Advances in the synthesis of multiphosphorylated peptides and peptide libraries: tools for studying the effects of phosphorylation patterns on protein function and regulation.
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Accelerating solid-phase synthesis
is crucial for accessing a large
number of peptides in a short time. Since standard peptide synthesis
is usually done under poor diffusion conditions with slow or no mixing
of the solid support, acceleration of the process is achieved by applying
a large excess of reagents. In this work, overhead stirring and heating
were combined to provide accelerated solid-phase peptide synthesis
without using an excess of reagent. A new setup that allows both heating
and fast stirring was designed specifically for research laboratory-scale
peptide synthesis. By increasing the diffusion of both reagents and
beads in a narrow dimension reactor, solid-phase reactions were done
in seconds and medium-size peptides were synthesized in minutes.
We present a possible molecular basis for the opposite activity of two homologues proteins that bind similar ligands and show that this is achieved by fine-tuning of the interaction interface. The highly homologous ASPP proteins have opposite roles in regulating apoptosis: ASPP2 induces apoptosis while iASPP inhibits it. The ASPP proteins are regulated by an autoinhibitory interaction between their Ank-SH3 and Pro domains. We performed a detailed biophysical and molecular study of the Pro – Ank-SH3 interaction in iASPP and compared it to the interaction in ASPP2. We found that iASPP Pro is disordered and that the interaction sites are entirely different: iASPP Ank-SH3 binds iASPP Pro via its fourth Ank repeat and RT loop while ASPP2 Ank-SH3 binds ASPP2 Pro via its first Ank repeat and the n-src loop. It is possible that by using different moieties in the same interface, the proteins can have distinct and specific interactions resulting in differential regulation and ultimately different biological activities.
Intrinsically disordered regions in proteins (IDRs) mediate many disease‐related protein–protein interactions. However, the unfolded character and continuous conformational changes of IDRs make them difficult to target for therapeutic purposes. Here, we show that a designed peptide based on the disordered p53 linker domain can be used to target a partner IDR from the anti‐apoptotic iASPP protein, promoting apoptosis of cancer cells. The p53 linker forms a hairpin‐like structure with its two termini in close proximity. We designed a peptide derived from the disordered termini without the hairpin, designated as p53 LinkTer. The LinkTer peptide binds the disordered RT loop of iASPP with the same affinity as the parent p53 linker peptide, and inhibits the p53–iASPP interaction in vitro. The LinkTer peptide shows increased stability to proteolysis, penetrates cancer cells, causes nuclei shrinkage, and compromises the viability of cells. We conclude that a designed peptide comprising only the IDR from a peptide sequence can serve as an improved inhibitor since it binds its target protein without the need for pre‐folding, paving the way for therapeutic targeting of IDRs.
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