Improving the Utility of a Dynorphin Peptide Analogue Using Mannosylated Glycoliposomes.

Peptide therapeutics offer numerous advantages in the treatment of diseases and disorders of the central nervous system (CNS). However, they are not without limitations, especially in terms of their pharmacokinetics where their metabolic lability and low blood-brain barrier penetration hinder their application. Targeted nanoparticle delivery systems are being tapped for their ability to improve the delivery of therapeutics into the brain non-invasively. We have developed a family of mannosylated glycoliposome delivery systems for targeted drug delivery applications. Herein, we demonstrate via in vivo distribution studies the potential of these glycoliposomes to improve the utility of CNS active therapeutics using dynantin, a potent and selective dynorphin peptide analogue antagonist of the kappa opioid receptor (KOR). Glycoliposomal entrapment protected dynantin against known rapid metabolic degradation and ultimately improved brain levels of the peptide by approximately 3-3.5-fold. Moreover, we linked this improved brain delivery with improved KOR antagonist activity by way of an approximately 30-40% positive modulation of striatal dopamine levels 20 min after intranasal administration. Overall, the results clearly highlight the potential of our glycoliposomes as a targeted delivery system for therapeutic agents of the CNS.

Dynorphins in Development and Disease: Implications for Cardiovascular Disease.

It is well-established that cardiovascular disease continues to represent a growing health problem and significant effort has been made to elucidate the underlying mechanisms. In this review, we report on past and recent high impact publications in the field of intracrine network signaling, focusing specifically on opioids and their interrelation with key modulators of the cardiovascular system and the onset of related disease. We present an overview of studies outlining the scope of cardiovascular and cerebrovascular processes that are affected by opioids, including heart function, ischemia, reperfusion, and blood flow. Specific emphasis is placed on the importance of dynorphin molecules in cerebrovascular and cardiovascular regulation. Evidence suggests that excessive or insufficient dynorphin could make an important contribution to cardiovascular physiology, yet numerous paradoxical observations frequently impede a clear understanding of the role of dynorphin. Thus, we argue that dynorphin-mediated signaling events for which an immediate regulatory effect is disputed should not be dismissed as unimportant, as they may play a role in cross-talk with other signaling networks. Finally, we consider the most recent evidence on the role of dynorphin during cardiovascular-related inflammation and on the potential value of endogenous and exogenous inhibitors of kappa-opioid receptor, a major dynorphin A receptor, to limit or prevent cardiovascular disease and its related sequelae.

Strengthening peptide-based drug activity with novel glyconanoparticle.

The therapeutic application of peptide-based drugs is significantly limited by the rapid proteolytic degradation that occurs when in blood. Encapsulation of these peptide structures within a delivery system, such as liposomes, can greatly improve both stability and target delivery. As part of our work focused on novel ambiphilic mannosylated neoglycolipids as targeted drug delivery systems, we have developed a C14-alkyl-mannopyranoside that forms self-assembled monodisperse liposomes. Herein, these glycoliposomes are investigated as a potential method to improve the plasma stability of peptide-based drugs. Reversed phase high-performance liquid chromatography (RP-HPLC) and mass spectrometry (MS) methods were developed to assess the in vitro plasma stability of two structurally diverse peptides, including the kappa opioid receptor selective antagonist dynantin, and the NOD2 innate immune receptor ligand muramyl dipeptide (MDP). The RP-HPLC methods developed were able to resolve the peptides from background plasma contaminants and provided suitable response levels and linearity over an appropriate concentration range. Both compounds were found to be significantly degraded in rat plasma. Increasing degrees of both entrapment and stabilization were noted when dynantin was combined with the C14-alkyl-mannopyranoside in increasing peptide:glycoside ratios. The combination of MDP with the glycolipid also led to peptide entrapment, which greatly improved the plasma stability of the peptide. Overall, the results clearly indicate that the stability of peptide-based structures, which are subject to degradation in plasma, can be greatly improved via entrapment within C14-alkyl-mannopyranoside-bearing glycoliposomes.

Development and characterization of functionalized niosomes for brain targeting of dynorphin-B.

A niosomal formulation, functionalized with N-palmitoylglucosamine, was developed as potential brain targeted delivery system of dynorphin-B. In fact, this endogenous neuropeptide, selective agonist of k opioid receptors, is endowed with relevant pharmacological activities on the central nervous system, including a marked antinociceptive effect, but is unable to cross the blood brain barrier (BBB), thus requiring intracerebroventricular administration. Statistical design of experiments was utilized for a systematic evaluation of the influence of variations of the relative amounts of the components of the vesicle membrane (Span 60, cholesterol and SolulanC24) on vesicle mean diameter, polydispersity index and drug entrapment efficiency, chosen as the responses to optimize. A Scheffé simplex-centroid design was used to obtain the coefficients of the postulated mathematical model. The study of the response surface plots revealed that variations of the considered factors had different effects on the selected responses. The desirability function enabled for finding the optimal mixture composition, which represented the best compromise to simultaneously optimize all the three responses. The experimental values obtained with the optimized formulation were very similar to the predicted ones, proving the validity of the proposed regression model. The optimized niosomal formulation of dynorphin-B administered intravenously to mice (100mg/kg) showed a pronounced antinociceptive effect, significantly higher (P<0.05) than that given by i.v. administration of the simple solution of the peptide at the same concentration, proving its effectiveness in enabling the peptide brain delivery. These positive results suggest that the proposed approach could be successfully extended to other neuro-active peptides exerting a strong central action, even at low doses, but unable to cross the BBB.

A Phase II, multicenter, randomized, double-blind, placebo-controlled crossover study of CJC-1008--a long-acting, parenteral opioid analgesic--in the treatment of postherpetic neuralgia.

INTRODUCTION: CJC-1008 is a chemical modification of the opioid peptide dynorphin A (1-13) (Dyn A) that promotes dynorphin's covalent attachment to human serum albumin in vivo after administration, thus prolonging its duration of action. The primary objective of this study was to evaluate the preliminary efficacy and safety of CJC-1008 as compared with placebo in patients with postherpetic neuralgia (PHN). METHODS: Patients with PHN were assigned 1:1 to receive active study medication or placebo. After dosing, measurements were made every 15 minutes for the first hour; at two, three, four, six, and eight hours postdose; and during return visits to the study site after two, seven, and 28 days (as necessary), as well as during precrossover and exit visits. These measurements examined: 1) overall pain intensity, 2) pain intensity for each individual PHN type, 3) categorical overall pain intensity, 4) categorical pain relief and 5) adverse events (AEs). When PHN pain intensity returned to baseline and/or at patients' first request for rescue analgesia other than acetaminophen (typically around 28 days after dosing but sometimes as soon as two days postdose), patients were to cross over to the alternative treatment and be monitored on the same schedule. RESULTS: A substantial placebo response was observed, but the analgesic effect observed in the active group was greater than that in the placebo group for the first eight hours. By 24 hours, the difference was not significant. A total of 29 out of 30 patients (96 percent) experienced at least one treatment-emergent AE during active drug treatment, while 14 of 27 patients (52 percent) reported such AEs during placebo treatment. Of the AEs occurring within the first eight hours after dosing, 97 percent were reported during treatment with active drug and 3 percent were reported during treatment with placebo. The majority of these AEs were mild in intensity. DISCUSSION: This study provides evidence of a greater analgesic effect when using CJC-1008 compared to placebo in patients with PHN. However, the effect only lasted through eight hours postdose and diminished by 24 hours. This study provides evidence of a peripheral action of dynorphin, since CJC-1008 does not cross the blood-brain barrier.

Altered extracellular striatal in vivo biotransformation of the opioid neuropeptide dynorphin A(1-17) in the unilateral 6-OHDA rat model of Parkinson's disease.

The in vivo biotransformation of dynorphin A(1-17) (Dyn A) was studied in the striatum of hemiparkinsonian rats by using microdialysis in combination with nanoflow reversed-phase liquid chromatography/electrospray time-of-flight mass spectrometry. The microdialysis probes were implanted into both hemispheres of unilaterally 6-hydroxydopamine (6-OHDA) lesioned rats. Dyn A (10 pmol microl(-1)) was infused through the probes at 0.4 microl min(-1) for 2 h. Samples were collected every 30 min and analyzed by mass spectrometry. The results showed for the first time that there was a difference in the Dyn A biotransformation when comparing the two corresponding sides of the brain. Dyn A metabolites 1-8, 1-16, 5-17, 10-17, 7-10 and 8-10 were detected in the dopamine-depleted striatum but not in the untreated striatum. Dyn A biotransformed fragments found in both hemispheres were N-terminal fragments 1-4, 1-5, 1-6, 1-11, 1-12 and 1-13, C-terminal fragments 2-17, 3-17, 4-17, 7-17 and 8-17 and internal fragments 2-5, 2-10, 2-11, 2-12, and 8-15. The relative levels of these fragments were lower in the dopamine-depleted striatum. The results imply that the extracellular in vivo processing of the dynorphin system is being disturbed in the 6-OHDA-lesion animal model of Parkinson's disease.

Dynorphin A(1-17) biotransformation in striatum of freely moving rats using microdialysis and matrix-assisted laser desorption/ionization mass spectrometry.

The biotransformation of the opioid peptide dynorphin A(1-17) was investigated in striatum of freely moving Fischer rats, by direct infusion of this peptide, followed by recovery of the resulting biotransformation products via microdialysis and identification using matrix-assisted laser desorption/ionization mass spectrometry. The observed peptides are consistent with enzymatic cleavage at the Arg7-Ile8 position of dynorphin A(1-17), followed by terminal degradation of the resulting dynorphin A(1-7) and dynorphin A(8-17) peptides. Unexpectedly, novel post-translational modifications were found on C-terminal fragments of dynorphin A(1-17). Using tandem mass spectrometry, a covalent modification of mass 172 Da, the nature of which is not understood, was found on the tryptophan residue of C-terminal fragments (Trp14). Additional modifications, of mass 42 and 113 Da, were also found on the N-terminus (Ile8 or Pro10) of these same C-terminal fragments. The role of these modifications of C-terminal fragments has not yet been characterized.

Dynorphin A (2-17) attenuates the unconditioned but not the conditioned effects of opiate withdrawal in the rat.

OBJECTIVES: An unbiased place preference conditioning procedure was used to examine the influence of the non-opioid peptide, dynorphin A 2-17 (DYN 2-17), upon the conditioned and unconditioned effects of opiate withdrawal in the rat. METHODS: Rats were implanted SC with two pellets containing 75 mg morphine or placebo. Single-trial place conditioning sessions with saline and the opioid receptor antagonist naloxone (0.1-1.0 mg/kg; SC) commenced 4 days later. Ten minutes before SC injections, animals received an IV infusion of saline or DYN 2-17 (0.1-5.0 mg/kg). Additional groups of placebo- and morphine-pelleted animals were conditioned with saline and DYN 2-17. During each 30-min conditioning session, somatic signs of withdrawal were quantified. Tests of place conditioning were conducted in pelleted animals 24 h later. RESULTS: Naloxone produced wet-dog shakes, body weight loss, ptosis and diarrhea in morphine-pelleted animals. Morphine-pelleted animals also exhibited significant aversions for an environment previously associated with the administration of naloxone. These effects were not observed in placebo-pelleted animals. DYN 2-17 pretreatment resulted in a dose-related attenuation of somatic withdrawal signs. However, conditioned place aversions were still observed in morphine-pelleted animals that had received DYN 2-17 in combination with naloxone. Furthermore, the magnitude of this effect did not differ from control animals. CONCLUSIONS: These data demonstrate that the administration of DYN 2-17 attenuates the somatic, but not the conditioned aversive effects of antagonist-precipitated withdrawal from morphine in the rat. Differential effects of this peptide in modulating the conditioned and unconditioned effects of opiate withdrawal are suggested.

Assessment of complex peptide degradation pathways via structured multicompartmental modeling approaches: the metabolism of dynorphin A1-13 and related fragments in human plasma.

Peptide metabolic pathways in blood or other tissues are often complex because multiple enzyme systems are involved in the degradation of parent drug and its metabolites. Michaelis-Menten-type studies with isolated enzymes have been frequently employed for evaluating the metabolism of peptides. Alternatively, studies with selective enzyme inhibitors or the evaluation of the area under the drug- or metabolite-time profiles have been employed. We tested in this study the usefulness of a multicompartmental pharmacokinetic approach for the assessment of the apparent first-order metabolism of dynorphin A1-13 up to the fourth metabolite generation in human plasma. This multicompartmental kinetic analysis proved instrumental in clarifying ambiguous degradation pathways not easily detectable by the other methods of assessment (enzyme inhibition studies and noncompartmental analysis) because of the lack of specific enzyme inhibitors or specificity problems of the analytical technique employed. The proposed multicompartmental fitting approach was also highly suitable to verify the overall metabolic pathways suggested by the other methods up to the fourth metabolite by testing whether the rate constants obtained by these methods are suitable to describe the overall degradation profile after Dyn A1-13 degradation. Local sensitivity analysis for the degradation of DYNA 1-13 revealed that the model was, however, not able to adequately identify on its own all of the parameters involved in the degradation of dynorphin A1-13. Thus, the method proved beneficial in evaluating and testing the correctness of the overall degradation pathways suggested by other methods.

Pharmacokinetics of intravenous dynorphin A(1-13) in opioid-naive and opioid-treated human volunteers.

BACKGROUND: Dynorphin A(1-13) is a fragment of the endogenous opioid neuropeptide dynorphin A. Previous research suggested that intravenously administered dynorphin A(1-13) has the ability to modulate morphine-induced analgesia. We designed this study to characterize the disposition of intravenous dynorphin immunoreactivity in humans and to determine whether concomitant long-term opioid therapy influenced the pharmacokinetics or side-effects profile of dynorphin A(1-13). METHODS: The study subjects comprised 20 volunteers divided into two groups of 10 each, stratified by dose (low dose, 250 micrograms/kg; high dose, 1000 micrograms/kg). There were four volunteers receiving long-term opioid therapy and six opioid-naive volunteers (nonopioid group) within each dosing group. Dynorphin A(1-13) was infused over 10 minutes, and arterial blood samples were drawn and assayed for dynorphin immunoreactivity. A population modeling approach was used to characterize the pharmacokinetics. Dynorphin effects on heart rate and arterial blood pressure were also studied. RESULTS: The pharmacokinetics of dynorphin immunoreactivity were linear over the dose range studied and were best described by a three-compartment mammillary model whose parameters were volume 1, 5.0 L; volume 2, 0.80 L; volume 3, 12 L; clearance 1, 6.0 L/min; clearance 2, 0.054 L/min; and clearance 3, 0.044 L/min. Concomitant opioid medication did not affect the disposition of dynorphin immunoreactivity. Tachycardia and flushing were commonly observed side effects. The incidence of side effects was dose dependent and was not influenced by long-term opioid use. CONCLUSIONS: Intravenously administered dynorphin A(1-13) is very rapidly metabolized, on the basis of the time course of immunoreactivity in the blood. Long-term opioid therapy did not influence either the pharmacokinetics or incidence of side effects.

Penetration of dynorphin 1-13 across the blood-brain barrier.

Previous studies have demonstrated neuroprotective effects of the opioid peptide dynorphin (dyn) 1-13 in focal cerebral ischemia. The passage of dyn 1-13 across the blood-brain barrier (BBB) was studied by a modification of the Oldendorf technique in the normal rat and cat, as well as in a feline model of experimentally induced focal cerebral ischemia. In the rat, dyn 1-13 penetration of the BBB could not be detected by this technique, even in the presence of peptidase inhibitors. In contrast, dyn 1-13 did cross the BBB into the normal cat hippocampus, cortex and cerebellum. The passage of dyn 1-13 across the BBB was greater in cats with experimentally induced focal cerebral ischemia. Some of the tritium-labeled material which crossed the BBB was confirmed by high performance liquid chromatography to be dyn 1-13. These studies support the hypothesis that the therapeutic effects observed after the peripheral administration of dyn 1-13 to cats with focal cerebral ischemia can be produced by a central mechanism of action.

Dynorphin A (1-8) analog, E-2078, crosses the blood-brain barrier in rhesus monkeys.

E-2078 is a dynorphin A (1-8) analog, [N-methyl-Tyr1, N-methyl-Arg7-D-Leu8] dynorphin A (1-8) ethylamide. Its ability to cross the blood-brain barrier was examined in rhesus monkeys using matrix-assisted laser desorption/ionization mass spectrometry. In vivo studies were carried out by i.v. injecting E-2078, 10 mg/kg, a dose that had been found to be antinociceptive, to rhesus monkeys. Blood and cerebrospinal fluid samples were collected at various time points after the injection. It was found that E-2078 was stable in vivo in rhesus monkey blood. No biotransformation products were detected in the blood. Mass spectrometric analysis of the cerebrospinal fluid samples collected after E-2078 injection detected the presence of E-2078, indicating that E-2078 had crossed the blood-brain barrier. These findings are consistent with the possibility that systemically administered E-2078 could produce centrally mediated behavioral and physiological effects.

Dynorphin A (1-8) analog, E-2078, is stable in human and rhesus monkey blood.

E-2078 is a dynorphin A (1-8) analog, [N-methyl-Tyr1, N-methyl-Arg7-D-Leu8] Dyn A (1-8) ethylamide. Its biochemical stability against enzymatic degradation in vitro in human and rhesus monkey blood, and in vivo in rhesus monkey blood was studied using matrix-assisted laser desorption/ionization mass spectrometry. In vitro studies were carried out in freshly drawn human and rhesus monkey blood, incubated at 37 degrees C for various time periods. In vivo studies were conducted by E-2078 i.v. injection to rhesus monkeys, and blood samples were collected at various time points after the injection. It was found that E-2078 was stable against enzymatic degradation in vitro in freshly drawn human and rhesus monkey blood. Minor biotransformation products from E-2078, such as E (1-4), E (1-5) and E (3-6), were detected in vitro in some human and rhesus monkey blood, but they made up less than 5% of the total starting E-2078 peptide. No biotransformation products were detected in the blood samples from in vivo studies. The apparent half-life of elimination of E-2078 in vivo from the rhesus monkey blood was determined to be 44.0 min.

An HPLC/RIA method for dynorphin A1-13 and its main metabolites in human blood.

A selective HPLC/RIA procedure for the determination of dynorphin A1-13 (Dyn A1-13) and its major metabolites in human blood was developed. In order to block peptidase activity, blood samples were transferred into an aliquot of a blocking solution (5% aqueous ZnSO4 solution-acetonitrile-methanol; 5:3:2, v/v/v). After solid phase extraction, reconstituted aliquots were injected into an isocratic reversed phase HPLC system to separate Dyn A1-13 from its main metabolites (Dyn A2-13, Dyn A1-12 and Dyn A2-12). The isolated and concentrated HPLC-fractions were assayed by RIA using a commercially available antiserum. Intra-day variabilities for quality controls (0.07, 0.25, and 1 ng ml-1) of Dyn A1-13, A2-13, A1-12, A2-12 were between 9 and 41%. Accuracy was between 86 and 132%. Inter-day variability for single quality controls analyzed on five days for Dyn A1-13, A2-13, A1-12, A2-12 was between 4 and 49% for 0.07, 0.25 and 1 ng ml-1 samples, respectively. Accuracy was between 72 and 129%. Five different batches of control blood showed blood levels no different from zero. Considering the complexity of the assay, the method is selective, accurate and reproducible with a limit of detection of 0.07 ng ml-1 for Dyn A1-13, Dyn A2-13, Dyn A1-12 and 0.21 ng ml-1 for Dyn A2-12. The assay was applied to the determination of Dyn A1-13 and its metabolites in blood samples of 2 subjects receiving i.v. infusions of 250 micrograms or 1000 micrograms kg-1 Dyn A1-13 over 10 min.

In vitro biotransformation of dynorphin A (1-17) is similar in human and rhesus monkey blood as studied by matrix-assisted laser desorption/ionization mass spectrometry.

Dynorphin A (1-17) [Dyn A (1-17)] is an endogenous opioid peptide. In vitro biotransformation of Dyn A (1-17) in human and rhesus monkey blood was studied by matrix-assisted laser desorption/ionization mass spectrometry. Biotransformation was observed to produce various opioid and nonopioid dynorphin A peptides. In this study, in vitro Dyn A (1-17) biotransformation at physiological temperature (37 degrees C) was found to be very similar in human and rhesus monkey blood, although Dyn A (1-17) processing occurred at a faster rate in vitro in monkey blood than in human blood. One dominant pathway in this biotransformation was the slow removal of tyrosine at position one from Dyn A (1-17) to yield the dominant product, Dyn A (2-17). Further slow biotransformation of Dyn A (2-17) also occurred. Another major pathway of Dyn A (1-17) biotransformation is cleavage of the peptide linkage between Arg(6) and Arg(7) to produce the opioid peptide, Dyn A (1-6), and the nonopioid peptide, Dyn A (7-17). These two peptides had a short lifetime in blood, undergoing rapid biotransformation. Our results indicate that the rhesus monkey may be a good model for further in vivo pharmacological and neurobiological studies.

Interspecies comparison of in vitro plasma degradation of dynorphin A 1-13.

Enzymatic cleavage of peptides might release metabolites with distinct pharmacological profile. Interspecies differences in the metabolism of peptides might represent a potential source of error when animal data are intended to predict the human situation. Therefore, the metabolism of dynorphin (Dyn) A1-13 was investigated in the plasma of various species used in experimental practice (monkey, rabbit, rat, guinea pig) and compared to previously reported human data. The metabolic pathways were evaluated by enzyme inhibition and kinetic analysis, both yielding almost identical results. Rapid metabolism was observed with all dynorphin fragments across all species (half-lives from 0.3 min for Dyn A1-12 in guinea pig plasma to 2.6 min for Dyn A2-12 in monkey plasma). The metabolism of Dyn A1-13 differed mainly with respect to the half-life (from 0.5 min in guinea pig plasma) to 1.1 min in monkey plasma), while the metabolic routes were similar across the species (Dyn A1-12 major metabolite of Dyn A1-13: from 88% in guinea pig plasma to 71% in rabbit plasma). The metabolic fate of Dyn A1-12, the most important metabolite of Dyn A1-13 is much more heterogeneous across the species then the one observed for Dyn A1-13. For a first assessment, the metabolic routes and rates of Dyn A1-13 in plasma of all investigated species, except from guinea pigs, resemble those in human plasma sufficiently.

Metabolism of dynorphin A 1-13 in human blood and plasma.

PURPOSE: A detailed investigation of the metabolic routes and rates of Dyn A1-13 in human blood and plasma was performed. METHODS: Human plasma was incubated at 37 degrees C with dynorphin A 1-13 (Dyn A1-13, 15-20 microM). The generated dynorphin fragments were separated by a new ion-pair chromatographic method and identified by matrix assisted laser desorption mass spectroscopy. The kinetic behavior of parent compound and metabolites was evaluated in the absence and presence of enzyme inhibitors. RESULTS: The major plasma metabolites of Dyn A1-13 were Dyn A1-12, A2-12, A4-12 and A4-8. Further metabolites were Dyn A2-13, A3-13, A3-12, A5-12, A6-12, A7-12, A1-10, A2-10, A2-8 and A3-8. At 37 degrees C, Dyn A1-13 had a half-life of less than one minute in plasma and blood. Plasma half-lives of major metabolites ranged between 0.5 and 4 min. Inter- and intra-individual differences in healthy volunteers were 30% (c.v.). Dyn A1-13 is mainly metabolized by carboxypeptidases to Dyn A1-12 (80%) and by aminopeptidases to Dyn A2-13 (15%). Dyn A1-12 and Dyn A2-13 are predominantly converted into Dyn A2-12 (67% of Dyn A1-13). Subsequent metabolic steps yield Dyn A3-12 (16%), Dyn A4-12 (37%) and Dyn A4-8 (33%). Aminopeptidases generate Dyn A2-12, A3-12, A4-12, A5-12. ACE metabolizes Dyn A1-12 (19%), A2-12 (33%), A3-12 (34%) and A4-12 (46%). Bestatin-sensitive endopeptidases (possibly endopeptidase 24.11) metabolize 30% of Dyn A2-12. Dyn A4-8 is formed via Dyn A4-12 (23% of Dyn A4-12) and Dyn A2-10 (37% of Dyn A2-10). CONCLUSIONS: The combination of enzyme inhibition experiments and noncompartmental kinetic analysis proved to be a powerful tool for the detailed evaluation of the metabolic fate of Dyn A1-13 in human blood and plasma.

Effects of high intravenous doses of dynorphin A(1-13) on tail flick latency and central nervous system histology in rats.

Dynorphin A(1-13) blocks opiate withdrawal in rats without producing dependence, and enhances analgesia in morphine-tolerant animals. Its potential use in humans is therefore of interest. Dynorphin A(1-13) has little toxicity when administered at modest doses IV but has been reported to cause hindlimb paralysis and necrosis of the spinal cord in rats, at the catheter tip, when administered intrathecally. To further evaluate its potential neurotoxicity, we administered dynorphin A(1-13) to rats at very high doses IV. Rats (n = 6-10 per group) received dynorphin A(1-13) as bolus IV doses of 5 mg/kg, or as continuous IV infusions of 40 mg/kg/day for 1 day, with saline controls. The appearance and behavior of all animals was normal. Tail flick latencies remained unchanged (p > 0.5). There were no histologic abnormalities of the spinal cord or brain when examined by light microscopy. Two additional groups received bolus injections of dynorphin A(1-13) 50 or 100 mg/kg IV. Animals receiving 50 mg/kg showed cutaneous flushing, labored respirations, and decreased spontaneous movement, which resolved within 10 min. Histology at 1 week was normal. All six animals receiving 100 mg/kg convulsed and died within minutes. Three animals that received dynorphin A(1-13) 40 mg/kg/day for 7 days had normal behavior and histology. We conclude that the previously observed neurotoxicity of intrathecally administered dynorphin A(1-13) is a local effect that does not occur when dynorphin A(1-13) is administered IV, even at very high doses.

In vitro stability of some reduced peptide bond pseudopeptide analogues of dynorphin A.

Eight analogues of DYN A(1-11)-NH2 incorporating the nonhydrolyzable psi [CH2-NH] peptide bond surrogate were tested for their in vitro enzymatic stability in mouse brain homogenates. Results show that the Leu(5)-Arg6 and to a lesser extent the Arg(7)-Ile8 and Ile(8)-Arg9 peptide bonds are the more susceptible to enzymatic cleavage in the native peptide. (Leu5 psi[CH(2)-NH]Arg6)DYN A(1-11)-NH2 exhibits an almost complete resistance to enzymatic cleavage with a half-life greater than 500 min in brain, compared to 42 min for the standard peptide, DYN A(1-11)-NH2.

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.