Control of Melanoblast Differentiation in Amphibia by α-Melanocyte Stimulating Hormone,a Serum Melanization Factor,and a Melanization Inhibiting Factor

A ventrally localized melanization inhibiting factor (MIF) has been suggested to play an important role in the establishment of the dorsal-ventral pigment pattern in Xenopus laevis [Fukuzawa and Ide: Dev. Biol., 129:25–36, 1988]. To examine the possibility that melanoblast expression might be controlled by local putative MIF and melanogenic factors, the effects of α-melanocyte stimulating hormone (α-MSH), a serum melanization factor (SMF) from X. laevis or Rana pipiens, and MIF on the “outgrowth” and “melanization” of Xenopus neural crest cells were studied. Outgrowth represents the number of neural crest cells emigrating from cultured neural tubes, and melanization concerns the percentage of differentiated melanophores among the emigrated cells. MSH or SMF stimulate both outgrowth and melanization. The melanogenic effect of Xenopus serum in this system is more than twice that of Rana serum. The actions of MSH and Xenopus serum on melanization seem to be different: 1) Stronger melanization is induced by Xenopus serum than by MSH, and the onset of melanization occurs earlier with Xenopus serum; 2) MSH stimulates melanization only in the presence of added tyrosine; and 3) MSH causes young melanophores to assume a prominent state of melanophore dispersion during culture, while Xenopus serum (10%) had only a slight dispersing effect and not until day 3. A fraction of Xenopus serum presumably containing molecules of a smaller molecular weight (MW <30 kDa) than that of a pigment promoting factor reported in calf serum [Jerdan et al.: J. Cell Biol., 100:1493–1498, 1985] produces the same remarkable melanogenic effects as does intact serum. While this fraction stimulates outgrowth, another fraction presumably containing larger molecules (MW > 100 kDa) does not. MIF contained in Xenopus ventral skin conditioned medium (VCM) inhibits both outgrowth and melanization dose dependently. When VCM is used in combination with MSH, the stimulating effects of MSH on both outgrowth and melanization are completely inhibited. In contrast, the stimulatory effects of Xenopus serum are not completely inhibited when combined with VCM, although melanization is reduced to approximately 40% that of controls. MIF activity was also found to be present in ventral, but not in dorsal, skin conditioned media of R. pipiens when tested in the Xenopus neural crest system. We suggest that ventrally localized MIF plays an important role in amphibian pigment pattern formation and that the interacting effects of MIF and melanogenic factors influence melanoblast differentiation, migration, and/or proliferation of neural crest cells to effect the expression of pigmentary patterns.     

A ventrally localized inhibitor of melanization in Xenopus laevis skin

Melanophores normally differentiate in dorsal but not in ventral skin of Xenopus laevis. We have sought factors which might regulate this differentiation pattern, and we have obtained a putative melanization inhibiting factor (MIF) from ventral but not from dorsal skin. Preliminary studies reveal that MIF is destroyed by heat or trypsin treatment, indicating its protein composition, and has a molecular weight in the range of 300 kDa. The effects of MIF on the differentiation of neural crest derivatives to melanophores were examined in vitro in the presence of tyrosine and fetal calf serum (FCS). Tyrosine enhances melanophore differentiation in vitro at concentrations equivalent to those estimated in adult Xenopus blood plasma (20 microM). FCS also stimulates melanization, by way of materials other than the tyrosine contained in FCS. MIF strongly inhibits outgrowth and melanization of neural crest cells from neural tube explants. MIF also inhibits the differentiation of melanoblasts contained in cultured explants of ventral skin. Inhibition of melanization or melanophore differentiation by MIF occurs even in the presence of L-tyrosine and/or FCS. We suggest that MIF plays an important role in the establishment of dorso-ventral pigment patterns in amphibia.     

Intrinsic pigment cell stimulating activity in the skin of the leopard frog, Rana pipiens.

Consistent with the concept that specific pigment patterns of amphibians might result from the highly localized distribution of stimulators and inhibitors of pigment cell expression in the skin, the spot pattern of the leopard frog, Rana pipiens, was examined through the use of the Xenopus neural tube explant assay system (Fukuzawa and Ide, 1988). Media conditioned with pieces of skin from dorsal black spotted areas promoted melanization of neural crest cells at a significantly higher level than did media conditioned with dorsal interspot skin in the absence of extra tyrosine. All conditioned media contained exceedingly low concentrations of tyrosine. With the addition of supplemental tyrosine, the melanization capacity of conditioned media from the interspot areas was elevated to that of the spotted skin. Control media conditioned with ventral frog skin inhibited melanization, as usual, because of the presumed presence of melanization inhibiting factor (MIF). It is considered that dorsal skin contains a melanization stimulating factor (MSF) which is present in significantly higher levels in spotted skin than in interspot areas and that expression of the particular pigmentary pattern of this leopard frog is regulated by the relative distribution of MIF, MSF, and possibly other intrinsic substances present in the skin.     

Preliminary biological characterization of a melanization stimulating factor (MSF) from the dorsal skin of the channel catfish, Ictalurus punctatus.

A two step fractionation of conditioned media made from the darkly pigmented dorsal skin of the channel catfish, Ictalurus punctatus, has produced fractions that contain a melanization stimulating factor (MSF). Isolated neural tubes of Xenopus laevis embryos exposed to conditioned media and to specific fractions exhibit greater melanization (increased numbers of melanized cells and elevated percentages of melanized cells), a greater number of dendrites per melanized cell, and a greater number of emigrated neural crest cells than control neural tubes. The presence of MSF activity in the darkly pigmented dorsal integument suggests a role for a molecule or molecules in the development and maintenance of the dorsal/ventral pigment pattern of this piscine species and possibly of other vertebrates.     

Cell surface carbohydrate involvement in controlling the adhesion and morphology of neural crest cells and melanophores of Xenopus laevis

Pieces of dorsal neural tube (stages 22-23) or late neural crest tissue (stages 24-26) of Xenopus laevis were cultured. Migratory cells moved out of explants to form an outgrowth of multipolar melanophores on the substratum. Treatment with beta-galactosidase (0.1-0.4 U/ml) to remove cell surface galactose was correlated with detachment of melanophores. In the presence of lower concentrations of this enzyme the shapes of these cells were converted to arborized, spidery morphologies and cell movement was inhibited. Unpigmented cells were affected more slowly. Neuraminidase treatment, to remove cell surface sialic acid and expose more galactose, only affected melanophores. These became increasingly spread on the substratum and cell overlap was observed. These results suggest that the relative amounts of galactose and sialic acid at the cell surface become increasingly important in controlling cell adhesion as X. laevis neural crest cells migrate and differentiate into melanophores.     

Studies on cellular adhesion of Xenopus laevis melanophores: modulation of cell-cell and cell-substratum adhesion in vitro by endogenous Xenopus galactoside-binding lectin

We have investigated cell-cell and cell-substratum adhesion of Xenopus laevis neural crest cells at various stages of melanophore differentiation. Single-cell suspensions were obtained by trypsinization and aggregated in a cell-cell adhesion assay. Unpigmented cells did not adhere while the rate of adhesion of melanophores correlated with the degree of melanization. Melanophore cell-cell adhesion decreased significantly in the presence of beta-galactosidase, which suggests that cell-surface galactose is involved. Beta-galactoside-binding lectin has been isolated and purified from embryos at the stage of neural crest migration. When added to aggregating cells smaller, looser clusters formed compared to controls. When lectin was added to cells in stationary culture to test cell-substratum adhesion, melanophores spread more smoothly and formed more regular spacing patterns. These results suggest that this lectin can modulate receptors used in cell-cell and cell-substratum adhesion of melanophores.     

Melanocyte-stimulating hormone affects melanogenic differentiation of quail neural crest cells in vitro

Quail neural crest cells were treated in vitro with alpha-melanocyte-stimulating hormone (alpha-MSH) or dibutyryl cyclic AMP (dbcAMP) plus theophylline. These treatments increased the proportion of melanocytes to total cells in crest cell outgrowth cultures. Pigmentation of neural crest cell clusters proceeded more rapidly when cultures were treated with alpha-MSH or dbcAMP plus theophylline than when untreated. In clonal cell cultures, the proportion of pigmented colonies to total colonies was increased by MSH treatment. From these results, MSH seems not only to accelerate melanogenic differentiation but also to affect the state of commitment of neural crest cells to melanogenic differentiation in vitro, and this action of MSH appears to be mediated by cAMP.     

Intrinsic Pigment-Cell Stimulating Activity in the Catfish Integument

In keeping with the concept that local factors in the vertebrate integument affect the expression of pigment cells, the present study was directed toward demonstrating the existence of such factors in the skin of the channel catfish, Ictalurus punctatus. This species has a dark dorsal surface in marked contrast to an almost white midventral surface. Pieces of skin from these two surfaces were used to condition culture media, which were in turn bioassayed using the Xenopus neural tube explant system (Fukuzawa and Ide, 1988, Dev. Biol. 129:25). A certain number of neural crest cells grow out from the explant, and many of these are melanized in a culture medium of Steinberg's basic salt solution (BSS). When the BSS was conditioned with either dorsal or ventral skin, a profound increase in both the number of crest cells emigrated from the neural tubes and the percentage of melanized cells was observed. The effects of dorsal skin were stronger than those of ventral skin and were evident on a dose/response basis. Initial fractionation of conditioned BSS with DEAE ion exchange chromatography produced fractions of particular potency in the stimulation of melanogenesis. A similarly conditioned medium based upon Leibovitz's L-15 was used in the primary culture of mature chromatophores, namely, melanophores, iridophores, and xanthophores from tadpoles of Rana pipiens. Both dorsal and ventral conditioned media stimulated iridophores and xanthophores, but seemed to have little or no effect on tadpole melanophores. A melanization inhibiting factor (MIF) from the ventral surface of adult frogs has been suggested as the basis for the light colored ventrum of amphibians, and although the present experiments were not designed to study catfish MIF, the possible existence of such a factor in this species was supported by the results. The total results of this investigation are discussed in the light of the possible presence of a melanization inhibiting factor (MIF) of greater prevalence in the ventrum and a melanization stimulatory factor (MSF) of greater prevalence in the dorsal integument. It is suggested that the light-colored ventral surface of the catfish and other poikilotherms may result from the presence of higher levels of MIF than MSF. Thus, the expression of melanophores is inhibited while that of iridophores is enhanced. In contrast, higher levels of MSF over MIF in the dark dorsal surface would result in melanophore stimulation and inhibition of iridophore expression.     

Pigment cell pattern formation in amphibian embryos: a reexamination of the dopa technique

Neural crest-derived melanophores form species-specific patterns in the dermis of amphibian embryos. Melanophore patterns may be generated by one of two general mechanisms: pigment cell precursors disperse throughout the embryo, with melanophores differentiating in certain regions due to environmental cues, or melanoblasts may localize in different regions as a result of a hierarchy of tissue affinities. Both of these mechanisms have been proposed to be responsible for the dorso-ventral patterning of melanophores in Xenopus laevis. We have reexamined the distribution of melanoblasts in X. laevis and Taricha torosa using the dopa (3,4-dihydroxyphenyl-alanine)-staining technique. We have found that many of the dopa-positive cells identified as melanoblasts by some researchers are actually not derived from the neural crest: dopa-positive cells in T. torosa were identified in the transmission electron microscope to be either leukocytes or erythrocytes, in X. laevis dopa-positive cells are found between the ectoderm and somites where neural crest cells are not found, and X. laevis embryos surgically depleted of neural crest have dopa-staining patterns identical to control embryos. Melanoblasts are apparently not found in the ventralmost regions of early T. torosa and X. laevis embryos, providing additional evidence for the role of differential tissue affinities in directing the formation of embryonic pigment cell patterns.     

The Amphibian Melanization Inhibiting Factor (MIF) Blocks the α-MSH Effect on Mouse Malignant Melanocytes

We have found that a melanization inhibitory factor (MIF) extracted from the ventral skin of Rana forreri has a slight inhibitory effect on the activity levels of tyrosinase and dopachrome tautomerase in B16/F10 and Cloudman S-91 murine melanoma cell lines. Furthermore, this factor appears to block the effects of α-MSH on these enzymatic activities. However, MIF treatment does not affect the melanogenic action of theophylline on the same cells, suggesting that MIF acts proximal to MSH-mediated cAMP formation, possibly by interaction with the MSH receptor. In this way, we show that this amphibian factor has biological activity on mammalian melanocytes. This suggests the existence of mammalian counterparts of amphibian MIF in the mouse integument that might regulate epidermal melanocytes. These peptides might be related to the agouti protein, as they share similar mechanisms of action. The interaction of different peptides with the MSH receptor would be a complex but general mechanism responsible for many mammalian coat color variants.     

Mechanisms of Melanophore Induction in Amphibian Development

Induction of melanophores was examined by the sandwich method of explantation with embryonic tissues of Xenopus laevis +/+ and the white mutant, a^P/a^P. Interspecific combinations of tissues of Triturus taeniatus and Xenopus borealis were also used. The ectoderm used as the reacting system was taken from embriyos at various stages and combined with various tissues known to be melanogenic inductors. The following results were obtained: 1) The sources of melanophore induction in both +/+ and a^p/a^p studied by sandwich explantation were the same in both retinal pigmented epithelium and dermal melanophores: 2) Melanophores were induced in epidermal material from embryos at stages from the early gastrula to the late tail bud stage: 3) The presence of melanoblasts together with other ectomesenchymal cells in the neural crest is not sine qua non for their determination and differentiation: 4) On isolation of reacting material from the late gastrula, melanophores appeared in all cases. This shows that two hours contact between inductor tissues and the ectoderm is necessary and sufficient for melanophore induction: 5) Melanophore induction is not species-specific, but occurred in Xenopus ectoderm under the action of endomesoderm of Tr. taeniatus or X. borealis , and vice versa. The shapes and structures of melanophores induced were typical for the species from which the ectoderm was taken: 6) Melanogenic activity in the late gastrula stage has a gradient of distribution with a maximum in the prechordal plate: 7) In the mutant only the primary source of melanogenic inductors, the prechordal plate (PrP1), was active in stages both before and after its invagination: 8) Despite the fact that skin melanophores and retinal melanocytes have different genesis in development, all the present data suggest the identity of the mechanisms of melanin synthesizing machinery in the two.     

Differentiation of neural crest cells of Xenopus laevis in clonal culture

Clonal cultures were performed with the use of neural crest cells and their derivatives, chromatophores, from Xenopus laevis in order to elucidate the state of commitment in early embryogenesis. Neural crest cells that outgrew from neural tube explants were isolated and plated at clonal density. Cloned neural crest cells differentiated and gave rise to colonies that consisted of 1) only melanophores, 2) only xanthophores, or 3) melanophores and xanthophores. Xanthophores and iridophores, which differentiated in vitro, were also isolated and cloned. Cloned xanthophores proliferated in a stable fashion and did not lose their properties. On the other hand, cloned iridophores converted into melanophores as they proliferated. These results suggest that there is heterogeneity in the state of commitment of neural crest cells immediately after migration with regard to chromatophore differentiation and that iridophore determination is relatively labile (at least in vitro), whereas melanophore and xanthophore phenotypes are stable.     

Melanophore differentiation in the periodic albino mutant of Xenopus laevis

That embryonic ventral truck tissue might play a role in expression of the periodic albino mutant phenotype (ap/ap) in Xenopus laevis was suggested from the experiments of MacMillan (1980). In contrast, the present experiments, involving the culture of isolated regions of Xenopus embryos, have demonstrated that both mutant and wild-type melanoblasts differentiate independently of a ventral trunk factor. A similar conclusion, that mutant melanoblasts differentiate independently of a ventral trunk factor, is derived from observations on neural crest cultures, wherein melanization of neural crest cells in both wild-type and mutant cultures occurred in a manner consistent with their genotype.     

Genetic and experimental studies on a new pigment mutant in Xenopus laevis.

White lethal (wl) is a recessive mutation affecting the differentiation of the three types of chromatophores in Xenopus laevis and eventually leading to the death of the mutants around stage 50. Melanophores appear at st. 33 but differentiate abnormally, remaining pale grey, and do not proliferate after st. 41. The rare xanthophores present contain only a few differentiated pterinosomes, and the iridophores consist of noniridescent white dots. When the albino gene (ap) is combined with wl, melanophores do not differentiate. Reciprocal heterotopic and orthotopic trunk neural crest grafts have shown that the defect is intrinsic to the neural crest cells but is not due, in the case of melanophores, to a tyrosinase deficiency as revealed by the dopa reaction. The mode of action of the gene, the abnormal pattern, and lethality are discussed.     

Studies on cellular adhesion of Xenopus laevis melanophores: pigment pattern formation and alteration in vivo by endogenous galactoside-binding lectin or its sugar hapten inhibitor

We have studied the development of Xenopus laevis tail melanophores and the effects on these cells on confrontation with endogenous X. laevis galactoside-binding lectin or its sugar hapten inhibitor thiodigalactoside (TDG). An initial population of unpigmented cells differentiates into melanophores on the dorsal surface of the neural tube, and on the dorsal and ventral apices of the myotomes, forming the larval pattern. Melanophores secondarily populate the flank, forming a spaced arrangement which is later transformed into a dorsal and ventral strip. A technique has been developed for confrontation of premigratory neural crest with purified lectin or TDG. These molecules impact on tail melanophores. With lectin treatment melanophore numbers decrease, and cell morphologies and arrangements change. TDG treatment, however, primarily affects pigment cell morphology. These results suggest that both galactoside-bearing receptors for this lectin and the lectin itself can affect melanophores in this species of frog.     

Melanization stimulating factors in the integument of the Mugil cephalus and Dicertranchus labrax

The pigment pattern expression resides in the chromatoblasts of the embryonic skin. The differentiation of these chromatoblasts is influenced by specific local factors such a melanization inhibiting factor (MIF) and a melanization-stimulating factor (MSF). We reveal the presence of these factors by means of a series of experiments on the skin of the marine species of fish Dicertranchus labrax and Mugil cephalus, each with different pigment pattern, the former having a light skin and the latter a darker one. Media conditioned by exposure to dorsal and/or ventral skin, stimulates the melanization of Xenopus laevis neural crest cells throughout a 3 day assay period. Similarly conditioned culture media tested on B16-F10 murine malignant melanocytes, revealed a considerable influence in enzymatic activities: dopachrome tautomerase (DCT), tyrosine hydroxylase and dopa oxidase. The use of media in a dose response basis suggests that the conditioned media may contain both melanophore stimulating and inhibiting factors. The results obtained may actually reflect the resultant activity of the two factors present.     

Proinsulin cDNAs from the leopard frog, Rana pipiens: evolution of proinsulin processing

We have isolated a proinsulin cDNA from the Amphibian Rana pipiens. The predicted R. pipiens insulin A- and B-chain amino acid sequences differ from that deduced from the closely related Rana catesbeiana at one residue (Asp for Pro at B2). The R. pipiens and Xenopus laevis proinsulin precursor sequences are of identical length, with the amino acid sequences of the mature A- and B-chains being well conserved. The proinsulin C-peptide amino acid sequence is less well conserved between R. pipiens and X. laevis and also differs in length. The R. pipiens C-peptide is shorter than the homologous X. laevis sequence due to a two amino acid residue truncation. The truncation of the R. pipiens C-peptide compensates for a two amino acid residue extension observed at the N-terminal of the A-chains of insulins from Ranid frogs. A change in the site of proinsulin processing can explain both the C-peptide and A-chain length differences. The evolution of the new proinsulin processing site required two amino acid substitutions.     

Cytostatic factor (CSF) in the eggs of Xenopus laevis

Cytostatic factor (CSF) in unfertilized egg cytoplasm causes metaphase arrest when microinjected into zygotes. This was originally described in Rana pipiens eggs In Xenopus laevis, CSF has also been demonstrated. but only when the calcium-chelating agent, EGTA, was injected into the egg cytoplasm. In the present study, however, CSF was demonstrated in Xenopus eggs when donor egg activation was prevented by treatment with CO2 and Mg2+ instead of by EGTA, and recipient blastomere degeneration was prevented by increasing the KCl in the surrounding medium.     

Melanophore lineage and clonal organization of the epidermis in Xenopus embryos as revealed by expression of a biogenic marker, GFP

Melanophore lineage during embryogenesis of Xenopus laevis was traced using the overexpression of a biogenic marker, green fluorescent protein (GFP). Two different approaches were applied after injection of GFP mRNA (hence a marker construct) into each blastomere at the 16-cell stage. In in vivo experiments, the embryos injected with a marker construct were grown until stage 45, in which melanophores were distributed over the whole body and were good enough for checking GFP expression at their migratory destination. In in vitro experiments, neural tubes of the embryos injected with a marker construct were isolated and cultured at stage 21 to examine by virtue of GFP expression how neural crest cells differentiate into melanophores. The results obtained from both in vivo and in vitro experiments indicated the following: 1) selected animal blastomeres vastly contribute to the development of melanophores, whereas other animal blastomeres do so slightly at a limited pace; and 2) vegetal blastomeres never contribute to melanophores in normal development, whereas certain vegetal blastomeres have a potential to give rise to melanophores in vitro. The analyses using GFP also disclosed that the dorsal and ventral epidermis derive from the restricted animal blastomeres in the normal development. Since the dorso-ventrality of the epidermis has been inseparably coupled with integumental pigmentation, the clonal organization of the epidermis observed in the present study is discussed in the light of pigment pattern formation attributed by melanophores.