Cuthill Innes C, Allen William L, Kevin A, et al. The biology of color[J]. Science, 2017, 357(6350):470
|
Cal L, Suarez-Bregua P, Moran P, et al. Fish Pigmentation. A Key Issue for the Sustainable Development of Fish Farming[M]//Emerging Issues in Fish Larvae Research. Cham:Springer International Publishing, 2018:229-252
|
Kaur R, Dua A. Colour changes in Labeo rohita (Ham.) due to pigment translocation in melanophores, on exposure to municipal wastewater of Tung Dhab drain, Amritsar, India[J]. Environmental Toxicology and Pharmacology, 2015, 39(2):747-757
|
Lifshitz N, St Clair C C. Coloured ornamental traits could be effective and non-invasive indicators of pollution exposure for wildlife[J]. Conservation Physiology, 2016, 4(1):cow028
|
Parolini M, Iacobuzio R, Bassano B, et al. Melanin-based skin coloration predicts antioxidant capacity in the brown trout (Salmo trutta)[J]. Physiological and Biochemical Zoology, 2018, 91(5):1026-1035
|
Toft G, Baatrup E. Sexual characteristics are altered by 4-tert-octylphenol and 17beta-estradiol in the adult male guppy (Poecilia reticulata)[J]. Ecotoxicology and Environmental Safety, 2001, 48(1):76-84
|
McGree M M, Winkelman D L, Vieira N K M, et al. Reproductive failure of the red shiner (Cyprinella lutrensis) after exposure to an exogenous estrogen[J]. Canadian Journal of Fisheries and Aquatic Sciences, 2010, 67(11):1730-1743
|
Kristensen T, Baatrup E, Bayley M. 17α-ethinylestradiol reduces the competitive reproductive fitness of the male guppy (Poecilia reticulata)[J]. Biology of Reproduction, 2005, 72(1):150-156
|
吴鹏. 三丁基锡对孔雀鱼(Poecilia reticulata)性征和生殖的影响及机制研究[D]. 青岛:中国海洋大学, 2013:24-28 Wu P. Effects and mechanisms of tributyltin on sexual characteristics and reproduction of guppy (Poecilia reticulata)[D]. Qingdao:Ocean University of China, 2013:24
-28(in Chinese)
|
Zhang J L, Zhang C N, Li E C, et al. Triphenyltin exposure affects mating behaviors and attractiveness to females during mating in male guppies (Poecilia reticulata)[J]. Ecotoxicology and Environmental Safety, 2019, 169:76-84
|
Xiao Y, Jiang J Q, Hu W X, et al. Toxicity of triphenyltin on the development of retinal axons in zebrafish at low dose[J]. Aquatic Toxicology, 2017, 189:9-15
|
Ward J L, Blum M J. Exposure to an environmental estrogen breaks down sexual isolation between native and invasive species[J]. Evolutionary Applications, 2012, 5(8):901-912
|
Baatrup E, Junge M. Antiandrogenic pesticides disrupt sexual characteristics in the adult male guppy Poecilia reticulate[J]. Environmental Health Perspectives, 2001, 109(10):1063-1070
|
Arellano-Aguilar O, Macías Garcia C. Exposure to pesticides impairs the expression of fish ornaments reducing the availability of attractive males[J]. Proceedings Biological Sciences, 2008, 275(1640):1343-1350
|
Shenoy K. Environmentally realistic exposure to the herbicide atrazine alters some sexually selected traits in male guppies[J]. PLoS One, 2012, 7(2):e30611
|
李赟. 久效磷对孔雀鱼(Poecilia reticulata)性征的影响[D]. 青岛:中国海洋大学, 2008:43-48 Li Y. The effects of monocrotophos on sexual characteristics of guppies (Poecilia reticulata)[D]. Qingdao:Ocean University of China, 2008:43
-48(in Chinese)
|
Richterová Z, Máchová J, Stará A, et al. Effects of cyhalothrin-based pesticide on early life stages of common carp (Cyprinus carpio L.)[J]. BioMed Research International, 2014, 2014:107373
|
Pereira A, Carvalho A P, Cruz C, et al. Histopathological changes and zootechnical performance in juvenile zebrafish (Danio rerio) under chronic exposure to nitrate[J]. Aquaculture, 2017, 473:197-205
|
Avinashe A M. Zinc sulphate induced histopathological changes in architecture of trunk kidney of the air breathing fish, Heteropneustes fossilis (Bloch)[J]. Vidyabharati International Interdisciplinary Research Journal, 2014, 3(1):32-36
|
Bhavani K, Karuppasamy R. Acute toxicity bioassay and behavioural changes on zebrafish, Danio rerio (Hamilton) under arsenic trioxide[J]. International Journal of Modern Research and Reviews, 2014, 2(1):40-46
|
Lennquist A, Mårtensson Lindblad L G, Hedberg D, et al. Colour and melanophore function in rainbow trout after long term exposure to the new antifoulant medetomidine[J]. Chemosphere, 2010, 80(9):1050-1055
|
Nelson J A. Physiological observations on developing rainbow trout, Salmo gairdneri (Richardson), exposed to low pH and varied calcium ion concentrations[J]. Journal of Fish Biology, 1982, 20(3):359-372
|
Kaur R, Dua A. Fish scales as indicators of wastewater toxicity from an international water channel Tung Dhab drain[J]. Environmental Monitoring and Assessment, 2012, 184(5):2729-2740
|
Mojovic L, Dierksen K P, Upson R H, et al. Blind and native classification of toxicity by fish chromatophores[J]. Journal of Applied Toxicology, 2004, 24(5):355-361
|
Gronemeyer H, Gustafsson J Å, Laudet V. Principles for modulation of the nuclear receptor superfamily[J]. Nature Reviews Drug Discovery, 2004, 3(11):950-964
|
Huang R L, Xia M H, Cho M H, et al. Chemical genomics profiling of environmental chemical modulation of human nuclear receptors[J]. Environmental Health Perspectives, 2011, 119(8):1142-1148
|
Wang J Q, Hou L, Zhang R F, et al. The tyrosinase gene family and albinism in fish[J]. Chinese Journal of Oceanology and Limnology, 2007, 25(2):191-198
|
D'Alba L, Shawkey M D. Melanosomes:Biogenesis, properties, and evolution of an ancient organelle[J]. Physiological Reviews, 2019, 99(1):1-19
|
Olson V A, Owens I P F. Costly sexual signals:Are carotenoids rare, risky or required?[J]. Trends in Ecology & Evolution, 1998, 13(12):510-514
|
Dick C, Arendt J, Reznick D N, et al. The developmental and genetic trajectory of coloration in the guppy (Poecilia reticulata)[J]. Evolution & Development, 2018, 20(6):207-218
|
Braasch I, Schartl M, Volff J N. Evolution of pigment synthesis pathways by gene and genome duplication in fish[J]. BMC Evolutionary Biology, 2007, 7:74
|
Ziegler I, McDonald T, Hesslinger C, et al. Development of the pteridine pathway in the zebrafish, Danio rerio[J]. The Journal of Biological Chemistry, 2000, 275(25):18926-18932
|
Leclercq E, Taylor J F, Migaud H. Morphological skin colour changes in teleosts[J]. Fish and Fisheries, 2009, 11(2):159-193
|
Zhou L L, Liang H W, Zhou X Y, et al. Genetic characteristic and RNA-Seq analysis in transparent mutant of carp-goldfish nucleocytoplasmic hybrid[J]. Genes, 2019, 10(9):704
|
Higdon C W, Mitra R D, Johnson S L. Gene expression analysis of zebrafish melanocytes, iridophores, and retinal pigmented epithelium reveals indicators of biological function and developmental origin[J]. PLoS One, 2013, 8(7):e67801
|
Ng A, Uribe R A, Yieh L, et al. Zebrafish mutations in gart and paics identify crucial roles for de novo purine synthesis in vertebrate pigmentation and ocular development[J]. Development, 2009, 136(15):2601-2611
|
Welin M, Egeblad L, Johansson A, et al. Structural and functional studies of the human phosphoribosyltransferase domain containing protein 1[J]. The FEBS Journal, 2010, 277(23):4920-4930
|
Tian X, Pang X L, Wang L Y, et al. Dynamic regulation of mRNA and miRNA associated with the developmental stages of skin pigmentation in Japanese ornamental carp[J]. Gene, 2018, 666:32-43
|
Greenwood A K, Cech J N, Peichel C L. Molecular and developmental contributions to divergent pigment patterns in marine and freshwater sticklebacks[J]. Evolution & Development, 2012, 14(4):351-362
|
Hubbard J K, Uy J A, Hauber M E, et al. Vertebrate pigmentation:From underlying genes to adaptive function[J]. Trends in Genetics, 2010, 26(5):231-239
|
Braasch I, Volff J N, Schartl M. The evolution of teleost pigmentation and the fish-specific genome duplication[J]. Journal of Fish Biology, 2008, 73(8):1891-1918
|
Wishkerman A, Boglino A, Darias M J, et al. Image analysis-based classification of pigmentation patterns in fish:A case study of pseudo-albinism in Senegalese sole[J]. Aquaculture, 2016, 464:303-308
|
Aybar M J, Glavic A, Mayor R. Extracellular signals, cell interactions and transcription factors involved in the induction of the neural crest cells[J]. Biological Research, 2002, 35(2):267-275
|
Patterson L B, Parichy D M. Zebrafish pigment pattern formation:Insights into the development and evolution of adult form[J]. Annual Review of Genetics, 2019, 53(1):505-530
|
Varghese T, Ebeneezar S, Sreekanth G B, et al. Into the pigmentation of fish:A physiological perspective[J]. International Journal of Science and Research, 2014, 3(12):1053
|
蒋锐达, 赵敏, 赵三军, 等. 胚胎发育中神经嵴细胞迁移机制的研究进展[J]. 基因组学与应用生物学, 2018, 37(9):3799-3809
Jiang R D, Zhao M, Zhao S J, et al. Research advance on the migration mechanism of neural crest cell during embryonic development[J]. Genomics and Applied Biology, 2018, 37(9):3799-3809(in Chinese)
|
Williams J S, Hsu J Y, Rossi C C, et al. Requirement of zebrafish pcdh10a and pcdh10b in melanocyte precursor migration[J]. Developmental Biology, 2018, 444(Suppl 1):S274-S286
|
Eom D S, Inoue S, Patterson L B, et al. Melanophore migration and survival during zebrafish adult pigment stripe development require the immunoglobulin superfamily adhesion molecule Igsf11[J]. PLoS Genetics, 2012, 8(8):e1002899
|
Braasch I, Brunet F, Volff J N, et al. Pigmentation pathway evolution after whole-genome duplication in fish[J]. Genome Biology and Evolution, 2009, 1:479-493
|
Kottler V A, Künstner A, Schartl M. Pheomelanin in fish?[J]. Pigment Cell & Melanoma Research, 2015, 28(3):355-356
|
Darias M J, Andree K B, Boglino A, et al. Coordinated regulation of chromatophore differentiation and melanogenesis during the ontogeny of skin pigmentation of Solea senegalensis (Kaup, 1858)[J]. PLoS One, 2013, 8(5):e63005
|
Béjar J, Hong Y H, Schartl M. Mitf expression is sufficient to direct differentiation of medaka blastula derived stem cells to melanocytes[J]. Development, 2003, 130(26):6545-6553
|
Parichy D M, Ransom D G, Paw B, et al. 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[J]. Development, 2000, 127(14):3031-3044
|
Dooley C M, Mongera A, Walderich B, et al. On the embryonic origin of adult melanophores:The role of ErbB and Kit signalling in establishing melanophore stem cells in zebrafish[J]. Development, 2013, 140(5):1003-1013
|
van Bebber F, Hruscha A, Willem M, et al. Loss of Bace2 in zebrafish affects melanocyte migration and is distinct from Bace1 knock out phenotypes[J]. Journal of Neurochemistry, 2013, 127(4):471-481
|
Fujii R. The regulation of motile activity in fish chromatophores[J]. Pigment Cell Research, 2000, 13(5):300-319
|
Kawauchi H, Kawazoe I, Tsubokawa M, et al. Characterization of melanin-concentrating hormone in chum salmon pituitaries[J]. Nature, 1983, 305(5932):321-323
|
Logan D W, Burn S F, Jackson I J. Regulation of pigmentation in zebrafish melanophores[J]. Pigment Cell Research, 2006, 19(3):206-213
|
Sugimoto M. Morphological color changes in fish:Regulation of pigment cell density and morphology[J]. Microscopy Research and Technique, 2002, 58(6):496-503
|
Sugimoto M, Yuki M, Miyakoshi T, et al. The influence of long-term chromatic adaptation on pigment cells and striped pigment patterns in the skin of the zebrafish, Danio rerio[J]. Journal of Experimental Zoology Part A, Comparative Experimental Biology, 2005, 303(6):430-440
|
van der Salm A L, Metz J R, Bonga S E, et al. Alpha-MSH, the melanocortin-1 receptor and background adaptation in the Mozambique tilapia, Oreochromis mossambicus[J]. General and Comparative Endocrinology, 2005, 144(2):140-149
|
Dijkstra P D, Maguire S M, Harris R M, et al. The melanocortin system regulates body pigmentation and social behaviour in a colour polymorphic cichlid fish[J]. Proceedings of the Royal Society B:Biological Sciences, 2017, 284(1851):20162838
|
Cal L, Suarez-Bregua P, Cerdá-Reverter J M, et al. Fish pigmentation and the melanocortin system[J]. Comparative Biochemistry and Physiology Part A, Molecular & Integrative Physiology, 2017, 211:26-33
|
Sefc K M, Brown A C, Clotfelter E D. Carotenoid-based coloration in cichlid fishes[J]. Comparative Biochemistry and Physiology Part A:Molecular & Integrative Physiology, 2014, 173:42-51
|
Svensson, Wong. Carotenoid-based signals in behavioural ecology:A review[J]. Behaviour, 2011, 148(2):131-189
|
Faivre B, Grégoire A, Préault M, et al. Immune activation rapidly mirrored in a secondary sexual trait[J]. Science, 2003, 300(5616):103
|
Schweikert L E, Fitak R R, Johnsen S. De novo transcriptomics reveal distinct phototransduction signaling components in the retina and skin of a color-changing vertebrate, the hogfish (Lachnolaimus maximus)[J]. Journal of Comparative Physiology A, Neuroethology, Sensory, Neural, and Behavioral Physiology, 2018, 204(5):475-485
|
Kingston A C, Kuzirian A M, Hanlon R T, et al. Visual phototransduction components in cephalopod chromatophores suggest dermal photoreception[J]. The Journal of Experimental Biology, 2015, 218(Pt 10):1596-1602
|
Ban E, Kasai A, Sato M, et al. The signaling pathway in photoresponses that may be mediated by visual pigments in erythrophores of Nile tilapia[J]. Pigment Cell Research, 2005, 18(5):360-369
|
Ramirez M D, Oakley T H. Eye-independent, light-activated chromatophore expansion (LACE) and expression of phototransduction genes in the skin of Octopus bimaculoides[J]. The Journal of Experimental Biology, 2015, 218(Pt 10):1513-1520
|
Chen S C, Xiao C F, Troje N F, et al. Functional characterisation of the chromatically antagonistic photosensitive mechanism of erythrophores in the tilapia Oreochromis niloticus[J]. The Journal of Experimental Biology, 2015, 218(Pt 5):748-756
|
Chen S C, Robertson R M, Hawryshyn C W. Possible involvement of cone opsins in distinct photoresponses of intrinsically photosensitive dermal chromatophores in tilapia Oreochromis niloticus[J]. PLoS One, 2013, 8(8):e70342
|
Shao C W, Bao B L, Xie Z Y, et al. The genome and transcriptome of Japanese flounder provide insights into flatfish asymmetry[J]. Nature Genetics, 2017, 49(1):119-124
|
Estévez A, Sameshima M, Ishikawa M, et al. Effect of diets containing low levels of methionine and oxidized oil on body composition, retina structure and pigmentation success of Japanese flounder[J]. Aquaculture Nutrition, 1997, 3(3):201-216
|
Kanazawa A. Nutritional mechanisms involved in the occurrence of abnormal pigmentation in hatchery-reared flatfish[J]. Journal of the World Aquaculture Society, 1993, 24(2):162-166
|
Bolker J A, Hill C R. Pigmentation development in hatchery-reared flatfishes[J]. Journal of Fish Biology, 2000, 56(5):1029-1052
|
Neuhauss S C, Biehlmaier O, Seeliger M W, et al. Genetic disorders of vision revealed by a behavioral screen of 400 essential loci in zebrafish[J]. The Journal of Neuroscience:the official Journal of the Society for Neuroscience, 1999, 19(19):8603-8615
|
García-Heras M S, Arroyo B, Simmons R E, et al. Pollutants and diet influence carotenoid levels and integument coloration in nestlings of an endangered raptor[J]. Science of the Total Environment, 2017, 603-604:299-307
|
Larsen M G, Hansen K B, Henriksen P G, et al. Male zebrafish (Danio rerio) courtship behaviour resists the feminising effects of 17alpha-ethinyloestradiol-Morphological sexual characteristics do not[J]. Aquatic Toxicology, 2008, 87(4):234-244
|
Laskey J W, Phelps P V. Effect of cadmium and other metal cations on in vitro Leydig cell testosterone production[J]. Toxicology and Applied Pharmacology, 1991, 108(2):296-306
|
Blas J, Pérez-Rodríguez L, Bortolotti G R, et al. Testosterone increases bioavailability of carotenoids:Insights into the honesty of sexual signaling[J]. Proceedings of the National Academy of Sciences of the United States of America, 2006, 103(49):18633-18637
|
Noriega N C, Hayes T B. DDT congener effects on secondary sex coloration in the reed frog Hyperolius argus:A partial evaluation of the Hyperolius argus endocrine screen[J]. Comparative Biochemistry and Physiology Part B, Biochemistry & Molecular Biology, 2000, 126(2):231-237
|
Allen T, Awasthi A, Rana S V S. Fish chromatophores as biomarkers of arsenic exposure[J]. Environmental Biology of Fishes, 2004, 71(1):7-11
|
Prota G. Regulatory mechanisms of melanogenesis:Beyond the tyrosinase concept[J]. The Journal of Investigative Dermatology, 1993, 100(2 Suppl):156S-161S
|
Jawor J M, Breitwisch R. Melanin ornaments, honesty, and sexual selection[J]. The Auk, 2003, 120(2):249-265
|
Lerner A B. Effect of ions on melanin formation[J]. The Journal of Investigative Dermatology, 1952, 18(1):47-52
|
Spickler J L, Swaddle J P, Gilson R L, et al. Sexually selected traits as bioindicators:Exposure to mercury affects carotenoid-based male bill color in zebra finches[J]. Ecotoxicology, 2020, 29(8):1138-1147
|
Dauwe T, Eens M. Melanin- and carotenoid-dependent signals of great tits (Parus major) relate differently to metal pollution[J]. Die Naturwissenschaften, 2008, 95(10):969-973
|
刘文敏, 张晓娜, 魏朋浩, 等. 双酚S长期暴露对雌性斑马鱼视觉系统的影响[J]. 中国海洋大学学报:自然科学版, 2018, 48(11):71-78
Liu W M, Zhang X N, Wei P H, et al. Effects of long-term exposure to bisphenol S on the visual system of female zebrafish (Danio rerio)[J]. Periodical of Ocean University of China, 2018, 48(11):71-78(in Chinese)
|
Yuan J, Zhang X L, Yu L, et al. Stage-specific malformations and phenotypic changes induced in embryos of amphibian (Xenopus tropicalis) by triphenyltin[J]. Ecotoxicology and Environmental Safety, 2011, 74(7):1960-1966
|
Tanaka Y. Ecological risk assessment of pollutant chemicals:Extinction risk based on population-level effects[J]. Chemosphere, 2003, 53(4):421-425
|