Toyoko Akiyama

Endothelin receptor B2 ( EDNRB2) is responsible for the tyrosinase-independent recessive white (mow) and mottled (mo) plumage phenotypes in the chicken

A mutation that confers white plumage with black eyes was identified in the Minohiki breed of Japanese native chicken (Gallus gallus domesticus). The white plumage, with a few partially pigmented feathers, was not associated with the tyrosinase gene, and displayed an autosomal recessive mode of inheritance against the pigmented phenotype. All F1 offspring derived from crosses with mottled chickens (mo/mo), which show characteristic pigmented feathers with white tips, had plumage with a mottled-like pattern. This result indicates that the white plumage mutation is a novel allele at the mo locus; we propose the gene symbol mow for this mutant allele. Furthermore, the F1 hybrid between the mow/mow chicken and the panda (s/s) mutant of Japanese quail (Coturnix japonica), whose causative gene is the endothelin receptor B2 (EDNRB2) gene, showed a mow/mow chicken-like plumage, suggesting the possibility that the mutations in parental species are alleles of the same gene, EDNRB2. Nucleotide sequencing of the entire coding region of EDNRB2 revealed a non-synonymous G1008T substitution, which causes Cys244Phe amino acid substitution in exon 5 (which is part of the extracellular loop between the putative fourth and fifth transmembrane domains of EDNRB2) in the mutant chicken. This Cys244Phe mutation was also present in individuals of four Japanese breeds with white plumage. We also identified a non-synonymous substitution leading to Arg332His substitution that was responsible for the mottled (mo/mo) plumage phenotype. These results suggest that the EDN3 (endothelin 3)–EDNRB2 signaling is essential for normal pigmentation in birds, and that the mutations of EDNRB2 may cause defective binding of the protein with endothelins, which interferes with melanocyte differentiation, proliferation, and migration.

Pigment Cells Representing Polychromatic Colony Color in Botrylloides simodensis (Ascidiacea, Urochordata): Cell Morphology and Pigment Substances

Abstract The colonial ascidian Botrylloides simodensis displays multiple body colors—yellow, orangered, violet, black and white—in a clonal colony. The colors are due to pigmented blood cells that exist particularly around a branchial siphon or on an atrial languet of individual zooids. These pigment cells are distributed in mesenchymal space or vascular lumen, and many of them are loosely bound to the epithelium. In the space, there are also colorless blood cells that are circulating with blood. When the colorless blood cells are isolated and cultured, some of the cells produce colored substances and change to pigment cells. Therefore, it is presumed that the pigment cells are derived from colorless blood cells. The pigment cells in this ascidian have a spherical shape with no dendrites and contain many granules. Electron microscopic observation showed that there are several different types of granules, and all types of granules are similarly packed in a large vacuole in the cytoplasm. Chemical analysis disclosed that the pigmentary tissues contain carotenoids, pteridine, and purines that are known pigments in vertebrates. The main components of black and violet pigment cells are still unidentified. The former may be a melanin-like substance, but a significant dose of eumelanin or phaeomelanin was not obtained. Although ascidian pigment cells show a certain extent of similarity to vertebrates in their pigments, their cell structure is quite different from that in vertebrates. Because of the phylogenetic relationship between ascidians and vertebrates, it is assumed that ascidian pigment cells might be a primitive type of those in chordates, although these ascidian cells seem to have a unique origin and function.

Production of crystallins and lens‐like structures in differentiation‐induced neoplastic pigment cells (goldfish erythrophoroma cells) in vitro

We examined the crystallins present in lens-like cell aggregates produced by goldfish erythrophoroma (tumors of integumental erythrophores) cells in vitro using a combination of Sephadex-G-200 gel filtration, one- and two-dimensional sodium-dodecyl-sulfate/polyacryl-amide gel electrophoresis, immunoblotting, and indirect immunofluorescence assays. The two studied neoplastic pigment cell lines, GEM 81 and GEM 218, formed small, spherical, transparent cell aggregates, resembling lentoid bodies, within the cell mounds of monolayer cultures after treatment with dimethylsulfoxide (DMSO) and autologous serum. Partial purification of a water-soluble extract of such lens-like cell aggregates and subsequent immunoblotting using antibodies (polyclonal) against newt whole lens proteins revealed the presence of about 20 unequivocally conjugated peptides with molecular masses of 19-27 kilodaltons. From their antigenicity and their behavior during gel filtration and electrophoresis, most of these peptides were identified as either alpha- or beta-form crystallins. Immunofluorescence microscopy using antibodies to newt whole lens proteins revealed intense fluorescence in the lens-like cell aggregates formed by these erythrophoroma cells, whereas the cell mounds in cultures of the same cell lines that had not been subjected to differentiation induction were almost unlabeled. Thus, goldfish erythrophoroma cells appear to be capable of crystallin production as well as the formation of lens-like cell aggregates upon the induction of differentiation. There is little available information indicating that normal pigment cells are capable of lens formation and crystallin synthesis during vertebrate ontogeny, and thus it is possible that neoplastic transformation of pigment cells is associated with the acquisition of the ability to produce crystallins.

Myosin and actin in melanophore-like variants of goldfish erythrophoroma cells: their intracellular distribution and possible association with pigment translocation

SummaryThe occurrence and intracellular distribution of myosin and actin in melanophore-like cells derived from a goldfish erythrophoroma cell line have been studied by means of sodium dodecylsulfate-polyacrylamide gel electrophoresis (SDS-PAGE), immunoblot and immunofluorescence using antisera against chick gizzard myosin heavy chain and carp skeletal muscle actin. SDS-PAGE of the cell extracts separates out one band at 200 kDalton; this is conjugated with the anti-myosin antiserum. Immunofluorescence using the anti-myosin antiserum discloses that myosin in these cells occurs in two forms: discrete, minute clusters and thin filaments bearing a resemblance to “stress fibers”. The former is distributed evenly over the entire cytoplasm in the cells with dispersed pigments and, upon pigment aggregation, accumulates densely around collapsed melanosomes. The latter runs as thin bundles either radially along the cell center-to-periphery axis or connecting the corners of cell margins; it gives a similar profile in all states of the motile response. Immunofluorescence using the antiactin antiserum or rhodamine-conjugated phalloidin discloses that actin is similarly distributed to myosin, suggesting its possible existence as actomyosin. Simultaneous translocation of the amorphous forms of myosin and actin with melanosomes indicates that they may be involved in pigment migration.

The origin and evolution of fibromelanosis in domesticated chickens: Genomic comparison of Indonesian Cemani and Chinese Silkie breeds

Like Chinese Silkie, Indonesian Ayam Cemani exhibits fibromelanosis or dermal hyperpigmentation and possesses complex segmental duplications on chromosome 20 that involve the endothelin 3 gene, EDN3. A genomic region, DR1 of 127 kb, together with another region, DR2 of 171 kb, was duplicated by unequal crossing over, accompanied by inversion of one DR2. Quantitative PCR and copy number variation analyses on the Cemani genome sequence confirmed the duplication of EDN3. These genetic arrangements are identical in Cemani and Silkie, indicating a single origin of the genetic cause of Fm. The two DR1s harbor two distinct EDN3 haplotypes in a form of permanent heterozygosity, although they remain allelic in the ancestral Red Jungle Fowl population and some domesticated chicken breeds, with their allelic divergence time being as recent as 0.3 million years ago. In Cemani and Silkie breeds, artificial selection favoring the Fm phenotype has left an unambiguous record for selective sweep that extends in both directions from tandemly duplicated EDN3 loci. This highly homozygous tract is different in length between Cemani and Silkie, reflecting their distinct breeding histories. It is estimated that the Fm phenotype came into existence at least 6600–9100 years ago, prior to domestication of Cemani and Silkie, and that throughout domestication there has been intense artificial selection with strength s > 50% in each breed.

An association of actin isoforms with the expression of motile response in pigmentation variants induced from goldfish erythrophoroma cells

Comparison of actin isoforms in unpigmented goldfish cells (a normal dermal fibroblast-like cell line, and an unpigmented erythrophoroma cell line capable of being induced to undergo melanization) and in normal and neoplastic melanized goldfish cells shows that the melanized phenotype is accompanied by the presence of multiple actin isoforms. In contrast, the unpigmented cells have only beta-actin. The possible significance of this to pigment organelle translocation is discussed.