Abstract
Zebrafish has emerged as a powerful model in studies dealing with pigment development and pathobiology of pigment diseases. Due to its conserved pigment pattern with established genetic background, the zebrafish is used for screening of active compounds influencing melanophore, iridophore, and xanthophore development and differentiation. In our study, zebrafish embryos and larvae were used to investigate the influence of third-generation noncompetitive P-glycoprotein inhibitor, tariquidar (TQR), on pigmentation, including phenotype effects and changes in gene expression of chosen chromatophore differentiation markers. Five-day exposure to increasing TQR concentrations (1 µM, 10 µM, and 50 µM) resulted in a dose-dependent augmentation of the area covered with melanophores but a reduction in the area covered by iridophores. The observations were performed in three distinct regions—the eye, dorsal head, and tail. Moreover, TQR enhanced melanophore renewal after depigmentation caused by 0.2 mM 1-phenyl-2-thiourea (PTU) treatment. qPCR analysis performed in 56-h post-fertilization (hpf) embryos demonstrated differential expression patterns of genes related to pigment development and differentiation. The most substantial findings include those indicating that TQR had no significant influence on leukocyte tyrosine kinase, GTP cyclohydrolase 2, tyrosinase-related protein 1, and forkhead box D3, however, markedly upregulated tyrosinase, dopachrome tautomerase and melanocyte inducing transcription factor, and downregulated purine nucleoside phosphorylase 4a. The present study suggests that TQR is an agent with multidirectional properties toward pigment cell formation and distribution in the zebrafish larvae and therefore points to the involvement of P-glycoprotein in this process.
Highlights
The popularity of zebrafish as a model for studying vertebrate embryogenesis and development is constantly increasing
Based on the studies dealing with tyrosinase activity it can be assumed that pigment development starts from retinal pigment epithelium (RPE) around 21.5 h post fertilization and is followed by melanophore formation within the dorsolateral skin, where first cells are visible around 24 hpf [8]
To understand better pigment disorders in humans, the most valuable results obtained in zebrafish would be those dealing with pigment pattern variations and mutations observed in melanocytes, which represent pigment cells commonly found in all vertebrates
Summary
The popularity of zebrafish as a model for studying vertebrate embryogenesis and development is constantly increasing. Based on the studies dealing with tyrosinase activity it can be assumed that pigment development starts from RPE around 21.5 h post fertilization (hpf) and is followed by melanophore formation within the dorsolateral skin, where first cells are visible around 24 hpf [8]. The development of the striped pattern in zebrafish depends on a variety of genes that regulate pigment cell fate, proliferation, survival, migration, and differentiation [2]. In this regard, zebrafish serves as an excellent model, because of the sequenced genome and the availability of plenty of pigment mutants with known genetic backgrounds [2]. Based on recent investigations purine nucleoside phosphorylase 4a (pnp4a) has been proposed as a new marker of early iridoblast development and differentiation [10,12]
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