Effect of morphine on proenkephalin gene expression in the rat brain

In vivo regulation of the μ opioid receptor: role of the endogenous opioid agents

It is well known that genotypic differences can account for the subject-specific responses to opiate administration. In this regard, the basal activity of the endogenous system (either at the receptor or ligand level) can modulate the effects of exogenous agonists as morphine and vice versa. The μ opioid receptor from zebrafish, dre-oprm1, binds endogenous peptides and morphine with similar affinities. Morphine administration during development altered the expression of the endogenous opioid propeptides proenkephalins and proopiomelanocortin. Treatment with opioid peptides (Met-enkephalin [Met-ENK], Met-enkephalin-Gly-Tyr [MEGY] and β-endorphin [β-END]) modulated dre-oprm1 expression during development. Knocking down the dre-oprm1 gene significantly modified the mRNA expression of the penk and pomc genes, thus indicating that oprm1 is involved in shaping penk and pomc expression. In addition, the absence of a functional oprm1 clearly disrupted the embryonic development, since proliferation was disorganized in the central nervous system of oprm1-morphant embryos: mitotic cells were found widespread through the optic tectum and were not restricted to the proliferative areas of the mid- and hindbrain. Transferase-mediated dUTP nick-end labeling (TUNEL) staining revealed that the number of apoptotic cells in the central nervous system (CNS) of morphants was clearly increased at 24-h postfertilization. These findings clarify the role of the endogenous opioid system in CNS development. Our results will also help unravel the complex feedback loops that modulate opioid activity and that may be involved in establishing a coordinated expression of both receptors and endogenous ligands. Further knowledge of the complex interactions between the opioid system and analgesic drugs will provide insights that may be relevant for analgesic therapy.

Opiate-like effects of sugar on gene expression in reward areas of the rat brain

Drugs abused by humans are thought to activate areas in the ventral striatum of the brain that engage the organism in important adaptive behaviors, such as eating. In support of this, we report here that striatal regions of sugar-dependent rats show alterations in dopamine and opioid mRNA levels similar to morphine-dependent rats. Specifically, after a chronic schedule of intermittent bingeing on a sucrose solution, mRNA levels for the D2 dopamine receptor, and the preproenkephalin and preprotachykinin genes were decreased in dopamine-receptive regions of the forebrain, while D3 dopamine receptor mRNA was increased. While morphine affects gene expression across the entire dopamine-receptive striatum, significant differences were detected in the effects of sugar on the nucleus accumbens and adjacent caudate-putamen. The effects of sugar on mRNA levels were of greater magnitude in the nucleus accumbens than in the caudate-putamen. These areas also showed clear differences in the interactions among the genes, especially between D3R and the other genes. This was revealed by a novel multivariate analysis method that identified cooperative interactions among genes, specifically in the nucleus accumbens but not the caudate-putamen. Finally, a role for these cooperative interactions in a load-sharing response to perturbations caused by sugar was supported by the finding of a different pattern of correlations between the genes in the two striatal regions. These findings support a major role for the nucleus accumbens in mediating the effects of naturally rewarding substances and extend an animal model for studying the common substrates of drug addiction and eating disorders.

Restricted daily consumption of a highly palatable food (chocolate EnsureR) alters striatal enkephalin gene expression

Brain opioid peptide systems are known to play an important role in motivation, emotion, attachment behaviour, the response to stress and pain, and the control of food intake. Opioid peptides within the ventral striatum are thought to play a key role in the latter function, regulating the affective response to highly palatable, energy-dense foods such as those containing fat and sugar. It has been shown previously that stimulation of mu opiate receptors within the ventral striatum increases intake of palatable food. In the present study, we examined enkephalin peptide gene expression within the striatum in rats that had been given restricted daily access to an energy-dense, palatable liquid food, chocolate Ensure(R). Rats maintained on an ad libitum diet of rat chow and water were given 3-h access to Ensure(R) daily for two weeks. One day following the end of this period, preproenkephalin gene expression was measured with quantitative in situ hybridization. Compared with control animals, rats that had been exposed to Ensure(R) had significantly reduced enkephalin gene expression in several striatal regions including the ventral striatum (nucleus accumbens), a finding that was confirmed in a different group with Northern blot analysis. Rats fed this regimen of Ensure(R) did not differ in weight from controls. In contrast to chronic Ensure(R), acute ingestion of Ensure(R) did not appear to affect enkephalin peptide gene expression. These results suggest that repeated consumption of a highly rewarding, energy-dense food induces neuroadaptations in cognitive-motivational circuits.

Gene expression following acute morphine administration

The long-term response to neurotropic drugs depends on drug-induced neuroplasticity and underlying changes in gene expression. However, alterations in neuronal gene expression can be observed even following single injection. To investigate the extent of these changes, gene expression in the medial striatum and lumbar part of the spinal cord was monitored by cDNA microarray following single injection of morphine. Using robust and resistant linear regression (MM-estimator) with simultaneous prediction confidence intervals, we detected differentially expressed genes. By combining the results with cluster analysis, we have found that a single morphine injection alters expression of two major groups of genes, for proteins involved in mitochondrial respiration and for cytoskeleton-related proteins. RNAs for these proteins were mostly downregulated both in the medial striatum and in lumbar part of the spinal cord. These transitory changes were prevented by coadministration of the opioid antagonist naloxone. Data indicate that microarray analysis by itself is useful in describing the effect of well-known substances on the nervous system and provides sufficient information to propose a potentially novel pathway mediating its activity.

Effects of in utero ethanol exposure and maternal treatment with a 5-HT(1A) agonist on S100B-containing glial cells

This laboratory previously showed that in utero ethanol exposure severely impairs the development of the cell bodies and projections of serotonin (5-HT) neurons, and that maternal treatment with a 5-HT(1A) agonist prevents many of these abnormalities. Others demonstrated that stimulation of fetal astroglial 5-HT(1A) receptors increases production and release of S100B, a glial trophic factor that is essential for the development of 5-HT neurons. The present study investigated a potential mechanism by which ethanol hinders development of 5-HT neurons, and by which maternal 5-HT(1A) agonist treatment prevents this damage. This study tested the hypothesis that in utero ethanol exposure reduces the number of S100B immunopositive glia and that maternal 5-HT(1A) agonist treatment prevents ethanol-associated changes in S100B. To test our hypothesis, we determined the effects of in utero ethanol exposure and maternal treatments with the 5-HT(1A) agonists ipsapirone and buspirone on S100B immunopositive glial cells. On gestation day 20 (G20), S100B immunopositive cells were quantified in the midline raphe glial structure (MRGS), a large transient structure that contains substantial numbers of S100B-positive glial cells and that spans the dorsal raphe, median raphe, and B9 complex of 5-HT neurons. S100B immunopositive glial cells were also determined in an area proximal to the dorsal raphe in postnatal day 2 (PN2) rats. In utero ethanol exposure significantly reduced S100B immunopositive glial cells in the MRGS at G20 and in the dorsal raphe at PN2. In addition, treatment of pregnant rats with a 5-HT(1A) agonist between G13 and G20 prevented the ethanol-associated reduction in S100B immunopositive glial cells. These studies demonstrated that part of ethanol's damaging effects on developing 5-HT neurons is mediated by a reduction of S100B and that some of the protective effects of maternal 5-HT(1A) agonist treatment are related to the actions of these drugs on glial cells.

Long-lasting sensitization towards morphine in motoric and limbic areas as determined by c-fos expression in rat brain

Chronic application of morphine leads to the development of tolerance towards several of its effects, e.g., analgesia or respiratory depression. Simultaneously, however, sensitization arises which becomes apparent in behavioral tests as increased locomotion or increased self-application. A human correlate for the latter may be the increasing craving for opioids in addicts. To identify brain areas involved in these long-lasting processes, we studied the expression of the transcription factor c-fos by in situ hybridization in rat brain as a marker for changes in gene expression after single or repeated morphine applications in the animals. The only c-fos signal that exceeded background after a single dose of morphine (50 mg/kg) was a diffuse expression in the lateral septum. In contrast, repeated dosage twice daily for 10 days and ascending from 10 to 50 mg/kg resulted in a sharply delineated morphine-induced c-fos synthesis in the dorsomedial and lateral striatum, lateral septum, medial mammillary nuclei, anterior thalamus and, in part masked by a high background due to injection stress, in the cingulate cortex. Most of these areas belong to the limbic system or are closely associated with it. The c-fos response was inducible by morphine in pretreated animals for up to 8 weeks after finishing the repeated application scheme. Retrograde tracing studies revealed that the dorsomedial part of the striatum, which was strongly labeled with the c-fos probe, received inputs from limbic as well as from motoric parts of the thalamus and cortex. Therefore, the sensitization of morphine-induced c-fos expression in parts of the striatum seems to correlate with the locomotor effects of repeated morphine application, whereas the observed sensitization in several limbic brain areas might reflect emotional phenomena like increased self-administration in rats or drug craving in humans.

Transmitters involved in antinociception in the spinal cord

The possible physiological and pathophysiological role of monoamines-adrenergic transmitter (norepinephrine), serotonin; cholinergic transmitter (acetylcholine); inhibitory (gamma-aminobutyric acid) and excitatory (glutamate) amino acids; opioid and nonopioid peptides, enkephalins, beta-endorphin and substance P, neurokinin-A, neurokinin-B, neurotensin, cytokines, calcitonine gene-related peptide, galanin, neuropeptide Y, nerve growth factor, cholecystokinin; purines; nitric oxide; vanilloid receptor agonists (capasaicin); and nociceptin-in spinal transmission of pain is reviewed. The role of substance P, neurokinin-A and neurokinin-B in the dorsal horn has been identified. These were suggested to be primary afferent transmitters mediating or facilitating the expression of nociceptive inputs. Pronociceptive modulators will be discussed later. Recent findings showing that N-methyl-D-aspartate (NMDA) receptor activation generates nitric oxide and prostanoids that enhance pain transmission whereas adenosine release acts to control these NMDA-mediated events are also mentioned. The clinical importance of centrally acting alpha2-adrenoceptor agonists (clonidine and dexmedetomidine) is also discussed. Antinociceptive and morphine-potentiating drugs are ideal adjuvants for anesthesia; their application in spinal anesthesia is highlighted. The recent development in understanding the importance of noradrenergic transmission and subtypes of alpha2-adrenoceptors (alpha2A and alpha2B) for the first time is reviewed.

Effects of halothane and methoxyflurane on regional brain and spinal cord substance P-like and beta-endorphin-like immunoreactivities in the rat

Effects of acute exposure (2 hr) to either 1.5% halothane or 0.5% methoxyflurane were investigated in the Sprague Dawley rat. Pituitary (PIT) and central nervous system (CNS) substance P (SP)-like and beta-endorphin (beta-end)-like immunoreactivities were evaluated immediately after anesthetic exposure (2 h), after righting reflex (4 h) or 24 hr postexposure (24 h). Only halothane significantly reduced SP-like immunoreactivity in olfactory bulbs in both the 2-h and 4-h groups. Halothane elevated SP-like immunoreactivity of hippocampus at all three time periods, and in the hypothalamus at 2 h. Both anesthetics significantly depleted thalamic concentrations of SP-like immunoreactivity. Methoxyflurane anesthesia resulted in a drastic decrease in SP-like immunoreactivity in PIT at all three time periods periods, while halothane elevated PIT concentrations of this peptide at 4 h. Both anesthetics significantly decreased beta-end-like immunoreactivity in the olfactory bulbs and thalami at 2, 4, and 24 h. However, halothane alone significantly elevated beta-end-like immunoreactivity in the spinal cord at 24 h. Halothane significantly elevated PIT beta-end-like immunoreactivity at 2 and 24 h, while methoxyflurane significantly lowered it in the 4-h group, but elevated the levels of the same in the 24-h group. Brain stem beta-end immunoreactivity were significantly reduced at 2 h by both anesthetics, and at 4 h by methoxyflurane. Results indicate that halothane and methoxyflurane may differ significantly in their actions on SP and beta-end secreting neurons in the CNS.

Estrogen alters proenkephalin RNAs in the paraventricular nucleus of the hypothalamus following stress

Gonadal steroids modulate activity of the hypothalamo-pituitary-adrenal axis (HPA) following stress, but the regulatory pathways of this modulation are unknown. A possible site of action is the synthesis of CRH and/or enkephalin in cells of the paraventricular nucleus of the hypothalamus (PVN). To investigate this possibility, we utilized two stressors, i.p. hypertonic saline injection (HSI) or exposure to novel environment, and examined the response of CRH or c-fos mRNAs and proenkephalin (PPE) mRNA and heteronuclear RNA (hnRNA, primary transcript). Male rats were gonadectomized and treated with estrogen or dihydrotestosterone propionate (DHTP) for 2 weeks. In situ hybridization revealed that novelty or HSI elevated levels of PPE hnRNA and c-fos mRNA in the PVN. Estrogen attenuated the elevation of PPE hnRNA in the PVN following HSI, and enhanced the c-fos mRNA response to novelty. In contrast, DHTP did not affect PPE hnRNA, but inhibited the c-fos mRNA response to novelty. These data indicate that in male rats estrogen receptor but not androgen receptor may modulate the endocrine stress response by altering PPE transcription in the PVN and that this effect depends on the type of stressor.