Taylor Gillian C A, Macdonald Lewis, Szulc Natalia A, Gudauskaite Evelina, Hernandez Moran Brianda, Brisbane Jennifer M, Donald Molly, Taylor Ella, Zheng Dejin, Gu Bin, Mill Pleasantine, Yeyati Patricia L, Pokrzywa Wojciech, Ribeiro de Almeida Claudia, Wood Andrew J
MRC Human Genetics Unit, Institute of Genetics and Cancer, University of Edinburgh, Edinburgh, United Kingdom.
MRC National Mouse Genetics Network, Degron Tagging Cluster, Mary Lyon Centre, Harwell, United Kingdom.
PLoS Genet. 2025 Aug 25;21(8):e1011830. doi: 10.1371/journal.pgen.1011830. eCollection 2025 Aug.
Genetic fusion of protein tags is widely used to study protein functions in vivo. It is well known that tag fusion can cause unwanted changes in protein stability, but whether this is an inherent property of the tagged protein, or can be influenced by the cell and tissue environment, is unclear. Using a series of genome edited mouse models, we show that tag-dependent changes in protein expression can vary across different primary cell and tissue contexts. In one case (Ncaph2), a C-terminal auxin-inducible degron fusion strongly increased protein stability in some tissues but decreased it in others. Destabilisation resulted from tissue-specific 'leakage' of the auxin-inducible degron, which depended on TIR1 expression, and occurred selectively in the small intestine where basal concentrations of auxin/ indole-3-acetic acid can reach levels that are sufficient to trigger protein degradation in cultured cells. Stabilisation occurred in post-mitotic cells via an endogenous degradation signal situated at the NCAPH2 C-terminus, which normally undergoes activation upon cell cycle exit, but is inactivated by C-terminal tag fusion. Our results highlight the underappreciated importance of cell and tissue environment in determining the consequences of tag fusions on protein expression, which may be particularly important in animal models that contain diverse cell types.
蛋白质标签的基因融合被广泛用于在体内研究蛋白质功能。众所周知,标签融合会导致蛋白质稳定性出现不必要的变化,但这是标记蛋白的固有特性,还是会受到细胞和组织环境的影响,目前尚不清楚。通过一系列基因编辑小鼠模型,我们发现蛋白质表达中依赖标签的变化在不同的原代细胞和组织环境中会有所不同。在一个例子(Ncaph2)中,C端生长素诱导降解子融合在某些组织中强烈增加了蛋白质稳定性,但在其他组织中却降低了稳定性。不稳定是由于生长素诱导降解子的组织特异性“渗漏”导致的,这取决于TIR1的表达,并且选择性地发生在小肠中,在那里生长素/吲哚-3-乙酸的基础浓度可以达到足以触发培养细胞中蛋白质降解的水平。在有丝分裂后细胞中,通过位于NCAPH2 C端的内源性降解信号实现了稳定,该信号通常在细胞周期退出时被激活,但因C端标签融合而失活。我们的结果凸显了细胞和组织环境在决定标签融合对蛋白质表达影响方面未得到充分重视的重要性,这在包含多种细胞类型的动物模型中可能尤为重要。
