A Tunable and Reversible Platform for the Intracellular Formation of Genetically Engineered Protein Microdomains

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• 作者：Martha K. Pastuszka ; Siti M. Janib ; Isaac Weitzhandler ; Curtis T. Okamoto ; Sarah Hamm-Alvarez ; J. Andrew MacKay
• 刊名：Biomacromolecules
• 出版年：2012
• 出版时间：November 12, 2012
• 年：2012
• 卷：13
• 期：11
• 页码：3439-3444
• 全文大小：341K
• 年卷期：v.13,no.11(November 12, 2012)
• ISSN：1526-4602

文摘

From mitochondria to the nuclear envelope, the controlled assembly of micro- and nanostructures is essential for life; however, the level at which we can deliberately engineer the assembly of microstructures within intracellular environments remains primitive. To overcome this obstacle, we present a platform to reversibly assemble genetically engineered protein microdomains (GEPMs) on the time scale of minutes within living cells. Biologically inspired from the human protein tropoelastin, these protein polymers form a secondary aqueous phase above a tunable transition temperature. This assembly process is easily manipulated to occur at or near physiological temperature by adjusting molecular weight and hydrophobicity. We fused protein polymers to green fluorescent protein (GFP) to visualize their behavior within the cytoplasm. While soluble, these polymers have a similar intracellular diffusion constant as cytosolic proteins at 7.4 渭m²/s; however, above their phase transition temperature, the proteins form distinct microdomains (0.1鈥? 渭m) with a reduced diffusion coefficient of 1.1 渭m²/s. Microdomain assembly and disassembly are both rapid processes with half-lives of 3.8 and 1.0 min, respectively. Via selection of the protein polymer, the assembly temperature is tunable between 20 and 40 掳C. This approach may be useful to control intracellular formation of genetically engineered proteins and protein complexes into concentrated microdomains.