Differentiating the effects of microwave and heat on tissue proteins and their crosslinking by formaldehyde

Summary Alkaline phosphatase activity in mouse liver blocks, cooled by an ice-bath, decreased by 50% in 5 min of microwave irradiation (280 W). This loss of protein tertiary structure has been mirrored by ultrastructural changes in the same tissue. Microwave irradiation did not produce clevage or polymerization of lysozyme or haemoglobin. Protein formaldehyde reaction mixtures produced protein polymers between 0° and 40°C which could be separated by SDS-polyacrylamide gel electrophoresis. Microwave irradiation of lysozyme or haemoglobin plus formaldehyde on icebath up to 30 min produced a similar electrophoretic pattern. When lysozyme or haemoglobin plus formaldehyde was heated to 60°C for 30 min, the protein polymers migrated faster on electrophoresis, suggesting a smaller hydrodynamic volume than expected due to intramolecular crosslink formation, not opened up under the conditions of electrophoresis.     

The pupillary effects of oploids

Morphine's miotic action on the pupil is an easily recognizable and quantifiable effect in man. The neural pathways responsible for regulating pupil size are reasonably well defined. Yet, the mechanisms behind this and related effects of opioids on the eye in humans and laboratory animals have just begun to be explored. In this review, we have attempted to organize the available information on pupillary actions of opioids, emphasizing the dynamic nature of the responses, their species specificity, possible mechanisms of action, and the recently discovered development of tolerance to these actions. Our current knowledge regarding differences among the opioids, the effects of endogenous opioid peptides and the role of the various opiate receptor subtypes in pupillary effects is also summarized.     

Body temperature effects of opioids administered into the periaqueductal grey area of rat brain

The ability of opioids to influence rectal temperature after injection into the periaqueductal grey region (PAG) of rat brain was investigated. Both morphine and beta-endorphin caused a dose-dependent increase in rectal temperature of up to 2 degrees C. By using selective ligands of the subclasses of opiate receptor such as [D-Ala2,D-Leu5]enkephalin for delta-receptors and ethylketocyclazocine, dynorphin(1-17) and dynorphin(1-8) for kappa-receptors, it was possible to show that neither the delta- nor the kappa-opiate receptor was involved in the hyperthermic response. However, [D-Ala2,MePhe4,Gly-ol5]enkephalin (DAGO), a mu-receptor ligand, did produce a dose-dependent hyperthermia. The ability of naltrexone, an opiate receptor antagonist, to reverse the hyperthermia induced by beta-endorphin and DAGO suggests that the opioid-stimulated increase in body temperature via the PAG is mediated through the mu-opiate receptor. Since the application of opioids to the PAG produces a hyperthermic response, it is possible that this brain site may have a role in the peptidergic control of body temperature.     

Vascular remnants of pupillary membrane in the albino rat eye.

As remnants of pupillary membrane, some albino rat eyes revealed vascular loops starting from arteriovenous bridges near the pupillary margin and crossing the pupil. These vascular loops bend in miosis and straighten in mydriasis, which prevents them from being broken during pupillary movement. The vessel wall reveals endothelial cells and pericytes. The lumen contains red blood cells, which means that they are functional vessels. They may function as vascular shunts between opposite sides of the albino rat iris.     

Inhibitory effects of opioids on compound action potentials in frog sciatic nerves and their chemical structures

An opioid tramadol more effectively inhibits compound action potentials (CAPs) than its metabolite mono-O-demethyl-tramadol (M1). To address further this issue, we examined the effects of opioids (morphine, codeine, ethylmorphine and dihydrocodeine) and cocaine on CAPs by applying the air-gap method to the frog sciatic nerve. All of the opioids at concentrations less than 10 mM reduced the peak amplitude of the CAP in a reversible and dose-dependent manner. The sequence of the CAP peak amplitude reductions was ethylmorphine>codeine>dihydrocodeine> or = morphine; the effective concentration for half-maximal inhibition (IC(50)) of ethylmorphine was 4.6 mM. All of the CAP inhibitions by opioids were resistant to a non-specific opioid-receptor antagonist naloxone. The CAP peak amplitude reductions produced by morphine, codeine and ethylmorphine were related to their chemical structures in such that this extent enhanced with an increase in the number of -CH(2) in a benzene ring, as seen in the inhibitory actions of tramadol and M1. Cocaine reduced CAP peak amplitudes with an IC(50) value of 0.80 mM. It is concluded that opioids reduce CAP peak amplitudes in a manner being independent of opioid-receptor activation and with an efficacy being much less than that of cocaine. It is suggested that the substituted groups of -OH bound to the benzene ring of morphine, codeine and ethylmorphine as well as of tramadol and M1, the structures of which are quite different from those of the opioids, may play an important role in producing nerve conduction block.     

The effects of endogenous opioids on tension development of isolated, electrically stimulated rat atria

The possible inotropic effects of all three classes of endogenous opioids were tested alone or in combination with noradrenaline, adrenaline, or carbachol on electrically stimulated atria isolated from male Sprague-Dawley rats. Noradrenaline (6.0 and 12 microM) and adrenaline (4.0 and 8.0 microM) injections caused marked but transient (5 min) dose-related increases in atrial tension compared with preinjection control values, whereas carbachol (0.14 and 1.4 microM) caused a more potent and prolonged (over 15 min) dose-related decrease in atrial tension development. Adrenal enkephalins (0.3-4.0 microM) of methionine enkephalin, leucine enkephalin, Met-enkephalin-Arg6-Phe7, and Met-enkephalin-Arg6-Gly7-Leu8, beta-endorphin (0.2-2.0 microM), or dynorphin A(1-13) (0.2-2.0 microM) did not change atrial tension for a 15-min postadministration test period. In addition, these opioids did not affect the positive inotropic effects of noradrenaline (12 microM) or adrenaline (8.0 microM) or the negative inotropic actions of carbachol (1.4 microM) when the same doses of noradrenaline, adrenaline, or carbachol were given alone. These data indicate that endogenous opioids given in micromolar concentrations tested did not affect atrial tension development of electrically stimulated rat atria. Comparing these data with those of past literature, it is suggested that circulating endogenous opioids probably do not have any direct effects on the rat myocardium to affect myocardial contractility.     

Differential regulation of preovulatory luteinizing hormone and follicle-stimulating hormone release by opioids in the proestrous rat

We have investigated the role of mu- and kappa-opioid receptors in the central control of preovulatory LH and FSH release in the proestrous rat. Animals were anesthetized with chloral hydrate at 14:00 h on proestrus day. Following femoral artery cannulation, they were mounted in a stereotaxic apparatus. Morphine and U-50488H (benzene-acetamide methane sulphonate) were infused intracerebroventricularly either alone or in combination with naloxone and MR1452, respectively. Controls received sterile saline alone. Blood samples were obtained at hourly intervals between 15:00 h and 17:00 h. Plasma LH and FSH levels were measured by radioimmunoassay. Morphine did not significantly change plasma LH levels at 15:00 h and 16:00 h sampling intervals. A significant increase was observed at 17:00 h compared to the controls (p<0.05). U-50488H significantly increased LH levels at 16:00 h and 17:00 h (p<0.05). The co-administration of naloxone and MR1452 with mu- and kappa-agonist had no significant effect on LH levels at any sampling interval. In all groups, LH levels showed a linear rise over the sampling period between 15:00 h and 17:00 h. None of the treatments significantly altered plasma FSH levels which however, declined towards the end of the afternoon surge. In conclusion, we suggest that the secretion of LH and FSH is differentially regulated by mu- and kappa-opioid receptors. It is thought that in all groups chloral hydrate interfered with the LH surge secretory systems.     

Prejunctional effects of opioids in the perfused mesentery of the rat and rabbit: interactions with alpha 2-adrenoceptors.

Prejunctional effects of opioids were examined in the perfused mesentery of two species: the rat and rabbit. Use of agonists selective for subtypes of mu, delta, and kappa opioid receptors produced no effect on contractile responses to adrenergic nerve stimulation in the rat perfused mesentery, except for small effects of the kappa agonist EKC, which may be non specific. In contrast, mu, delta and kappa receptors appear to be present in the rabbit. The mu selective agonist, DAMGO, kappa agonist, ethylketocyclazocine, and delta agonists, DPDPE and [Leu5]-enkephalin, all produced significant inhibition of contractile responses to transmural nerve stimulation. The inhibitory effect was greatest for ethylketocyclazocine. To test the possibility that prejunctional activation of alpha 2 adrenoceptors with endogenous norepinephrine might decrease the activity of prejunctional opioid receptors in the rabbit, inhibitory effects of delta and kappa selective agonists were tested in the presence of 10(-7) M yohimbine. Inhibitory responses of the kappa selective agonist ethylketocyclazocine were enhanced, while that of delta selective agonists [Leu5]-enkephalin and DPDPE remained unchanged when yohimbine was present. Thus, the effects of opioids vary and depend on the tissue and receptor subtypes they act upon. Furthermore, the enhanced inhibitory effect of opioid receptor activation in the presence of yohimbine is not found for all opioid receptors.     

Naloxone-resistant effects of opioids on the twitch in frog skeletal muscle

Morphine and several other opioid agonists including the enkephalins caused a dual action on the twitch in the isolated, curarized, and electrically stimulated frog toe muscle; a potentiating action at low drug concentrations and a potentiation followed by an inhibitory action at higher concentrations. The twitch potentiation was found to be nonstereospecific and resistant to antagonism by naloxone. The inhibitory action too was naloxone-resistant and is probably due to a nonspecific local anesthetic effect of the opioids on the electric properties of the frog skeletal muscle fibre membrane.     

Peripheral effects of opioids and nociceptin in neuropathic pain

Melanocortin peptides have been reported to influence opiate tolerance, but the neuronal basis underlying these actions is unknown. We studied the contribution of melanocortin (MC4R) receptors to morphine effects. The MC4R mRNA level in the amygdala was decreased after acute morphine treatment and increased in rats tolerant to morphine as evidenced by quantitative real-time PCR method. Moreover, the intra-amygdalar microinjection of antagonist of MC4R attenuated morphine tolerance. Expression of the spinal MC4R after sciatic nerve injury was decreased in the early phase of neuropathy and slightly decreased 2–3 weeks after injury. These findings suggest that the altered melanocortin receptor function may contribute to the development of morphine-induced effects. Thus, the melanocortin receptors may be a target for development of better and more effective drugs for the therapy of chronic pain.
Acknowledgement:  Supported by KBN grant for the statutory activity.     

Modulation of GABA-augmented norepinephrine release in female rat brain slices by opioids and adenosine

GABA_A receptor activation augments electrically-stimulated release of norepinephrine (NE) from rat brain slices. Because this effect is not observed in synaptoneurosomes, GABA probably acts on inhibitory interneurons to disinhibit NE release. To determine whether opioids or adenosine influence GABA-augmented NE release, hypothalamic and cortical slices from female rats were superfused with GABA or vehicle in the presence and absence of 10 M morphine or 100 M adenosine. GABA augments [³H]NE release in the cortex and hypothalamus. Morphine alone has no effect on [³H]NE release, but attenuates GABA augmentation of [³H]NE release in both brain regions. Adenosine alone modestly inhibits [³H]NE release in the cortex, but not in the hypothalamus. Adenosine inhibits GABA-augmented [³H]NE release in both brain regions. The general protein kinase inhibitor H-7, augments [³H]NE release in both brain regions and may have additive effects with GABA in cortical slices. These results implicate opioid and adenosine interneurons and possibly protein kinases in regulating GABAergic influences on NE transmission.     

The role of endogenous opioids and their receptors in the immune system.

Opioid peptides appear to be dynamic signaling molecules that are produced within the immune system and are active regulators of an immune response. Furthermore, the receptors for these peptides occurring on immunocyte membranes share characteristics with neuronal opioid receptors, including molecular size, immunogenicity, and the use of specific intracellular signaling pathways. Recent studies of the interaction of opioids with cytokines have indicated that opioid peptides are intimately involved within the immune system. Specifically, opioids, including 2-n-pentyloxy-2-phenyl-4-methyl-morpholine, naloxone, and beta-endorphin, have been shown to interact with IL-2 receptors (134) and regulate production of IL-1 and IL-2 (48-50, 135). Conversely, IL-1 has been shown to up-regulate opioid peptide binding in brain tissue (136). Furthermore, the induction of IL-1 by opioids has also been identified in the invertebrate Mytilus, indicating the evolutionary conservation of this relationship (137). These results seem to typify the intricate association between the immune and neuroendocrine systems through opioid pathways. It is predicted that future endeavors will use this relationship to diagnose and treat specific diseases that have at their basis neuroendocrine and immunologic imbalances.     

In vivo pupillary constrictor effects of substance P in man.

The ocular effects of substance P (SP) were studied in 13 normal volunteers. Various concentrations of SP (0.135, 1.35 and 135 micrograms per 100 microliters) were instilled into the conjunctival sac and pupillary area changes were evaluated by means of an electronic pupillometer. The ability of SP to modify the mydriasis induced by pretreatment with 1% homatropine eyedrops was also studied. The instillation of SP produced miosis in a dose-dependent manner without provoking any ocular disturbances. Furthermore, the highest concentration tested was unable to reduce the homatropine-induced mydriasis. These findings indicate that SP exerts a pupillokinetic action in humans which probably occurs via a receptor mechanism. Since muscarinic blockade is not overcome by the peptide instillation, the results do not clarify whether SP causes miosis acting on iris muscles and/or cholinergic fibres.     

Glucocorticoid effects and receptors in two rat colon carcinoma cell lines differing by their tumorigenicity

Steroid hormones, regulators of cell differentiation and proliferation, are believed to play a role in carcinogenesis. Glucocorticoid hormones in particular modulate the expression of a number of proteins implicated in this process. We have investigated the effect of dexamethasone on two cell lines derived from a colon carcinoma, which differ by their tumorigenicity. Dexamethasone was found to inhibit growth of both the progressive (PROb) and the regressive clone (REGb). Upon hormonal treatment, glucocorticoid hormones induced fibronectin secretion by the two clones, whereas PROb cells were found to secrete an additional Mr approximately 43,000 protein. The cellular effect of glucocorticoid hormones being mediated through a specific soluble receptor, we have characterized this protein. The progressive cells (PROb) contained more specific glucocorticoid-binding sites (approximately 170,000 sites per cell) than the regressive ones (REGb cells; approximately 100,000 sites per cell). In both clones, the receptor was associated with the Mr approximately 90,000 heat shock protein to yield large complexes (Stokes radius Rs approximately 7.5 nm), which were dissociated to the same extent upon heat- and salt-treatment. The steroid- and DNA-binding unit of the receptor, characterized under denaturing conditions using an anti-receptor monoclonal antibody was found to be more degraded in the progressive cell line.     

Iris movement mediates vascular apoptosis during rat pupillary membrane regression

In the course of mammalian lens development, a transient capillary meshwork known as the pupillary membrane (PM) forms, which is located at the pupil area; the PM nourishes the anterior surface of the lens and then regresses to make the optical path clear. Although the involvement of apoptotic process has been reported in the PM regression, the initiating factor remains unknown. We initially found that regression of the PM coincided with the development of iris motility, and iris movement caused cessation and resumption of blood flow within the PM. Therefore, we investigated whether the development of the iris's ability to constrict and dilate functions as an essential signal that induces apoptosis in the PM. Continuous inhibition of iris movement with mydriatic agents from postnatal day 7 to day 12 suppressed apoptosis of the PM and migration of macrophage toward the PM, and resulted in the persistence of PM in rats. The distribution of apoptotic cells in the regressing PM was diffuse and showed no apparent localization. These results indicated that iris movement induced regression of the PM by changing the blood flow within it. This study suggests the importance of the physiological interactions between tissues-in this case, the iris and the PM-as a signal to advance vascular regression during organ development, and defines a novel function of the iris during ocular development in addition to the well-known function, that is, optimization of light transmission into the eye.     

Displacement of 3H-EKC binding by opioids in rat kidney: a correlate to diuretic activity

Multiple opioid binding sites have been documented in brain tissue. In this study we report on the presence of binding sites for the opioid ethylketocyclazocine (EKC) in a membrane fraction of rat kidney. Binding appeared to be selective in that opioids varied markedly in their capacities to displace 3H-EKC. Correlating with the capacity of an opioid to displace 3H-EKC was the ability to produce diuresis. Although our studies cannot assign a particular physiological or pharmacological role for the renal EKC binding sites, binding studies of this nature may, nonetheless, be a means by which diuretic activity of opioids can be predicted.     

Antagonism between L-DOPA and apomorphine in their effects on rat behavior

The effect of simultaneous injections of apomorphine and l-DOPA on stereotypy, aggressiveness, on the exploratory motor activity, the threshold of emotional reactivity and aggressiveness elicited by painful electrical stimulation was studied in experiments on male albino rats. When injected separately, in control experiments, both compounds had similar effects on the exploratory-motor activity and the emotional behaviour, but when injected simultaneously in various doses a distinct antagonism between l-DOPA and apomorphine, according to all the behaviour tests, was noted (a decrease of sterotypy, aggressiveness and emotional reactivity). Against the background of l-DOPA apomorphine (5 mg/kg) increased the dopamine content in the forebrain and in the diencephalon even more. It is suggested that the increased level of the functionally active mediator suppressed the activity of postsynaptic receptors sensitive to it.     

Hyperactivity versus explosive motor behavior induced by opioids in the rat. Mechanisms elucidated with enkephalin-tyrosine-o-sulfate and morphine congeners

A relatively mild hyperactive state (HAS), characterized by agitation and hypermotility, is induced by opiate drugs and opioid peptides in general and is blocked by naloxone. HAS can be distinguished from the profound hyperresponsiveness of an explosive motor behavior (EMB). Sulfation of the phenolic moiety in morphine or in methionine enkephalin essentially abolishes opiate receptor binding activity. The sulfated peptide lacks detectable pharmacological activity in the rat, whereas sulfated morphine is several hundred-fold more potent than morphine in eliciting (EMB). Thus, EMB is elicited only by congeners of morphine having appropriate hydrophilic substitution at C-6 and which is mediated through a receptor that is insensitive to naloxone.