Abstract
Specific nuclear sub-compartments that are regions of fundamental processes such as gene expression or DNA repair, contain phosphoinositides (PIPs). PIPs thus potentially represent signals for the localization of specific proteins into different nuclear functional domains. We performed limited proteolysis followed by label-free quantitative mass spectrometry and identified nuclear protein effectors of the most abundant PIP—phosphatidylinositol 4,5-bisphosphate (PIP2). We identified 515 proteins with PIP2-binding capacity of which 191 ‘exposed’ proteins represent a direct PIP2 interactors and 324 ‘hidden’ proteins, where PIP2 binding was increased upon trypsin treatment. Gene ontology analysis revealed that ‘exposed’ proteins are involved in the gene expression as regulators of Pol II, mRNA splicing, and cell cycle. They localize mainly to non-membrane bound organelles—nuclear speckles and nucleolus and are connected to the actin nucleoskeleton. ‘Hidden’ proteins are linked to the gene expression, RNA splicing and transport, cell cycle regulation, and response to heat or viral infection. These proteins localize to the nuclear envelope, nuclear pore complex, or chromatin. Bioinformatic analysis of peptides bound in both groups revealed that PIP2-binding motifs are in general hydrophilic. Our data provide an insight into the molecular mechanism of nuclear PIP2 protein interaction and advance the methodology applicable for further studies of PIPs or other protein ligands.
Highlights
Various limited proteolysis followed by quantitative mass spectrometry (LiP-qMS) approaches have been successfully used for the determination of tertiary structure or conformational changes of proteins [10,11]
We developed a novel experimental workflow PIPsLiP-qMS in order to understand molecular processes with involvement of nuclear PIP2
Based on the PIP2-associated proteome, we can predict the molecular processes in which PIP2-effectors participate
Summary
Various limited proteolysis followed by quantitative mass spectrometry (LiP-qMS) approaches have been successfully used for the determination of tertiary structure or conformational changes of proteins [10,11]. LiP-based experimental pipeline using covalently conjugated PIP2 agarose beads followed by qMS to identify the proteins that interact with PIP2. We refer to this experimental pipeline as Phosphoinositide phosphates-based Limited Proteolysis quantitative mass spectrometry (PIPsLiP-qMS). This novel two-step approach allowed us to identify PIP2interactome of the nuclear proteome and provides data discriminating two different types of PIP2-binding regions. Our approach provides information about structural features of the PIP2–protein interaction on a nuclear proteome scale and a methodological pipeline for further evaluation of other nuclear PIPs interactors and determination of their possible functions
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