ISSN:
1573-5001
Keywords:
backbone dynamics
;
chemical exchange
;
Mbp1-DNA interaction
;
spectral density mapping
Source:
Springer Online Journal Archives 1860-2000
Topics:
Biology
,
Chemistry and Pharmacology
Notes:
Abstract Mbp1 is a transcription factor involved in the regulation of the cell cycle in yeast. The N-terminus of this protein contains a DNA binding domain that includes a winged helix-turn-helix motif. The C-terminal 24 residues of this domain (the `tail') are disordered in the crystal state, but are important for DNA binding. We have measured 15N NMR relaxation rates at 11.75 and 14.1 T to determine the dynamics of the free protein and in its complex with a specific DNA duplex. The dynamics data were quantitatively analysed using both spectral density mapping and the Lipari–Szabo formalism including the effects of chemical exchange and rotational anisotropy. A detailed analysis has been made of the effect of anisotropy, exchange and experimental precision on the recovered motional parameters. The backbone NH relaxation is affected by motions on a variety of time scales from millisecond to tens of picoseconds. The relaxation data show a structured core of 100 residues corresponding to that observed in the crystal state. Within the core of the protein, two regions on either side of the putative recognition helix (helix B) show slow (ca. 0.2 ms) conformational exchange dynamics that are quenched upon DNA binding. The C-terminal 24 residues are generally more dynamic than in the core. However, in the free protein, a stretch of ∼8 residues in the middle of the tail show relaxation behaviour similar to that in the core, indicating a structured region. NOEs between Ala 114 in this structured part of the tail and residues in the N-terminal beta strand of the core of the protein demonstrate that the tail folds back onto the core of the protein. In the complex with DNA, the structured part of the tail extends by ca. 3 residues. These data provide a framework for understanding the biochemical data on the mechanism and specificity of DNA binding.
Type of Medium:
Electronic Resource
URL:
http://dx.doi.org/10.1023/A:1008374129366
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