1. Physicochemical properties that control protein aggregation also determine whether a protein is retained or released from necrotic cells
- Author
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Andre L. Samson, Bosco Ho, Amanda E. Au, Simone M. Schoenwaelder, Mark J. Smyth, Stephen P. Bottomley, Oded Kleifeld, and Robert L. Medcalf
- Subjects
protein aggregation ,necrosis ,disulfide ,immune tolerance ,rna-binding protein fus ,proteomics ,Biology (General) ,QH301-705.5 - Abstract
Amyloidogenic protein aggregation impairs cell function and is a hallmark of many chronic degenerative disorders. Protein aggregation is also a major event during acute injury; however, unlike amyloidogenesis, the process of injury-induced protein aggregation remains largely undefined. To provide this insight, we profiled the insoluble proteome of several cell types after acute injury. These experiments show that the disulfide-driven process of nucleocytoplasmic coagulation (NCC) is the main form of injury-induced protein aggregation. NCC is mechanistically distinct from amyloidogenesis, but still broadly impairs cell function by promoting the aggregation of hundreds of abundant and essential intracellular proteins. A small proportion of the intracellular proteome resists NCC and is instead released from necrotic cells. Notably, the physicochemical properties of NCC-resistant proteins are contrary to those of NCC-sensitive proteins. These observations challenge the dogma that liberation of constituents during necrosis is anarchic. Rather, inherent physicochemical features including cysteine content, hydrophobicity and intrinsic disorder determine whether a protein is released from necrotic cells. Furthermore, as half of the identified NCC-resistant proteins are known autoantigens, we propose that physicochemical properties that control NCC also affect immune tolerance and other host responses important for the restoration of homeostasis after necrotic injury.
- Published
- 2016
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