Reducing the Number of Subunits in the CAMKIIα Holoenzyme Alters Catalytic Domain Pairing, Diffusion Time, and T286 Autophosphorylation

Abstract

Calcium/Calmodulin (CaM) dependent protein kinase (CaMKII) is an important regulator of learning and memory, and it is thought to play a key role in sensing neuronal calcium oscillations. In cells, CaMKIIα primarily forms dodecamers comprised of two stacked rings of 6 subunits, each of which has 3 domains: an N-terminal catalytic domain, a C-terminal oligomerization domain, and between them, a regulatory domain. This regulatory domain activates the enzyme upon binding CaM and harbors a T286 autophosphorylation site that is associated with calcium independent persistent activation. To form the holoenzyme, the oligomerization domain of each subunit interacts with three other oligomerization domains: two laterally to form a ring of association domains, and one transversely to stabilize the double ring structure. Projecting outwards from the rings are catalytic domains, which form pairs, as indicated by homo-FRET analysis. Assemblies comprised of 8-14 subunits are also thought to exist, but it is not known if the number of subunits in the holoenzyme alters the activity or behavior of the catalytic domain pairs. To study the impact of subunit stoichiometry on catalytic domain pairing and T286 autophosphorylation, we generated mutants by altering oligomerization domain residues at the lateral interaction sites. Using fluorescence polarization and fluctuation analysis (FPFA) we simultaneously monitored homo-FRET between Venus-tagged catalytic domains, lateral diffusion of the holoenzyme, and the number of subunits present in these altered assemblies. We find that when the holoenzyme has fewer than 8 subunits, the holoenzyme diffusion time changes and homo-FRET between catalytic domains begins to attenuate. Finally, T286 autophosphorylation in a dimeric mutant holoenzyme is approximately half of that observed in the native holoenzyme. The structural implication of these changes will be discussed.