A defect in the mitochondrial protein Mpv17 underlies the transparent casper zebrafish

D'Agati, Gianluca; Beltre, Rosanna; Sessa, Anna K.; Burger, Alexa; Zhou, Yi; Mosimann, Christian; White, Richard M.

doi:10.1016/j.ydbio.2017.07.017

Cited by 83 publications

(90 citation statements)

References 22 publications

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“…This metabolic fasting also activated transcriptional changes beyond gluconeogenesis genes and modulated other fasting adaptation pathways, such as β‐oxidation and cellular respiration, which drive ATP production in the mitochondria during low‐energy states (Houten, Violante, Ventura, & Wanders, ). A role for TSPO in regulating pigment patterning has not been uncovered, although changes in mitochondrial function and metabolic regulation have been noted to disrupt pigmentation in vertebrates (D'Agati et al, ).…”

Section: Introductionmentioning

confidence: 99%

GABA‐A receptor and mitochondrial TSPO signaling act in parallel to regulate melanocyte stem cell quiescence in larval zebrafish

Allen

Skeath

Johnson

2019

Pigment Cell Melanoma Res

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Tissue regeneration and homeostasis often require recruitment of undifferentiated precursors (adult stem cells; ASCs). While many ASCs continuously proliferate throughout the lifetime of an organism, others are recruited from a quiescent state to replenish their target tissue. A long‐standing question in stem cell biology concerns how long‐lived, non‐dividing ASCs regulate the transition between quiescence and proliferation. We study the melanocyte stem cell (MSC) to investigate the molecular pathways that regulate ASC quiescence. Our prior work indicated that GABA‐A receptor activation promotes MSC quiescence in larval zebrafish. Here, through pharmacological and genetic approaches we show that GABA‐A acts through calcium signaling to maintain MSC quiescence. Unexpectedly, we identified translocator protein (TSPO), a mitochondrial membrane‐associated protein that regulates mitochondrial function and metabolic homeostasis, as a parallel regulator of MSC quiescence. We found that both TSPO‐specific ligands and induction of gluconeogenesis likely act in the same pathway to promote MSC activation and melanocyte production in larval zebrafish. In contrast, TSPO and gluconeogenesis appear to act in parallel to GABA‐A receptor signaling to regulate MSC quiescence and vertebrate pigment patterning.

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Section: Introductionmentioning

confidence: 99%

GABA‐A receptor and mitochondrial TSPO signaling act in parallel to regulate melanocyte stem cell quiescence in larval zebrafish

Allen

Skeath

Johnson

2019

Pigment Cell Melanoma Res

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“…Transgenic lines used in these studies included wild-type ( AB ), casper (D'Agati et al, 2017;White et al, 2008) , and the triple line (Ceol et al, 2011) ( mitfa :BRAF V600E ; p53 -/-; mitfa -/-) (provided by the Houvras lab at Weill Cornell).…”

Section: Zebrafish Mutant Linesmentioning

confidence: 99%

Cancer modeling by Transgene Electroporation in Adult Zebrafish (TEAZ)

Callahan

Tepan

Zhang

et al. 2018

Preprint

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Transgenic animals are invaluable for modeling cancer genomics, but often require complex crosses of multiple germline alleles to obtain the desired combinations.Zebrafish models have advantages in that transgenes can be rapidly tested by mosaic expression, but these typically lack spatial and temporal control of tumor onset, which limits their utility for the study of tumor progression and metastasis. To overcome these limitations, we have developed a method called Transgene Electroporation in Adult Zebrafish (TEAZ). TEAZ can deliver DNA constructs with promoter elements of interest 2 to drive fluorophores, oncogenes, or CRISPR-Cas9-based mutagenic cassettes in specific cell types. Using TEAZ, we created a highly aggressive melanoma model by expression of BRAF V600E in spatially constrained melanocytes in the context of p53 deficiency and Cas9-mediated inactivation of Rb1. Unlike prior models that take ~4 months to develop, we found that TEAZ leads to tumor onset in ~7 weeks and these develop in fully immunocompetent animals. As the resulting tumors initiated at highly defined locations, we could track their progression via fluorescence and documented deep invasion into tissues and metastatic deposits. TEAZ can be deployed to other tissues and cell types such as the heart with the use of suitable transgenic promoters.The versatility of TEAZ makes it widely accessible for rapid modeling of somatic gene alterations and cancer progression at a scale not achievable in other in vivo systems.

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“…The roy mutant shows a recessive phenotype with complete loss of iridophores and partial reduction of melanophores. Recent studies using cDNA cloning reported that mpv17 (a gene encoding a mitochondrial inner membrane protein) in casper and roy mutants had a 19-bp deletion in its mRNA (between exons 2 and 3), which is possibly responsible for the iridophore loss [7,8]. A mpv17-knockdown zebrafish exhibited a moderate loss of iridophores along the body axis [8].…”

Section: Introductionmentioning

confidence: 99%

Genome and Transcriptome Sequencing of casper and roy Zebrafish Mutants Provides Novel Genetic Clues for Iridophore Loss

Bian

Chen

Ruan

et al. 2020

IJMS

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casper has been a widely used transparent mutant of zebrafish. It possesses a combined loss of reflective iridophores and light-absorbing melanophores, which gives rise to its almost transparent trunk throughout larval and adult stages. Nevertheless, genomic causal mutations of this transparent phenotype are poorly defined. To identify the potential genetic basis of this fascinating morphological phenotype, we constructed genome maps by performing genome sequencing of 28 zebrafish individuals including wild-type AB strain, roy orbison (roy), and casper mutants. A total of 4.3 million high-quality and high-confidence homozygous single nucleotide polymorphisms (SNPs) were detected in the present study. We also identified a 6.0-Mb linkage disequilibrium block specifically in both roy and casper that was composed of 39 functional genes, of which the mpv17 gene was potentially involved in the regulation of iridophore formation and maintenance. This is the first report of high-confidence genomic mutations in the mpv17 gene of roy and casper that potentially leads to defective splicing as one major molecular clue for the iridophore loss. Additionally, comparative transcriptomic analyses of skin tissues from the AB, roy and casper groups revealed detailed transcriptional changes of several core genes that may be involved in melanophore and iridophore degeneration. In summary, our updated genome and transcriptome sequencing of the casper and roy mutants provides novel genetic clues for the iridophore loss. These new genomic variation maps will offer a solid genetic basis for expanding the zebrafish mutant database and in-depth investigation into pigmentation of animals.

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A defect in the mitochondrial protein Mpv17 underlies the transparent casper zebrafish

Cited by 83 publications

References 22 publications

GABA‐A receptor and mitochondrial TSPO signaling act in parallel to regulate melanocyte stem cell quiescence in larval zebrafish

GABA‐A receptor and mitochondrial TSPO signaling act in parallel to regulate melanocyte stem cell quiescence in larval zebrafish

Cancer modeling by Transgene Electroporation in Adult Zebrafish (TEAZ)

Genome and Transcriptome Sequencing of casper and roy Zebrafish Mutants Provides Novel Genetic Clues for Iridophore Loss

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