Nicotinic receptor partial agonists alter catecholamine homeostasis and response to nicotine in PC12 cells.

Repeated stress is a major public health concern where many stress responses are mediated by neuronal nicotinic acetylcholine receptors. In the present study we evaluated the effects of the nicotinic receptor partial agonists, cytisine and its derivative 3-(pyridin-3'-yl)-cytisine (3-pyr-Cyt) on two main biological outputs associated with activation of nAChR-release of neurotransmitters and increase in catecholamine biosynthesis to replenish the releasable pool. We compared these substances to the maximal response triggered by nicotine (full agonist) in PC12 cells. Cytisine, 3-pyr-Cyt or nicotine induced time-, dose- and Ca(2+)-dependent significant release of norepinephrine (NE) into the culture media. These effects were completely inhibited by mecamylamine but not by α-bungarotoxin, and only partially affected by α-conotoxin AulB, consistent with the involvement of α3ß4 receptors. Co-application of cytisine (or 3-pyr-Cyt) and nicotine resulted in attenuated nicotine-induced NE release. Cytisine or 3-pyr-Cyt alone induced a modest rise in tyrosine hydroxylase (TH) mRNA levels (index of the cell's catecholamine biosynthetic capacity). We conclude that both, cytisine and 3-pyr-Cyt (i) display typical partial agonist properties at naturally existing ganglionic nAChR (α3ß4 and α7 nAChR) with regard to catecholamine homeostasis (i.e. NE release and re-synthesis) and (ii) modulated the effect of nicotine during combined treatment.

Adrenocorticotropic hormone (MC-2) receptor mRNA is expressed in rat sympathetic ganglia and up-regulated by stress.

Stress triggered cardiovascular disorders are associated with elevated activity of the sympathetic nervous system, the major source of elevated plasma norepinephrine levels. Our previous studies revealed that administration of adrenocorticotropic hormone (ACTH) increases the gene expression of norepinephrine biosynthetic enzymes and several neuropeptides in rat sympathetic ganglia as much as stress. Here, we examine whether an ACTH-responsive receptor is expressed in rat superior cervical (SCG) and stellate ganglia (StG). Using reverse transcriptase-polymerase chain reaction (RT-PCR) we found expression of MC-2 receptor mRNA in these ganglia. Identical DNA fragments were amplified with mRNA from SCG, StG or from adrenal cortex. Sequencing revealed extensive homology to published sequences of mouse and human MC-2 receptor. Real time PCR was used to quantitate MC-2 receptor mRNA levels in the SCG under basal conditions and following immobilization stress. Immobilization stress triggered a large increase in MC-2 receptor mRNA in SCG. The results provide the first evidence that rat sympathetic ganglia express MC-2 receptor gene and are a target tissue for the peripheral actions of ACTH in response to stress.

Fos-related antigen 2: potential mediator of the transcriptional activation in rat adrenal medulla evoked by repeated immobilization stress.

The precise mechanisms by which beneficial responses to acute stress are transformed into long-term pathological effects of chronic stress are largely unknown. Western blot analyses revealed that members of the AP1 transcription factor family are differentially regulated by single and repeated stress in the rat adrenal medulla, suggesting distinct roles in establishing stress-induced patterns of gene expression in this tissue. The induction of c-fos was transient, whereas marked elevation of long-lasting Fos-related antigens, including Fra2, was observed after repeated immobilization. We investigated DNA protein interactions at the AP1-like promoter elements of two stress-responsive genes, tyrosine hydroxylase and dopamine beta-hydroxylase. Increased DNA-binding activity was displayed in adrenomedullary extract from repeatedly stressed rats, which was predominantly composed of c-Jun- and Fra2-containing dimers. The induction of Fra2 and increased AP1-like binding activity was reflected in sustained transcriptional activation of tyrosine hydroxylase and dopamine beta-hydroxylase genes after repeated episodes of stress. The functional link between Fra2 and regulation of tyrosine hydroxylase and dopamine beta-hydroxylase transcription was confirmed in PC12 cells coexpressing this factor and the corresponding promoter-reporter gene constructs. These studies emphasize the potential importance of stress-evoked increases in the expression of the Fra2 gene for in vivo adaptations of the adrenal catecholamine producing system.

Transient or sustained transcriptional activation of the genes encoding rat adrenomedullary catecholamine biosynthetic enzymes by different durations of immobilization stress.

The impact of stress on the transcription of rat adrenal tyrosine hydroxylase and dopamine beta-hydroxylase genes was examined. Nuclear run-on assays revealed that repeated immobilization stress elicited marked (about threefold) increases in the relative rates of transcription, being sustained for at least one day. Parallel changes in the steady-state messenger RNA levels for tyrosine hydroxylase and dopamine beta-hydroxylase were also observed. A single episode of stress triggered similar enhancements in their relative transcription rates. Depending on the duration of the stress signal, the effect on gene transcription varied in its persistence. After very short (5 min) immobilization, there was a marked transient rise in the transcription of both genes, without an accumulation of the corresponding mRNAs. Longer episodes of stress (30 min) increased the relative rate of tyrosine hydroxylase transcription for hours, causing elevations in the steady-state messenger RNA levels. In contrast, although dopamine beta-hydroxylase transcription was elevated to a similar extent by 30-min immobilization stress, the effect was transient and not reflected in significant accumulation of its messenger RNA. The results of our studies emphasize that the stress-evoked increases in the expression of the genes encoding adrenomedullary catecholamine biosynthetic enzymes involve transcriptional activation. Depending on the duration and reiteration of the stress signal, different transcriptional mechanisms may be employed.

Multiple signalling pathways exist in the stress-triggered regulation of gene expression for catecholamine biosynthetic enzymes and several neuropeptides in the rat adrenal medulla.

A critical component of the response to stress is the coincident activation of the hypothalamic-pituitary-adrenal axis and the sympathoadrenal system - comprised of sympathetic ganglia and the adrenal medullae. The sympathoadrenal system produces the catecholamines - noradrenaline and adrenaline, and several neuropeptides, involved in the homeostatic mechanisms that govern the adaptation to stress. This brief survey aims to provide a general overview of the present knowledge about the impact of stress on neurotransmitter gene expression in the adrenal medulla, with particular attention paid to the apparent heterogeneity in stress-evoked signals and regulatory pathways.

Heightened transcription for enzymes involved in norepinephrine biosynthesis in the rat locus coeruleus by immobilization stress.

BACKGROUND: The locus coeruleus (LC), a target for CRH neurons, is critically involved in responses to stress. Various physiological stresses increase norepinephrine turnover, tyrosine hydroxylase (TH) enzymatic activity, protein and mRNA levels in LC cell bodies and terminals; however, the effect of stress on other enzymes involved in norepinephrine biosynthesis in the LC is unknown. METHODS: Rats were exposed to single (2 hour) or repeated (2 hour daily) immobilization stress (IMO). Recombinant rat dopamine b-hydroxylase (DBH) cDNA was expressed in E. coli and used to generate antisera for immunohistochemistry and immunoblots in LC. Northern blots were used to assess changes in mRNA levels for TH, DBH, and GTP cyclohydrolase I (GTPCH) in the LC in response to the stress. Conditions were found to isolate nuclei from LC and to use them for run-on assays of transcription. RESULTS: Repeated stress elevated the DBH immunoreactive protein levels in LC. Parallel increases in TH, DBH and GTPCH mRNA levels of about 300% to 400% over control levels were observed with single IMO, and remained at similar levels after repeated IMO. This effect was transcriptionally mediated, and even 30 min of a single IMO significantly increased the relative rate of transcription. CONCLUSIONS: This study is the first to reveal transcriptional activation of the genes encoding catecholamine biosynthetic enzymes in the LC by stress. In addition to TH, changes in DBH and GTPCH gene expression may also contribute to the development of stress-triggered affective disorders.

Selective in vivo stimulation of stress-activated protein kinase in different rat tissues by immobilization stress.

Stress activated protein kinases (SAPK) are key enzymes mediating the cellular response to stressful stimuli. While they are intensively studied in cultured cells, little is known about their physiological role in vivo, or relevance to pathological conditions. Therefore we examined the effect of various times of immobilization on c-Jun N-terminal protein kinase (JNK) activity in several rat stress responsive tissues and in a number of other locations. The abundance and relative distribution of JNK isoforms, the basal levels, time course and relative magnitude of stress induced JNK activity differed among tissues and regions of the brain of the same animal. JNK immunoreactive proteins were most abundant in the brain, especially in the hippocampus, hypothalamus and frontal cortex. Marked activation in response to immobilization stress was observed in adrenal medulla, adrenal cortex, aorta and hippocampus, less pronounced in locus coeruleus. JNK was not affected in superior cervical ganglia, pituitary, hypothalamus, frontal cortex and cerebellum. In adrenal medulla, the activation of JNK by single immobilization stress is correlated with increased transcription of stress-responsive genes, tyrosine hydroxylase and dopamine beta-hydroxylase. These data suggest a potential role of JNK signal transduction pathway in mediating the long term adaptation to stressful stimuli in vivo.

Regulated expression of the tyrosine hydroxylase gene by membrane depolarization. Identification of the responsive element and possible second messengers.

Prolonged depolarization has been used as a model of adaptive changes in the expression of various proteins, such as ion channels and neurotransmitter biosynthetic enzymes, in response to increased trans-synaptic activity in the nervous system. In depolarized PC12 cells, tyrosine hydroxylase (TH) mRNA levels increased severalfold (Kilbourne, E. J., and Sabban, E. L. (1990) Mol. Brain Res. 8, 121-127). In this study, membrane depolarization caused an increase in the expression of the reporter gene chloramphenicol acetyltransferase (CAT), under transcriptional control of the 5' region of the rat TH gene. These results indicate that membrane depolarization leads to increased transcription of the TH gene. Protein kinase C inhibitors had no effect on the induction of TH mRNA by depolarization, as well as the increase in formation of CAT under control of the upstream region of the TH gene. The depolarization responsive element in the TH gene was mapped to the region containing the cAMP responsive element. This region of the TH gene also increased CAT activity in response to the calcium ionophore, ionomycin. Interestingly, combined treatment with cAMP analogs and membrane depolarization had a greater effect than either alone on TH mRNA levels, as well as on CAT activity in PC12 cells transfected with the plasmid containing the cAMP responsive element.

Activated ribosomal RNA synthesis in regenerated rat liver upon inhibition of protein synthesis.

Cycloheximide (Cyh), administered at a dose of 5 mg/kg body wt blocks protein synthesis in normal rat liver (NRL) and regenerating rat liver (RRL). The rate of synthesis of 45S pre-rRNA in RRL, studied after RNA labelling in vivo is activated 2.8 times. Pre-r RNA synthesis in RRL is more sensitive to the stopped translation, but never falls down to the level in NRL. The major contribution to the rDNA transcription activation in RRL comes from the 20-fold increase in the number of pol I molecules engaged in the transcription, the elongation rate being 1.4-fold accelerated. Cyh quenches partially the enhanced rDNA transcription in RRL: the number of pol I molecules and their elongation rate are about 1.7-fold and 1.5-fold higher, respectively, than the corresponding values in NRL after Cyh treatment. The results show that two different mechanisms control the number and the rate of initiation and elongation of RNA polymerase I in rat liver; one of them depends on continuous protein synthesis and can be inactivated by Cyh, the other is Cyh resistant.