Abstract
Myristoylated alanine-rich C kinase substrate (MARCKS) is an unfolded protein that contains well characterized actin-binding sites within the phosphorylation site domain (PSD), yet paradoxically, we now find that intact MARCKS does not bind to actin. Intact MARCKS also does not bind as well to calmodulin as does the PSD alone. Myristoylation at the N terminus alters how calmodulin binds to MARCKS, implying that, despite its unfolded state, the distant N terminus influences binding events at the PSD. We show that the free PSD binds with site specificity to MARCKS, suggesting that long-range intramolecular interactions within MARCKS are also possible. Because of the unusual primary sequence of MARCKS with an overall isoelectric point of 4.2 yet a very basic PSD (overall charge of +13), we speculated that ionic interactions between oppositely charged domains of MARCKS were responsible for long-range interactions within MARCKS that sterically influence binding events at the PSD and that explain the observed differences between properties of the PSD and MARCKS. Consistent with this hypothesis, chemical modifications of MARCKS that neutralize negatively charged residues outside of the PSD allow the PSD to bind to actin and increase the affinity of MARCKS for calmodulin. Similarly, both myristoylation of MARCKS and cleavage of MARCKS by calpain are shown to increase the availability of the PSD so as to activate its actin-binding activity. Because abundant evidence supports the conclusion that MARCKS is an important protein in regulating actin dynamics, our data imply that post-translational modifications of MARCKS are necessary and sufficient to regulate actin-binding activity.
Highlights
Myristoylated alanine-rich C kinase substrate (MARCKS) is an unfolded protein that contains well characterized actin-binding sites within the phosphorylation site domain (PSD), yet paradoxically, we find that intact MARCKS does not bind to actin
In several specific examples, MARCKS colocalizes with F-actin, and dissociation from actin is temporally associated with alterations in actin dynamics [22, 23], or MARCKS localization is altered after treatment that disrupts actin filaments [18, 22]
There were no reproducible differences in the amount of actin in the supernatants as a function of MARCKS concentration, i.e. MARCKS had no detectable effect on the critical concentration of actin
Summary
Because of the unusual primary sequence of MARCKS with an overall isoelectric point of 4.2 yet a very basic PSD (overall charge of ؉13), we speculated that ionic interactions between oppositely charged domains of MARCKS were responsible for long-range interactions within MARCKS that sterically influence binding events at the PSD and that explain the observed differences between properties of the PSD and MARCKS Consistent with this hypothesis, chemical modifications of MARCKS that neutralize negatively charged residues outside of the PSD allow the PSD to bind to actin and increase the affinity of MARCKS for calmodulin. The addition of a second non-cooperative binding site cannot explain the long-known result that myristoylated MARCKS binds to calmodulin with higher affinity than does non-myristoylated MARCKS [14] unless both binding sites can interact with a single calmodulin molecule simultaneously or myristoylation itself changes the accessibil- If the PSD of MARCKS is incompletely accessible to its many ligands in the intact protein, two questions emerge that are addressed in this study. 1) How can a natively unfolded protein maintain the PSD in a buried unavailable position? 2) Do mechanisms exist to alter the availability of the PSD? Here, we test a novel structural hypothesis related to the unusual charge distribution in the primary sequence of MARCKS and attribute physical significance to post-translational modifications that are shown to regulate the actinbinding functions of MARCKS
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