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D. Burz, R. V. Rivera-Pomar,
H. Jäckle, S. Hanes (1998). Cooperative DNA-binding provides
a mechanism for threshold-dependent gene activation in the Drosophila
embryo. EMBO J. 17, 5998-6009 |
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Cooperative DNA-binding
by Bicoid provides a mechanism for threshold-dependent gene activation
in the Drosophila embryo
Burz DS, Rivera-Pomar R, Jackle H, Hanes SD
Molecular Genetics Program, Wadsworth Center, New York
State Department of Health and Department of Biomedical Sciences, State
University of New York-Albany, NY 12208, USA
The Bicoid morphogen directs pattern formation along
the anterior-posterior (A-P) axis of the Drosophila embryo. Bicoid is
distributed in a concentration gradient that decreases exponentially from
the anterior pole, however, it transcribes target genes such as hunchback
in a step-function-like pattern; the expression domain is uniform and
has a sharply defined posterior boundary. A 'gradient-affinity' model
proposed to explain Bicoid action states that (i) cooperative gene activation
by Bicoid generates the sharp on/off switch for target gene transcription
and (ii) target genes with different affinities for Bicoid are expressed
at different positions along the A-P axis. Using an in vivo yeast assay
and in vitro methods, we show that Bicoid binds DNA with pairwise cooperativity;
Bicoid bound to a strong site helps Bicoid bind to a weak site. These
results support the first aspect of the model, providing a mechanism by
which Bicoid generates sharp boundaries of gene expression. However, contrary
to the second aspect of the model, we find no significant difference between
the affinity of Bicoid for the anterior gene hunchback and the posterior
gene knirps. We propose, instead, that the arrangement of Bicoids bound
to the target gene presents a unique signature to the transcription machinery
that, in combination with overall affinity, regulates the extent of gene
transcription along the A-P axis