Abstract
CooA, the carbon monoxide-sensing transcription factor from Rhodospirillum rubrum, binds CO through a heme moiety resulting in conformational changes that promote DNA binding. The crystal structure shows that the N-terminal Pro(2) of one subunit (Met(1) is removed post-translationally) provides one ligand to the heme of the other subunit in the CooA homodimer. To determine the importance of this novel ligand and the contiguous residues to CooA function, we have altered the N terminus through two approaches: site-directed mutagenesis and regional randomization, and characterized the resulting CooA variants. While Pro(2) appears to be optimal for CooA function, it is not essential and a variety of studied variants at this position have substantial CO-sensing function. Surprisingly, even alterations that add a residue (where Pro(2) is replaced by Met(1)-Tyr(2), for example) accumulate heme-containing CooA with functional properties that are similar to those of wild-type CooA. Other nearby residues, such as Phe(5) and Asn(6) appear to be important for either the structural integrity or the function of CooA. These results are contrasted with those previously reported for alteration of the His(77) ligand on the opposite side of the heme.
Highlights
The sensing of dissolved gas molecules by proteins in biology has recently attracted considerable biochemical interest
Fluorescence Polarization Assay for DNA Binding—We have developed an assay for detecting DNA binding by the CooA1⁄7CO complex, based on fluorescence polarization (FP) [30, 31], in order to test quantitatively the activity (i.e. DNA binding in response to CO binding to the heme of CooA) of our CooA protein preparations
It is interesting that the Pro2 region variants in Table I that accumulate best are those with an “extended” N terminus, resulting from the presumed retention of Met1; the retention of the terminal Met1 was confirmed by N-terminal sequencing of purified P2Y CooA
Summary
The sensing of dissolved gas molecules by proteins in biology has recently attracted considerable biochemical interest. To determine the importance of this novel ligand and the contiguous residues to CooA function, we have altered the N terminus through two approaches: site-directed mutagenesis and regional randomization, and characterized the resulting CooA variants.
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