Cellular Aspects of the Control of Physiological Color Changes in Amphibians

SYNOPSIS. The present paper is concerned mainly with the melanin-dispersingeffect of melanocyte-stimulating hormones (MSH's) on the skinmelanophores of amphibians. In addition, some of the more recentevidence for the unihumoral theory of the control of color changeis reviewed. The mechanism of dispersion of melanin is stillunknown, but evidence is accumulating that the action of MSHmay be mediated by an increase in the melanophoric content ofadenosine 3', 5'-monophosphate (cyclic AMP). For example, cyclicAMP has a specific, reversible melanin-dispersing effect onthe melanophores of the isolated skin of R. pipiens and Xenopuslaevis. It also has a reversible "melanophore—expanding"effect on the tissue—cultured embryonic melanophores ofthe spotted salamander, Ambystoma maculatum. The effect of cyclicAMP on melanophores of R. pipiens does not require sodium butis inhibited by hypertonicity. Finally, new evidence is presented that confirms that the melanin-dispersingeffect of catecholamines on melanophores of X. laevis is mediatedby beta adrenergic receptors,because it is blocked by the highlyspecific ß—blocking agent, propranolol. On theother hand, the melanin-aggregating effect of catecholamineson amphibian melanophores appears to be mediated by alpha adrenergicreceptors. There is even a possibility that the effects of catecholaminesare also mediated through a control of cyclic AMP levels inmelanophores, with beta adrenergic stimulation producing anincrease in cyclic AMP levels, followed by dispersion of melanin,and alpha adrenergic stimulation producing a decrease in cyclicAMP levels, followed by aggregation of melanin.     

Chromatophores and color change in the lizard,Anolis carolinensis

Summary The skin of the lizard, Anolis carolinensis, changes rapidly from bright green to a dark brown color in response to melanophore stimulating hormone (MSH). Chromatophores responsible for color changes of the skin are xanthophores which lie just beneath the basal lamina containing pterinosomes and carotenoid vesicles. Iridophores lying immediately below the xanthophores contain regularly arranged rows of reflecting platelets. Melanophores containing melanosomes are present immediately below the iridophores. The ultrastructural features of these chromatophores and their pigmentary organelles are described. The color of Anolis skin is determined by the position of the melanosomes within the melanophores which is regulated by MSH and other hormones such as norepinephrine. Skins are green when melanosomes are located in a perinuclear position within melanophores. In response to MSH, they migrate into the terminal processes of the melanophores which overlie the xanthophores above, thus effectively preventing light penetration to the iridophores below, resulting in skins becoming brown. The structural and functional characteristics of Anolis chromatophores are compared to the dermal chromatophore unit of the frog.This study was supported in part by GB-8347 from the National Science Foundation.Contribution No. 244, Department of Biology, Wayne State University.The authors are indebted to Dr. Joseph T. Bagnara for his encouragement during the study and to Dr. Wayne Ferris for his advice and the use of his electron microscope laboratory.     

Photoaffinity Labelling of MSH Receptors on Anolis Melanophores: Effects of Catecholamines,Calcium and Forskolin

Abstract

Photoaffinity labelling of MSH receptors on Anolis melanophores was used as a tool for studying the effects of catecholamines, calcium and forskolin on hormone-receptor interaction and receptor-adenylate cyclase coupling. Covalent attachment of photoreactive α-MSH to its receptor was suppressed in calcium-free buffer but was hardly influenced by catecholamines or forskolin. The longlasting signal generated by the covalent MSH-receptor complex was readily and reversibly abolished by adrenaline, noradrenaline, dopamine or clonidine or by the absence of calcium. The suppression of pigment dispersion by catecholamines was blocked by the simultaneous presence of yohimbine but not prazosin, indicating that the catecholamines antagonize the α-MSH signal by inhibitory action on the adenylate cyclase system through an alpha-2 receptor. Forskolin, which stimulates melanophores by direct action on the catalytic unit of the adenylate cyclase and at about the same speed as α-MSH, produced a slower and weaker response in the presence of noradrenaline. If MSH receptors were covalently labelled and then exposed to noradrenaline, the characteristics of the forskolin-induced response were identical to those of unlabelled cells that had not been exposed to noradrenaline. This may point to a partial restoration of receptor-adenylate cyciase coupling by forskolin. The results show that the longlasting stimulation of Anolis melanophores by photoaffinity labelling proceeds via a permanently stimulated adenylate-cyclase system whose coupling to the receptor depends on calcium and is abolished by alpha-2 receptor agonists. Calcium is also essential for hormone-receptor binding.     

Action of melanophore-stimulating hormone on melanophores of the cyprinid fish Zacco temmincki

1. Alpha MSH was extremely effective in inducing melanosome dispersion in both innervated and denervated melanophores in isolated scales of Zacco termmincki. 2. The sensitivity of the melanophores to MSH did not change after denervation. 3. The MSH action was blocked by mersalyl, a SH inhibitor, but not by any of alpha and beta adrenergic blockers. 4. Ca2+ was required for the MSH action, but not for melanosome dispersion itself, since the beta adrenergic response was normally produced in the absence of this ion. 5. Mg2+, Sr2+ and Ba2+ could not replace the Ca2+. 6. Mn2+ reversibly inhibited the MSH action.     

Synthesis and biological actions of melanin concentrating hormone

A melanin (melanosome) concentrating hormone, MCH, was synthesized and the methodology for its synthesis is detailed. This heptadecapeptide, H-Asp-Thr-Met-Arg-Cys-Met-Val-Gly-Arg-Val-Tyr-Arg-Pro-Cys-Trp-Glu-Val-OH , stimulated melanosome concentration (centripetal aggregation) within melanophores of all species of teleost fishes studied. Melanosome aggregation in response to MCH was not blocked by Dibenamine as was the response to norepinephrine (NE), demonstrating that melanosome aggregating responses to MCH and NE are mediated through separate receptors. Melanosome aggregation in response to MCH was reversed by an equimolar concentration of alpha-melanocyte stimulating hormone (alpha-MSH). In contrast, MCH stimulated melanosome dispersion (centrifugal movement) within melanophores of a frog (Rana pipiens) and a lizard (Anolis carolinensis). Therefore, MCH exhibits both melanosome concentrating and dispersing actions depending upon the species studied.     

Berberine-induced pigment dispersion in Bufo melanostictus melanophores by stimulation of beta-2 adrenergic receptors

Abstract

Reduced production of melanin by decreased or the absence of melanocytes leads to various hypopigmentation disorders, and the development of melanogenetic agents for photoprotection and hypopigmentation disorders is one of the top priority areas of research. Hence, the present study was carried out to elucidate the ability of berberine, a principal active ingredient present in the roots of the herb Berberis vulgaris to stimulate pigment dispersion in the isolated skin melanophores of the toad Bufo melanostictus. In the present study, mean melanophore size index of the isolated skin melanophores of B. melanostictus was assayed after treating with various concentrations of berberine. A marked melanin dispersion response leading to skin darkening was observed in the isolated melanophores of toad in response to berberine, which was found to be mediated through beta-2 adrenergic receptors. The physiologically significant dose-related melanin dispersion effects of berberine per se were found to be completely abolished by propranolol, which is a specific beta-2 adrenergic receptor blocker. These per se melanin dispersal effects were also found to be markedly potentiated by isoprenaline, which is a specific beta-adrenoceptor agonist. The results indicate that berberine causes a tremendous, dose-dependent, physiologically significant pigment dispersing in the isolated skin melanophores of B. melanostictus.     

The role of calcium in MSH stimulated melanosome dispersion

We have examined the role of the calcium ion in the response of the melanophores of the lizard, Anolis carolinensis to alpha-melanocyte stimulating hormone (alpha-MSH) by a rate method which allows kinetic analysis of melanosome dispersion. Dose-response curves to alpha-MSH were compared in the presence of different calcium concentrations, and Schild regression plots were constructed. An avidly binding analogue of alpha-MSH, Nle4-D-Phe7-alpha-MSH, was used to demonstrate kinetically the involvement of calcium in the melanophore response both for MSH receptor binding and the subsequent transduction of the MSH signal across the melanophore membrane.     

Basic properties of beta adrenergic receptors mediating melanosome dispersion of melanophores in a cyprinid fish, Zacco temmincki

In melanophores of a cyprinid fish, Zacco temmincki, receptor mechanisms of melanosome dispersion induced by catecholamines were examined. While possessing a melanosome-aggregating action in higher concentrations, isoproterenol and epinephrine in lower concentrations acted to disperse melanosomes. Norepinephrine, epinine and dopamine altered their action from melanosome aggregation to melanosome dispersion after alpha adrenergic blockade. The catecholamine-induced melanosome dispersion was inhibited by beta adrenergic blocking agents. Mediation of dispersion is regulated through beta adrenergic receptors. The beta adrenergic responses were unaffected by mersalyl, a sulfhydryl inhibitor. A prospective substance acting in dispersing melanosomes appears to be adrenaline, but not noradrenaline.     

Peptides Containing Multiple Photolabels: A new Tool for the Analysis of Ligand-Receptor Interactions: Reversible Long-lasting Stimulation and Inhibition of MSH Receptors by Multiple Photocrosslinks with α-MSH

Abstract

Crosslinking of MSH receptors on melanophores of the lizard Anolis carolinensis with analogues of α-MSH containing a photoreactive group in position 1, 7, 9 or 13 leads to long-lasting receptor stimulation. Reversibility of this long-lasting stimulation is obtained by employing a disulfide-containing photoreactive group which can be cleaved from the receptor by thiol reagents [Ref. 3]. When two photo-reactive groups are simultaneously present on the α-MSH molecule (e.g in positions 1 + 9; 1 + 13; 7 + 13, or 9 + 13), identical results were obtained and long-lasting receptor stimulation was not altered after cleavage of one single crosslink. α-MSH analogues with three photoreactive groups in positions 1 + 7 + 13 led to irreversible receptor stimulation whereas one compound with the photoreactive groups in positions 1 + 9 + 13 induced reversible receptor inactivation which could be changed into long-lasting stimulation by cleaving the crosslink at position 1 of α-MSH. These results demonstrate that one and the same peptide ligand may contain structural information for both receptor activation and inhibition and that the receptor may become arrested in an activated or inhibited state by multiple photocrosslinking, depending on the relative positions of these crosslinks.     

Comparative analyses of the pigment-aggregating and -dispersing actions of MCH on fish chromatophores

In melanophores of the peppered catfish and the Nile tilapia, melanin-concentrating hormone (MCH) at low doses (<1 μM) induced pigment aggregation, and the aggregated state was maintained in the presence of MCH. However, at higher MCH concentrations (such as 1 and 10 μM), pigment aggregation was immediately followed by some re-dispersion, even in the continued presence of MCH, which led to an apparent decrease in aggregation. This pigment-dispersing activity at higher concentrations of MCH required extracellular Ca²⁺ ions. By contrast, medaka melanophores responded to MCH only by pigment aggregation, even at the highest concentration employed (10 μM). Since it is known that medaka melanophores possess specific receptors for α-melanophore-stimulating hormone (α-MSH), the possibility that interaction between MSH receptors and MCH at high doses in the presence of Ca²⁺ might cause pigment dispersion is ruled out. Cyclic MCH analogs, MCH (1–14) and MCH (5–17), failed to induce pigment dispersion, whereas they induced aggregation of melanin granules. These results suggest that another type of MCH receptor that mediates pigment dispersion is present in catfish and tilapia melanophores, and that intact MCH may be the only molecule that can bind to these receptors. Determinations of cAMP content in melanophores, which were isolated from the skin of three fish species and treated with 10 nM or 10 μM MCH, indicate that MCH receptors mediating aggregation may be coupled with Gi protein, whereas MCH receptors that mediate dispersion may be linked to Gs. The response of erythrophores, xanthophores and leucophores to MCH at various concentrations was also examined, and the results suggest that the distribution patterns of the two types of MCH receptors may differ among fish species and among types of chromatophore in the same fish.     

Calcium-dependent irreversible effect of ionophore A23187 on melanophores

The calcium ionophore, A231187, induces a Ca2+ -dependent movement (dispersion) of melanosomes within skin melanophores of the lizard, Anolis carolinensis, in vitro. The effects of A23187 are irreversible, since after repeated rinsing of the skins in the absence of the ionophore they will always darken in Ringer containing Ca2+ but will immediately lighten when transferred to Ca2+ -free Ringer. These results suggest that the ionophore is irreversibly localized to the melanophore membrane and that its melanosome-dispersing effect is continuously dependent upon extracellular calcium.     

Interaction and developmental activation of two neuroendocrine systems that regulate light‐mediated skin pigmentation

Lower vertebrates use rapid light‐regulated changes in skin colour for camouflage (background adaptation) or during circadian variation in irradiance levels. Two neuroendocrine systems, the eye/alpha‐melanocyte‐stimulating hormone (α‐MSH) and the pineal complex/melatonin circuits, regulate the process through their respective dispersion and aggregation of pigment granules (melanosomes) in skin melanophores. During development, Xenopus laevis tadpoles raised on a black background or in the dark perceive less light sensed by the eye and darken in response to increased α‐MSH secretion. As embryogenesis proceeds, the pineal complex/melatonin circuit becomes the dominant regulator in the dark and induces lightening of the skin of larvae. The eye/α‐MSH circuit continues to mediate darkening of embryos on a black background, but we propose the circuit is shut down in complete darkness in part by melatonin acting on receptors expressed by pituitary cells to inhibit the expression of pomc, the precursor of α‐MSH.     

THE MELANOCYTE MODEL : Colchicine-like Effects of Other Antimitotic Agents

The effect of various agents that cause metaphase arrest in dividing cells was studied on the rapid reversible darkening of frog skin under the influence of melanocyte-stimulating hormone (MSH). Darkening is due to dispersion of melanin granules in melanocytes and is thought to be accompanied by a gel-to-sol cytoplasmic transformation. After subsequent washing the skin lightens, with aggregation of melanin granules and cytoplasmic gelation. As previously shown with colchicine, preincubation of frog skin with vinblastine, vincristine, or colcemid produced an increase in darkening induced by MSH, as compared to control skins, and a dosage-dependent inhibition of subsequent lightening. Preincubation with each drug, without subsequent MSH, produced a gradual, irreversible, dosage-dependent darkening over several hours. On a molar basis, the relative strength of the various agents was vinblastine > vincristine > colcemid > colchicine; vinblastine was about 100 times stronger than colchicine. Preincubation of frog skin with griseofulvin, followed by washing, had no subsequent effects on darkening or lightening. However, effects similar to those of the Colchicum and Vinca alkaloids were seen if griseofulvin was kept in the ambient media. These effects were rapidly reversible on removal of the drug from the media. These findings support the melanocyte model originally proposed for the action of colchicine, and emphasize certain facts that models of melanin granule movement will have to accommodate.     

Biosensing of opioids using frog melanophores

Spectacular color changes of fishes, frogs and other lower vertebrates are due to the motile activities of specialized pigment containing cells. Pigment cells are interesting for biosensing purposes since they provide an easily monitored physiological phenomenon. Melanophores, containing dark brown melanin pigment granules, constitute an important class of chromatophores. Their melanin-filled pigment granules may be stimulated to undergo rapid dispersion throughout the melanophores (cells appear dark), or aggregation to the center of the melanophores (cells appear light). This simple physiological response can easily be measured in a photometer. Selected G protein coupled receptors can be functionally expressed in cultured frog melanophores. Here, we demonstrate the use of recombinant frog melanophores as a biosensor for the detection of opioids. Melanophores were transfected with the human opioid receptor 3 and used for opiate detection. The response to the opioid receptor agonist morphine and a synthetic opioid peptide was analyzed by absorbance readings in an aggregation assay. It was shown that both agonists caused aggregation of pigment granules in the melanophores, and the cells appeared lighter. The pharmacology of the expressed receptors was very similar to its mammalian counterpart, as evidenced by competitive inhibition by increasing concentrations of the opioid receptor inhibitor naloxone. Transfection of melanophores with selected receptors enables the creation of numerous melanophore biosensors, which respond selectively to certain substances. The melanophore biosensor has potential use for measurement of substances in body fluids such as saliva, blood plasma and urine.     

A rapid quantitative bioassay for evaluating the effects of ligands upon receptors that modulate cAMP levels in a melanophore cell line.

A new method for rapidly evaluating the effects of drugs on receptors that regulate intracellular cAMP in a cell line derived from Xenopus laevis melanophores has been developed. Melanophores were plated into sterile 96 well microtiter plates, and 3 days later the cells were treated with melatonin for 30 min to induce melanosome aggregation. Subsequent exposure to MSH or adrenergic agonists caused dose dependent pigment dispersion that peaked within 30 min. The cumulative pigment displacement from cells could be quantitated by using a microplate reader to measure changes in transmittance of light through the wells. The acquired data enabled detailed and reproducible dose response curves and time course analyses to be generated. In addition, the assay followed for the rapid characterization of the effects of antagonists upon the beta adrenergic receptor (beta AR). The assay has the potential to test the effects of ligands upon any receptor capable of mediating pigment translocation in the melanophore cell line.     

Regulation of Organelle Movement in Melanophores by Protein Kinase A (PKA), Protein Kinase C (PKC), and Protein Phosphatase 2A (PP2A)

We used melanophores, cells specialized for regulated organelle transport, to study signaling pathways involved in the regulation of transport. We transfected immortalized Xenopus melanophores with plasmids encoding epitope-tagged inhibitors of protein phosphatases and protein kinases or control plasmids encoding inactive analogues of these inhibitors. Expression of a recombinant inhibitor of protein kinase A (PKA) results in spontaneous pigment aggregation. α-Melanocyte-stimulating hormone (MSH), a stimulus which increases intracellular cAMP, cannot disperse pigment in these cells. However, melanosomes in these cells can be partially dispersed by PMA, an activator of protein kinase C (PKC). When a recombinant inhibitor of PKC is expressed in melanophores, PMA-induced pigment dispersion is inhibited, but not dispersion induced by MSH. We conclude that PKA and PKC activate two different pathways for melanosome dispersion. When melanophores express the small t antigen of SV-40 virus, a specific inhibitor of protein phosphatase 2A (PP2A), aggregation is completely prevented. Conversely, overexpression of PP2A inhibits pigment dispersion by MSH. Inhibitors of protein phosphatase 1 and protein phosphatase 2B (PP2B) do not affect pigment movement. Therefore, melanosome aggregation is mediated by PP2A.     

Transformation of amphibian iridophores into melanophores in clonal culture.

Iridophores isolated from bullfrog tadpoles were successfully cloned. In primary culture, the iridophores showed contraction of cell bodies by the addition of alkali-treated ACTH. The disappearance of reflecting platelets occurred in proliferating iridophores and many small black melanin granules were synthesized in the cells. The chromatophores now showed melanin dispersion by the addition of the above hormone. The findings suggest that iridophores transform into melanophores in vitro.     

A comparison of structure-activity relationships within alpha-MSH on melanophores of Anolis carolinensis and Rana pipiens

We have compared the structure-function relationship of the tridecapeptide alpha-melanocyte stimulating hormone (alpha-MSH) on the melanophores of the lizard Anolis carolinensis and the frog Rana pipiens by determining the melanosome-dispersing potency of 15 shorter peptide sequences and 8 substituted alpha-MSH analogues. Major differences were found between the lizard and the frog in their response to alpha-MSH peptide fragments and analogues. In Anolis, the sequence Ser-Tyr-Ser- is not as important for the pigmentary response as in Rana since alpha-MSH-(4-13) was nearly as potent (89%) as alpha-MSH-(1-13) (100%), whereas in Rana alpha-MSH-(4-13) potency was reduced to 7.5%. In addition, loss of potency due to removal of residues Pro and Val was more marked in Rana (alpha-MSH-(1-11) = 0.1%) than in Anolis (alpha-MSH-(1-11) = 1%), suggesting that this C-terminal sequence is necessary for pigmentary activity in the frog melanophore. These results together with those of other peptide fragments and analogues have led us to define the minimal pigmentary sequence of alpha-MSH as alpha-MSH-(4-12) in Anolis in contrast to alpha-MSH-(1-13) in Rana. This suggests that Anolis and Rana alpha-MSH receptors recognise different message amino acids of the alpha-MSH peptide sequence even though the final response (melanosome dispersion) is the same.     

Fibronectin-induced migration of melanophores in vitro in scales of medaka,Oryzias latipes

Summary The effects of fibronectin on melanophores were examined in two mutant strains of medaka, Oryzias latipes: mm (BmmR), which has condensed melanophores and normal dendritic melanophores; and cm (BcmR), which has condensed melanophores. When medaka scales were cultured in the presence of fibronectin, melanophores of the wild type and dendritic melanophores of the mm mutant changed their shape and migrated, whereas melanophore migration was rarely seen in the absence of fibronectin. Melanophores of the cm mutant and condensed melanophores of the mm mutant did not migrate even in the presence of fibronectin. When melanophores of the wild type and mm mutant were condensed by adrenalin, they did not migrate. On the other hand, when melanophores of the cm mutant were dispersed by theophylline, they were able to migrate. These results indicate that fibronectin induces the migration of melanophores and that dispersion of melanin granules may be requisite for such migration.     

Effect of cyclic AMP and cytochalasin B on tissue cultured melanophores of Xenopus laevis

The effects of cytochalasin B or low concentrations of adenosine 3′,5′-monophosphate (cyclic AMP) were tested on melanophores in hanging drop preparations of neural fold explants from Xenopus laevis embryos in Barths' solution. After one week in culture, the melanophores were punctate in this medium. Cyclic AMP at 5 mM consistently caused reversible morphological transformation of these cells to the stellate state, whether they were situated within an epithelial outgrowth or isolated on the surface of the coverglass. Only the isolated melanophores consistently responded to 1 mM cyclic AMP. Cytochalasin B at 1–10 μg/ml caused aggregation of melanin granules in stellate cells, but left long, narrow cell branches containing some melanosomes. Its effect was at least partially reversible and appeared to be dose dependent. At 1% concentration, dimethyl sulfoxide caused melanin dispersion.