasons, peptide 5 retains the three structural units previously postulated for beta-endorphin; the major difference with regard to previous models is that the whole C-terminal segment, residues 13-31, has been built using only D-amino acids. In aqueous buffered solutions as well as in 2,2,2-trifluoroethanol-containing solutions, the CD spectra of peptide 5 show the presence of a considerable amount of left-handed helical structure. Enzymatic degradation studies employing rat brain homogenate indicate that peptide 5 is stable in this milieu. In delta- and mu-opiate receptor-binding assays, peptide 5 shows a slightly higher affinity than beta-endorphin for both receptors while retaining the same delta/mu selectivity. In opiate assays on the guinea pig ileum, the potency of peptide 5 is twice that of beta-endorphin. In the rat vas deferens assay, which is very specific for beta-endorphin, peptide 5 displays mixed agonist-antagonist activity. Most remarkably, peptide 5 displays a potent opiate analgesic effect when injected intracerebroventricularly into mice. At equal doses, the analgesic effect of peptide 5 is less than that of beta-endorphin (10-15%) but longer lasting. In conjunction with our previous model studies, these results clearly demonstrate that the amphiphilic helical structure in the C terminus of beta-endorphin is of predominant importance with regard to activity in rat vas deferens and analgesic assays. The similarity between the in vitro and in vivo opiate activities of beta-endorphin and peptide 5, when compared to the drastic change in chirality in the latter model, demonstrates that even a left-handed amphiphilic helix formed by D-amino acids can function satisfactorily as a structural unit in a beta-endorphin-like peptide.     

Endogenous opioid peptide effects on the guinea-pig biliary tract

The effects of the endogenous opioid peptides, dynorphin (1-13), Met-enkephalin and beta-endorphin, on contraction induced by transmural stimulation of terminal bile duct preparations (terminal cavity and ampulla) and gallbladder were investigated in vitro. These peptides inhibited ampulla contraction, dose dependently. The potency order, indicated by ID50, was the same as in the guinea-pig ileum, but the absolute ID50 values in the ampulla were lower than in the ileum. In the terminal cavity, the dynorphin (1-13) ID50 was still less than in the ampulla, and beta-endorphin and Met-enkephalin did not reduce contraction by as much as 50%. In the gallbladder, the effects of these opioid peptides on contraction induced by transmural stimulation were not significant. The results suggest differences in the receptor populations of the ampulla and terminal cavity, and lack of opiate receptors (at least micro and k receptors) in the gallbladder.     

Hypoinsulinemic and hyperglycemic effects of beta-endorphin in rabbits

The present study was designed to investigate the in vivo effects of beta-endorphin on plasma levels of glucagon, insulin and glucose in rabbits, and to elucidate some of the mechanisms involved. beta-Endorphin (50 micrograms) injected intravenously into fasted rabbits, decreased plasma levels of insulin (-4.5 +/- 1.3 microU/ml, P less than 0.05) and increased plasma levels of glucose (+2.7 +/- 0.4 mmol/l, P less than 0.05). Similar hypoinsulinemic and hyperglycemic effects were observed for 25 and 2.5 micrograms beta-endorphin in fasted and 50 and 0.5 micrograms beta-endorphin in fed rabbits. beta-Endorphin produced slight and transient increases in plasma levels of glucagon at the highest dose in fed rabbits, only (+80 +/- 9 pg/ml, P less than 0.05). The beta-endorphin-induced hypoinsulinemia was not inhibited by phentolamine, yohimbine, propranolol or atropine, which is in consistency with a direct inhibitory effect of beta-endorphin on the beta-cell in rabbits. The beta-endorphin-induced hyperglycemia was reduced by naloxone (+0.8 +/- 0.1 mmol/l) but not by N-methyl-naloxone (ORG 10908) a peripheral opiate receptor blocking drug (+2.2 +/- 0.2 mmol/l), suggesting a central nervous action on opiate receptors. This central action of beta-endorphin was probably not mediated by catecholamine release or other stimulation of adrenergic or muscarinic receptors, since the beta-endorphin-induced hyperglycemia was not inhibited by phentolamine, yohimbine, propranolol or atropine. These results suggest that the beta-endorphin-induced hyperglycemia was caused, at least in part, by a peripheral inhibition of insulin release and a central stimulation on glucoregulation.     

The isolation of multiple forms of beta-endorphin from the intermediate pituitary of the Australian lungfish, Neoceratodus forsteri

The pituitary of the Australian lungfish, Neoceratodus forsteri, was screened immunohistochemically with heterologous antisera specific for either the C-terminal of mammalian beta-endorphin or the acetylated N-terminal of beta-endorphin. Immunopositive cells were only detected with the N-terminal specific antiserum; these cells were restricted to the intermediate pituitary. Acid extracts of the intermediate pituitary were fractionated by Sephadex gel filtration chromatography, CM cation exchange chromatography and reverse phase HPLC. Fractions were analyzed by radioimmunoassay (RIA) with a N-acetyl specific beta-endorphin RIA and by radioreceptor assay for the presence of opiate active forms of beta-endorphin. Both immunoreactive and opiate active forms of beta-endorphin were detected. Of the total beta-endorphin-related material isolated from the intermediate pituitary, approximately 97% was detected with the N-terminal specific RIA and approximately 3% was detected by the radioreceptor assay. The N-acetylated immunoreactive beta-endorphin could be separated into two forms. The major form had an apparent molecular weight of 3.2 Kda. This material had a net charge at pH 2.5 of +5. The minor form of immunoreactive beta-endorphin had an apparent molecular weight of 1.4 Kda and a net charge at pH 2.5 of +1. Neither immunoreactive form exhibited receptor binding activity in the radioreceptor assay. A single peak of opiate active beta-endorphin was detected. This material had an apparent molecular weight of 3.5 Kda and a net charge at pH 2.5 of +7.     

Binding characteristics of dermorphin, and [dermorphin1-7]-beta c-endorphin in rat brain membranes

Dermorphin and a camel beta-endorphin (beta c-EP) analog in which residues 1-7 correspond to the dermorphin sequence ([Dermorphin1-7]-beta c-EP) have been investigated with respect to their receptor binding characteristics using human and camel beta-EP as reference peptides. Tritiated dihydromorphine, [D-Ala2, D-Leu5]-enkephalin, ethylketocyclazocine and human beta-endorphin were used as primary ligands in the rat brain membrane preparation for radioreceptor assay. Camel beta-endorphin was the most potent peptide in all experiments. [Dermorphin1-7]-beta c-EP is significantly less potent towards 3H-ethylketocyclazocine and 3H-[D-Ala2, D-Leu5]-enkephalin but is as potent towards 3H-dihydromorphine and 3H-human beta-endorphin. Dermorphin itself weakly displaces tritiated dihydromorphine, [D-Ala2, D-Leu5]-enkephalin and ethylketocyclazocine (potency relative to camel beta-EP, 1-4%) but it is more potent (9%) in competition with tritiated human beta-endorphin. Dermorphin and the [Dermorphin-1-7]-beta c-EP appear to interact preferentially with mu opiate receptors.     

N-acetyl-beta-endorphin1-31 antagonizes the suppressive effect of beta-endorphin1-31 on murine splenocyte proliferation via a naloxone-resistant receptor.

High affinity binding sites for beta-endorphin1-31 (beta-EP) have been observed on transformed mononuclear cells such as the human U937 monocyte-like cell line and the murine EL4-thymoma line, and on normal murine splenocytes. Binding of beta-EP at these sites is resistant to competition by naloxone and other opiate receptor ligands but sensitive to N-acetyl-beta-endorphin1-31 (N-Ac), cations and GTP-gamma-sulfate. Thus, the following studies were done to determine the functional significance of binding beta-EP and N-Ac. beta-EP suppressed phytohemagglutinin (PHA)-stimulated [3H]thymidine uptake in a dose-dependent, naloxone-insensitive fashion. beta-Endorphin1-27, (des)-tyrosine beta-endorphin2-31, or N-Ac failed to duplicate the suppressive effect of beta-EP. However, N-Ac, which is equipotent to beta-EP at displacing 125I-beta-EP bound to murine splenocytes or U937 cells, antagonized the suppressive effect of beta-EP. Taken together with previous binding studies, the present observations suggest that beta-EP effects receptor-mediated responses on normal immunocytes that do not depend on the activation of neuronal-like opiate receptors which are naloxone-sensitive. N-Ac, which shows minimal binding to such brain opiate receptors, is a potent functional antagonist of the naloxone-insensitive immunocyte receptor for beta-EP.     

Opioid activity of delta O-endorphin in the guinea pig ileum.

The oligopeptides beta- and delta O-endorphin were isolated from porcine and bovine pituitary respectively. Their opiate activity was determined in the guinea pig ileum and compared to that of the pentapeptide methionine-enkephalin and morphine. The rank order of opioid activity was found to be: morphine greater than beta-endorphin = Met-enkephalin greater than delta O-Endorphin which lacks the four C-terminal amino acids of beta-endorphin displayed 60% of the activity of beta-endorphin. These results indicate, that C-terminal amino acids contribute little to the affinity of beta-endorphin for opiate receptors in the guinea pig ileum.     

Opiate tolerance and dependence: recent findings and synthesis.

Recent studies have led to a greater understanding of the behavioral, cellular, and molecular mechanisms underlying opiate tolerance and physical dependence. Behavioral studies have demonstrated that both direct pharmacological effects and the learning of interactions between drug effects and environmental cues are important in these phenomena. Behavioral studies have also revealed that N-methyl-D-aspartate receptors may play a role in their development (or acquisition). Although in early cellular studies no consistent role was found for opioid receptors or endogenous opioid peptides in opiate tolerance and dependence, recent experiments suggest that beta-endorphin, enkephalin, and dynorphin neurons may indeed have a role. Finally, studies at the molecular level suggest that a functional decoupling of opioid receptors from GTP-binding proteins (G proteins) may be important. In this review, we discuss these disparate findings and present a synthesis that shows how they might together contribute to the phenomena of opiate tolerance and physical dependence.     

Endorphinergic and alpha-noradrenergic systems in the paraventricular nucleus: effects on eating behavior

Brain cannulated rats were injected with the opioid peptide beta-endorphin (beta-EP) directly into the hypothalamic paraventricular nucleus (PVN) where norepinephrine (NE) is most effective in stimulating eating behavior. Beta-Endorphin (1.0 nmole) reliably increased food intake in satiated animals, and this response was blocked by local administration of the selective opiate antagonist naloxone. The eating induced by beta-EP was positively correlated in magnitude with the NE response and, like NE, was antagonized by PVN injection of the alpha-noradrenergic blocker phentolamine. Naloxone had no effect on NE-induced eating, and the dopaminergic blocker fluphenazine failed to alter either beta-EP or NE eating. When injected simultaneously, at maximally effective doses, beta-EP and NE produced an eating response which was significantly larger than either of the responses elicited separately by beta-EP or NE and was essentially equal to the sum of these two responses. The evidence obtained in this study suggests that beta-EP and NE stimulate food ingestion through their action on PVN opiate and alpha-noradrenergic receptors, respectively, and that beta-EP's action is closely related to, and in part may be dependent upon, the PVN alpha-noradrenergic system for feeding control.