TY  - JOUR
AU  - Kang, Kyongok
AU  - Platten, Florian
AU  - Ray, Debes
TI  - Electric response of multiarm protein crystals
JO  - Physical review / E
VL  - 113
SN  - 2470-0045
CY  - Woodbury, NY
PB  - APS
M1  - FZJ-2025-05295
SP  - 014403
PY  - 2026
AB  - Electric fields can modify protein-protein interactions and thereby influence phase behavior. In lysozyme–sodium thiocyanate solutions, we recently observed shifts in both the crystallization boundary and theliquid-liquid phase separation line under a weak applied field, along with a range of distinct crystal morphologies.Here, we explore how forming protein crystals respond to variations in field frequency and amplitude, focusingon the morphologies of complex, multiarm structures. At constant protein and salt concentrations, the appliedfield governs both the number and the angular distribution of crystal arms. These features are analyzed throughFourier analysis of microscopy images, revealing cooperative angular ordering among the arms. Based on theseobservations, we classify three principal multiarm protein crystal (pX) morphologies: flowerlike pX (dominantat high field strengths), triconic pX (appearing nonmonotonically at lower fields), and conic pX (widely observedunder low-field conditions). Near the crystallization boundary, field-driven metastable structures such as tubules,clusters, nematic domains, and fibers also occur in response to the field. These findings demonstrate that electricfields effectively steer protein crystallization pathways and provide insight into the mechanisms of variousmultiarm crystallization.
LB  - PUB:(DE-HGF)16
DO  - DOI:10.1103/ql7f-wzpr
UR  - https://juser.fz-juelich.de/record/1049215
ER  -