Phased cis-acting promoter elements interact at short distances to direct avian skeletal alpha-actin gene transcription.

Recently, site-directed mutagenesis uncovered four positive cis-acting elements in the 5' promoter region of the chicken skeletal alpha-actin gene that directs myogenic tissue-restricted expression. In this study, interactions between the four promoter sites were examined by means of a series of insertion mutations that increased the linker region between adjacent elements by roughly half or complete DNA helical turns. Unexpectedly, transcriptional activity for all three sets of linker mutants, as assayed with a chloramphenicol acetyltransferase reporter gene, was found to vary in a fashion resembling a damped sinusoid with a period of roughly 10 base pairs, where the sinusoidal maxima appeared when length was increased by half-integral number of helix turns. We present a model which states that in the undistorted wild-type 5' flanking sequence, linker domains position each of the four promoter sites on the helix face opposite that of its immediate neighbors; when any of the three linkers is increased by approximately a half-integral number of helix turns, pairs of neighboring promoter sites are brought into alignment. We propose that this is the required orientation for inducing skeletal muscle-specific promoter activity, achieved in the wild-type promoter as a result of protein-induced torsional deformation.