Crystal structure of the C2 domain from protein kinase C-δ

AbstractBackground: The protein kinase C (PKC) family of lipid-dependent serine/threonine kinases plays a central role in many intracellular eukaryotic signalling events. Members of the novel (δ, ϵ, η, θ) subclass of PKC isotypes lack the Ca2+ dependence of the conventional PKC isotypes and have an N-terminal C2 domain, originally defined as V0 (variable domain zero). Biochemical data suggest that this domain serves to translocate novel PKC family members to the plasma membrane and may influence binding of PKC activators.Results: The crystal structure of PKC-δ C2 domain indicates an unusual variant of the C2 fold. Structural elements unique to this C2 domain include a helix and a protruding β hairpin which may contribute basic sequences to a membrane-interaction site. The invariant C2 motif, Pro–X–Trp, where X is any amino acid, forms a short crossover loop, departing radically from its conformation in other C2 structures, and contains a tyrosine phosphorylation site unique to PKC-δ. This loop and two others adopt quite different conformations from the equivalent Ca2+-binding loops of phospholipase C-δ and synaptotagmin I, and lack sequences necessary for Ca2+ coordination.Conclusions: The N-terminal sequences of Ca2+-independent novel PKCs defines a divergent example of a C2 structure similar to that of phospholipase C-δ. The Ca2+-independent regulation of novel PKCs is explained by major structural and sequence differences resulting in three non-functional Ca2+-binding loops. The observed structural variation and position of a tyrosine-phosphorylation site suggest the existence of distinct subclasses of C2-like domains which may have evolved distinct functional roles and mechanisms to interact with lipid membranes