Pro-opiomelanocortin peptides in the human fetal pituitary

Levels of immunoreactive pro-opiomelanocortin (POMC) peptides (N- and C-terminal ACTH, N- and C-terminal LPH and α-MSH) have been measured in pituitary extracts from human fetuses of 12–22 weeks gestation. The levels of ACTH were 30–200 times higher than α-MSH in all fetuses studied. Sephadex G-75 and G-25 chromatography of 8 extracts showed peaks of 34 kilodaltons (K) POMC, 22K ACTH, β-LPH, γ-LPH, β-endorphin, approximately 8K ACTH, 1–39 ACTH, α-MSH and CLIP. The 8K and 22K forms of ACTH are both partly glycosylated.In vitro culture of pituitaries from 2 fetuses (22 and 26 weeks gestation) gave a detectable basal output of ACTH but not of α-MSH. Stimulation of these pituitary cells with human fetal and rat hypothalamic extracts and with synthetic ovine CRF-41 produced a significant increase in ACTH release, and either small or undetectable amounts of α-MSH.These results demonstrate the presence of POMC-related peptides in early gestation human fetal pituitaries and suggest that ACTH, and not α-MSH, is the major corticotrophic hormone at this stage of gestation.     

Presence of cells and fibers immunoreactive toward antibodies to different peptides or amine in the digestive tract of the snailHelix aspersa

An immunocytological study of four different parts of the gut of Helix aspersa clearly demonstrates the presence of many cells and fibers immunoreactive toward antibodies directed to vertebrate (α, β-endorphin, α, β-MSH, ACTH 1–24 and ACTH 17–39, met-enkephalin, somatostatin, insulin, glucagon, P.P., serotonin) or invertebrate (FMRF-amide) peptides. These results are evidence of the presence of different substances related to known peptides or amines in the epithelial and connective tissue cells and nerve fibers of the snail gut. Immunocytochemistry may help to elucidate the morpho-functional characteristics of the enteroendocrine cells of H. aspersa.     

Characterisation of ACTH Peptides in Human Skin and Their Activation of the Melanocortin-1 Receptor

α-Melanocyte-stimulating hormone (α-MSH) is a proopiomelanocortin (POMC)-derived peptide, which is produced in the pituitary and at other sites including the skin. It has numerous effects and in the skin has a pigmentary action through the activation of the melanocortin-1 (MC-1) receptor, which is expressed by melanocytes. Recent evidence suggests that the related POMC peptides such as adrenocorticotrophin (ACTH), which is the precursor of α-MSH, is also an agonist at the MC-1 receptor. By using immunocytochemistry, we confirmed the presence of α-MSH in human skin where staining was evident in keratinocytes and especially strong in melanocytes and possibly Langerhans cells. ACTH was also present and tended to show the strongest reaction in differentiated keratinocytes. Immunostaining was also observed for the prohormone convertases, PC1 and PC2, which are involved in the formation of ACTH and its cleavage to α-MSH, respectively. The amounts of immunoreactive ACTH exceeded those of α-MSH. Using HPLC we identified for the first time the presence of ACTH1-39, ACTH1-17, ACTH1-10, acetylated ACTH1-10, α-MSH, and desacetyl α-MSH in epidermis and in cultured keratinocytes. The ability of these peptides to activate the human MC-1 receptor was examined in HEK 293 cells that had been transfected with the receptor. All peptides increased adenylate cyclase in these cells with the following order of potency: ACTH1-17 > α-MSH > ACTH1-39 > desacetyl α-MSH > acetylated ACTH1-10 > ACTH1-10. ACTH1-17 also increased the dendricity and melanin content of cultured human melanocytes indicating that the peptide was able to activate MC-1 receptors when present in their normal location. However, as found with α-MSH, not all cultures were responsive and, as we have previously suggested, we suspect that this was the result of changes at the MC-1 receptor. Nevertheless, it would appear that ACTH peptides can serve as natural ligands of the MC-1 receptor on human melanocytes and their presence in the skin suggests that, together with α-MSH, they may have a role in the regulation of human melanocytes.     

Adrenocorticotropin/α-Melanocyte-Stimulating Hormone (ACTH/MSH)-Like Peptides Modulate Adenylate Cyclase Activity in Rat Brain Slices: Evidence for an ACTH/MSH Receptor-Coupled Mechanism

Abstract: The regulation of adenylate cyclase activity by adrenocorticotropin/α-melanocyte–stimulating hormone (ACTH/MSH)-like peptides was investigated in rat brain slices using a superfusion method. Adenylate cyclase activity was concentration-dependently increased by ACTH-(1–24), α-MSH (EC₅₀ values 16 and 6 nM, respectively), and [Nle⁴,D-Phe⁷]α-MSH (EC₅₀ value 1.6 nM), in the presence of forskolin (1 μM, optimal concentration). 1-9-Dideoxy-forskolin did not augment the response of adenylate cyclase to ACTH-(1–24). Various peptide fragments were tested for their ability to enhance [³H]cyclic AMP production. [Nle⁴,D-Phe⁷]α-MSH increased [³H]cyclic AMP formation with a maximal effect of 30% and was more potent than ACTH-(1–24), ACTH-(1–16)-NH₂, α-MSH, ACTH-(1–13)-NH₂, [MetO⁴]α-MSH, [MetO₂⁴,D-Lys⁸,Phe⁹]ACTH-(4–9), ACTH-(7–16)-NH₂, ACTH-(1–10), and ACTH-(11–24), in order of potency. This structure–activity relationship resembles that found for the previously described peptide-induced display of excessive grooming. ACTH-(1–24) stimulated adenylate cyclase activity in both striatal (maximal effect, ?20%) and septal slices (maximal effect, ?40%), but not in hippocampal or cortical slices. Lesioning of the dopaminergic projections to the striatum did not result in a diminished effect of [Nle⁴,D-Phe⁷]α-MSH on [³H]cyclic AMP accumulation, which indicates that the ACTH/MSH receptor–stimulated adenylate cyclase is not located on striatal dopaminergic terminals. ACTH-(1–24) did not affect the dopamine D₁ or D₂ receptor–mediated modulation of adenylate cyclase activity. Based on the present data, we suggest that the binding of endogenous ACTH or α-MSH to a putative ACTH/MSH receptor in certain brain regions leads to the activation of a signal transduction pathway using cyclic AMP as a second messenger.     

Effect of nicotine on in vivo secretion of melanocorticotropic hormones in the rat

Corticosterone, ACTH, β-endorphin and α-MSH were measured in rat plasma by radioimmunoassay before and 2,5,15,30 minutes after an intraperitoneal injection of nicotine (500 μg/Kg b.w.). Nicotine induced an increase of plasma corticosterone (p < 0.05 at t + 15 min), ACTH and β-endorphin (p < 0.01 at t + 5 min) and a decrease of α-MSH (p < 0.005 at t + 15 min). Dose response experiments showed an increase of corticosterone, ACTH, β-endorphin 15 min after 250 μg/Kg b.w. nicotine I.P., no effect being observed after injection of 100 μg/Kg b.w. The decrease of α-MSH was observed 15 min after 100, 250 or 500 μg/Kg b.w. nicotine I.P. Our results suggest that the increase of corticosterone is mediated through ACTH release.     

Does α-MSH Have a Role in Regulating Skin Pigmentation in Humans?

Over the years there has been much debate as to whether α-MSH has a role as a pigmentary hormone in humans. There are two main reasons for this. First, despite the observations in the 1960s that α-MSH increased skin darkening in humans, there are reports that the peptide has no effect on melanogenesis in cultured human melanocytes. Second, the human pituitary, unlike that of most mammals, secretes very little α-MSH and circulatory levels of the peptide in humans are extremely low. However, there is now evidence from several groups that α-MSH is capable of stimulating melanogenesis in cultured human melanocytes. Rather than producing an overall increase in melanin production, it appears that the peptide acts specifically to increase the synthesis of eumelanin. Such an action could well explain the previously observed skin darkening effects of α-MSH. It is also now known that α-MSH is not produced exclusively in the pituitary but has been found at numerous sites, including the skin where it is produced by several cell types. Related Proopiomelanocortin (POMC) peptides such as ACTH are also produced in human skin. The ACTH peptides act at the same receptor (MC-1) as α-MSH and certain of these would appear to be more potent than α-MSH in stimulating melanogenesis. The ACTH peptides are also present in greater amounts than α-MSH in human epidermis and it is likely that they play an important role in regulating pigmentary responses. These POMC peptides are released from keratinocytes in response to ultraviolet radiation (UVR) and it has been proposed that they serve as paracrine factors in mediating UV induced pigmentation. Their production by keratinocytes could therefore be critical in determining pigmentary responses and any changes in the availability of these POMC peptides might explain the variations in tanning ability seen in different individuals. However, the possibility that tanning ability is also dependent upon differences at the level of the MC-1 receptor cannot be ruled out and it has been suggested that an inability to tan may depend upon the presence of non-functional changes at the MC-1 receptor. α-MSH does, of course, affect human melanocytes in several ways and its stimulation of melanogenesis could be the consequence of some other fundamental action in the melanocyte. The peptide also has many other target sites in the skin and while it may have a role in regulating skin pigmentation in humans, it should not be viewed solely as a pigmentary peptide. α-MSH clearly has many different actions and its primary role in the skin may be to maintain homeostasis.     

Interaction of adrenocorticotropin peptides with microheterogeneous systems — A fluorescence study

Adrenocorticotropin (ACTH) and α-melanocyte stimulating hormone (α-MSH) are peptides which present many physiological effects related to pigmentation, motor and sexual behavior, learning and memory, analgesia, anti-inflammatory and antipyretic processes. The 13 amino acid residues of α-MSH are the same initial sequence of ACTH and due to the presence of a tryptophan residue in position 9 of the peptide chain, fluorescence techniques could be used to investigate the conformational properties of the hormones in different environments and the mechanisms of interaction with biomimetic systems like sodium dodecyl sulphate (SDS) micelles, sodium dodecyl sulphate-poly(ethylene oxide) (SDS-PEO) aggregates and neutral polymeric micelles. In buffer solution, fluorescence parameters were typical of peptides containing tryptophan exposed to the aqueous medium and upon addition of surfactant and polymer molecules, the gradual change of those parameters demonstrated the interaction of the peptides with the microheterogeneous systems. From time-resolved experiments it was shown that the interaction proceeded with conformational changes in both peptides, and further information was obtained from quenching of Trp fluorescence by a family of N-alkylpyridinium ions, which possess affinity to the microheterogeneous systems dependent on the length of the alkyl chain. The quenching of Trp fluorescence was enhanced in the presence of charged micelles, compared to the buffer solution and the accessibility of the fluorophore to the quencher was dependent on the peptide and the alkylpyridinium: in ACTH(1–21) highest collisional constants were obtained using ethylpyridinium as quencher, indicating a location of the residue in the surface of the micelle, while in α-MSH the best quencher was hexylpyridinium, indicating insertion of the residue into the non-polar region of the micelles. The results had shown that the interaction between the peptides and the biomimetic systems where driven by combined electrostatic and hydrophobic effects: in ACTH(1–24) the electrostatic interaction between highly positively charged C-terminal and negatively charged surface of micelles and aggregates predominates over hydrophobic interactions involving residues in the central region of the peptide; in α-MSH, which presents one residual positive charge, the hydrophobic interactions are relevant to position the Trp residue in the non-polar region of the microheterogeneous systems.     

Distribution of pro-opiomelanocortin and its peptide end products in the brain and hypophysis of the aquatic toad, Xenopus laevis

Using in situ hybridization with a pro-opiomelanocortin (POMC)-mRNA probe and immunocytochemistry with antisera to POMC and to various POMC-derived peptides, it is shown that melanotrope cells in the pars intermedia of the hypophysis of the South African aquatic toad Xenopus laevis contain POMC, α-melanophore-stimulating hormone (α-MSH), γ-MSH, acetylated and non-acetylated endorphins and adrenocorticotropic hormone (ACTH). With the exception of γ-MSH, these peptides are also found in the corticotrope cells in the rostral pars distalis. In the Xenopus brain, neuronal cell bodies in the ventral hypothalamic nucleus express POMC, α-MSH, γ-MSH, non-acetylated endorphins and ACTH, neurones in the anterior preoptic area reveal POMC, α-MSH, γ-MSH and non-acetylated endorphin, neurones in the suprachiasmatic nucleus contain α-MSH, non-acetylated endorphin and ACTH and neurones in the posterior tubercle show α-MSH, non-acetylated endorphin and ACTH immunoreactivities. In the locus coeruleus POMC and ACTH coexist, whereas α-MSH and non-acetylated endorphin occur together in the nucleus accumbens, the striatum and the nucleus of the paraventricular organ. Finally, α-MSH alone is present in the olfactory bulb, the medial septum, the medial and lateral parts of the amygdala, the ventromedial and posterior thalamic nuclei, the optic tectum and the anteroventral tegmental nucleus, and non-acetylated endorphin alone appears in the epiphysis. It is suggested that neurones that form POMC-derived peptides may play a direct or indirect role in the control of POMC-producing hypophyseal cells and/or in the physiological processes these endocrine cells regulate. This idea is supported by the fact that the suprachiasmatic nucleus and the locus coeruleus, both involved in melanotrope cell control, show POMC and POMC-peptide expression. A possible involvement in melanotrope and/or corticotrope control of the anterior preoptic and ventral hypothalamic nuclei, which both express POMC and various POMC-derived peptides, deserves future attention.     

Effect of α-MSH 11–13 (lysine-proline-valine) on fever in the rabbit

In previous experiments, α-MSH (1–13) and ACTH (1–24), which contains the α-MSH 1–13 amino acid sequence, were found to reduce fever after central and peripheral administration of low, non-hypothermic doses. Shorter molecules, including α-MSH 1–10, had no effect. The idea that the 11–13 amino acid sequence is important to the effect of the parent molecule was tested by giving lysine-proline-valine both centrally and peripherally to rabbits made febrile by IV administration of leukocytic pyrogen. The tripeptide reduced fever after both central (0.5–2.0 mg) and peripheral (2–200 mg) administration. It appears that the 11–13 sequence is part of the message sequence of α-MSH with regard to antipyretic activity. However, the lower potency relative to that of the parent molecule suggests that other portions of the molecule are essential to full expression of the antipyretic effect.     

Behavioral profile of ψ-MSH: Relationship with acta and β-endorphin action

In view of the close structural similarity of the pro-opiocortin fragment γ-MSH and of ACTH/MSH type peptides, the behavioral profile of γ-MSH was explored. Attention was first focussed on behavioral procedures in which ACTH/MSH related neuropeptides have been found effective. Using different procedures to test avoidance behavior, it was found that γ-MSH and ACTH-like neuropeptides had opposite effects. In this respect the activity of γ-MSH resembles that of opiate antagonists rather than that of β-endorphin. Accordingly, ACTH_1–24-induced excessive grooming which is blocked by opiate antagonists, is attenuated by γ-MSH. In addition, γ-MSH injected into the periaqueductal gray matter of the brainstem of opiate naive rats elicited symptoms reminiscent of those seen after opiate withdrawal. γ-MSH attenuated more or less several effects of intracerebroventricularly administered β-endorphin (e.g. antinociception, hypothermia, α-MSH release) and decreased acquisition of heroin self-administration. Although γ-MSH at rather high doses displaced naloxone from its specific binding sites in brain homogenates, it did not interfere with β-endorphin-induced effects on in vitro muscle preparations (guinea pig ileum, rat rectum). Interestingly, γ-MSH induced relaxation of the rat rectum in vitro. It is postulated that γ-MSH may attenuate β-endorphin-induced effects by acting via γ-MSH receptor sites (functional antagonism), although a pharmacological antagonism cannot be excluded as yet.     

Hormonal regulation of serine dehydratase activity in primary cultures of adult rat hepatocytes

The capacity of the following peptides to stimulate steroidogenesis in suspensions of capsule (largely glomerulosa) and fasciculata/reticularis cells from rat adrenals was studied: ACTH_1–24, ACTH_1–13-amide, α-MSH, γ₁-MSH, γ-MSH precursor, ACTH_4–10, CLIP, and ovine and human β-lipotropin. Only α-MSH and ACTH_1–13-amide stimulated glomerulosa cells alone, without effect on fasciculata/reticularis cells. Like ACTH_1–24 the two samples of β-lipotropin stimulated both capsule and inner zone cell types in a similar manner. Their activity is attributable to slight ACTH_1–39 contamination, as shown by HPLC fractionation. The other peptides lacked any activity. It is likely that the predicted specific glomerulosa stimulant from the pituitary closely resembles α-MSH.     

α-MSH injected into the septal region reduces fever in rabbits

In previous research the concentration of α-MSH within the septal region of rabbits increased with fever. This finding raises the possibility that the septal concentration of this peptide, which reduces fever when given both peripherally and intracerebroventricularly, is important to limitation of fever. To test this idea, rabbits with cannulas in the septal region were made febrile by IV injections of leukocytic pyrogen (LP). Injection of α-MSH (1 μg bilaterally) into the septal region did reduce fever, consistent with the idea that the increase in septal α-MSH concentration which occurs naturally in fever limits the febrile response. We also noted late rises in body temperature when experimental and control septal injections were given close together in time. These increases in temperature were similar to those known to occur after injections into the primary temperature control in the PO/AH region. This commonality further strengthens the possibility that septal neurons are important to central modulation of body temperature.     

Effect of various ACTH analogs on lordosis behavior in the female rat

The effect of ACTH and various related analogs on lordosis behavior in female rats was compared with that produced by α-MSH. Ovariectomized rats received 2 μg estradiol benzoate on Day 1 and Day 3 either 0.1 or 0.2 mg progesterone. Four hours later the females were placed with sexually experienced male rats and the lordosis quotient (LQ) noted. These particular doses of progesterone were chosen because they were sub-maximal and produced a proportion of both nonreceptive (LQ less than 50%) and receptive (LQ greater than 50%) rats. Treatment with 20 μg α-MSH on Day 2 stimulated lordosis in nonreceptive rats but inhibited lordosis in the receptive rats.Of the other peptides tested only ACTH4–10 was as effective as α-MSH in facilitating and inhibiting lordosis behavior. ACTH1–24 and ACTH4–9 also produced both effects. ACTH1–39 and ACTH1–16, on the other hand, had neither effect but were both effective in stimulating and inhibiting lordosis when administered on Days 1, 2 and 3. It is suggested that ACTH4–10 may contain the essential sequence for these facilitatory and inhibitory effects on female sexual receptivity and that elongation of the peptide chain beyond ACTH 1–13 (α-MSH) may decrease this activity.     

Radioreceptor Assay for α;-Msh Using Mouse B16 Melanoma Cells

Abstract

A radioreceptor assay for α;-MSH is described which is based on cultured mouse B16 melanoma cells and bioactive monoiodinated [Nle⁴]-α;-MSH tracer. The assay was used (1) to study the binding characteristics of α;-MSH to B16 cells, (2) to determine the relative binding activity of MSH peptides, and (3) to measure MSH in tissue extracts. The association of α;-MSH to B16 cells reached a stable plateau after 3 h at 15°C. At 25° or 37°C, the binding was transient and at 0-1°C, the association was very slow. The hormone-receptor complex was relatively stable between 0° and 15°C whereas a 50% dissociation was reached after 90 min at 25°C and after 35 min at 37°C. The mean K_D for α;-MSH of four saturation experiments was 1.3 nM and the number of receptors 9570 per cell. 1,10-Phenanthroline had a stabilizing effect in the binding assay when used at a 0.3 mM concentration. From the MSH peptides tested in the binding assay, some showed similar potencies in three bioassays (tyrosinase, melanin and Anolis skin), whereas others displayed considerably     

Synthesis and biological activity of four gamma-melanotropin peptides derived from the cryuptic region of the adrenocorticotropin/beta-lipotropin precursor.

A third melanotropin coding fragment named γ-MSH was discovered by Nakanishi et al (Nature $\text{278}$, 423–427 (1979)) in the cryptic region outside the portion coding for ACTH and β-LPH in the ACTH/β-LPH precursor mRNA isolated from the intermediate lobe of bovine pituitary. Four possible γ-MSH peptides derived from this coding fragment were synthesized by solid-phase methodology and their bioactivity determined in an $\text{in vitro}$ MSH assay as well as the anterior pituitary primary culture assay. Relative to α-MSH, the melanotropic activities of Ac-γ₁-MSH, γ₁-MSH, γ₂-MSH and γ₃-MSH are 7.3 × 10^?4, 3.3 × 10^?5, 1.4 × 10^?4 and 4.6 × 10^?7 respectively. None of these γ-MSH peptides releases LH, FSH, PRL, GH and TSH in the pituitary culture medium at a dose as high as 100 ng per dish.     

Adrenocortical response to corticotropin is inhibited by gamma 3-MSH antisera in normotensive and spontaneously hypertensive rats

In order to further investigate the coordinate action of pro-corticotropin/endorphin-derived peptides on adrenal steroidogenesis, we have evaluated the effects of highly specific antisera to synthetic rat gamma 3-MSH (1-27) peptide (gamma 3-MSH Ab) on corticosterone, 18-hydroxycorticosterone and aldosterone responses to ACTH (1-24) in chronically cannulated spontaneously hypertensive rats (SHR) and their normotensive controls (WKY). Antisera eliminated the ACTH induced rise of all three corticosteroids. It had no effect on basal corticosteroid levels. Our results offer further evidence that the potentiating action of gamma 3-MSH may play an important role in modulating ACTH induced steroidogenesis.     

Characterization of Nα-acetylation of corticotropin fragments by a rat pituitary enzyme

The rat pituitary contains an enzyme which will acetylate certain corticotropin (ACTH) fragments using acetyl coenzyme A (AcCoA). This acetyltransferase activity was found in all three lobes of the rat pituitary. The enzyme was largely particulate in nature. The enzyme sedimenting at 27,000 and 100,000g had specific activities 4–10 times greater than the soluble fraction. The acetyltransferase activity was dependent on substrate concentration (ACTH), was linear with time, and was inactivated at 55 °C. The enzyme would acetylate ACTH (1–24), (1–10), and (4–10), but would not use ACTH (2–10), (3–10), or (1–8) as substrates. The apparent K_m values for the substrates were as follows: AcCoA, 2.2 μm ACTH (1–24), 4.2 μm; ACTH (1–10), 96 μm; and ACTH (4–10), 37 μm.     

Immunohistochemical Identification of the Adenohypophysial Cells in the Indian Paddy Field Frog,Rana limnocharis

Cells of the pituitary pars distalis (PD) and pars intermedia (PI) in the frog Rana limnocharis have been identified by an unlabelled antibody enzyme method using antisera developed in rabbit against mammalian hypophysial hormones. On the basis of their immunoreactivity, six types of cells, viz. thyrotropic (TSH), gonadotropic (GTH), prolactin (PRL), growth hormone (GH), corticotropic (ACTH) and melanotropic (MSH), cells have been recognized. GTH and PRL cells are distributed throughout the PD. GH cells usually occur in the anterodorsal and central region of the gland. Immunoreactive TSH cells are fewer in number and are localized in the ventromedian region of the PD. Cells showing immunoreactivity to ACTH 1–24 antiserum are encountered in the rostroventral part of the PD. Cells of the PI also show immunoreactivity to ACTH 1–24 antiserum. PI cells cross-react with α-MSH antiserum at all dilutions up to 1: 50 000. However, when the same antiserum was used at dilutions up to 1: 20 000, the ACTH cells of the PD also showed cross-reactivity.