Abstract
Nucleophosmin (NPM1/B23) is a nucleolar protein implicated in growth-associated functions, in which the RNA binding activity of B23 plays essential roles in ribosome biogenesis. The C-terminal globular domain (CTD) of B23 has been believed to be the RNA binding domain because the splicing variant B23.2 lacking the CTD binds considerably less efficiently to RNA. However, the recognition of target RNAs by B23 remains poorly understood. Herein, we report a novel mechanism by which B23 recognizes specific RNA targets. We observed that the nucleolar retention of B23.3 lacking the basic region of B23.1 was lower than that of B23.1 because of its low RNA binding activity. Circular dichroism measurements indicated that the basic region and adjacent acidic regions of B23 are intrinsically disordered regions (IDRs). Biochemical analyses revealed that the basic IDR alone strongly binds to RNA with low specificity. The excessive RNA binding activity of the basic IDR was restrained by intra-molecular interaction with the acidic IDR of B23. Chemical cross-linking experiments and fluorescent labeling of bipartite tetracysteine-tagged proteins suggested that the inter- and intra-molecular interactions between the two IDRs contribute to the regulation of the RNA binding activity of CTD to control the cellular localization and functions of B23.
Highlights
The biological activities of proteins are often exerted by structurally ordered domains; structurefunction analyses have been central in understanding several biological processes
We previously demonstrated that the cdc2/cyclin B kinase phosphorylates the basic intrinsically disordered regions (IDRs) of B23.1, and this phosphorylation significantly decreases its RNA binding activity [26]
Our results suggest that B23.1 recognizes RNA through two fragments, basic IDR (bIDR) and C-terminal globular domain (CTD), and that acidic IDR (aIDR) modulates the non-specific RNA binding activity of bIDR, allowing B23 CTD to recognize and interact with target RNAs
Summary
The biological activities of proteins are often exerted by structurally ordered domains; structurefunction analyses have been central in understanding several biological processes. Recent studies have documented that the structurally disordered flexible domain in the native state [intrinsically disordered regions (IDRs)] play crucial roles in the regulation of protein– protein and protein–nucleic acid interactions [1]. The N-terminal transactivation domain in the transcription factor p53 is intrinsically disordered and folded on binding to the Taz domain of the co-activator, p300 [2]. Several DNA binding proteins containing zinc fingers, helix–loop– helix motifs and homeodomains have N- or C-terminal extended IDRs that assist efficient recognition and binding to target sequences [3]. Various post-translational modifications occur in the IDRs, suggesting that the IDRs play an integral role in regulation of the protein functions [4]
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