James Douglass

Neuronal adaptation to amphetamine and dopamine: Molecular mechanisms of prodynorphin gene regulation in rat striatum

Induction of prodynorphin gene expression by psychostimulant drugs may represent a compensatory adaptation to excessive dopamine stimulation and may contribute to the aversive aspects of withdrawal. We therefore investigated the molecular mechanisms by which dopamine psychostimulant drugs induce prodynorphin gene expression in vivo and in rat primary striatal cultures. We demonstrate that three recently described cAMP response elements (CREs), rather than a previously reported noncanonical AP-1 site, are critical for dopamine induction of the prodynorphin gene in striatal neurons. CRE-binding protein (CREB) binds to these CREs in striatal cell extracts and is phosphorylated on Ser-133 after dopamine stimulation in a D1 dopamine receptor-dependent manner. Surprisingly, following chronic administration of amphetamine, levels of phosphorylated CREB are increased above basal in rat striatum in vivo, whereas c-fos mRNA is suppressed below basal levels. D1 receptor-mediated CREB phosphorylation appears to mediate adaptations to psychostimulant drugs in the striatum.

Differential activation of spinal cord dynorphin and enkephalin neurons during hyperalgesia: evidence using cDNA hybridization

A unilateral experimental inflammation of the hindlimb produces hyperalgesia to both mechanical and radiant thermal stimuli that is rapid in onset. During this period, parameters of dynorphin biosynthesis are elevated to a much greater degree than those of the enkephalin system. An increase in the content of the peptide dynorphin A(1-8) occurs in the spinal cord segments that receive sensory input from the affected limb. This is accompanied by a rapid (within 24 h) and pronounced increase in the levels of mRNA coding for the dynorphin protein precursor. Maximum elevations (6- to 8-fold) of preprodynorphin mRNA are observed between days 2 and 5 subsequent to the induction of inflammation. Compared to the increase in mRNA, the increase in dynorphin A(1-8) peptide was appreciably delayed and proportionately less; maximal increases in peptide (3-fold) were seen at day 5 of inflammation. Dorsal spinal cord preproenkephalin mRNA is elevated to a lesser degree (50-80%). However, the increase in preproenkephalin mRNA is apparently not enough to yield a measurable increase in the proenkephalin-derived peptide met5-enkephalin-Arg6-Gly7-Leu8, the levels of which showed no significant change during the 14-day inflammatory period. These data suggest the active participation of opioid neurons, especially those containing dynorphin, at the spinal level, in the modulation of sensory afferent input during peripheral inflammatory pain states.

Heteropolymeric potassium channels expressed in xenopus oocytes from cloned subunits

Voltage-dependent potassium currents were measured in Xenopus oocytes previously injected with RNAs generated in vitro from each of three cloned cDNAs (RBK1, RBK2, and RGK5). The currents differed in their sensitivities to blockade by tetraethylammonium (TEA; respective KDs 0.3, greater than 100, and 10 mM) and in their inactivation during a depolarizing pulse. Injections of RNA combinations (RBK1/RBK2 and RBK1/RGK5) caused currents that had TEA sensitivities different from those expected from the sum, in any proportion, of the two native channels. It is concluded that novel potassium channels are formed by the oocytes injected with two RNAs, presumably by heteropolymerization of subunits; such heteropolymerization would contribute functional diversity to voltage-dependent potassium channels in addition to that provided by a large gene family.

Characterization of the human cDNA and genomic DNA encoding CART: a cocaine- and amphetamine-regulated transcript

PCR differential display screening has recently identified a rat mRNA termed CART (cocaine- and amphetamine-regulated transcript) which is transcriptionally regulated in the striatum following acute administration of psychomotor stimulants. The endogenous CART transcript is expressed in diverse rat brain structures, as well as endocrine tissues. The deduced CART protein contains a hydrophobic signal sequence, suggesting that it may be targeted for secretion. Thus, the CART protein may represent a novel neuroendocrine signaling molecule. The study described here represents a complete analysis of the human CART cDNA and gene. The complete nucleotide (nt) sequence of the approx. 900-nt human CART transcript is contained within three distinct exons, with the entire human CART gene localized to a segment of genomic DNA approx. 2 kb in length. The human CART cDNA sequence is 80% identical to the corresponding rat cDNA, with 92% homology observed within the deduced protein-coding region. Third-nt changes account for most of the latter differences, with CART exhibiting 95% identity between these two species at the amino-acid sequence level. PCR/Southern blot analysis of DNA isolated from human/rodent somatic cell hybrid panels localizes the CART gene to human chromosome 5. Lastly, Northern blot analysis reveals that the gross pattern of distribution of CART mRNA in human brain is similar to that previously observed in rat. These overall similarities suggest that CART plays a conserved role within the mammalian neuroendocrine system.

Coordinate Expression of Hypothalamic Pro-Dynorphin and Pro-Vasopressin mRNAs with Osmotic Stimulation

Peptides derived from pro-dynorphin and pro-vasopressin precursors coexist within neurosecretory vesicles of magnocellular neurons in the rat hypothalamus projecting to the posterior pituitary. The secretory activity of these neurons can be stimulated using physiological manipulations known to increase plasma vasopressin levels, such as dehydration and salt-loading. With chronic osmotic challenge, the mRNAs for both pro-dynorphin and pro-vasopressin increase in parallel in the supraoptic and paraventricular nuclei of the hypothalamus, but not within the nonmagnocellular suprachiasmatic nucleus cell groups projecting elsewhere than the neural lobe. The results indicate an example of coordinate regulation of mRNA expression for coexisting peptides within the brain.

Systemic administration of kainic acid differentially regulates the levels of prodynorphin and proenkephalin mRNA and peptides in the rat hippocampus

The effects of systemic kainic acid (KA) administration on hippocampal levels of prodynorphin and proenkephalin mRNA, as well as opioid peptides derived from these precursors, were evaluated. A single subcutaneous injection of KA induced a range of seizure states, from mild wet dog shakes to generalized motor seizures. Northern blot analysis of hippocampal mRNA revealed an increase in both prodynorphin and proenkephalin mRNA levels which corresponded to the intensity of the convulsions. Conversely, hippocampal levels of immunoreactive dynorphin A (1-8) and [Met]5-enkephalin were decreased as a function of seizure frequency and intensity. The time course of KA-induced alterations in prodynorphin and proenkephalin mRNA and peptide levels was also investigated. Hippocampal prodynorphin mRNA levels rose at a dramatic rate. At 3 h following KA administration, mRNA levels were maximally elevated approximately 13-fold. The levels decreased over a 48 h period, eventually reaching control values. In contrast, proenkephalin mRNA levels increased more slowly. At 24 h, a maximal 24-fold increase was observed. At 72 h after injection, proenkephalin mRNA levels were still slightly elevated. In the same experiment, immunoreactive enkephalin peptide levels, although somewhat decreased at 3-12 h, began to increase between 12 and 24 h after injection, and were still rising at 72 h. In marked contrast, immunoreactive dynorphin peptide levels ranged from 40% to 80% of control values at all times tested.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of Ovariectomy on GnRH mRNA, proGnRH and GnRH Levels in the Preoptic Hypothalamus of the Female Rat

Experiments were carried out to investigate the effects of ovariectomy on gonadotropin-releasing hormone (GnRH) messenger RNA (mRNA), proGnRH and GnRH peptide levels in the hypothalamus of female rats. Intact proestrous female rats and female rats, which had been ovariectomized for 2 weeks, were sacrificed at 9.00 h and the preoptic area (POA) and basal hypothalamus (BH) were dissected out and frozen on dry ice. One group of tissues from proestrous control and ovariectomized females were extracted in acetic acid, centrifuged at 13,000 g and the supernatant purified on a C18 column. The purified extract was then radioimmunoassayed for proGnRH, using a specific antiserum to rat proGnRH (ARK-2), and for GnRH using the E1-14 antiserum. Total cellular RNA was isolated from another group of tissues and prepared as Northern blots. Hybridization with 32P-labeled GnRH cRNA was used to detect GnRH mRNA. A third group of proestrous and ovariectomized female rats were perfused, and 50 microns vibratome sections were cut. These were immunostained with proGnRH or GnRH antiserum, followed by in situ hybridization with 35S-labeled GnRH cRNA to detect GnRH mRNA. Based on the histochemical staining, mRNA was colocalized to the cell soma of neurons containing proGnRH and GnRH throughout the POA and BH. Based on the radioimmunoassay, proGnRH levels were 2 times higher in the POA versus the BH, but GnRH levels were 6-7 times higher in the BH. Ovariectomy significantly decreased proGnRH levels in both the POA and BH, while GnRH decreased in the BH. In contrast, quantitative Northern blot analysis demonstrated that ovariectomy had no effect on mRNA levels in the POA and BH. These data indicate that the effects of ovariectomy on proGnRH and GnRH levels are a result of altered translation, posttranslational processing and/or secretion of GnRH.

Basal and inducible transcriptional activity of an upstream AP-1/CRE element (DYNCRE3) in the prodynorphin promoter.

During chronic pain and inflammation, prodynorphin gene expression is elevated in the spinal cord. To characterize the molecular regulation of prodynorphin gene expression, we examined an AP-1/CRE-like element, TGCGTCA, located at -1545 in the prodynorphin gene (the DYNCRE3 site). Previous work in our laboratory demonstrated by gel shift analysis that Fos and non-Fos-containing complexes formed with oligonucleotides containing this element. To examine the functional significance of this site, constructs containing variable length regions of the prodynorphin promoter were transiently transfected into PC12 or HeLa cells. Constructs containing the DYNCRE3 site consistently permitted higher levels of transcriptional activity than those lacking this site. Furthermore, placement of upstream regions containing the DYNCRE3 site adjacent to the minimal promoter yielded transcriptional activity much greater than that in the presence of the native constructs. PC12 cells transfected with constructs containing the DYNCRE3 site responded to a far greater degree to forskolin stimulation than those transfected with constructs that did not contain this site. Mutation of the DYNCRE3 site (CTcgtca) markedly reduced forskolin-induced increases in transcriptional activity. The phorbol ester 12-O-tetradecanoylphorbol 13-acetate produced little or no change in transcriptional activity. By examining successively more isolated fragments of prodynorphin promoter and by mutational analysis, we identify and characterize a 7-bp site, DYNCRE3, which, though largely unaffected by stimulations of the PKC pathway, dramatically responds to stimulations via the PKA second messenger pathway.

Differential patterns of regulated gene expression in the adult rat epididymis.

Specialization among the principal epithelial cells of the epididymal tubule is documented following the analysis of transcriptional activity of four distinct species of mRNA. In situ histochemical analysis revealed a unique pattern of expression for each transcript. This observation supports the concept that region-specific patterns of transcriptional expression along the epididymal tubule serve as the major molecular basis underlying region-specific patterns of luminal proteins within the tubule. Additionally, multiple testicular factors appear to regulate expression of these mRNAs. The transcript encoding peptidyl-prolyl cis-trans isomerase is constitutively expressed. Those encoding the major secretory proteins, protein B/C and protein D/E, are directly regulated by testicular androgen. That encoding the opioid peptide precursor, proenkephalin, is regulated by a non-androgen testicular factor(s), specifically, spermatozoa or a spermatozoa-related factor. Thus, a complex array of nuclear events and signals received by the principal cells serve to determine the transcriptional status of genes expressed within this epididymal cell type.

Deep prepyriform cortex kindling differentially alters the levels of prodynorphin mRNA in rat hippocampus and striatum

The effect of deep prepyriform cortex (DPC) kindling on the levels of prodynorphin mRNA (DYN mRNA) in rat hippocampus and striatum was examined under two different stimulation paradigms. Electrical stimulations were delivered to rats twice per day (slow kindling) or once every hour (fast kindling) until two consecutive stage 5 kindled seizures occurred. Animals were decapitated 24 h after reaching the second stage 5 seizure, and DYN mRNA levels in the brain were determined by RNA blot analysis. In the slow kindling model, the level of DYN mRNA in the hippocampus was reduced by 57%, whereas the level of striatal DYN mRNA was increased by 34% compared to sham-operated controls. Fast kindling induced a similar decrease in the DYN mRNA level in the hippocampus, but did not alter that in the striatum. These results, together with the previous report that kindling decreased dynorphin A(1-8) level in the hippocampus, suggest that electrical kindling decreases the biosynthesis of dynorphin peptides in the hippocampus and, in the slow DPC kindling model, also increases the gene expression of dynorphin in the striatum.