Sodium channel auxiliary subunits.

Voltage-gated ion channels are well known for their functional roles in excitable tissues. Excitable tissues rely on voltage-gated ion channels and their auxiliary subunits to achieve concerted electrical activity in living cells. Auxiliary subunits are also known to provide functional diversity towards the transport and biogenesis properties of the principal subunits. Recent interests in pharmacological properties of these auxiliary subunits have prompted significant amounts of efforts in understanding their physiological roles. Some auxiliary subunits can potentially serve as drug targets for novel analgesics. Three families of sodium channel auxiliary subunits are described here: beta1 and beta3, beta2 and beta4, and temperature-induced paralytic E (TipE). While sodium channel beta-subunits are encoded in many animal genomes, TipE has only been found exclusively in insects. In this review, we present phylogenetic analyses, discuss potential evolutionary origins and functional data available for each of these subunits. For each family, we also correlate the functional specificity with the history of evolution for the individual auxiliary subunits.

Calcium channel auxiliary subunits.

Many channels and carriers associate with auxiliary subunits which modify their activities and facilitate biogenesis. Advances in genome sequencing as well as biochemical, molecular genetic, and physiological experimentation have allowed for the discovery of many transport auxiliary subunits. Recent interests in the pharmacology of the calcium auxiliary subunits prompted a large amount of effort in deciphering their specific role in the conductance of calcium ions. In this review, we evaluate the functions of the 'extra' subunits of the voltage-gated calcium channels in animals as an example of auxiliary subunits of transporters in general. We discuss the functional data available for each of these subunits, present phylogenetic analyses, and discuss their potential evolutionary origins. Our analyses also reveal novel homologues of these subunits which might be of interest to the community.