Abstract
Mechanisms leading to the assembly of wheat storage proteins into proteins bodies within the endoplasmic reticulum (ER) of endosperm cells are unresolved today. In this work, physical chemistry parameters which could be involved in these processes were explored. To model the confined environment of proteins within the ER, the dynamic behavior of γ‐gliadins inserted inside lyotropic lamellar phases was studied using FRAP experiments. The evolution of the diffusion coefficient as a function of the lamellar periodicity enabled to propose the hypothesis of an interaction between γ‐gliadins and membranes. This interaction was further studied with the help of phospholipid Langmuir monolayers. γ‐ and ω‐gliadins were injected under DMPC and DMPG monolayers and the two‐dimensional (2D) systems were studied by Brewster angle microscopy (BAM), polarization modulation infrared reflection‐absorption spectroscopy (PM‐IRRAS), and surface tension measurements. Results showed that both gliadins adsorbed under phospholipid monolayers, considered as biological membrane models, and formed micrometer‐sized domains at equilibrium. However, their thicknesses, probed by reflectance measurements, were different: ω‐gliadins aggregates displayed a constant thickness, consistent with a monolayer, while the thickness of γ‐gliadins aggregates increased with the quantity of protein injected. These different behaviors could find some explanations in the difference of aminoacid sequence distribution: an alternate repeated ‐ unrepeated domain within γ‐gliadin sequence, while one unique repeated domain was present within ω‐gliadin sequence. All these findings enabled to propose a model of gliadins self‐assembly via a membrane interface and to highlight the predominant role of wheat prolamin repeated domain in the membrane interaction. In the biological context, these results would mean that the repeated domain could be considered as an anchor for the interaction with the ER membrane and a nucleus point for the formation and growth of protein bodies within endosperm cells. © 2009 Wiley Periodicals, Inc. Biopolymers 91: 610–622, 2009.
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