Developmental and Cellular Basis of Vertical Bar Color Patterns in the East African Cichlid Fish Haplochromis latifasciatus

Liang, Yipeng; Gerwin, Jan; Meyer, Axel; Kratochwil, Claudius F.

doi:10.3389/fcell.2020.00062

Cited by 33 publications

(43 citation statements)

References 87 publications

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“…To test whether and how the morphological color change in M. auratus can be explained by changes in chromatophore number, distribution and characteristics, we compared chromatophores in yellow and dark morph using light microscopy of whole-mount scale preparations. In line with previous descriptions for cichlids 7,38 , three types of chromatophores could be detected in both morphs: melanophores with black to dark brown pigmentation, xanthophores with yellow to orange pigmentation, and iridophores that produce iridescent/reflective colors ( Supplementary Fig. S1).…”

Section: Resultssupporting

confidence: 89%

“…Photographs of M. auratus scales were captured on Leica DM6B upright microscope with a Leica DMC 2900 camera. We captured images in three different modes: brightfield for melanophore coverage and dispersed diameter, polarized light for iridophore coverage 7 , fluorescent with GFP filter for xanthophore coverage and dispersed diameter 80,81 . To count the number of melanophores and xanthophores, we treated the scales immediately after taking the above photos with 10 mg/ml adrenaline (SIGMA-ALDRICH) for 5 min at room temperature on microscope slides to aggregate the melanosomes which permit robust cell number quantification ( Supplementary Fig.…”

Section: Light Microscope Image Acquisition For Fish Scalesmentioning

confidence: 99%

“…In vertebrates the color of the integument is shaped by the multilayered arrangement and interaction of cells with different pigmentary and structural properties 5 . Variations in the density, shape and properties of chromatophores and the intracellular organization of pigments and reflective molecules shapes the macroscopic appearance of the integument 6 , 7 . Several types of pigment-bearing and light-reflecting chromatophores have been identified in teleosts 8 .…”

Section: Introductionmentioning

confidence: 99%

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Neural innervation as a potential trigger of morphological color change and sexual dimorphism in cichlid fish

Liang

Meyer

Kratochwil

2020

Sci Rep

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Many species change their coloration during ontogeny or even as adults. color change hereby often serves as sexual or status signal. the cellular and subcellular changes that drive color change and how they are orchestrated have been barely understood, but a deeper knowledge of the underlying processes is important to our understanding of how such plastic changes develop and evolve. Here we studied the color change of the Malawi golden cichlid (Melanchromis auratus). females and subordinate males of this species are yellow and white with two prominent black stripes (yellow morph; female and non-breeding male coloration), while dominant males change their color and completely invert this pattern with the yellow and white regions becoming black, and the black stripes becoming white to iridescent blue (dark morph; male breeding coloration). A comparison of the two morphs reveals that substantial changes across multiple levels of biological organization underlie this polyphenism. these include changes in pigment cell (chromatophore) number, intracellular dispersal of pigments, and tilting of reflective platelets (iridosomes) within iridophores. At the transcriptional level, we find differences in pigmentation gene expression between these two color morphs but, surprisingly, 80% of the genes overexpressed in the dark morph relate to neuronal processes including synapse formation. Nerve fiber staining confirms that scales of the dark morph are indeed innervated by 1.3 to 2 times more axonal fibers. Our results might suggest an instructive role of nervous innervation orchestrating the complex cellular and ultrastructural changes that drive the morphological color change of this cichlid species. Coloration is an important feature that plays crucial roles in terms of natural and sexual selection. It can serve in predator avoidance, prey capture through camouflage, conspecific communication and protection from radiation 1,2. Besides these ecological and evolutionary aspects, the formation of pigment patterns provides insights into the genetic basis of adaptive evolution 3 as well as the formation of complex tissues 4. In vertebrates the color of the integument is shaped by the multilayered arrangement and interaction of cells with different pigmentary and structural properties 5. Variations in the density, shape and properties of chromatophores and the intracellular organization of pigments and reflective molecules shapes the macroscopic appearance of the integument 6,7. Several types of pigment-bearing and light-reflecting chromatophores have been identified in teleosts 8. The most common cell types are melanophores (containing the brown to black pigment melanin), xanthophores/erythrophores (containing yellow to red pigments including carotenoids and pteridines), leucophores (white) and iridophores (containing guanine platelet crystals that produce structural coloration) 9. Although coloration is often perceived and studied as a static trait, it can change very dynamically on different time scales during the lifetime of a...

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Section: Resultssupporting

confidence: 89%

Section: Light Microscope Image Acquisition For Fish Scalesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Neural innervation as a potential trigger of morphological color change and sexual dimorphism in cichlid fish

Liang

Meyer

Kratochwil

2020

Sci Rep

Self Cite

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“…RNA extraction, complementary DNA (cDNA) synthesis and RT‐qPCR were performed as previous described (Kratochwil et al, 2018; Liang et al, 2020). Briefly, dissected skin tissues were stored in RNAlater (Invitrogen).…”

Section: Methodsmentioning

confidence: 99%

Functional conservation and divergence of color‐pattern‐related agouti family genes in teleost fishes

et al. 2021

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While color patterns are highly diverse across the animal kingdom, certain patterns such as countershading and stripe patterns have evolved repeatedly. Across vertebrates, agouti‐signaling genes have been associated with the evolution of both patterns. Here we study the functional conservation and divergence by investigating the expression patterns of the two color‐pattern‐related agouti‐signaling genes, agouti‐signaling protein 1 (asip1) and agouti‐signaling protein 2b (asip2b, also known as agrp2) in Teleostei. We show that the dorsoventral expression profile of asip1 and the role of the “stripe repressor” asip2b are shared across multiple teleost lineages and uncover a previously unknown association between stripe–interstripe patterning and both asip1 and asip2b expression. In some species, including the zebrafish (Danio rerio), these two genes show complementary and overlapping expression patterns in line with functional redundancy. Our results thus suggest how conserved and novel functions of agouti‐signaling genes might have shaped the evolution of color patterns across teleost fishes.

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“…chromatophores; mainly melanophores, iridophores, leucophores and xanthophores) are distributed in the hypo- and the epidermis in fish, and mutational or other analyses allowed for increased understanding in the complex mechanisms of pigment cell fates during development and their resulting distribution (Kelsh et al, 2004, 2009; Kimura et al, 2014; Eom, Bain, Patterson, Grout, & Parichy, 2015; Nüsslein-Völlard & Singh, 2017; Parichy & Spiewak, 2015; Singh & Nüsslein-Völlard, 2015; Salis et al, 2018; Volkening 2020). Studies now extend to other fish species (Maan & Sfec, 2013; Irion & Nüsslein-Völlard, 2019) and to a large array of eco-evolutionary questions regarding the involvement of genes or regulatory pathways in fish pigmentation, its epistatic and pleiotropic nature, its modularity and its control, sexually antagonist selection or its role in speciation as well as the impact of whole-genome duplication that promoted the diversification of pigment cell lineages (Hultman, Bahary, Zon, & Johnson, 2007; Miller et al, 2007; Braasch, Brunet, Volff, & Schartl, 2009; Roberts, Ser & Kocher, 2009; Albertson et al, 2014; Santos et al 2014; Ceinos, Guillot, Kelsh, Cerdá-Reveter, & Rotlland, 2015; Yong, Peichel, & McKinnon, 2015; Gu & Xia 2017; Kimura, Takehana, & Naruse, 2017; Roberts, Moore, & Kocher, 2017; Sefc et al, 2017; Lorin, Brunet, Laudet, & Volff, 2018; Kratochwil et al, 2018; Nagao et al, 2018; Cal et al, 2019; Lewis et al, 2019; Kon et al, 2020; Liang, Gerwin, Meyer, & Kratochwil, 2020). An increasing number of studies engaged fish research in high-throughput genomic approach of pigmentation variation (guppy: Tripathi et al, 2009; three-spine stickleback: Greenwood et al, 2011; Malek, Boughman, Dworkin, & Peichel, 2012; cichlids: O’Quin, Drilea, Conte, & Kocher, 2013; Henning, Jones, Franchini, & Meyer, 2013; Henning, Lee, Franchini, & Meyer, 2014; Albertson et al, 2014; Zhu et al, 2016; Roberts et al 2017; koi carp: Xu et al, 2014; arowana: Bian et al, 2016; goldfish: Kon et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Spotting genome-wide pigmentation variation in a brown trout admixture context

Valette¹,

Leitwein

Lascaux³

et al. 2020

Preprint

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Colour and pigmentation variation attracted fish biologists for a while, but high-throughput genomic studies investigating the molecular basis of body pigmentation remain still limited to few species and conservation biology issues ignored. Using 75,684 SNPs, we investigated the genomic basis of pigmentation pattern variation among individuals of the Atlantic and Mediterranean clades of the brown trout (Salmo trutta), a polytypic species in which Atlantic hatchery individuals are commonly used to supplement local wild populations. Using redundancy analyses and genome-wide association studies, a set of 384 “colour patterning loci” (CPL) significantly correlated with pigmentation traits such as the number of red and black spots on flanks, but also the presence of a large black stain on the opercular bone was identified. CPLs map onto 35 out of 40 brown trout linkage groups indicating a polygenic basis to pigmentation patterns. They are mostly located in coding regions (43.4%) of 223 candidate genes, and correspond to GO-terms known to be involved in pigmentation (e.g. calcium and ion-binding, cell adhesion). Annotated genes especially include 24 candidates with known pigmentation effects (e.g. SOX10, PEML, SLC45A2), but also the Gap-junction Δ2 (GJD2) gene that was previously showed be differentially expressed in trout skin. Patterns of admixture were found significantly distinct when using either the full SNP data set or the set of CPLs, indicating that pigmentation patterns accessible to practitioners are not a reliable proxy of genome-wide admixture. Consequences for management are discussed.

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Developmental and Cellular Basis of Vertical Bar Color Patterns in the East African Cichlid Fish Haplochromis latifasciatus

Cited by 33 publications

References 87 publications

Neural innervation as a potential trigger of morphological color change and sexual dimorphism in cichlid fish

Neural innervation as a potential trigger of morphological color change and sexual dimorphism in cichlid fish

Functional conservation and divergence of color‐pattern‐related agouti family genes in teleost fishes

Spotting genome-wide pigmentation variation in a brown trout admixture context

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