Shuffled lipidation pattern and degree of lipidation determines the membrane interaction behavior of a linear cationic membrane-active peptide.

HYPOTHESIS: Permeation of macromolecular drugs across biological plasma membranes is a major challenge in drug delivery. Cationic cell-penetrating peptides (CPPs) are attractive functional excipient candidates for the delivery of macromolecules across membrane barriers, due to their membrane translocating ability. The properties of CPPs can be tailored by lipidation, a promising approach to facilitate enhanced membrane insertion, potentially promoting increased translocation of the CPP and cargo. EXPERIMENTS: To explore the impact that site and degree of lipidation have on the membrane interaction of a cationic CPP, we designed and investigated CPP conjugates with one or two fatty acid chains. FINDINGS: Compared to the parent CPP and the single-lipidated conjugates, the double-lipidated conjugate exhibited the most pronounced membrane perturbation effects, as measured by several biophysical techniques. The experimental findings were supported by molecular dynamics (MD) simulations, demonstrating that all CPP conjugates interacted with the membrane by insertion of the lipid chain(s) into the core of the bilayer. Moreover, membrane-thinning effects and induced membrane curvature were displayed upon CPP interaction. Our results demonstrate that the impact exerted by the CPP on the membrane is notably affected by positioning and especially the degree of lipidation, which might influence the properties of CPPs as functional excipients.

The N Terminus of Sarcolipin Plays an Important Role in Uncoupling Sarco-endoplasmic Reticulum Ca2+-ATPase (SERCA) ATP Hydrolysis from Ca2+ Transport.

The sarcoendoplasmic reticulum Ca(2+)-ATPase (SERCA) is responsible for intracellular Ca(2+) homeostasis. SERCA activity in muscle can be regulated by phospholamban (PLB), an affinity modulator, and sarcolipin (SLN), an uncoupler. Although PLB gets dislodged from Ca(2+)-bound SERCA, SLN continues to bind SERCA throughout its kinetic cycle and promotes uncoupling of Ca(2+) transport from ATP hydrolysis. To determine the structural regions of SLN that mediate uncoupling of SERCA, we employed mutagenesis and generated chimeras of PLB and SLN. In this study we demonstrate that deletion of SLN N-terminal residues (2)ERSTQ leads to loss of the uncoupling function even though the truncated peptide can target and constitutively bind SERCA. Furthermore, molecular dynamics simulations of SLN and SERCA interaction showed a rearrangement of SERCA residues that is altered when the SLN N terminus is deleted. Interestingly, transfer of the PLB cytosolic domain to the SLN transmembrane (TM) and luminal tail causes the chimeric protein to lose SLN-like function. Further introduction of the PLB TM region into this chimera resulted in conversion to full PLB-like function. We also found that swapping PLB N and C termini with those from SLN caused the resulting chimera to acquire SLN-like function. Swapping the C terminus alone was not sufficient for this conversion. These results suggest that domains can be switched between SLN and PLB without losing the ability to regulate SERCA activity; however, the resulting chimeras acquire functions different from the parent molecules. Importantly, our studies highlight that the N termini of SLN and PLB influence their respective unique functions.