|ZFIN ID: ZDB-PUB-150729-2|
Inactivation of ca10a and ca10b Genes Leads to Abnormal Embryonic Development and Alters Movement Pattern in Zebrafish
Aspatwar, A., Tolvanen, M.E., Ojanen, M.J., Barker, H.R., Saralahti, A.K., Bäuerlein, C.A., Ortutay, C., Pan, P., Kuuslahti, M., Parikka, M., Rämet, M., Parkkila, S.
|Source:||PLoS One 10: e0134263 (Journal)|
|Keywords:||Larvae, Zebrafish, Sequence motif analysis, Embryos, Sequence alignment, Sequence databases, Multiple alignment calculation, Gene expression|
|PubMed:||26218428 Full text @ PLoS One|
Aspatwar, A., Tolvanen, M.E., Ojanen, M.J., Barker, H.R., Saralahti, A.K., Bäuerlein, C.A., Ortutay, C., Pan, P., Kuuslahti, M., Parikka, M., Rämet, M., Parkkila, S. (2015) Inactivation of ca10a and ca10b Genes Leads to Abnormal Embryonic Development and Alters Movement Pattern in Zebrafish. PLoS One. 10:e0134263.
ABSTRACTCarbonic anhydrase related proteins (CARPs) X and XI are highly conserved across species and are predominantly expressed in neural tissues. The biological role of these proteins is still an enigma. Ray-finned fish have lost the CA11 gene, but instead possess two co-orthologs of CA10. We analyzed the expression pattern of zebrafish ca10a and ca10b genes during embryonic development and in different adult tissues, and studied 61 CARP X/XI-like sequences to evaluate their phylogenetic relationship. Sequence analysis of zebrafish ca10a and ca10b reveals strongly predicted signal peptides, N-glycosylation sites, and a potential disulfide, all of which are conserved, suggesting that all of CARP X and XI are secretory proteins and potentially dimeric. RT-qPCR showed that zebrafish ca10a and ca10b genes are expressed in the brain and several other tissues throughout the development of zebrafish. Antisense morpholino mediated knockdown of ca10a and ca10b showed developmental delay with a high rate of mortality in larvae. Zebrafish morphants showed curved body, pericardial edema, and abnormalities in the head and eye, and there was increased apoptotic cell death in the brain region. Swim pattern showed abnormal movement in morphant zebrafish larvae compared to the wild type larvae. The developmental phenotypes of the ca10a and ca10b morphants were confirmed by inactivating these genes with the CRISPR/Cas9 system. In conclusion, we introduce a novel zebrafish model to investigate the mechanisms of CARP Xa and CARP Xb functions. Our data indicate that CARP Xa and CARP Xb have important roles in zebrafish development and suppression of ca10a and ca10b expression in zebrafish larvae leads to a movement disorder.