Comparison of structural requirements of alpha-MSH and ACTH for inducing excessive grooming and pigment dispersion

alpha-MSH and ACTH-like peptides are known to play an important role in the adaptation of many vertebrates to a new environment. These peptides induce pigment dispersion in amphibian melanophores through a receptor-mediated mechanism. In this study we compared the structural requirements of these peptides for melanotropic activity on Xenopus laevis melanophores with those for inducing excessive grooming in the rat. With the exception of ACTH1-24 there is a close resemblance in structure-activity relationships of the fragments and analogs tested in the two bioassays. [Nle4,-D-Phe7]-alpha-MSH is extremely active in both assays. Weak agonists such as [Leu9]-alpha-MSH did not possess antagonistic properties either in the melanophore assay or in the excessive grooming test. The data suggest that the mechanism of action of alpha-MSH-like peptides in rat brain is receptor-mediated like their action on melanophores.     

Comparison of structural requirements of α-MSH and ACTH for inducing excessive grooming and pigment dispersion

α-MSH and ACTH-like peptides are known to play an important role in the adaptation of many vertebrates to a new environment. These peptides induce pigment dispersion in amphibian melanophores through a receptor-mediated mechanism. In this study we compared the structural requirements of these peptides for melanotropic activity on Xenopus laevis melanophores with those for inducing excessive grooming in the rat. With the exception of ACTH_1–24 there is a close resemblance in structure-activity relationships of the fragments and analogs tested in the two bioassays. [Nle⁴,-D-Phe⁷]-α-MSH is extremely active in both assays. Weak agonists such as [Leu⁹]-α-MSH did not possess antagonistic properties either in the melanophore assay or in the excessive grooming test. The data suggest that the mechanism of action of α-MSH-like peptides in rat brain is receptor-mediated like their action on melanophores.     

Comparison between excessive grooming induced by bombesin or by ACTH: the differential elements of grooming and development of tolerance

Bombesin and ACTH-(1-24) induce a dose dependent increase in grooming behavior. Lower doses of bombesin induce a more general type of compulsive grooming in which most elements are involved, whereas higher amounts of bombesin induce a shift towards the element scratching at the cost of bodily grooming and sexual grooming. In contrast ACTH-(1-24) induces a dose dependent increase of all elements of grooming. It is concluded that the grooming displayed by animals treated with ACTH-(1-24) or with bombesin is of a completely different nature. In addition it is observed that under the conditions used tolerance occurs for the grooming inducing effect of ACTH-(1-24), but not for that of bombesin. Moreover, it appears that no cross tolerance exists between bombesin and ACTH-(1-24).     

Limbic-midbrain lesions and ACTH-induced excessive grooming.

The induction of excessive grooming by intraventricular administration of ACTH_1–24 was studied in rats with lesions in midbrain-limbic structures. Such areas have been reported to be implicated in mediating ACTH-induced effects on avoidance behavior, sexual excitement or stretching and yawning. Electrolytic lesions in the septal complex, the anterior hypothalamic/preoptic area, the mammillary bodies, the amygdala, the posterior thalamus and dorsal or ventral hippocampus did not interfere with ACTH-induced excessive grooming. Lesioning of the hippocampal complex by aspiration led to an inhibition of excessive grooming depending on the degree of hippocampal damage. Amygdala and hippocampal lesions enhanced the display of stretching and yawning activity after treatment with the peptide. The data indicate differences in the neural substrates mediating the effect of ACTH on extinction of conditioned avoidance behavior, excessive grooming, sexual excitement and stretching and yawning.     

CRF-induced excessive grooming behavior in rats and mice

We studied the grooming response to lateral ventricle injection of CRF in both rats and mice under similar conditions. One microgram of CRF ICV induced a pronounced increase (3- to 4-fold) in the frequency of self-grooming in rats, but only a much smaller (less than 20%) increase in mice. The minimum effective dose of CRF in rats was 300 ng. Although ACTH1-24 induced less grooming in mice than in rats, the difference in potency did not appear to be sufficient to explain the differences between the effectiveness of CRF in the two species. Whereas ACTH increased all types of grooming scored. CRF increased all forms of grooming except flank scratching with the hind limb. The major effect of CRF was to increase the number of episodes of grooming, whereas ACTH1-24 tended to prolong the length of individual episodes. The excessive grooming induced by ICV CRF was not affected by prior treatment with dexamethasone, suggesting that the increased grooming was not due to secondary release of ACTH from the pituitary. Nevertheless, ICV CRF might induce grooming by releasing MSH/ACTH from cerebral storage sites. CRF-induced grooming, like ACTH-induced grooming, was inhibited by naloxone pretreatment. Despite the small qualitative differences, CRF-induced grooming could be due to secondary release of ACTH.     

The induction of excessive grooming in the rat by intraventricular application of peptides derived from ACTH: structure-activity studies.

Intraventricular administration of synthetic ACTH-like peptides in the rat induces excessive grooming, stretching and yawning. The present study demonstrates that induction of excessive grooming is dose-dependent and independent of the endocrine system. Structure-activity studies show that ACTH_1–24, ACTH_1–16-NH₂, ACTH_1–16, α-MSH and β_p-MSH are equipotent. Although the presence of the sequence ACTH_5–10 in the peptides studies seems of importance in the induction of excessive grooming, it appeared that C-terminal elongation is necessary for the expression of the activity. Administration of [D-Phe⁷] ACTH_4–10 and [D-Phe⁷] ACTH_1–10 results in appreciable grooming activity of the rat. However, substitution of a D-arginine at the 8 position did not alter the activity of ACTH_4–10. The structure-activity relationship of these peptides on grooming activity of the rat is compared to that known for retardation of avoidance extinction. Although some similarities exist, it is concluded that the expression of excessive grooming and retardation of avoidance activity is mediated through different mechanisms.     

Deficiency of antinociception and excessive grooming induced by acute immobilization stress in Per1 mutant mice

Acute stressors induce changes in numerous behavioral parameters through activation of the hypothalamic-pituitary-adrenal (HPA) axis. Several important hormones in paraventricular nucleus of the hypothalamus (PVN) play the roles in these stress-induced reactions. Corticotropin-releasing hormone (CRH), arginine-vasopressin (AVP) and corticosterone are considered as molecular markers for stress-induced grooming behavior. Oxytocin in PVN is an essential modulator for stress-induced antinociception. The clock gene, Per1, has been identified as an effecter response to the acute stresses, but its function in neuroendocrine stress systems remains unclear. In the present study we observed the alterations in grooming and nociceptive behaviors induced by acute immobilization stress in Per1 mutant mice and other genotypes (wild types and Per2 mutant). The results displayed that stress elicited a more robust effect on grooming behavior in Per1 mutant mice than in other genotypes. Subsequently, the obvious stress-induced antinociception was observed in the wild-type and Per2 mutant mice, however, in Per1 mutant, this antinociceptive effects were partially-reversed (mechanical sensitivity), or over-reversed to hyperalgesia (thermal sensitivity). The real-time qPCR results showed that in PVN, there were stress-induced up-regulations of Crh, Avp and c-fos in all of genotypes; moreover, the expression change of Crh in Per1 mutant mice was much larger than in others. Another hormonal gene, Oxt, was up-regulated induced by stress in wild-type and Per2 mutant but not in Per1 mutant. In addition, the stress significantly elevated the serum corticosterone levels without genotype-dependent differences, and accordingly the glucocorticoid receptor gene, Nr3c1, expressed with a similar pattern in PVN of all strains. Taken together, the present study indicated that in acute stress treated Per1 mutant mice, there are abnormal hormonal responses in PVN, correlating with the aberrant performance of stress-induced behaviors. Therefore, our findings suggest a novel functional role of Per1 in neuroendocrine stress system, which further participates in analgesic regulation.     

Isolation of ACTH1-39,ACTH1-38 and CLIP from the calf anterior pituitary

Calf anterior pituitaries were defatted and homogenized and peptides were adsorbed from the homogenate supernatant onto octadecylsilyl-silica. After elution, the resulting extract was subjected to gradient elution reversed-phase high pressure liquid chromatography (RP-HPLC) using aqueous acetonitrile containing 0.1% ($\text{v}\text{v}$) trifluoroacetic acid (TFA). Radioimmunoassay of column fractions for corticotropin (ACTH) revealed three major areas of immunoreactivity. Each was purified to homogeneity by gradient elution RP-HPLC employing aqueous acetonitrile containing either 0.13% heptafluorobutyric acid ($\text{v}\text{v}$) or 0.1% TFA ($\text{v}\text{v}$). Amino acid analysis and exopeptidase and trypsin digestions revealed the three forms of corticotropin to be ACTH_1–38, corticotropin-like intermediary lobe peptide, (CLIP, ACTH_18–39) and ACTH_1–39. ³H-labeled ACTH_1–39 did not give rise to either ³H-ACTH_1–38 or ³H-CLIP during isolation.     

Effect of ACTH1-24 and ACTH4-10 on distribution of 3H-noradrenaline in the brain of adrenalectomized rats.

Painful stimuli led to a decrease of the radioactive catecholamine pool in adrenalectomized rats. Intraventricular administration of both tritiated noradrenaline and ACTH produced a greater decrease of the labelled catecholamine pool than in the control adrenalectomized rats in 12 to 18 hr following injection. Blocking of monoamino-oxidase activity or biosynthesis by systemic administration of Pargyline or alpha-methyl-tyrosine did not prevent the effect of ACTH on brain catecholamines. It is concluded that ACTH exerts a direct influence on the brain catecholaminergic system and that this effect might be involved in ACTH dependent behavioural responses.     

The D1 family dopamine receptor,DopR, potentiates hind leg grooming behavior in Drosophila

Drosophila groom away debris and pathogens from the body using their legs in a stereotyped sequence of innate motor behaviors. Here, we investigated one aspect of the grooming repertoire by characterizing the D1 family dopamine receptor, DopR. Removal of DopR results in decreased hind leg grooming, as substantiated by quantitation of dye remaining on mutant and RNAi animals vs. controls and direct scoring of behavioral events. These data are also supported by pharmacological results that D1 receptor agonists fail to potentiate grooming behaviors in headless DopR flies. DopR protein is broadly expressed in the neuropil of the thoracic ganglion and overlaps with TH‐positive dopaminergic neurons. Broad neuronal expression of dopamine receptor in mutant animals restored normal grooming behaviors. These data provide evidence for the role of DopR in potentiating hind leg grooming behaviors in the thoracic ganglion of adult Drosophila. This is a remarkable juxtaposition to the considerable role of D1 family dopamine receptors in rodent grooming, and future investigations of evolutionary relationships of circuitry may be warranted.     

Effects of ACTH(1-24) and ACTH/MSH(4-10) on isolation-induced distress vocalization in domestic chicks

The effects of centrally administered ACTH(1-24) and ACTH(4-10) on isolation-induced distress vocalizations (DVs) were assessed in the presence or absence of social cues (mirrored and plain environments). A dose-response analysis indicated that ACTH(1-24) at doses of 0.5 nM and above increased DVs relative to controls when the animals were tested in mirrored or social environments which reduce baseline levels of calling. This effect, however, was short-lived (approx. 15 min). When tested again 1 hr after injection, the treated animals did not differ from controls. ACTH/MSH(4-10) had no effect on vocalization when the animals were tested immediately after injection, but marginally increased calling when animals were tested an hour later. In addition to vocalization changes, ACTH(1-24) induced squatting when animals were isolated in the test boxes, and yawning, head shaking, wing flapping and preening when animals were reunited after testing. ACTH(1-24)-treated chicks also exhibited longer latencies to close their eyes when they were held in the cupped hands of the experimenter. Taken together, the results suggest that ACTH(1-24) induces a central state of arousal in chicks that resembles fear/anxiety.     

Heterochromatin dispersion and blebbing of the nuclear membrane induced by melanophore stimulating hormone

Stimulation (in vivo and in vitro) of dermal melanophores of the leaf frog, Agalychnis dacnicolor, by melanophore stimulating hormone (MSH) elicits two responses in addition to the dispersion of melanosomes: (1) dispersion of heterochromatin; and (2) blebbing of the outer membrane of the nuclear envelope. The latter leads to the formation of dilated rough endoplasmic reticulum with the involvement of 80–100 Å microfilaments. N⁶,O²-dibutyryl adenosine 3′,5′-monophosphate (db-cAMP) elicits a similar response. Actinomycin D prevents both heterochromatin dispersion and membrane blebbing while cytochalasin B (CB) prevents only the latter.     

Iontophoretic release of cyclic AMP and dispersion of melanosomes within a single melanophore

Selective dispersion of melanosomes was often observed after iontophoretic injection of cyclic adenosine monophosphate (AMP) from a glass microelectrode positioned in a target melanophore in frog skin (as viewed from above through a microscope), with other melanophores in the field serving as controls. Because the skin has orderly arrays of several types of closely spaced cells, it is probable that at times the microelectrode also impales cells other than melanophores. When cyclic AMP injection inside a cell resulted in dispersion of melanosomes from a perinuclear position into dendritic processes, the onset of dispersion was relatively rapid, in many cases less than 4 min (mean time of onset, 5.3 +/- 2.9 [SD] min). A much slower dispersion (mean time of onset, 19.0 +/- 5.0 min) of melanosomes was observed when the microelectrode was positioned adjacent to a melanophore, and much larger quantities of cyclic AMP were released. In addition, no changes were observed for injections of 5'-AMP or cyclic guanosine monophosphate (GMP) through electrodes positioned inside or adjacent to melanophores. Potential measurements showed that after impaling a clell, a constant transmembrane potential could often be recorded over many minutes, indicating that the membrane tends to seal around the microelectrode. The results indicate that cyclic AMP acts more rapidly on the inside of a cell than when applied outside a cell and allowed to diffuse through the plasma membrane. This study introduces a model system whereby the properties of the plasma membrane and melanocyte-stimulating hormone (MSH) receptors can be studies within a single target cell.     

Cyclic analogs of ACTH fragments in self-stimulation and grooming behavior in rabbits

In present study new cyclic fragments of ACTH EHFRWGKPVG--NH2 and KHFRWG--NH2 were investigated in organization of self-stimulation and grooming behaviour in rabbits. Intracerebroventricular injections of EHFRWGPVG--NH2 in doses of 0.1-2.5 g evoked significant increases of self-stimulation and in doses of 4-5 g suppressed self-stimulation in rabbits. The effect of other fragments KHFRWG--NH2 on self-stimulation was not statistically significant. Both fragments induced excessive grooming behaviour in rabbits. The effects of these fragments persisted of 48-72 hours.     

Interleukin-1 potentiates basal and AVP-stimulated ACTH secretion in vitro--the role of CRH pre-incubation.

The acute-phase cytokine interleukin-1 (IL-1) is known to activate the hypothalamic pituitary adrenal axis, primarily via corticotropin releasing hormone (CRH). The aim of this study was to determine whether IL-1beta could directly stimulate ACTH secretion from perifused equine anterior pituitary cells, and whether CRH pre-incubation affected corticotroph responsiveness. Isolated equine anterior pituitary cells were pre-incubated with media containing 10 nM CRH or vehicle for 20 hours before being loaded onto columns and perifused with 0.02 nM CRH and 100 nM cortisol. Columns were given a 5-minute pulse of arginine vasopressin (AVP, 10 nM), perifused for 4 hours with 0 (control) or 1 nM IL-1beta, then given a further 5-minute pulse of AVP (10nM). ACTH was measured in 5 minute fractions. In the setting of CRH pre-incubation, cells perifused with IL-1beta for 4 hours showed increased basal ACTH secretion compared to control (114 +/- 6 pM vs. 86 +/- 4 pM [means +/- S.E.M.], p < 0.001) and a significantly greater ACTH response to the final AVP pulse (240 +/- 32% vs. 96 +/- 30%, p = 0.009, expressed as % of ACTH response to the initial AVP pulse). The potentiation of AVP-stimulated ACTH release by IL-1 was not observed in cells pre-incubated with vehicle alone. In conclusion, IL-1 increases ACTH release in equine corticotroph cells pre-incubated with CRH and potentiates responsivity to AVP.