Sequence-selective DNA Binding by Basic Region/Leucine Zipper Proteins at Noncognate Gene Regulatory Sequences

Chan, I-San

20 August 2012

This thesis explores how basic region/leucine zipper (bZIP) transcription factors target gene regulatory sequences. The GCN4 bZIP binds to more than one target site [CRE (TGACGTCA) and cognate AP-1 (TGACTCA)] and exhibits flexibility in -helical structure. These observations suggest that the GCN4 bZIP can establish sequence-selective DNA binding at noncognate target sites. Studies on such noncognate but sequence-selective binding can provide insights into how bZIP proteins search for and localize to their cognate target sites. This thesis investigates DNA binding by the GCN4 bZIP and its structural and functional mimic, the wild-type (wt) bZIP, at noncognate gene regulatory sequences C/EBP (TTGCGCAA), E-box (CACGTG), HRE (GCACGTAG), XRE1 (TTGCGTGA), and related DNA sequences. These DNA-binding activities are sequence-selective, as confirmed by DNase I footprinting and electrophoretic mobility shift assay (EMSA). Full- and half-site DNA-binding affinities, determined by EMSA titrations, decrease from cognate to noncognate binding. At noncognate target sites, the bZIP proteins form a dimer of -helices, as indicated by circular dichroism (CD) spectroscopy and EMSA. These results demonstrate that the bZIP proteins can establish noncognate but sequence-selective DNA binding, and suggest such DNA binding potentially contributes to structure preorganization and rapid translocation of the bZIP proteins when they search for their cognate target sites, to which they then bind with high affinity. This thesis also indicates a highly dynamic DNA-binding model for the bZIP proteins to establish strong and sequence-selective DNA binding. The C/EBP site includes two 5H-LR (TTGCG) half-sites, each of which comprises two 4-bp subsites. The in vitro and in silico results together demonstrate that the basic region at 5H-LR recognizes the 4-bp subsites alternately as distinct units, which requires it to translocate between the subsites, potentially by sliding or hopping. Taken as a whole, this thesis provides further insights into how bZIP transcription factors accomplish sequence-selective DNA binding.

bZIP

DNA binding

GCN4

C/EBP

basic region

leucine zipper

transcription

gene regulatory

0487

Sequence-selective DNA Binding by Basic Region/Leucine Zipper Proteins at Noncognate Gene Regulatory Sequences

Chan, I-San

20 August 2012

This thesis explores how basic region/leucine zipper (bZIP) transcription factors target gene regulatory sequences. The GCN4 bZIP binds to more than one target site [CRE (TGACGTCA) and cognate AP-1 (TGACTCA)] and exhibits flexibility in -helical structure. These observations suggest that the GCN4 bZIP can establish sequence-selective DNA binding at noncognate target sites. Studies on such noncognate but sequence-selective binding can provide insights into how bZIP proteins search for and localize to their cognate target sites. This thesis investigates DNA binding by the GCN4 bZIP and its structural and functional mimic, the wild-type (wt) bZIP, at noncognate gene regulatory sequences C/EBP (TTGCGCAA), E-box (CACGTG), HRE (GCACGTAG), XRE1 (TTGCGTGA), and related DNA sequences. These DNA-binding activities are sequence-selective, as confirmed by DNase I footprinting and electrophoretic mobility shift assay (EMSA). Full- and half-site DNA-binding affinities, determined by EMSA titrations, decrease from cognate to noncognate binding. At noncognate target sites, the bZIP proteins form a dimer of -helices, as indicated by circular dichroism (CD) spectroscopy and EMSA. These results demonstrate that the bZIP proteins can establish noncognate but sequence-selective DNA binding, and suggest such DNA binding potentially contributes to structure preorganization and rapid translocation of the bZIP proteins when they search for their cognate target sites, to which they then bind with high affinity. This thesis also indicates a highly dynamic DNA-binding model for the bZIP proteins to establish strong and sequence-selective DNA binding. The C/EBP site includes two 5H-LR (TTGCG) half-sites, each of which comprises two 4-bp subsites. The in vitro and in silico results together demonstrate that the basic region at 5H-LR recognizes the 4-bp subsites alternately as distinct units, which requires it to translocate between the subsites, potentially by sliding or hopping. Taken as a whole, this thesis provides further insights into how bZIP transcription factors accomplish sequence-selective DNA binding.

bZIP

DNA binding

GCN4

C/EBP

basic region

leucine zipper

transcription

gene regulatory

0487