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Sequence Blockiness Controls the Structure of Polyampholyte Necklaces

Artem M. Rumyantsev, A. Johner, Juan Pablo

2021ACS Macro Letters32 citationsDOIOpen Access PDF

Abstract

A scaling theory of statistical (Markov) polyampholytes is developed to understand how sequence correlations, that is, the blockiness of positive and negative charges, influences conformational behavior. An increase in the charge patchiness leads to stronger correlation attractions between oppositely charged monomers, but simultaneously, it creates a higher charge imbalance in the polyampholyte. A competition between effective short-range attractions and long-range Coulomb repulsions induces globular, pearl-necklace, or fully stretched chain conformations, depending on the average length of the block of like charges. The necklace structure and the underlying distribution of the net charge are also controlled by the sequence. Sufficiently long blocks allow for charge migration from globular beads (pearls) to strings, thereby providing a nonmonotonic change in the number of necklace beads as the blockiness increases. The sequence-dependent structure of polyampholyte necklaces is confirmed by molecular dynamics simulations. The findings presented here provide a framework for understanding the sequence-encoded conformations of synthetic polyampholytes and intrinsically disordered proteins (IDPs).

Topics & Concepts

Sequence (biology)Chemical physicsNecklaceIntrinsically disordered proteinsGlobular proteinCharge (physics)Block (permutation group theory)Molecular dynamicsElectrostaticsChemistryBiological systemMaterials scienceNanotechnologyCrystallographyBiophysicsPhysicsComputational chemistryBiologyMathematicsGeometryQuantum mechanicsBiochemistryPhysical chemistryCombinatoricsElectrostatics and Colloid InteractionsPolymer Surface Interaction StudiesProtein Structure and Dynamics