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Identification of novel functional mini-receptors by combinatorial screening of split-WW domains.

Hermann NeitzNiels Benjamin PaulFlorian R HägeChristina LindnerRoman GraebnerMichael KovermannFranziska Thomas
Published in: Chemical science (2022)
β-Sheet motifs such as the WW domain are increasingly being explored as building blocks for synthetic biological applications. Since the sequence-structure relationships of β-sheet motifs are generally complex compared to the well-studied α-helical coiled coil (CC), other approaches such as combinatorial screening should be included to vary the function of the peptide. In this study, we present a combinatorial approach to identify novel functional mini-proteins based on the WW-domain scaffold, which takes advantage of the successful reconstitution of the fragmented WW domain of hPin1 (hPin1 WW ) by CC association. Fragmentation of hPin1 WW was performed in both loop 1 (CC-hPin1 WW -L1) and loop 2 (CC-hPin1 WW -L2), and the respective fragments were linked to the strands of an antiparallel heterodimeric CC. Structural analysis by CD and NMR spectroscopy revealed structural reconstitution of the WW-domain scaffold only in CC-hPin1 WW -L1, but not in CC-hPin1 WW -L2. Furthermore, by using 1 H- 15 N HSQC NMR, fluorescence and CD spectroscopy, we demonstrated that binding properties of fragmented hPin1 WW in CC-hPin1 WW -L1 were fully restored by CC association. To demonstrate the power of this approach as a combinatorial screening platform, we synthesized a four-by-six library of N- and C-terminal hPin1 WW -CC peptide fragments that was screened for a WW domain that preferentially binds to ATP over cAMP, phophocholine, or IP6. Using this screening platform, we identified one WW domain, which specifically binds ATP, and a phosphorylcholine-specific WW-based mini-receptor, both having binding dissociation constants in the lower micromolar range.
Keyphrases
  • high resolution
  • transcription factor
  • high throughput
  • mass spectrometry
  • dna binding
  • tissue engineering
  • solid state
  • energy transfer