The α2Na+/K+-ATPase is critical for skeletal and heart muscle function in zebrafish.

The Na(+)/K(+)-ATPase generates ion gradients across the plasma membrane, essential for multiple cellular functions. In mammals, four different Na(+)/K(+)-ATPase α-subunit isoforms are associated with characteristic cell-type expression profiles and kinetics. We found the zebrafish α2Na(+)/K(+)-ATPase associated with striated muscles and that knockdown causes a significant depolarization of the resting membrane potential in slow-twitch fibers of skeletal muscles. Abrupt mechanosensory responses were observed in α2Na(+)/K(+)-ATPase-deficient embryos, possibly linked to a postsynaptic defect. The α2Na(+)/K(+)-ATPase deficiency reduced the heart rate and caused a loss of left-right asymmetry in the heart tube. Similar phenotypes from knockdown of the Na(+)/Ca(2+) exchanger indicated a role for the interplay between these two proteins in the observed phenotypes. Furthermore, proteomics identified up- and downregulation of specific phenotype-related proteins, such as parvalbumin, CaM, GFAP and multiple kinases, thus highlighting a potential proteome change associated with the dynamics of α2Na(+)/K(+)-ATPase. Taken together, our findings show that zebrafish α2Na(+)/K(+)-ATPase is important for skeletal and heart muscle functions.

Localization of Kv2.2 protein in Xenopus laevis embryos and tadpoles.

Voltage-gated potassium (Kv) channels sculpt neuronal excitability and play important developmental roles. Kv channels consist of pore-forming alpha- and auxiliary subunits. For many Kv alpha-subunits, existing mRNA probes and antibodies have allowed analysis of expression patterns, typically during adult stages. Here, we focus on the Kv2.2 alpha-subunit, for which the mRNA shows broad expression in the embryo and adult. A lack of suitable antibodies, however, has hindered detailed analysis of Kv2.2 protein localization, especially during development. We developed an antibody that specifically recognizes Kv2.2 protein in Xenopus laevis, a vertebrate well suited for study of early developmental stages. The Kv2.2 antibody recognized heterologously expressed Kv2.2 but not the closely related Kv2.1 protein. Immunodetection of the protein showed its presence at St 32 in ventrolateral regions of the hindbrain and spinal cord. At later stages, several sensory tissues (retina, otic, and olfactory epithelia) also expressed Kv2.2 protein. As development progressed in the central nervous system, Kv2.2 protein distribution expanded in close association with the cytoskeletal marker alpha-tubulin, consistent with growth of neuronal tracts. We analyzed the subcellular distribution of Kv2.2 protein within single cultured neurons. In addition to a surface membrane presence, Kv2.2 protein also resided intracellularly closely associated with alpha-tubulin, as in vivo. Furthermore, in contrast to Kv2.1, Kv2.2 protein localized to long, axonal-like processes, consistent with its in vivo location in tracts. Despite their primary sequence similarity, the contrasting localizations of Kv2.1 and Kv2.2 support different roles for the two during development and neuronal signaling.

Kv1 potassium channel complexes in vivo require Kvbeta2 subunits in dorsal spinal neurons.

Whereas Kvbeta2 subunits modulate potassium current properties carried by Kv1 channel complexes in heterologous systems, little is known about the contributions of Kvbeta2 subunits to native potassium channel function. Using antisense approaches and in situ recordings from Xenopus embryo spinal cord neurons, we tested the in vivo roles of Kvbeta2 subunits in modulation of voltage-dependent potassium current (IKv). We focused on 1) two different populations of dorsal spinal neurons that express both Kvbeta2 and Kv1 alpha-subunit genes and 2) the 24- and 48-h developmental period, during which IKv undergoes developmental regulation. At both 24 and 48 h, antisense methods produced efficient knock-down of both Kvbeta2 protein and IKv. At both times, dominant negative suppression of Kv1 channels also eliminated IKv, indicating that Kv1 channels require Kvbeta2 subunits to function in dorsal spinal neurons. Even though Kv1 channels determined the IKv values of both dorsal neuron types, comparisons of their IKv properties revealed important differences at both developmental stages. The latter results support the notion that different Kv1 alpha-subunits and/or posttranslational modifications underlie the IKv values of the two dorsal neuron types. Overall, the results demonstrate that Kvbeta2 subunits function in vivo as obligatory subunits of Kv1 channels in at least two neuron types and two different developmental stages.