Lighting up Nobel Prize-winning studies with protein intrinsic disorder.

Intrinsically disordered proteins and regions (IDPs and IDRs) and their importance in biology are becoming increasingly recognized in biology, biochemistry, molecular biology and chemistry textbooks, as well as in current protein science and structural biology curricula. We argue that the sequence → dynamic conformational ensemble → function principle is of equal importance as the classical sequence → structure → function paradigm. To highlight this point, we describe the IDPs and/or IDRs behind the discoveries associated with 17 Nobel Prizes, 11 in Physiology or Medicine and 6 in Chemistry. The Nobel Laureates themselves did not always mention that the proteins underlying the phenomena investigated in their award-winning studies are in fact IDPs or contain IDRs. In several cases, IDP- or IDR-based molecular functions have been elucidated, while in other instances, it is recognized that the respective protein(s) contain IDRs, but the specific IDR-based molecular functions have yet to be determined. To highlight the importance of IDPs and IDRs as general principle in biology, we present here illustrative examples of IDPs/IDRs in Nobel Prize-winning mechanisms and processes.

Different Oligomeric States of the Tumor Suppressor p53 Show Identical Binding Behavior towards the S100ß Homodimer.

The tumor suppressor protein p53 is a transcription factor that is referred to as the "guardian of the genome" and plays an important role in cancer development. p53 is active as a homotetramer; the S100ß homodimer binds to the intrinsically disordered C-terminus of p53 affecting its transcriptional activity. The p53/S100ß complex is regarded as highly promising therapeutic target in cancer. It has been suggested that S100ß exerts its oncogenic effects by altering the p53 oligomeric state. Our aim was to study the structures and oligomerization behavior of different p53/S100ß complexes by ESI-MS, XL-MS, and SPR. Wild-type p53 and single amino acid variants, representing different oligomeric states of p53 were individually investigated regarding their binding behavior towards S100ß. The stoichiometry of the different p53/S100ß complexes were determined by ESI-MS showing that tetrameric, dimeric, and monomeric p53 variants all bind to an S100ß dimer. In addition, XL-MS revealed the topologies of the p53/S100ß complexes to be independent of p53's oligomeric state. With SPR, the thermodynamic parameters were determined for S100ß binding to tetrameric, dimeric, or monomeric p53 variants. Our data prove that the S100ß homodimer binds to different oligomeric states of p53 with similar binding affinities. This emphasizes the need for alternative explanations to describe the molecular mechanisms underlying p53/S100ß interaction.