Zinc-Dependent Structure of a Single-Finger Domain of Yeast ADR1
- 16 September 1988
- journal article
- research article
- Published by American Association for the Advancement of Science (AAAS) in Science
- Vol. 241 (4872), 1489-1492
- https://doi.org/10.1126/science.3047872
Abstract
In the proposed "zinc finger" DNA-binding motif, each repeat unit binds a zinc metal ion through invariant Cys and His residues and this drives the folding of each 30-residue unit into an independent nucleic acid-binding domain. To obtain structural information, we synthesized single and double zinc finger peptides from the yeast transcription activator ADR1, and assessed the metal-binding and DNA-binding properties of these peptides, as well as the solution structure of the metal-stabilized domains, with the use of a variety of spectroscopic techniques. A single zinc finger can exist as an independent structure sufficient for zinc-dependent DNA binding. An experimentally determined model of the single finger is proposed that is consistent with circular dichroism, one- and two-dimensional nuclear magnetic resonance, and visual spectroscopy of the single-finger peptide reconstituted in the presence of zinc.Keywords
This publication has 16 references indexed in Scilit:
- Zinc-finger motifs expressed in E. coli and folded in vitro direct specific binding to DNANature, 1988
- Zinc fingers: Gilt by associationCell, 1988
- ‘Zinc fingers’: a novel protein motif for nucleic acid recognitionTrends in Biochemical Sciences, 1987
- Two zinc fingers of a yeast regulatory protein shown by genetic evidence to be essential for its functionNature, 1987
- Synthesis of a Site-Specific DNA-Binding PeptideScience, 1987
- EXAFS study of the zinc-binding sites in the protein transcription factor IIIANature, 1986
- Sequence homology of the yeast regulatory protein ADR1 with Xenopus transcription factor TFIIIANature, 1986
- The primary structure of transcription factor TFIIIA has 12 consecutive repeatsFEBS Letters, 1985
- Sequential resonance assignments in protein 1H nuclear magnetic resonance spectra: Computation of sterically allowed proton-proton distances and statistical analysis of proton-proton distances in single crystal protein conformationsJournal of Molecular Biology, 1982
- Prediction of protein conformationBiochemistry, 1974