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Literature DB >> 16845369

Spot pattern of leopard Danio is caused by mutation in the zebrafish connexin41.8 gene.

Masakatsu Watanabe¹, Motoko Iwashita, Masaru Ishii, Yoshihisa Kurachi, Atsushi Kawakami, Shigeru Kondo, Norihiro Okada.

Abstract

Leopard, a well-known zebrafish mutant that has a spotted skin pattern instead of stripes, is a model for the study of pigment patterning. To understand the mechanisms underlying stripe formation, as well as the spot variation observed in leopard, we sought to identify the gene responsible for this phenotype. Using positional cloning, we identified the leopard gene as an orthologue of the mammalian connexin 40 gene. A variety of different leopard alleles, such as leo(t1), leo(tq270) and leo(tw28), show different skin-pattern phenotypes. In this manuscript we show that the mutation in allele leo(t1) is a nonsense mutation, whereas alleles leo(tq270) and leo(tw28) contain the missense mutations I202F and I31F, respectively. Patch-clamp experiments of connexin hemichannels demonstrated that the I202F substitution in allele leo(tq270) disrupted the channel function of connexin41.8. These results demonstrate that mutations in this gene lead to a variety of leopard spot patterns.

Entities: Disease Gene Mutation Species

Mesh：

Substances：

Year: 2006 PMID： 16845369 PMCID： PMC1559663 DOI： 10.1038/sj.embor.7400757

Source DB: PubMed Journal: EMBO Rep ISSN： 1469-221X Impact factor: 8.807

25 in total

Review 1. The reaction-diffusion system: a mechanism for autonomous pattern formation in the animal skin.

Authors: Shigeru Kondo
Journal: Genes Cells Date: 2002-06 Impact factor: 1.891

2. Molecular cloning, functional analysis, and RNA expression analysis of connexin45.6: a zebrafish cardiovascular connexin.

Authors: Tara L Christie; Rickie Mui; Thomas W White; Gunnar Valdimarsson
Journal: Am J Physiol Heart Circ Physiol Date: 2004-01-02 Impact factor: 4.733

3. Pigment cell distributions in different tissues of the zebrafish, with special reference to the striped pigment pattern.

Authors: Masashi Hirata; Kei-Ichiro Nakamura; Shigeru Kondo
Journal: Dev Dyn Date: 2005-10 Impact factor: 3.780

4. ATP released via gap junction hemichannels from the pigment epithelium regulates neural retinal progenitor proliferation.

Authors: Rachael A Pearson; Nicholas Dale; Enrique Llaudet; Peter Mobbs
Journal: Neuron Date: 2005-06-02 Impact factor: 17.173

5. Isoform composition of connexin channels determines selectivity among second messengers and uncharged molecules.

Authors: C G Bevans; M Kordel; S K Rhee; A L Harris
Journal: J Biol Chem Date: 1998-01-30 Impact factor: 5.157

6. Mutational analysis of endothelin receptor b1 (rose) during neural crest and pigment pattern development in the zebrafish Danio rerio.

Authors: D M Parichy; E M Mellgren; J F Rawls; S S Lopes; R N Kelsh; S L Johnson
Journal: Dev Biol Date: 2000-11-15 Impact factor: 3.582

7. A reaction-diffusion wave on the skin of the marine angelfish Pomacanthus.

Authors: S Kondo; R Asal
Journal: Nature Date: 1995-08-31 Impact factor: 49.962

8. Pigment cell organization in the hypodermis of zebrafish.

Authors: Masashi Hirata; Kei-ichiro Nakamura; Takaaki Kanemaru; Yosaburo Shibata; Shigeru Kondo
Journal: Dev Dyn Date: 2003-08 Impact factor: 3.780

9. Reduced gap junctional intercellular communication and altered biological effects in mouse osteoblast and rat liver oval cell lines transfected with dominant-negative connexin 43.

Authors: Brad L Upham; Junji Suzuki; Gang Chen; Yurong Wang; Laura R McCabe; Chia-Cheng Chang; Vladimir A Krutovskikh; Hiroshi Yamasaki; James E Trosko
Journal: Mol Carcinog Date: 2003-08 Impact factor: 4.784

Spot pattern of leopard Danio is caused by mutation in the zebrafish connexin41.8 gene.

Review 1. The reaction-diffusion system: a mechanism for autonomous pattern formation in the animal skin.

2. Molecular cloning, functional analysis, and RNA expression analysis of connexin45.6: a zebrafish cardiovascular connexin.

3. Pigment cell distributions in different tissues of the zebrafish, with special reference to the striped pigment pattern.

4. ATP released via gap junction hemichannels from the pigment epithelium regulates neural retinal progenitor proliferation.

5. Isoform composition of connexin channels determines selectivity among second messengers and uncharged molecules.

6. Mutational analysis of endothelin receptor b1 (rose) during neural crest and pigment pattern development in the zebrafish Danio rerio.

7. A reaction-diffusion wave on the skin of the marine angelfish Pomacanthus.

8. Pigment cell organization in the hypodermis of zebrafish.

9. Reduced gap junctional intercellular communication and altered biological effects in mouse osteoblast and rat liver oval cell lines transfected with dominant-negative connexin 43.

Review 10. Connexin disorders of the ear, skin, and lens.

Review 1. Lymphatic communication: connexin junction, what's your function?

2. Generation of a novel wing colour pattern by the Wingless morphogen.

3. A quantitative modelling approach to zebrafish pigment pattern formation.

4. Pattern regulation in the stripe of zebrafish suggests an underlying dynamic and autonomous mechanism.

Review 5. Gap junctional communication in morphogenesis.

6. Interactions between zebrafish pigment cells responsible for the generation of Turing patterns.

7. Embryonic requirements for ErbB signaling in neural crest development and adult pigment pattern formation.

Review 8. Not just black and white: pigment pattern development and evolution in vertebrates.

Review 9. Connexins, pannexins, innexins: novel roles of "hemi-channels".

10. Basonuclin-2 requirements for zebrafish adult pigment pattern development and female fertility.