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.     

Pigment cell mechanisms underlying dorsal color‐pattern polymorphism in the japanese four‐lined snake

To provide histological foundation for studying the genetic mechanisms of color‐pattern polymorphisms, we examined light reflectance profiles and cellular architectures of pigment cells that produced striped, nonstriped, and melanistic color patterns in the snake Elaphe quadrivirgata. Both, striped and nonstriped morphs, possessed the same set of epidermal melanophores and three types of dermal pigment cells (yellow xanthophores, iridescent iridophores, and black melanophores), but spatial variations in the densities of epidermal and dermal melanophores produced individual variations in stripe vividness. The densities of epidermal and dermal melanophores were two or three times higher in the dark‐brown‐stripe region than in the yellow background in the striped morph. However, the densities of epidermal and dermal melanophores between the striped and background regions were similar in the nonstriped morph. The melanistic morph had only epidermal and dermal melanophores and neither xanthophores nor iridophores were detected. Ghost stripes in the shed skin of some melanistic morphs suggested that stripe pattern formation and melanism were controlled independently. We proposed complete‐ and incomplete‐dominance heredity models for the stripe‐melanistic variation and striped, pale‐striped, and nonstriped polymorphisms, respectively, according to the differences in pigment‐cell composition and its spatial architecture. J. Morphol. 274:1353–1364, 2013. © 2013 Wiley Periodicals, Inc.     

Dermal and epidermal chromatophores of the Antarctic teleost Trematomus bernacchii

The physiological response and ultrastructure of the pigment cells of Trematomus bernacchii, an Antarctic teleost that lives under the sea ice north of the Ross Ice Shelf, were studied. In the integument, two types of epidermal chromatophores, melanophores and xanthophores, were found; in the dermis, typically three types of chromatophores--melanophores, xanthophores, and iridophores--were observed. The occurrence of epidermal xanthophore is reported for the first time in fish. Dermal melanophores and xanthophores have well-developed arrays of cytoplasmic microtubules. They responded rapidly to epinephrine and teleost melanin-concentrating hormone (MCH) with pigment aggregation and to theophylline with pigment dispersion. Total darkness elicited pigment aggregation in the majority of dermal xanthophores of isolated scales, whereas melanophores remained dispersed under both light and dark conditions. Pigment organelles of epidermal and dermal xanthophores that translocate during the pigmentary responses are carotenoid droplets of relatively large size. Dermal iridophores containing large reflecting platelets appeared to be immobile.     

alpha-MSH (melanocyte stimulating hormone) and MCH (melanin concentrating hormone) actions in Bufo ictericus ictericus melanophores

1. The darkening actions of MCH (melanin concentrating hormone), alpha-MSH and the synthetic analog [Nle4, D-Phe7]-alpha-MSH on the toad, Bufo ictericus ictericus, melanophores were studied regarding the role of calcium in the hormone receptor coupling, signal transduction and intracellular pigment translocation. 2. In the absence of external calcium, MCH and both melanotropins still elicit maximal skin darkening. 3. Verapamil, a calcium-channel blocker, completely abolishes the alpha-MSH-induced response and partially inhibits MCH-induced darkening, although the calcium carrier, ionophore A23187, was unable to promote any pigment translocation. 4. Since darkening responses promoted by cyclic nucleotides proceeded normally in the presence of verapamil and extracellular calcium was not necessary for melanotropin dispersing action, it is suggested that the blocking activity obtained with verapamil is probably due to an impairment of the Ca2+-dependent adenylate cyclase activity. 5. Reversal of melanotropin-induced darkening could be obtained with melatonin, in both normal and Ca2+-free Ringer, whereas MCH darkening is reversed by melatonin only in the absence of calcium. 6. The results seem to indicate that calcium is not required for hormone receptor binding and pigment migration, whereas it is specifically needed for signal transduction.     

Observations on the ultrastructure and distribution of chromatophores in the skin of chelonians

Alibardi, L. 2011. Observations on the ultrastructure and distribution of chromatophores in the skin of chelonians. —Acta Zoologica (Stockholm) 00 :1–11. The cytology and distribution of chromatophores responsible for skin pigmentation in chelonians is analyzed. Epidermal melanocytes are involved in the formation of dark spots or stripes in growing shelled and non‐shelled skin. Melanocytes rest in the basal layer of the epidermis and transfer melanosomes into keratinocytes during epidermal growth. Dermal melanophores and other chromatophores instead remain in the dermis and form the gray background of the skin. When dermal melanophores condense, they give origin to the dense spots or stripes in areas where no epidermal melanocytes are present. In the latter case, the epidermis and the corneous layer are transparent and reveal the dermal distribution of melanophores and other chromatophores underneath. As a result of this basic process of distribution of pigment cells, the dark areas visible in scales can have a double origin (epidermal and dermal) or a single origin (epidermal or dermal). Xanthophores, lipophores, and a cell containing both pterinosomes and lipid droplets are sparse in the loose dermis while iridophores are rarely seen in the skin of chelonians analyzed in the present study. Xanthophores and lipophores contribute to form the pale, yellow or oranges hues present among the dark areas of the skin in turtles.     

Response of the chromatophores in relation to the healing of skin wounds in an Indian Major Carp, Labeo rohita (Hamilton)

Chromatophores show significant changes during healing of skin wounds in Labeo rohita (Common Name - Rohu). Wound area can be divided into regions I, II and III. After infliction of wound, skin colour becomes significantly dark by 2 h that is gradually restored by 2 d. In regions II and III at 5 min, epidermal melanophores appear with beaded dendrites. In these regions at 2 h and in region I at 6 h, epidermal melanophores appear small, rounded or irregular shaped having dendritic processes with aggregated melanosomes. Subsequently, melanophores appear having elongated dendrites with dispersed or aggregated melanosomes. At 24 h, clusters of pigmented bodies appear in regions I and II. These bodies increase up to 2 d, and then diminish gradually and disappear by 8 d. Changes in dermal melanophores in region II at 5 min indicate the onset of degeneration. Degenerating melanophores increase up to 12 h, then gradually decline, and disappear by 4 d. Simultaneously, stellate melanophore reappear, gradually increase and appear like control by 8 d. Dermal melanophores in region III at different intervals appear stellate. In region I stellate dermal melanophores appear at 4 d. Stellate melanophores in all regions show different distribution of dispersed or aggregated melanosomes. With the appearance of dermal melanophores, highly refractive, crystalline structures, possibly the refractive platelets of the iridophores, are visualized around them. At subsequent intervals, these are frequently observed. This study provides interesting insights in injury induced changes in chromatophores in fish. The findings could be considered useful in perception of intriguing features in the development of pigment research in future.     

Melatonin does not affect the black pigment migration in the crab Neohelice granulata

N-acetyl-5-methoxytryptamine or melatonin is a multifunctional molecule. The main physiological function, at least in vertebrates, is to transduce to the animal the photoperiodic information and regulate rhythmic parameters. But studies have also observed the action of this molecule on pigment migration in ectothermic vertebrates. Thus the aim of this paper was to investigate in vivo and in vitro the influence of melatonin on the pigment migration in melanophores of the crab Neohelice granulate. Injections of melatonin (2 × 10⁻⁹ moles · crab⁻¹) at 07:00 h or 19:00 h did not affect (p > 0.05) the circadian pigment migration of the melanophores in constant darkness. Additionally no significant pigment migration (p > 0.05) was verified in normal and eyestalkless crabs injected with melatonin (10⁻¹⁰–10⁻⁷ moles · crab⁻¹) during the day or night. In the ^{in vitro} assay, the response of melanophores to the pigment-dispersing hormone in eyestalkless crabs injected with melatonin (2 × 10⁻⁹ moles · crab⁻¹) 1 and 12 hours before the observations did not differ (p > 0.05) from the control group (injected with physiological solution). These results suggest that melatonin does not act as a signaling factor for pigment dispersion or aggregation in the melanophores of N. Granulate.     

Analyzing the responses of saccharin in context with melatonin receptors on the melanophores of the fish Labeo rohita (Ham.)

The hormone melatonin regulates the biological clock and assist in various other physiologies of vertebrates. Present work is intended to check the affinity of saccharin towards the melatonin receptors and the possible role of saccharin interference in the melatonin physiology. The present in vitro study is based on the working model of isolated scale melanophores in the dorso-lateral region of Labeo rohita. The pigment cells were incubated in the agonist and the antagonists within a limited time frame and subsequently their Melanophore Size Index (MSI) were calculated. The inferences were drafted through the observed signal transduction upshots in pigment translocations within the melanophores. Saccharin, in a wide dose range, has consistently induced a concentration-related aggregation similar to the aggregatory effect as shown by melatonin on the melanophores. Binding of saccharin with the receptors and eliciting its aggregatory effect is partially dependent on the release of neurotransmitters. The aggregatory effects were found to be significantly blocked by luzindole, K185, and prazosin, which are the potent melatonin receptor blockers, at the higher concentrations of saccharin. Hence, all the three subtypes of melatonin receptors viz. MT₁, MT₂, and MT₃ are participating in saccharin-mediated aggregations. Blocking by neomycin shows that Ca²⁺ ions are very crucial in dispensing the aggregatory effect of the sweetener. This research demands that an intensive and careful thorough study should be made about saccharin, specifically its effects upon melatonin physiology, before its unwarranted use as the food ingredients for human use.     

Effect of melanin concentrating hormone on pigment and adrenal cells in vitro

Highly purified synthetic salmonid melanin concentrating hormone (MCH) and some analogs were investigated for their ability to concentrate the pigment in scale melanophores of the Chinese grass carp, Ctenopharyngodon idellus, to produce melanin dispersion in frog or lizard melanophores and to inhibit alpha-MSH in its action on mouse melanoma and rat adrenal glomerulosa cells in vitro. In the grass carp, MCH produced half-maximal pigment aggregation at 6 X 10(-11) M and its oxidized form at 7 X 10(-11) M. Replacement of the two methionines at position 3 and 6 with norvaline lowered the potency by a factor of 2.7 and with propargylglycine by a factor of about 7. Linear, Cys5,14-Acm-protected MCH was a full agonist of MCH but with a 345-fold lower potency. Iodinated MCH showed similar, low activity. In tetrapods, salmonid MCH and its analogs displayed only marginal pigment dispersion at concentrations greater than 10(-5) M. Alkali-treatment of MCH increased the pigment-dispersing potency by a factor of about 30 whereas the activity for pigment aggregation in the grass carp was destroyed. At high concentrations (10(-6), 10(-5) M) MCH also stimulated tyrosinase activity in B-16 mouse melanoma cells but did not modify the effects of alpha-MSH in this system. By contrast, when tested on rat adrenal glomerulosa cells, salmonid MCH had no effect alone but at a concentration of greater than 10(-10) M it slightly reduced corticosterone production by an alpha-MSH concentration of 10(-7) M. Aldosterone production was not affected and MCH did not influence the response to ACTH.     

Melatonin desensitizing effects on the in vitro responses to MCH,alpha-MSH,isoproterenol and melatonin in pigment cells of a fish (S. marmoratus), a toad (B. ictericus), a frog (R. pipiens), and a lizard (A. carolinensis), exposed to varying photoperiodic regimens

Melatonin is a weak dose-independent lightening agonist in fish skin, a moderate dose-dependent lightening agonist in toad skin and a potent lightening agent in frog and lizard skins (reversing in a dose-dependent manner the darkening caused by alpha-melanocyte-stimulating hormone). In frog skins, previous exposure to melatonin reduced further lightening actions of the indoleamine, and in toad skins, increasing concentrations of melatonin elicited decreasing lightening responses, suggesting an autodesensitizing action of the hormone. Various concentrations of melatonin diminished the responses to the lightening agonist melanin-concentrating hormone (MCH) in fish skins and to the darkening agonists alpha-MSH in toad, frog and lizard skins and isoproterenol in frog skins. In vitro inhibitory actions of melatonin are mimicked in the absence of the hormone in skin preparations from toads kept in continuous darkness for 48 hr. The lipophylic nature of the indoleamine associated with the results herein described suggests intracellular actions of melatonin on vertebrate pigment cells.     

Novel receptors for melatonin that mediate pigment dispersion are present in some melanophores of the pencil fish (Nannostomus)

1. Comparing the daytime and the night-time pigmentary patterns of the skin of the pencil fish, Nannostomus beckfordi, we noticed that specific regions of dark spots that were part of the night-time pattern became pale during the day.2. Microscopic observations revealed that melanosomes in the melanophores in those regions were aggregated during the day but became dispersed at night.3. These melanophores responded to melatonin by dispersal of melanosomes while the cells on other parts of the body responded to melatonin by aggregation of the pigment in the normal way.4. The melanophores that responded to melatonin by pigment dispersion responded normally to other hormones and neurotransmitters, as did those on other parts of the skin.5. The results indicate that, in addition to the known melatonin receptor that mediates the aggregation of melanosomes, there also exists an unusual receptor which mediates the dispersion of pigment in melanophores. We have tentatively designated this receptor the ‘beta-melatonin receptor’.     

Melanocyte stimulating hormone and melanin concentration hormone may be structurally and evolutionarily related

Two melanotropic peptides, melanin concentration hormone (MCH) and alpha-melanocyte stimulating hormone (alpha-MSH), exert opposing actions on melanosome (melanin granule) movements within teleost pigment cells, melanocytes (melanophores). MCH stimulates melanosome aggregation to the cell center whereas alpha-MSH stimulates pigment organelle dispersion out into the dendritic processes of the melanocytes. The actions of alpha-MSH are dependent upon extracellular calcium (Ca2+), whereas those of MCH are actually enhanced in the absence of the cation. At high concentrations (10(-5)-10(-8) M) MCH also exhibits MSH-like activity (autoantagonism), an effect which is abolished in the absence of Ca2+. Therefore, MCH exhibits MCH-like as well as MSH-like activity depending on the presence or absence of extracellular Ca2+. An analogue of MCH, [Ala5, Cys10]MCH, has been synthesized which is totally devoid of MCH activity but still exhibits MSH-like activity. These results suggest that the two melanotropic peptides share some component of structural similarity and may be evolutionarily related.     

5-HT receptor subtypes as key targets in mediating pigment dispersion within melanophores of teleost,Oreochromis mossambicus

The presence of distinct class of 5-HT receptors in the melanophores of tilapia (Oreochromis mossambicus) is reported. The cellular responses to 5-HT (5-hydroxytryptamine), 5-HT₁, and 5-HT₂, agonists on isolated scale melanophores were observed with regard to pigment translocation within the cells. It was found that 5-HT exerted rapid and strong concentration dependent pigment granule dispersion within the melanophores. The threshold pharmacological dose of 5-HT that could elicit a measurable response was as low as 4.7 × 10^? 12 M/L. Selective 5-HT₁ and 5-HT₂ agonists, sumatriptan and myristicin were investigated and resulted in dose-dependent pigment dispersion. The dispersing effects were effectively antagonized by receptor specific antagonists. It is suggested that 5-HT-induced physiological effects are mediated via distinct classes of receptors that possibly participate in modulation of pigmentary responses of the fish.     

Different Structural Requirements for Melanin‐Concentrating Hormone (MCH) Interacting with Rat MCH‐R1 (SLC‐1) and Mouse B16 Cell MCH‐R

Abstract

Melanin‐concentrating hormone (MCH) is a neuropeptide occurring in all vertebrates and some invertebrates and is now known to stimulate pigment aggregation in teleost melanophores and food‐intake in mammals. Whereas the two MCH receptor subtypes hitherto cloned, MCH‐R₁ and MCH‐R₂, are thought to mediate mainly the central effects of MCH, the MCH‐R on pigment cells has not yet been identified, although in some studies MCH‐R₁ was reported to be expressed by human melanocytes and melanoma cells. Here we present data of a structure‐activity study in which 12 MCH peptides were tested on rat MCH‐R₁ and mouse B16 melanoma cell MCH‐R, by comparing receptor binding affinities and biological activities. For receptor binding analysis with HEK‐293 cells expressing rat MCH‐R₁ (SLC‐1), the radioligand was [¹²⁵I]–[Tyr¹³]‐MCH with the natural sequence. For B16 cells (F1 and G4F sublines) expressing B16 MCH‐R, the analog [¹²⁵I]–[D‐Phe¹³, Tyr¹⁹]‐MCH served as radioligand. The bioassay used for MCH‐R₁ was intracellular Ca²⁺ mobilization quantified with the FLIPR instrument, whereas for B16 MCH‐R the signal determined was MAP kinase activation. Our data show that some of the peptides displayed a similar relative increase or decrase of potency in both cell types tested. For example, linear MCH with Ser residues at positions 7 and 16 was almost inactive whereas a slight increase in side‐chain hydrophilicity at residues 4 and 8, or truncation of MCH at the N‐terminus by two residues hardly changed binding affinity or bioactivity. On the other hand, salmonic MCH which also lacks the first two residues of the mammalian sequence but in addition has different residues at positions 4, 5, 9, and 18 exhibited a 5‐ to 10‐fold lower binding activity than MCH in both cell systems. A striking difference in ligand recognition between MCH‐R₁ and B16 MCH‐R was however observed with modifications at position 13 of MCH: whereas L‐Phe¹³ in [Phe¹³, Tyr¹⁹]‐MCH was well tolerated by both MCH‐R₁ and B16 MCH‐R, change of configuration to D‐Phe¹³ in [D‐Phe¹³, Tyr¹⁹]‐MCH or [D‐Phe¹³]‐MCH led to a complete loss of biological activity and to a 5‐ to 10‐fold lower binding activity with MCH‐R₁. By contrast, the D‐Phe¹³ residue increased the affinity of [D‐Phe¹³, Tyr¹⁹]‐MCH to B16 MCH‐R about 10‐fold and elicited MAP kinase activation as observed with [Phe¹³, Tyr¹⁹]‐MCH or MCH. These data demonstrate that ligand recognition by B16 MCH‐R differs from that of MCH‐R₁ in several respects, indicating that the B16 MCH‐R represents an MCH‐R subtype different from MCH‐R₁.     

Protein kinase C activation antagonizes melatonin-induced pigment aggregation in Xenopus laevis melanophores

The pineal hormone, melatonin (5-methoxy N-acetyltryptamine) induces a rapid aggregation of melanin-containing pigment granules in isolated melanophores of Xenopus laevis. Treatment of melanophores with activators of protein kinase C (PKC), including phorbol esters, mezerein and a synthetic diacylglycerol, did not affect pigment granule distribution but did prevent and reverse melatonin-induced pigment aggregation. This effect was blocked by an inhibitor of PKC, Ro 31-8220. The inhibitory effect was not a direct effect on melatonin receptors, per se, as the slow aggregation induced by a high concentration of an inhibitor of cyclic AMP-dependent protein kinase (PKA), adenosine 3',5'-cyclic monophosphothioate, Rp-diastereomer (Rp-cAMPS), was also reversed by PKC activation. Presumably activation of PKC, like PKA activation, stimulates the intracellular machinery involved in the centrifugal translocation of pigment granules along microtubules. alpha-Melanocyte stimulating hormone (alpha-MSH), like PKC activators, overcame melatonin-induced aggregation but this response was not blocked by the PKC inhibitor, Ro 31-8220. This data indicates that centrifugal translocation (dispersion) of pigment granules in Xenopus melanophores can be triggered by activation of either PKA, as occurs after alpha-MSH treatment, or PKC. The very slow aggregation in response to inhibition of PKA with high concentrations of Rp-cAMPS, suggests that the rapid aggregation in response to melatonin may involve multiple intracellular signals in addition to the documented Gi-mediated inhibition of adenylate cyclase.     

Pigment migration in the dermal melanophores of amphibian larvae in the interphase and during mitosis

Functioning of the dermal melanophores was studied in the isolated skin of the Rana temporaria and R. esculenta tadpoles at stages 17-21 and 20-24 (after Kopsch). At all stages we studied melanophores exhibited reaction to light. From stage 18 on repeated alternation of pigment dispersion and aggregation was obtained using melanotropins and melatonin. When observing transition of the melanophores from interphase to mitosis, it was found that dividing dermal melanophores could be distinguished due to changes in their appearance shortly before the end of prophase.     

Histology,ultrastructure, and pigmentation in the horny scales of growing crocodilians

Alibardi L. 2011. Histology, ultrastructure, and pigmentation in the horny scales of growing crocodilians. —Acta Zoologica (Stockholm) 92 : 187–200. The present morphological study describes the color of hatchling, juvenile, and adult crocodilian skin and the origin of its pigmentation. In situ hybridization and immunostaining indicate that crocodilian scales grow as an expansion of the proliferating epidermis of the hinge region that form thin lateral rings. In more central areas of growing scales, new epidermal layers contribute to increase the thickness of the stratum corneum. The dark pigmentation and color pattern derive from the different distribution of epidermal and dermal chromatophores. The more intensely pigmented stripes, irregular patches and dot‐like spots, especially numerous in dorsal scales, derive from the incorporation of the eumelanosomes of epidermal melanocytes in differentiating beta cells of the epidermis. Dermal melanophores, mainly localized in the loose upper part of the dermis, also contribute to the formation of the dark or gray background of crocodilian scales. The eumelanosomes of dermal melanophores determine the darkening of the skin pattern in association with the epidermal melanocytes. Iridophores are infrequent, while xantophores are present in the species analyzed with a sparse distribution in the superficial dermis among melanophores. The presence of xantophores and of the few iridophores in areas where epidermal melanocytes are absent appear to determine the brown or the light yellow‐orange background observed among the darker regions of crocodilian scales.     

Control of the melanophores of the crab,Pachygrapsus marmoratus: Release of pigment dispersing and pigment concentrating neurohormones by amines

1. The black pigment, in the melanophores, of Pachygrapsus marmoralus, a crab, disperses in specimens on a black background and concentrates in specimens on a white background.2. Bilateral eyestalk ablation results in black pigment concentration.3. These melanophores are regulated by pigment dispersing and concentrating hormones.4. In intact Pachygrapsus, 5-hydroxytryptamine produces black pigment dispersion whereas dopamine produces black pigment concentration.5. Neither 5-hydroxytryptamine nor dopamine affects melanophores in isolated legs. Presumably, therefore, these amines affect melanophores of intact Pachygrapsus indirectly only; 5-hydroxytryptamine by stimulating release of black pigment dispersing hormone and dopamine by stimulating release of black pigment concentrating hormone.     

Ultrastructural changes in dermal melanophores in the process of pigment granule migration

The results of electron microscope investigations on dermal melanophores of Rana temporaria L. during migration of pigment granules are presented. It was shown that in comparison to the previous observations dermal melanophores are flat cells without branches. Ultrastructural differences have been demonstrated in dermal melanophores during migration of pigment granules. During melanosome dispersion membrane vesicle bodies are seen in the cytoplasm to be inserted in the melanophore membrane.     

D-isomeric replacements within the 6-9 core sequence of Ac-[Nle4]-alpha-MSH4-11-NH2: a topological model for the solution conformation of alpha-melanotropin

Analogs of Ac-[Nle⁴]-α-MSH_4–11-NH₂ and Ac-[Nle⁴, D -Phe⁷]-α-MSH_4–11-NH₂ were prepared with D -isomeric replacements at the His⁶, Arg⁸, and Trp⁹ residues. The requirement for an indole moiety at position 9 also was evaluated by replacement with L -leucine in both parent fragment analogs. D -isomeric replacements at positions 6 and 8 in either series were detrimental to biological potency in frog (Rana pipiens) and lizard skin (Anolis carolinensis) in vitro melanotropic assays. However, Ac-[Nle⁴, D -Trp⁹]-α-MSH_4–11-NH₂ and Ac-[Nle⁴, D -Phe⁷, D -Trp⁹]-α-MSH_4–11-NH₂ were equipotent and 10 × more potent than Ac-[Nle⁴]-α-MSH_4–11-NH₂, respectively, in the lizard skin bioassay, and 30 and 1900 times more potent in the frog skin bioassay. Ac-[Nle⁴, D -Phe⁷, D -Trp⁹]-α-MSH_4–11-NH₂ was 3 × more potent than α-MSH in the frog skin bioassay. Proton nmr studies in aqueous solution revealed a marked preservation of the backbone conformation of these linear analogs. Chemical-shift variations due to the through-space anisotropic influence of the core aromatic amino acid residues permitted evaluation of side-chain topology. The observed topology was consistent with nonhydrogen-bonded β-like structure (? = ?139°, ψ = +135° for L -amino acids; ? = +139°, ψ = ?135° for D -amino acids) as the predominant solution conformation. The biological and conformational data suggest that high melanotropic potency requires a close spatial arrangement of the His⁶, Phe⁷, and Arg⁸ side chains.