The antinociceptive effect of intrathecal administration of epibatidine with clonidine or neostigmine in the formalin test in rats.

The analgesic effect of intrathecal injection of epibatidine, clonidine and neostigmine, compounds that elevate ACh, was examined in the formalin test, a model of post-injury central sensitization in the rat. The compounds were injected alone and in combination. Intrathecal injection of epibatidine alone did not alter pain behaviors, compared to vehicle-treated rats. Intrathecal injection of clonidine dose-dependently reduced tonic pain behaviors (ED(50)+/-95% confidence limits=6.7+/-4.8 microg). The combination of clonidine and epibatidine (C:E), in the ratio of 26:1, dose-dependently reduced tonic pain behaviors; and the ED(50) of C:E was 1.1+/-0.98 microg a significant 6-fold leftward shift of the dose response curve, compared with clonidine alone. The antinociceptive effect of C:E (26:1) was attenuated by pre-treatment with the nAChR antagonist mecamylamine. Neostigmine dose-dependently reduced tonic pain behaviors (ED(50)=1.5+/-1.3 microg). The combination of neostigmine and epibatidine, in a ratio of 8:1, significantly shifted the dose response curve 4-fold to the left (ED(50)=0.4+/-0.3 microg). The effect is mediated in part by the activation of the nAChR and possibly by the enhanced release of ACh. These data demonstrate significant enhancement of the antinociceptive effects of spinally delivered analgesics by a nAChR agonist, suggesting that this class of compounds may have utility as adjuvants when combined with conventional therapeutics.

Anxiolytic-like action of neuropeptide Y: mediation by Y1 receptors in amygdala, and dissociation from food intake effects.

Evidence from animal and human studies suggests that neuropeptide Y (NPY) may be a potent endogenous anxiolytic. The anatomic structures mediating this action of the peptide remain unknown. Furthermore, in addition to its anxiolytic-like effects, intracerebroventricular administration of NPY induces food intake through hypothalamic mechanisms, making the anxiolytic-like action of the peptide more difficult to interpret. The purpose of this study was to examine the anatomic substrate for the effects of NPY on anxiety, and to characterize the NPY receptors mediating these effects. Intracerebroventricular injection of NPY produced increased food intake in free-feeding animals, and dose-dependent anticonflict/anxiolytic-like effects in an established animal model of anxiety, the Geller-Seifter punished responding test. In contrast, microinjection of NPY into the central nucleus of the amygdala did not increase food intake in free-feeding animals, did not affect unpunished lever pressing for food, but did reproduce the anticonflict/anxiolytic-like effect with high potency. The selective NPY-Y1 agonist, p[Leu31,Pro34]NPY was approximately equipotent with native NPY in the conflict paradigm, and markedly more potent than the Y2 agonist, NPY13-36. Intrastriatal injections had no effect on conflict behavior. Thus, activation of Y1 receptors in the central nucleus of the amygdala produces effects similar to established anxiolytics without affecting food intake, suggesting that Y1-receptors in the amygdala may be a substrate for anxiolytic actions of NPY.

Anti-stress action of a corticotropin-releasing factor antagonist on behavioral reactivity to stressors of varying type and intensity.

Central administration of a Corticotropin-Releasing Factor (CRF) antagonist is well documented to attenuate a variety of behavioral responses to several distinct stressors; however, it is not yet clear whether the activation of CRF neurons is dependent on the type or intensity of the experimental stressor, or rather on the particular behavioral response to stress under study. To test the generality of the stress-protective effect of the CRF antagonist, alpha-helical CRF9-41, (1, 5 or 25 micrograms intracerebroventricularly), the present experiments employed a sensitive index of anxiogenic-like behavior by measuring suppression in exploration on the elevated plus-maze following exposure to social, swim, or restraint stressors. A 1 but not 5 or 25 micrograms dose of the CRF antagonist administered just prior to social, swim, or restraint stress reversed the stress-induced inhibition of exploratory behavior. Chlordiazepoxide and the steroid anesthetic, alphaxalone, also attenuated the anxiogenic-like effect of restraint stress and elevated the baseline exploratory behavior of nonstressed control groups. Although the stressors produced a graded secretion of adrenocorticotropin (ACTH) with the ranking restraint > swim > social, the relative amplitude of behavioral reactivity to social, swim, and restraint stress was comparable. The relative efficacy of the CRF antagonist to reverse the stressor effects was also comparable. These results suggest that antagonism of activated brain CRF systems attenuates the behavioral response to stress regardless of the type or intensity of the stressor as measured by ACTH secretion.

Corticotropin-releasing factor release from the mediobasal hypothalamus of the rat as measured by microdialysis.

Procedures were developed to permit the measurement of corticotropin-releasing factor in perfusate collected from microdialysis probes implanted in various brain areas of anesthetized and awake rats. Initially in vitro experiments were carried out to optimize the recovery of corticotropin-releasing factor and the radioimmunoassay conditions. Addition of a specific antiserum against corticotropin-releasing factor to the perfusion medium (artificial cerebrospinal fluid) increased the relative in vitro recovery over a range of different flow rates (1-10 microliters/min) using commercially available microdialysis probes with a membrane cutoff of 20,000 mol. wt. This procedure increased recovery from 3% to 6% at flow rate of 2.5 microliters/min, and from 4% to 8% at a flow rate of 5 microliters/min. In vivo experiments were performed with a flow rate of 3.3 microliters/min and 50-microliters fractions were used for radioimmunoassay. In each experiment, the standard curve of the radioimmunoassay was constructed from aliquots of the same medium used to perfuse the probe. Basal levels of corticotropin-releasing factor in dialysate collected from the mediobasal hypothalamus of anesthetized rats were estimated to be 0.75 +/- 0.07 fmol/50 microliters. Raising the concentration of potassium (60 mM) in the perfusate increased corticotropin-releasing factor levels to 2.04 +/- 0.37 fmol/50 microliters. Hypertonic stress induced by intraperitoneal injection of 1.5M NaCl (20 ml/kg) elevated the levels to 1.32 +/- 0.07 fmol/50 microliters. A marked increase of corticotropin-releasing factor levels was also produced by a 10-min pulse of the potassium-channel blocker 4-aminopyridine (10 mM) included in the perfusate. A second stimulation pulse with 4-aminopyridine, administered 2 h after the first pulse again increased the levels, with a mean ratio between the first and second pulse of 0.97. Corticotropin-releasing factor efflux produced by the second stimulation pulse was completely inhibited by perfusion with calcium-free medium containing calcium-chelating agent ethyleneglycol tetraacetic acid (10 mM). In separate experiments, microdialysis probes were implanted in several brain areas of anesthetized rats. Basal and potassium-evoked levels of corticotropin-releasing factor were measured in dialysate collected from the amygdala (1.20 +/- 0.22 and 2.05 +/- 0.48 fmol/50 microliters, respectively) and frontal cortex (0.51 +/- 0.10 and 1.64 +/- 0.15 fmol/50 microliters, respectively). Corticotropin-releasing factor levels in the dorsal part of the third ventricle and in the striatum were below the detection limits. In awake rats, corticotropin-releasing factor levels in the mediobasal hypothalamus were 0.98 +/- 0.03 fmol/50 microliters.(ABSTRACT TRUNCATED AT 400 WORDS)

Long-term reduction of vasopressin excretion induced by the central injection of an immunoconjugate (antibody to vasopressin linked to ricin A chain).

We have previously demonstrated that vasopressin-producing neurons are the target of monoclonal antibodies to vasopressin microinjected into the brain tissue. At the same time, this central microinjection of vasopressin-monoclonal antibody into the supraoptic nuclei produced hydro-osmotic disorders mimicking the effects of a central diabetes insipidus. In order to investigate the increase in both duration and amplitude of the biological effects seen after the injection of vasopressin-monoclonal antibody, an immunoconjugate was constructed with the vasopressin-monoclonal antibody IgG1k isotype and the cytotoxic part of the ricin molecule, the ricin A chain. The biological parameters, such as diuresis and urine osmolality which are directly regulated by vasopressin, and vasopressin excretion, were measured after the central injection of this immunotoxin/immunoconjugate. The consequences of immunotoxin injection were also studied when immunotoxin was co-injected with monensin (50 nM) which has been shown to decrease the intracellular degradation of immunotoxin, and plasma complement, which has been shown to increase the neuronal uptake of immunotoxin. Single injection of immunotoxin near the hypothalamic supraoptic nuclei significantly increased diuresis and decreased vasopressin excretion. However, these effects were only transient and disappeared 24 h later. Four successive injections of immunotoxin (one per day) with monensin induced a decrease of vasopressin excretion which was still observed after a resting period of four days after the fourth injection. The long-term reduction of vasopressin excretion was induced in rats receiving four successive injections of a mixture consisting of immunotoxin with monensin and plasma complement. In such experiments, the vasopressin content of urine remained low (55% under the baseline value), two weeks after the fourth injection of immunotoxin. At the same time, the diuresis was increased (80% above the baseline value) and urine osmolality lowered (45% under the baseline value). When non-specific IgG replaced specific antibody, vasopressin excretion, diuresis as well as urine osmolality were unchanged. The results of this study demonstrated that the use of a specific immunotoxin results in a local interference with the vasopressinergic neurons and induces a long-term reduction of vasopressin secretion.

Reduced cerebrospinal fluid levels of alpha-secretase-cleaved amyloid precursor protein in aged rats: correlation with spatial memory deficits.

The amyloid precursor protein undergoes proteolysis at several sites to yield a number of functionally relevant peptides, including beta-amyloid and the soluble amyloid precursor protein derivatives alpha-soluble amyloid precursor protein and beta-soluble amyloid precursor protein. beta-Amyloid is the primary constituent of senile plaques associated with Alzheimer's disease, while a-soluble amyloid precursor protein promotes synaptogenesis and plays a role in neuroprotective processes. We tested for age-related alterations in these amyloid precursor protein proteolytically derived peptides by measuring the levels of alpha-soluble amyloid precursor protein, total soluble amyloid precursor proteins (alpha- and beta-soluble amyloid precursor protein combined) and beta-amyloid in cerebrospinal fluid from three-, 13- and 23-month-old Fischer-344 rats. Western blot analysis using selective antibodies revealed 50% less total soluble amyloid precursor protein and a-soluble amyloid precursor protein in cisternal cerebrospinal fluid from 23-month-old rats compared with three- and 13-month-old animals. Mass spectrometric analysis indicated, however, that beta-amyloid in cerebrospinal fluid was not different between the three age groups. In a second group of young (five to six months of age) and aged (24-25 months of age) rats, spatial working and reference memory were assessed in a water maze followed by collection of cerebrospinal fluid. As a group, the aged rats consistently performed below the young rats in both working and reference memory tests. The aged rats also had 49% less cerebrospinal fluid alpha-soluble amyloid precursor protein than did their younger counterparts. There was a positive correlation (r= 0.52-0.57, P < 0.001) between performance in spatial memory tasks and cerebrospinal fluid alpha-soluble amyloid precursor protein in these young and aged rats. These results suggest that there is a positive association between cerebrospinal fluid levels of alpha-soluble amyloid precursor protein and cognitive performance in rats, and that alpha-soluble amyloid precursor protein may be involved in the spatial learning and memory changes that accompany ageing.

Long-term inhibition of stress-induced adrenocorticotropin release by intracerebral administration of a monoclonal antibody to rat corticotropin-releasing factor together with ricin a chain and monensin.

Abstract Previous studies have shown that microinjection of cytotoxic lgG2a monoclonal antibody to rat/human corticotropin-releasing factor (CRF-MAb) into the hypothalamic paraventricular nucleus of Long Evans rats resulted in antibody uptake into specific neurons of the paraventricular nucleus. We tested the hypothesis that this neuronal uptake may allow non-linked toxins to enter into specific neurons. The effects of central or peripheral administration of a mix containing CRF-MAb and cellular toxins (toxin/ CRF-MAb) on plasma adrenocorticotropin levels were determined before and after exposure to ether stress in freely moving rats. Peripheral injection (jugular vein) of the toxin/CRF-MAb mix or injection into the supraoptic nuclei did not affect resting or stress-induced adrenocorticotropin secretion. In contrast, bilateral injection of the same mix into the paraventricular nucleus or the lateral ventricle caused a consistent 70% reduction of the ether stress-induced adrenocorticotropin release but had no significant effect on the resting adrenocorticotropin levels. The blocking effect of intracerebroventricular administration disappeared after 24 h whereas the blockade persisted for at least 15 days after local injection into the paraventricular nucleus. The injection into the paraventricular nucleus of CRF-MAb without toxins restricted the inhibitory effects to 24 h. These data suggest that administration of a mix of toxins added to a specific lgG2a monoclonal antibody to CRF resulted in a long-term interference with the control of adrenocorticotropin secretion. This new approach may be of use for elucidating the physiological roles of different central peptidergic systems.

Antidepressant-like effects of the subtype-selective nicotinic acetylcholine receptor agonist, SIB-1508Y, in the learned helplessness rat model of depression.

RATIONALE: Epidemiological studies of smokers suggest that there is a link between nicotine and depression. Nonetheless, few studies have examined the potential use of nicotinic ligands in the treatment of depression. OBJECTIVES: The goal of this study was to evaluate the effects of SIB-1508Y, a novel subtype-selective ligand for high affinity nicotinic acetylcholine receptors (nAChRs), in the learned helplessness model of depression in rats. METHODS: In this model, exposure to inescapable foot-shock produces a lasting deficit in escape responses emitted in a subsequent conditioned avoidance procedure (learned helplessness). The effect of SIB-1508Y on learned helplessness was compared to the clinically used antidepressants, imipramine and fluoxetine, and the non-selective nAChR ligand, nicotine. RESULTS: Similarly to imipramine and fluoxetine, subchronic treatment (5 days) with SIB-1508Y reversed the escape deficit in the learned helplessness model in a dose dependent manner. The effect of SIB-1508Y on learned helplessness was still apparent 1 week following drug administration and was also maintained after 4 weeks of daily administration. In contrast, while nicotine was able to attenuate the learned helplessness deficit, this trend only reached statistical significance after chronic administration. The non-competitive ion channel blocker mecamylamine increased escape failures when administered alone and blocked the effects of SIB-1508Y but not imipramine. SIB- 1508Y also produced an increase in avoidance responding, which suggests an enhancement of learning. CONCLUSION: These results not only suggest a role for nAChRs in the development of a depressive-like syndrome, but also that subtype-selective nAChR agonists, such as SIB-1508Y, may offer a novel therapeutic approach to the treatment of depression.

The role of limbic and hypothalamic corticotropin-releasing factor in behavioral responses to stress.

CRF in the central nervous system appears to have activating properties on behavior and to coordinate behavioral responses to stress. These behavioral effects of CRF appear to be independent of the pituitary-adrenal axis and can be reversed by a CRF antagonist, alpha-helical CRF9-41. The CRF antagonist reverses not only decreases in behavior associated with stress, but also increases in behavior associated with stress, thus suggesting that the role of CRF is stress dependent and not intrinsic to a given behavioral response. Further, microinjection of alpha-helical CRF9-41 and immunotargeting of CRF neurons in separate brain compartments reveal a link between the anatomical sites that contain CRF and the nature of the behavioral response to stress that can be modified by suppression of endogenous CRF activity therein. Hence, consistent with the dual role of other hypothalamic-releasing factors in integrating hormonal and neural mechanisms by acting both as secretagogues for anterior pituitary hormones and as extrapituitary peptide neurotransmitters, CRF may coordinate coping responses to stress at several bodily levels (Fig. 6). Moreover, dysfunction in such a fundamental homeostatic system may be the key to a variety of pathophysiological conditions including mental disorders.

The role of CRF in behavioral aspects of stress.

CRF in the central nervous system appears to hve activating properties on behavior and to coordinate behavioral responses to stressors. These behavioral effects of CRF appear to be independent of the pituitary-adrenal axis and can be reversed by CRF antagonists. CRF antagonist administration reverses not only decreases in behavior associated with stress, but also increases in behavior associated with stress, thus suggesting that the role of CRF is stress dependent and not intrinsic to a given behavioral response. Further, microinjection of alpha-helical CRF 9-41 and immunotargeting of CRF neurons in separate brain compartments reveal a link between the anatomical sites that contain CRF and the nature of the behavioral response to stressors that can be modified by suppression of endogenous CRF activity therein. These actions of CRF in coordinating coping responses to stress at several bodily levels are consistent with a role for CRF similar to the dual role of other hypothalamic releasing factors in integrating hormonal and neural mechanisms by acting both as secretagogues for anterior pituitary hormones and as extrapituitary peptide neurotransmitters. Moreover, dysfunction in such a fundamental homeostatic system may be the key to a variety of pathophysiological conditions including mental disorders.

The role of corticotropin-releasing factor in the anxiogenic effects of ethanol withdrawal.

In summary, endogenous CRF has been demonstrated to play an important role in the endocrine but also autonomic and behavioral responses to a stressor and to mediate some of the signs and symptoms observed in human affective and anxiety disorders. These findings led to the hypothesis that the anxiety that characterizes drug withdrawal, such as ethanol withdrawal in humans, may be related in part to the action of CRF-producing neurons in the CNS. Indeed, rats made dependent on an ethanol liquid diet showed significant signs of enhanced stress responsiveness that was blocked by intracerebral administration of a CRF antagonist. At this time little is known about the specific site of action for endogenous CRF. However, recent studies using local administration of CRF antagonist and in vivo CRF microdialysis suggest that the central nucleus of the amygdala may be an important site for the increases in CRF activity associated with the anxiogenic effects of ethanol withdrawal. Although preliminary, these results propound that ethanol dependence may involve a prolonged dysregulation of the CRF system in the basal forebrain that may contribute to the increased motivational effect of ethanol withdrawal.

Endogenous corticotropin-releasing factor modulates feeding induced by neuropeptide Y or a tail-pinch stressor.

Previous work has characterized an anorexic action for endogenous, central nervous system corticotropin-releasing factor (CRF). Central injection of CRF decreases food intake induced pharmacologically by various appetite stimulants and a CRF antagonist attenuates restraint stress anorexia. Also, stressful physiological stimuli that are relevant to ingestive regulation, such as glucoprivation and protein nutrient deficiency, activate CRF systems. The present experiments examined the effects of exogenously administered CRF and a CRF antagonist, alpha-helical CRF(9-41), on spontaneous feeding induced by neuropeptide Y (NPY) and by a tail-pinch stressor. Pretreatment with a low dose of the CRF antagonist (1 microgram ICV) enhanced the hyperphagia induced by NPY while reducing the latency to begin feeding and increasing the duration of eating during tail pinch. Higher doses of alpha-hel CRF (5 and 25 micrograms ICV) exhibited diminishing or opposite effects. In contrast, CRF pretreatment (0.02, 0.1, and 0.5 microgram ICV) blocked the acquisition of tail-pinch feeding. Hence, while CRF administration impairs intake in these and other feeding paradigms, alpha-hel CRF actually facilitated dose dependently the intensity of the feeding response to NPY and tail pinch. These results suggest that endogenous CRF systems may play a role in modulating excessive feeding under conditions of evoked appetite and that brain CRF systems regulate feeding when excessive intake threatens to compromise the performance of other noningestive behaviors.

Antagonist of nicotinic acetylcholine receptors (nAChR) enhances formalin-induced nociception in rats: tonic role of nAChRs in the control of pain following injury.

Following tissue injury, spinal neurons increase in spontaneous activity and in responsiveness to peripheral stimulation. These changes in spinal neurons may underlie abnormal pain behavior. Nicotinic acetylcholine receptor (nAChR) agonists are analgesic when evaluated in animal models of pain, but it is not known if the nAChRs differentially modulate acute and tonic pain. To test this, mecamylamine, a non-subtype selective nAChR antagonist, was systemically injected into rats prior or after hind paw injection of formalin. Formalin injection results in biphasic pain-related behaviors, characterized by a first phase (i.e. acute pain) immediately following formalin injection, then by a second phase (i.e. tonic pain) 15-60 min after formalin injection. Either pre- or post-formalin treatment with mecamylamine decreased phase 1 behaviors and significantly increased phase 2 pain behaviors in a dose-dependent manner. These results suggest that nAChRs may exert opposing effects on acute versus tonic pain and, as such, may have implications for the potential development of nAChR ligands for the treatment of pain.

Corticotropin-releasing factor in the paraventricular nucleus modulates feeding induced by neuropeptide Y.

Central administration of neuropeptide Y (NPY) exerts a potent orexigenic effect in rats, whereas injection of corticotropin-releasing factor (CRF) suppresses food intake. Anatomical evidence of NPY-containing terminals located in close proximity to CRF-containing neurons and terminals of the hypothalamus and amygdala suggests possible interactions of these neuropeptide systems in food-intake regulation. The present study examined the effect of local administration of the CRF antagonist, alpha-helical CRF9-41, or peripheral treatment with dexamethasone on NPY-induced hyperphagia. Injection of a 250-ng dose of alpha-hel CRF within the paraventricular nucleus (PVN) of the hypothalamus significantly potentiated the feeding induced by a 500-ng dose of NPY injected into the same locus. In contrast, feeding induced by administration of the 500-ng dose of NPY into the ventromedial hypothalamus (VMH) was not modified by intra-VMH pre-treatment with a 250-ng dose of CRF antagonist. No effects of NPY or alpha-hel CRF on feeding were observed after administration into the central nucleus of the amygdala. Systemic pre-treatment with the synthetic glucocorticoid dexamethasone at a dose known to downregulate the function of CRF neurons in the PVN (100 micrograms/kg) enhanced feeding induced by intra-PVN administration of a 500-ng dose of NPY. These results suggest that hypothalamic CRF systems in the PVN exert inhibitory control over NPY-induced food intake.

Functional impairment of hypothalamic corticotropin-releasing factor neurons with immunotargeted toxins enhances food intake induced by neuropeptide Y.

Previous work has shown that administration of corticotropin-releasing factor (CRF) into the lateral ventricle antagonizes the orexigenic effect of neuropeptide Y (NPY), and central injection of CRF antagonist, alpha-helical CRF(9-41) enhanced NPY-induced food intake in satiated rats. The aim of the present study was to determine the effects of selective inactivation of hypothalamic CRF neurons on food intake induced by NPY injection and to delineate which hypothalamic nucleus is involved in this NPY/CRF interaction related to the regulation of food intake. Impairment of CRF neuron function by immunotargeting of a ricin A chain toxin with a monoclonal antibody to CRF (CRF-MAb) has been previously reported. Administration of CRF-MAb/toxins into the paraventricular nucleus (PVN) two weeks prior to testing produced markedly enhanced eating induced by injection of NPY into the same nucleus. This effect was accompanied by a 60% decrease in CRF content within the hypothalamus and a 43% decrease of CRF in the median eminence, a site of projection of CRF neurons from the PVN. In contrast, injection of CRF-MAb/toxins into the ventromedial nucleus of the hypothalamus (VMH) did not modify the feeding induced by NPY injection into this hypothalamic area. Systemic pretreatment with the synthetic glucocorticoid dexamethasone at a dose known to downregulate the levels of CRF in the PVN also enhanced the feeding induced by intra-PVN injection of NPY. This suggests that an equilibrium between CRF and NPY neuronal function within the PVN may play an important role in the regulation of food intake. This interactive mechanism may provide some partial explanation of the eating disorders related to stress, in particular anorexia nervosa.

Uptake of a monoclonal antibody to corticotropin-releasing factor (CRF) into rat hypothalamic neurons.

Previous immunocytochemical studies reported that when specific monoclonal antibody directed against vasopressin (VP) (VP-MAb) was injected in vivo above the rat hypothalamic nuclei, it penetrated and was specifically transported by VP-producing neurons. In this study, using the same methodological approach, the fate of monoclonal antibody directed against corticotropin-releasing factor (CRF) (CRF-MAb) injected in vivo above the paraventricular nucleus (PVN) of the rat brain was investigated by immunocytochemistry in male Zucker rats and adrenalectomized or colchicine-pretreated male Long-Evans rats. The simultaneous immunocytochemical localization of the injected CRF-MAb and endogenous peptides and enzyme synthesized by the neurons penetrated by the antibody, demonstrated that CRF-MAb was mainly detected in CRF neurons. But the CRF-MAb was also detected in VP, oxytocin, neuropeptide Y and tyrosine hydroxylase-producing neurons of the PVN. CRF-MAb was therefore localized in PVN neurons which synthesize CRF and in PVN neurons with physiological and morphological relationships with the CRF peptidergic system. Before obtaining biological effects of injected CRF-MAb, the results described here suggest that specific monoclonal antibodies provide a useful specific tool for elucidating the functional relationships between neuronal systems.

Alteration of pituitary-adrenal responses to adrenalectomy by the immunological targeting of CRF neurons.

We previously demonstrated that cellular toxins added to a cytotoxic IgG2a monoclonal antibody to corticotropin releasing factor (CRF-MAb) may specifically penetrate some hypothalamic CRF neurons, after central injection near the paraventricular nuclei. We attempt here to evaluate the consequential effects on the CRF neurons functioning. Such a toxic mix, 4 weeks after its central injection, caused a marked reduction (66%) of the chronic adrenocorticotropic hormone (ACTH) release in response to a bilateral adrenalectomy (7th day). This change was accompanied by a reduction in the CRF concentration (43%) measured in the median eminence. We concluded that specific internalization of toxins, by the way of CRF-MAb, leads to a long-term dysregulation of the CRF synthesis and/or neuronal transport.

Involvement of hypothalamic corticotropin-releasing factor neurons in behavioral responses to novelty in rats.

The purpose of this experiment was to investigate whether endogenous corticotropin-releasing factor (CRF) within the paraventricular nucleus of the hypothalamus (PVN) is involved in the alteration of locomotor activity related to a novel, presumably stressful, environment in rats. Impairment of the function of CRF-containing neurons was effected by immunotargeting ricin A chain toxin to these cells with a monoclonal antibody to CRF (CRF-MAb/toxins). CRF-MAb/toxins administered into the PVN 2 weeks prior to testing produced an increase in locomotor activity during exposure to novel environment photocell cages. This behavioral activation was maintained throughout the 120 min experimental session, but was not present when the rats where introduced to the same photocell cages after extensive habituation. These results suggest that the effect induced by CRF-MAb/toxin treatment was related to the exploration of the novel environment, and was not due to a generalized locomotor hyperactivity. This effect was accompanied by a 53% and 61% CRF decrease in the hypothalamus and the median eminence, respectively. Injection of CRF-MAb/toxins into the ventromedial nucleus of the hypothalamus did not modify the locomotor activity in either unfamiliar or familiar conditions. These data suggest that CRF neurons within the PVN may participate not only in the activation of the pituitary adrenal axis associated with stressors but also as physiological mediators of the behavioral responses to stress.

Suppression of corticotropin-releasing factor in the amygdala attenuates aversive consequences of morphine withdrawal.

The central nucleus of the amygdala is a CRF-containing limbic brain site which mediates both fear-like and avoidance behaviors, and intra-amygdala administration of a CRF antagonist blocks the increase in anxiogenic-like behavior characteristic of ethanol withdrawal. In order to evaluate the role of brain CRF in negative motivational states associated with other classes of abused drugs, the present studies examined the effects of suppression of amygdala CRF systems on the characteristic aversive state of precipitated withdrawal in morphine-dependent subjects. In a place conditioning paradigm, administration of a CRF antagonist, alpha-belical CRF (9-41) [250ng], bilaterally into the central nucleus of amygdala, reversed the withdrawal-induced conditioned place aversion produced by injection of the opiate antagonist, methylnaloxonium [500ng], into the same site. In a conditioned operant suppression paradigm, impairment of CRF neurons by immuno-targeted toxins administered into the central nucleus of amygdala, one month prior to testing, attenuated the decrease in response rate produced by exposure to distinctive sensory cues associated previously with systemic administration of naloxone [25µg/kg s.c.] in morphine-dependent subjects. These results indicate that suppression of intra-amygdala CRF systems weakens the aversive stimulus properties of conditioned opiate withdrawal, and suggest a general role for CRF in coordinating behavioral responses to negative motivational effects of drug withdrawal.

The potential of subtype-selective neuronal nicotinic acetylcholine receptor agonists as therapeutic agents.

Neuronal nicotinic acetylcholine receptors (NAChRs) are pentameric ligand-gated ion channel receptors which exist as different functional subunit combinations which apparently subserve different physiological functions as indicated by molecular biological and pharmacological techniques. It is possible to design and synthesize novel compounds that have greater selective affinities and efficacies than nicotine for different NAChRs, which should translate into different behavioral profiles and therapeutic potentials. Examples of NAChR agonists studied are nicotine, SIB-1508Y, SIB-1553A and epibatidine. These compounds have different degrees of selectivity for human recombinant NAChRs, different neurotransmitter release profiles in vitro and in vivo and differential behavioral profiles. Preclinical studies suggest that SIB-1508Y is a candidate for the treatment of the motor and cognitive deficits of Parkinson's disease, whereas SIB-1553A appears to have potential as a candidate for the treatment of Alzheimer's disease. Epibatidine has a strong analgesic profile, however the ratio between pharmacological activity and undesirable effects is so low that it is difficult to envisage the use of this compound therapeutically. Nicotine has a broad profile of pharmacological activity, for instance demonstrating activity in models for cognition and analgesia. As for epibatidine, the adverse effects of nicotine severely limits its therapeutic use in humans. The discovery of subtype-selective NAChR agonists such as SIB-1508Y and SIB-1553A provides a new class of neuropsychopharmacological agents with better therapeutic ratios than nonspecific agents such as nicotine.