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6UCP

Zinc finger 2 from the transcription factor Sp1 DNA binding domain

Summary for 6UCP
Entry DOI10.2210/pdb6ucp/pdb
Related1SP2 1VA2
NMR InformationBMRB: 30674
DescriptorTranscription factor Sp1, ZINC ION (2 entities in total)
Functional Keywordszinc finger, dna binding protein
Biological sourceHomo sapiens (Human)
Total number of polymer chains1
Total formula weight3898.80
Authors
Rao, S.R.,Horne, W.S. (deposition date: 2019-09-17, release date: 2020-06-24, Last modification date: 2024-10-16)
Primary citationRao, S.R.,Horne, W.S.
Proteomimetic Zinc Finger Domains with Modified Metal-binding beta-Turns.
Pept Sci (Hoboken), 112:-, 2020
Cited by
PubMed Abstract: The mimicry of protein tertiary folds by chains artificial in backbone chemical composition leads to proteomimetic analogues with potential utility as bioactive agents and as tools to shed light on biomacromolecule behavior. Notable successes toward such molecules have been achieved; however, as protein structural diversity is vast, design principles must be continually honed as they are applied to new prototype folding patterns. One specific structure where a gap remains in understanding how to effectively generate modified backbone analogues is the metal-binding β-turn found in zinc finger domains. Literature precedent suggests several factors that may act in concert, including the artificial moiety used to modify the turn, the sequence in which it is applied, and modifications present elsewhere in the domain. Here, we report efforts to gain insights into these issues and leverage these insights to construct a zinc finger mimetic with backbone modifications throughout its constituent secondary structures. We first conduct a systematic comparison of four turn mimetics in a common host sequence, quantifying relative efficacy for use in a metal-binding context. We go on to construct a proteomimetic zinc finger domain in which the helix, strands, and turn are simultaneously modified, resulting in a variant with 23% artificial residues, a tertiary fold indistinguishable from the prototype, and a folded stability comparable to the natural backbone on which the variant is based. Collectively, the results reported provide new insights into the effects of backbone modification on structure and stability of metal-binding domains and help inform the design of metalloprotein mimetics.
PubMed: 33733039
DOI: 10.1002/pep2.24177
PDB entries with the same primary citation
Experimental method
SOLUTION NMR
Structure validation

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