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Catalytically Inactive SHP1-C453S Mutant Gain of “Robust LLPS” Function
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Abstract
SHP1 is a non-receptor protein tyrosine phosphatase extensively expressed in hematopoietic cells, exerting a pivotal role as an immunosuppressive factor. Our previous studies have suggested that SHP1 can undergo liquid-liquid phase separation (LLPS). In this study, the SHP1-C455S mutant, commonly utilized in biochemical assays due to its lack of catalytic phosphatase activity, unexpectedly exhibited a remarkably robust ability for LLPS. Since the C453S mutation has been previously shown to potentially induce a conformational transition of SHP1 from a closed to an open state, we hypothesize that the enhanced LLPS capability of SHP1 may be facilitated by this conformational alteration. The SHP1-C453S mutant exhibited robust LLPS activity, while completely abrogating its phosphatase activity.
This allows for effective investigation of the catalytic activity and LLPS capability of SHP1.
Peertechz Publications Private Limited
Title: Catalytically Inactive SHP1-C453S Mutant Gain of “Robust LLPS” Function
Description:
Abstract
SHP1 is a non-receptor protein tyrosine phosphatase extensively expressed in hematopoietic cells, exerting a pivotal role as an immunosuppressive factor.
Our previous studies have suggested that SHP1 can undergo liquid-liquid phase separation (LLPS).
In this study, the SHP1-C455S mutant, commonly utilized in biochemical assays due to its lack of catalytic phosphatase activity, unexpectedly exhibited a remarkably robust ability for LLPS.
Since the C453S mutation has been previously shown to potentially induce a conformational transition of SHP1 from a closed to an open state, we hypothesize that the enhanced LLPS capability of SHP1 may be facilitated by this conformational alteration.
The SHP1-C453S mutant exhibited robust LLPS activity, while completely abrogating its phosphatase activity.
This allows for effective investigation of the catalytic activity and LLPS capability of SHP1.
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