Cloning and regulation of Erwinia herbicola pigment genes.

The genes coding for yellow pigment production in Erwinia herbicola Eho10 (ATCC 39368) were cloned and localized to a 12.4-kilobase (kb) chromosomal fragment. A 2.3-kb AvaI deletion in the cloned fragment resulted in the production of a pink-yellow pigment, a possible precursor of the yellow pigment. Production of yellow pigment in both E. herbicola Eho10 and pigmented Escherichia coli clones was inhibited by glucose. When the pigment genes were transformed into a cya (adenylate cyclase) E. coli mutant, no expression was observed unless exogenous cyclic AMP was provided, which suggests that cyclic AMP is involved in the regulation of pigment gene expression. In E. coli minicells, the 12.4-kb fragment specified the synthesis of at least seven polypeptides. The 2.3-kb AvaI deletion resulted in the loss of a 37K polypeptide and the appearance of a polypeptide of 40 kilodaltons (40K polypeptide). The synthesis of the 37K polypeptide, which appears to be required for yellow pigment production, was not repressed by the presence of glucose in the culture medium, as was the synthesis of other polypeptides specified by the 12.4-kb fragment, suggesting that there are at least two types of gene regulation involved in yellow pigment synthesis. DNA hybridization studies indicated that different yellow pigment genes exist among different E. herbicola strains. None of six pigmented plant pathogenic bacteria examined, Agrobacterium tumefaciens C58, Cornyebacterium flaccumfaciens 1D2, Erwinia rubrifaciens 6D364, Pseudomonas syringae ATCC 19310, Xanthomonas campestris 25D11, and "Xanthomonas oryzae" 17D54, exhibited homology with the cloned pigment genes.     

The white tigers of Rewa and gene homology in the felidae

The white tiger is a chinchillated variety, with the yellow pigment completely eliminated and the black pigment altered to a dark speia-brown. The causative mutant gene is inherited as an autosomal recessive and is seemingly a homologue of chinchilla mutants in other mammalian species. It is proposed that the gene be re-symbolized asc ^ch .     

Observations on the pigmentation of the pigeon iris

There are three genetically controlled iris types found in the pigeon, two of which contain stromal pigment cells, the third lacks pigment cells. The yellow (gravel) and white (pearl) iris types have pigment cells that contain birefringent pigment granules (crystals) and are ultrastructurally similar to iridophores of poikilothermic vertebrates. Both these iris types contain guanine as a major "pigment" and, in addition, the yellow iris contains at least two yellow fluorescing pigments that are tentatively identified as pteridines. The pigment cells of the yellow and white irises are structurally identical differing only in the presence or absence of these yellow pigments. The stromal pigment cells of the white iris correspond in structure and pigment chemistry to classical iridophores although they lack strong irridescence and are therefore perhaps best considered leucophores. The pigment cells of the yellow iris can be considered "reflecting xanthophores" having the combined properties of both classical xanthophores and iridophore/leucophores.     

Recessive yellow in the Mongolian gerbil (Meriones unguiculatus)

A new autosomal recessive coat color mutant in the Mongolian gerbil (Meriones unguiculatus) is described: recessive yellow. On the dorsal side the mutant has a rich yellow to ginger color. Ventrally it shows the typical creamy white belly of a wild-type Mongolian gerbil. The dorsal yellow hairs have short black tips, and a light olive green base. A clear demarcation line between dorsal and ventral color is present. Crosses between recessive yellow animals and multiple homozygous recessive tester animals (a/a; c^chm/c^chm; g/g; p/p) resulted only in animals of an agouti (wild-type) phenotype, showing that the new allele is not allelic with any of the known coat color mutations in the Mongolian gerbil. Molecular studies showed that the new mutant is caused by a missence mutation at the extension (E) locus. On a non-agouti background (a/a; e/e) mutant animals look like a dark wild-type agouti. In contrast to wild-type agouti it shows yellow pigmentation and dark ticking at the ventral side, resulting in the absence of a demarcation line. Since black pigment is present in both the agouti and non-agouti variant (A/A; e/e and a/a; e/e), we conclude that recessive yellow in the Mongolian gerbil is non-epistatic to agouti. Additionally we describe a second mutation at the same locus leading to a similar phenotype, however without black pigment and diminishing yellow pigment during life. Fertility and viability of both new mutants are within normal range. The extension (E) gene is known to encode the melanocortin 1 receptor (MC1R). Interestingly, this is the only gene that is known to account for substantial variation in skin and hair color in humans. Many different mutations are known of which some are associated with higher skin cancer incidence.     

The thermo-photoelectric (TPE) properties of the hornet cuticle: correlation with the morphological structure

The present study investigated thermoelectric phenomena in the cuticle of the Oriental hornet Vespa orientalis (Hymenoptera, Vespinae). This was done in dependence on the pigment extant at various cuticular region, that is, the brown cuticle in which the primary pigment is melanin and embedded within the cuticle, and the yellow stripes in which the yellow pigment is comprised of purines and pteridines that are located in special pockets between the upper part of the cuticle and the basement membrane. The yellow pigment could be separated from the cuticle proper, but the brown pigment was not thus separable. We found that all cuticular regions of the gaster evinced a thermoelectric response, in that with rise in temperature there was a rise in the thermoelectric current, and vice versa. Additionally, the intact hornet displayed a negative photoelectric response in each of its yellow segments, so that upon illumination with UV light, the maximal current dropped by about 40-50%. Measurements taken on individual stripes in the gaster segments revealed that the photoelectric response is elicited only in the yellow stripes. In all the latter the photoelectric response persists but the maximal current level is lower than in the intact whole hornet. If the yellow pigment is detached mechanically or by bacterial incubation, the photoelectric property of the cuticle is abrogated. Likewise the photoelectric property is abrogated upon immersion of the cuticle in alcohol, even though the yellow pigment is still retained. The specific heat of the yellow stripes in the cuticle is about twice as high as that of the same stripes that had been depleted of their yellow pigment, amounting to 1.8-1.9 J/g.K vs. 0.8 J/g.K.     

散囊菌黄色素的提取及稳定性研究

为寻找优质黄色素生产资源及研究其在不同条件下的稳定性,以冠突散囊菌（Eurotium cristatum）为材料,利用有机溶剂辅助超声波破碎等方法从固体平板和液体培养的菌丝体中提取黄色素,并分别研究了光、温度等理化因子对该色素的影响。结果表明,采用有机溶剂辅助超声波等方法成功提取出黄色素;该色素耐受日光灯光、室内散射光,不耐阳光和紫外光;耐酸,不耐碱;对温度敏感。各种金属离子对该色素有不同程度的影响;磷酸的破坏性显著;H2O2、NaHSO3对该色素有较强的破坏力;柠檬酸有一定的破坏作用;同等条件下,苯甲酸钠的破坏大于山梨酸钾;EDTA-Na2和Vc有一定的护色作用;糖类、NaCl、草酸和乳酸几乎无影响。     

Allelic Variation within the Emv-15 Locus Defines Genomic Sequences Closely Linked to the agouti Locus on Mouse Chromosome 2

Gene(s) at the agouti locus act within the microenvironment of the hair follicle to switch pigment synthesis in the melanocyte between eumelanin (black or brown pigment) and phaeomelanin (yellow pigment). Many phenotypic variants of this locus have been described. The mechanism(s) of gene action causing such variation in coat-color phenotype is not known. The close linkage of an endogenous ecotropic murine leukemia provirus, Emv-15, to the lethal yellow mutation of the agouti locus provides a means to molecularly access genes at or near the agouti locus. We have identified and used a unique mouse sequence flanking the Emv-15 provirus to define three alleles of the Emv-15 locus. We found a correlation between the presence of specific Emv-15 alleles and the origins of specific agouti locus mutations, confirming close linkage. However, we found some exceptions which suggest that the Emv-15 locus is closely linked to, but genetically separable from, the agouti locus.     

Molecular characterization of durum and common wheat recombinant lines carrying leaf rust resistance (Lr19) and yellow pigment (Y) genes from Lophopyrum ponticum

Chromosome 7E from Lophopyrum ponticum carries a valuable leaf rust resistant gene designated Lr19. This gene has not been widely used in common wheat breeding because of linkage with the yellow pigment gene Y. This gene tints flour yellow, reducing its appeal in bread making. However, a high level of yellow pigment is desirable in durum wheat breeding. We produced 97 recombinant chromosomes between L. ponticum transfer 7D.7E#1 and its wheat homoeologues, using the ph1b mutation that promotes homoeologous pairing. We characterized a subset of 37 of these lines with 11 molecular markers and evaluated their resistance to leaf rust and the abundance of yellow pigment. The Lr19 gene was mapped between loci Xwg420 and Xmwg2062, whereas Y was mapped distal to Xpsr687, the most distal marker on the long arm of chromosome 7. A short terminal 7EL segment translocated to 7A, including Lr19 and Y (line 1-23), has been transferred to durum wheat by backcrossing. The presence of this alien segment significantly increased the abundance of yellow pigment. The Lr19 also conferred resistance to a new durum leaf rust race from California and Mexico that is virulent on most durum wheat cultivars. The new durum lines with the recombinant 7E segment will be useful parents to increase yellow pigment and leaf rust resistance in durum wheat breeding programs. For the common wheat breeding programs, we selected the recombinant line 1-96, which has an interstitial 7E segment carrying Lr19 but not Y. This recombinant line can be used to improve leaf rust resistance without affecting flour color. The 7EL/7DL 1-96 recombinant chromosome did not show the meiotic self-elimination previously reported for a 7EL/7BL translocation.     

Red pigment in Bacillus megaterium spores

Bacillus megaterium QM B1551 spores contained a unique red pigment in their membranes that was not found in other species. This red pigment, presumably a carotenoid, was synthesized about the time of dipicolinic acid synthesis during sporulation and was associated with the forespores. A yellow pigment was synthesized during sporulation in rich medium and was found in the mother cell compartment. Although the yellow pigment was also associated with spores, it could be removed by two different extraction procedures without impairing germination; it was absent when sporulation occurred in a minimal medium. Although the yellow pigment of the mother cell appeared to be dispensable, the red pigment may serve a more critical function, such as membrane stabilization.     

Red pigment in Bacillus megaterium spores.

Bacillus megaterium QM B1551 spores contained a unique red pigment in their membranes that was not found in other species. This red pigment, presumably a carotenoid, was synthesized about the time of dipicolinic acid synthesis during sporulation and was associated with the forespores. A yellow pigment was synthesized during sporulation in rich medium and was found in the mother cell compartment. Although the yellow pigment was also associated with spores, it could be removed by two different extraction procedures without impairing germination; it was absent when sporulation occurred in a minimal medium. Although the yellow pigment of the mother cell appeared to be dispensable, the red pigment may serve a more critical function, such as membrane stabilization.     

Localization of the yellow pigment formed in roots of gramineous plants colonized by arbuscular fungi

Summary Many plants form yellow coloured roots when colonized by arbuscular mycorrhizal (AM) fungi. In maize, a yellow pigment is first visible as small droplets in parenchyma cells of roots in the vicinity of arbuscules, 3–4 weeks after mycorrhizal colonization. During the course of the development of the plants, the yellow pigment spreads all over the cells of the cortex (with the exception of the exodermis) and of the endodermis, whereas the other stelar elements remain uncoloured. Other gramineous plants (wheat, barley, millet) show the same pattern of pigment formation. In contrast, the deposition of this pigment is not detected in roots ofTagetes, garden bean, onion, or leek. Weak yellow fluorescence is also seen in the fungal structures, particularly in the arbuscules of the investigated probes. This is, however, clearly different from the intense yellow colour of the pigment formed in root cells of grasses. The yellow pigment is even detected in such cells which are never colonized by fungal structures (e.g., endodermal cells). A major constituent of the yellow pigment of AM-colonized root cells has been identified as a carotenoid with 14 carbon atoms and two carboxylic groups and termed mycorradicin. This carotenoid is likely deposited in the vacuoles of root cells as a result of the colonization specifically by arbuscular fungi.     

Biological Role of Pigment Production for the Bacterial Phytopathogen Pantoea stewartii subsp. stewartii

Pantoea stewartii subsp. stewartii, the causal agent of Stewart's wilt of sweet corn, produces a yellow carotenoid pigment. A nonpigmented mutant was selected from a bank of mutants generated by random transposon mutagenesis. The transposon insertion site was mapped to the crtB gene, encoding a putative phytoene synthase, an enzyme involved in the early steps of carotenoid biosynthesis. We demonstrate here that the carotenoid pigment imparts protection against UV radiation and also contributes to the complete antioxidant pathway of P. stewartii. Moreover, production of this pigment is regulated by the EsaI/EsaR quorum-sensing system and significantly contributes to the virulence of the pathogen in planta.     

An orthologue of the kit-related gene fms is required for development of neural crest-derived xanthophores and a subpopulation of adult melanocytes in the zebrafish, Danio rerio

Developmental mechanisms underlying traits expressed in larval and adult vertebrates remain largely unknown. Pigment patterns of fishes provide an opportunity to identify genes and cell behaviors required for postembryonic morphogenesis and differentiation. In the zebrafish, Danio rerio, pigment patterns reflect the spatial arrangements of three classes of neural crest-derived pigment cells: black melanocytes, yellow xanthophores and silver iridophores. We show that the D. rerio pigment pattern mutant panther ablates xanthophores in embryos and adults and has defects in the development of the adult pattern of melanocyte stripes. We find that panther corresponds to an orthologue of the c-fms gene, which encodes a type III receptor tyrosine kinase and is the closest known homologue of the previously identified pigment pattern gene, kit. In mouse, fms is essential for the development of macrophage and osteoclast lineages and has not been implicated in neural crest or pigment cell development. In contrast, our analyses demonstrate that fms is expressed and required by D. rerio xanthophore precursors and that fms promotes the normal patterning of melanocyte death and migration during adult stripe formation. Finally, we show that fms is required for the appearance of a late developing, kit-independent subpopulation of adult melanocytes. These findings reveal an unexpected role for fms in pigment pattern development and demonstrate that parallel neural crest-derived pigment cell populations depend on the activities of two essentially paralogous genes, kit and fms.     

Streptomyces coelicolor A3(2) produces a new yellow pigment associated with the polyketide synthase Cpk

Streptomyces coelicolor A3(2) is an extensively studied model organism for the genetic studies of Streptomycetes - a genus known for the production of a vast number of bioactive compounds and complex regulatory networks controlling morphological differentiation and secondary metabolites production. We present the discovery of a presumptive product of the Cpk polyketide synthase. We have found that on the rich medium without glucose S. coelicolor A3(2) produces a yellow compound secreted into the medium. We have proved by complementation that production of the observed yellow pigment is dependent on cpk gene cluster previously described as cryptic type I polyketide synthase cluster. The pigment production depends on the medium composition, does not occur in the presence of glucose, and requires high density of spore suspension used for inoculation.     

蛋用鹌鹑伴性羽色基因互作与连锁的关系

本研究首次发现了鹌鹑伴性羽基因的基因互作关系并进行了遗传验证.试验证明,鹌鹑的栗羽、黄羽和白羽是Z染色体上两个有连锁关系的基因座B/b和Y/y相互作用的结果.B和b为一对等位基因,不控制任何性状,只与色素的合成有关,B为有色基因,b为白化基因,B对b为显性;Y和y为另一对等位基因,分别控制栗羽和黄羽,Y对y为显性.栗羽和黄羽的表现取决于有色基因B的存在,B与Y相互作用产生栗羽,B与y相互作用产生黄羽,白羽是白化基因b对Y和y上位作用的结果.B/b和Y/y两基因座在雄性表现出一定的互换率,在雌性为完全连锁.这一研究补充和发展了以前人们对鹌鹑羽色伴性遗传的研究,为人们利用鹌鹑羽色进行自别雌雄配套系生产提供了重要的遗传学基础。 Abstract:The interaction of sex-linked gene for plumage color in quails was first discovered and identified by genetictest.It was proved that the phenotypic expressions of the maroon feather,the yellow feather and the white feather result from the interaction between B/b and Y/y loci in the Z-chromosome.The allele B and b have something to do with the composition of pigment in plumage and nothing to do with any relative characters,the coloured gene B is dominant to its albino allele b.The maroon and yellow feather constituted a pair of relative characters determined by a couple of alleles Y and y,the maroon feather was caused by a dominant allele Y,and the yellow feather caused by a recessive allele y.But the phenotypic expression of maroon and yellow was decided by the present of the coloured gene B in Z-chromosome,the maroon feather was the result of interaction between gene B and Y,the yellow feather was result of interaction between gene B and y.The white was caused by a recessive albino gene b which epistasis to gene Y and y.The incomplete linkage was present between B/b and Y/y in Z-chromosome in male and complete linkage in female.This research enriches and delelops the earlier studies of the sex-linked inheritance of plumage color.It provides an important genetic basis for the quail autosexing system production by means of plumage color.     

Drug-induced and genetic hypermelanism: effects on pigment cell differentiation

Allopurinol, a drug that inhibits the enzyme xanthine dehydrogenase (XDH), is known to cause hypermelanism in the axolotl. The hypermelanistic condition that results from allopurinol treatment is similar in most respects to the phenotype that results from the action of the melanoid (m) gene in axolotls. On the basis of structural and biochemical studies, it now seems clear that genetic and drug-induced hypermelanism are the same in the following ways. 1) Both types of melanism result in the production of more than normal amounts of melanin and more melanin-containing cells (melanophores). 2) In both cases the amount of pteridine-associated yellow pigment declines during development, and this is associated directly with fine structural changes that occur within the pigment organelles (pterinosomes) of yellow pigment cells (xanthophores). 3) In both cases the hypermelanistic condition results in the suppression of reflecting pigment cell (iridophore) differentiation. 4) Both conditions have now been linked directly to depressed levels of XDH activity. Thus both genetic and drug-induced hypermelanism result in alterations in the normal differentiation of all three pigment cell types and the subsequent disruption of normal pigment pattern formation. The possible significance of these findings with regard to factors known or suspected to direct the migration and/or differentiation of neural crest-derived pigment cells is discussed.     

Identification of a major gene and RAPD markers for yellow seed coat colour in Brassica napus.

The development of yellow-seeded Brassica napus for improving the canola-meal quality characteristics of lower fibre content and higher protein content has been restricted because no yellow-seeded forms of B. napus exist, and their conventional development requires interspecific introgression of yellow seed coat colour genes from related species. A doubled-haploid (DH) population derived from the F1 generation of the cross 'Apollo' (black-seeded) x YN90-1016 (yellow-seeded) B. napus was analysed via bulked segregant analysis to identify molecular markers associated with the yellow-seed trait in B. napus for future implementation in marker-assisted breeding. A single major gene (pigment 1) flanked by eight RAPD markers was identified co-segregating with the yellow seed coat colour trait in the population. This gene explained over 72% of the phenotypic variation in seed coat colour. Further analysis of the yellow-seeded portion of this DH population revealed two additional genes favouring 'Apollo' alleles, explaining 11 and 8.5%, respectively, of the yellow seed coat colour variation. The data suggested that there is a dominant, epistatic interaction between the pigment I locus and the two additional genes. The potential of the markers to be implemented in plant breeding for the yellow-seed trait in B. napus is discussed.     

A Transgenic Mouse Assay for Agouti Protein Activity

The mouse agouti gene encodes an 131 amino acid paracrine signaling molecule that instructs hair follicle melanocytes to switch from making black to yellow pigment. Expression of agouti during the middle part of the hair growth cycle in wild-type mice produces a yellow band on an otherwise black hair. The ubiquitous unregulated expression of agouti in mice carrying dominant yellow alleles is associated with pleiotropic effects including increased yellow pigment in the coat, obesity, diabetes and increased tumor susceptibility. Agouti shows no significant homology to known genes, and the molecular analysis of agouti alleles has shed little new light on the important functional elements of the agouti protein. In this paper, we show that agouti expression driven by the human β-ACTIN promoter produces obese yellow transgenic mice and that this can be used as an assay for agouti activity. We used this assay to evaluate a point mutation associated with the a(16H) allele within the region encoding agouti's putative signal sequence and our results suggest that this mutation is sufficient to cause the a(16H) phenotype. Thus, in vitro mutagenesis followed by the generation of transgenic mice should allow us to identify important functional elements of the agouti protein.