Dopamine binds calmodulin during autoregulation of dopaminergic D2 receptor signaling through CaMKIIα-calmodulin complex.

The role of dopaminergic D2 receptor (D2R) autoregulation in dopamine (DA) neurotransmission cannot be overemphasized in cause and progression of disorders associated with complex behaviors. Although previous studies have shown that D2R is structurally and physiologically linked with calcium/calmodulin-dependent kinase II (CaMKIIα), however, the role of calmodulin in the CaMKIIα complex in D2R regulation remains elusive. In this study, using structural biology modeling softwares (iGEMDOCK and CueMol), we have shown the interaction between D2R, CaMKIIα, calmodulin, and DA under varying conditions. The outcomes of this study suggest that CaMKIIα causes a change in DA binding affinity to the D2R receptive site while the detached DA binds to calmodulin to stop the activity of D2R in the D2R-dopaminergic D1 receptor (D1R) heteromer. Ultimately, we concluded that D2R autoregulates to stop its heteromeric combination with D1R. D2R interacts with D1R to facilitate calcium movement that activates calmodulin, then CaMKIIα. The CaMKIIα-calmodulin complex changes the affinity of DA-D2R causing DA to break free and bind with calmodulin.

Amyloid aggregation inhibitory mechanism of arginine-rich D-peptides.

It is widely believed that Alzheimer's disease pathogenesis is driven by the production and deposition of the amyloid-ß peptide (Aß) in the brain. In this study, we employ a combination of in silico and in vitro approaches to investigate the inhibitory properties of selected arginine-rich D-enantiomeric peptides (D-peptides) against amyloid aggregation. The D-peptides include D3, a 12-residue peptide with anti-amyloid potencies demonstrated in vitro and in vivo, RD2, a scrambled sequence of D3, as well as truncated RD2 variants. Using a global optimization method together with binding free energy calculations followed by molecular dynamics simulations, we perform a detailed analysis of D-peptide binding to Aß monomer and a fibrillar Aß structure. Results obtained from both molecular simulations and surface plasmon resonance experiments reveal a strong binding of D3 and RD2 to Aß, leading to a significant reduction in the amount of ß structures in both monomer and fibril, which was also demonstrated in Thioflavin T assays. The binding of the D-peptides to Aß is driven by electrostatic interactions, mostly involving the D-arginine residues and Glu11, Glu22 and Asp23 of Aß. Furthermore, we show that the anti-amyloid activities of the D-peptides depend on the length and sequence of the Dpeptide, its ability to form multiple weak hydrophobic interactions with Aß, as well as the Aß oligomer size.