Genetic compensation of γ CaMKII, an evolutionarily conserved gene.

CaMKII is a Ca2+/CaM-dependent protein kinase encoded by a family of conserved genes found throughout all metazoan species and expressed from fertilization into adulthood. One of these genes, camk2g1, is particularly important during early development as determined by pharmacologic, dominant negative and antisense morpholino approaches in zebrafish. Four other teleost fish species (cavefish, medaka, stickleback, and tilapia), exhibit sequence conservation of camk2g1 and duplication of the same CaMKII genes. A homozygous mutant of camk2g1 was generated in zebrafish using TALEN technology but yielded none of the phenotypic alterations seen using all other approaches and was reproductively viable. However, these camk2g1 mutant embryos showed a 4-fold over-expression of its paralog camk2g2. None of the other camk2 genes showed such transcriptional elevation, in fact, some of these genes were suppressed to 10% of wild type levels. In contrast, G0 camk2g1 CRISPR/Cas9 embryos recapitulated nearly all of the altered phenotypes observed in camk2g1 morphants, including renal, aural and ciliary defects. These findings validate the importance of this gene family during early zebrafish development and provide evidence for gene-specific transcriptional cross-talk consistent with genetic compensation.

Calcium signals act through histone deacetylase to mediate pronephric kidney morphogenesis.

BACKGROUND: Autosomal dominant polycystic kidney disease is the most common monogenetic kidney disorder and is linked to mutations in PKD1 and PKD2. PKD2, a Ca2+ -conducting TRP channel enriched in ciliated cells and gated by extracellular signals, is necessary to activate the multifunctional Ca2+/ calmodulin-dependent protein kinase type 2 (CaMK-II), enabling kidney morphogenesis and cilia stability. RESULTS: In this study, antisense morpholino oligonucleotides and pharmacological compounds were employed to investigate the roles of class II HDAC family members (HDAC 4, 5, and 6) in Zebrafish kidney development. While all three class II HDAC genes were expressed throughout the embryo during early development, HDAC5-morphant embryos exhibited anterior cysts and destabilized cloacal cilia, similar to PKD2 and CaMK-II morphants. In contrast, HDAC4-morphant embryos exhibited elongated cloacal cilia and lacked anterior kidney defects. Suppression of HDAC4 partially reversed the cilia shortening and anterior convolution defects caused by CaMK-II deficiency, whereas HDAC5 loss exacerbated these defects. EGFP-HDAC4, but not EGFP-HDAC5, translocated into the nucleus upon CaMK-II suppression in pronephric kidney cells. CONCLUSIONS: These results support a model by which activated CaMK-II sequesters HDAC4 in the cytosol to enable primary cilia formation and kidney morphogenesis. Developmental Dynamics 247:807-817, 2018. © 2018 Wiley Periodicals, Inc.