Solution structure of a mutant of transcription factor 1: implications for enhanced DNA binding

2006

Deinococcus radiodurans can reconstitute its genome from double-strand breaks, most likely due to unusually efficient DNA repair and recombination. Factors that may contribute to such processes include the histone-like protein HU. The D. radiodurans-encoded HU (DrHU), which binds preferentially to DNA recombination intermediates, contains a 47-amino acid extension preceding the fold characteristic of HU proteins. Here we use electrophoretic mobility shift assays and DNA footprinting to show that the DrHU N-terminal domain significantly modulates DNA binding. The truncated DrHU (deltaDrHU), comprising only the conserved DNA-binding fold, has a site size of approximately 11 bp in contrast to full-length DrHU which does not stably engage DNA shorter than approximately 50 bp. Unlike wild-type DrHU, deltaDrHU distinguishes between linear DNA and DNA with nicks or gaps. DeltaDrHU also binds preferentially to four-way junction (4WJ) DNA, with half-maximal saturation of 1.4 +/- 0.4 nM compared to 20 +/- 2 nM for 37 bp duplex DNA. However, in contrast to full-length protein which binds the junction arms, deltaDrHU primarily protects the junction crossover. Evidently, the DrHU N-terminus changes the mode of binding to both 4WJ DNA, duplex DNA, and DNA with nicks or gaps, thereby resulting in DrHU binding preferentially only to 4WJ structures. Combined with Western blots that confirm the presence of the extended form of DrHU in vivo, our data provide mechanistic insight into discrimination between 4WJ DNA and other distorted DNA constructs and suggest that an in vivo role of DrHU may be to stabilize DNA junctions.

Section: Resultsmentioning

confidence: 99%

The Deinococcus radiodurans-Encoded HU Protein Has Two DNA-Binding Domains

Ghosh

2006

“…Notably, a TF1 mutant protein (TF1-E15G-T32I) with ∼40-fold higher affinity than wild-type TF1 may be generated whose substitutions cause exposure of a positively charged patch on the protein surface in a region that contacts DNA beyond the ends of a 25 bp duplex (27,46,47). As the increased binding energy is manifested only with DNA longer than 25 bp, it must be due to contacts to the lateral sides of the protein.…”

Section: Discussionmentioning

confidence: 99%

Surface Salt Bridges Modulate DNA Wrapping by the Type II DNA-Binding Protein TF1

2003

The histone-like protein HU is involved in compaction of the bacterial genome. Up to 37 bp of DNA may be wrapped about some HU homologues in a process that has been proposed to depend on a linked disruption of surface salt bridges that liberates cationic side chains for interaction with the DNA. Despite significant sequence conservation between HU homologues, binding sites from 9 to 37 bp have been reported. TF1, an HU homologue that is encoded by Bacillus subtilis bacteriophage SPO1, has nM affinity for 37 bp preferred sites in DNA with 5-hydroxymethyluracil (hmU) in place of thymine. On the basis of electrophoretic mobility shift assays, we show that TF1-DNA complex formation is associated with a net release of only approximately 0.5 cations. The structure of TF1 suggests that Asp13 can form a dehydrated surface salt bridge with Lys23; substitution of Asp13 with Ala increases the net release of cations to approximately 1. These data are consistent with complex formation linked to disruption of surface salt bridges. Substitution of Glu90 with Ala, which would expose Lys87 predicted to contact DNA immediately distal to a proline-mediated DNA kink, causes an increase in affinity and an abrogation of the preference for hmU-containing DNA. We propose that hmU preference is due to finely tuned interactions at the sites of kinking that expose a differential flexibility of hmU- and T-containing DNA. Our data further suggest that the difference in binding site size for HU homologues is based on a differential ability to stabilize the DNA kinks.

“…In support of these interpretations, we also point out that another TF1 mutant protein, in which two internal, buried residues were substituted, was recently studied by NMR. It was shown that this TF1 mutant protein, whose overall structure is essentially superimposable on the structure of the wild-type protein, exposes additional positive surface potential on each lateral side of the protein dimer that results in an ∼40-fold higher affinity, but only for DNA that is longer than 25 bp ( , ). This is consistent with an important contribution to affinity at a position that corresponds to the location of Lys3.…”

Section: Discussionmentioning

confidence: 99%

The Role of Surface-Exposed Lysines in Wrapping DNA about the Bacterial Histone-Like Protein HU

Saavedra

2002

Several basic proteins, including the ubiquitous HU proteins, serve histone-like functions in prokaryotes. Significant sequence conservation exists between HU homologues; yet binding sites varying from 9 to 37 bp have been reported. TF1, an HU homologue with a 37 bp binding site that is encoded by the Bacillus subtilis bacteriophage SPO1, binds with nM affinity to DNA that contains 5-hydroxymethyluracil (hmU) in place of thymine and to T-containing DNA with loops. We evaluated the contribution of three conserved lysines to specifying the length of the binding site and show that Lys3 is critical for maintaining a long binding site in T-containing DNA: A mutant protein in which Lys3 is replaced with Gln(TF1-K3Q) is completely deficient in forming a stable complex. The affinity for 37 bp hmU-containing DNA is also reduced, from approximately 3 nM for wild-type TF1 to approximately 90 nM for TF1-K3Q. The decrease in affinity of TF1-K3Q for hmU-containing DNA > or = 25 bp suggests that Lys3 contacts DNA 8-9 bp distal to the sites of kinking. We propose that Lys3 forms an internal saltbridge to Asp26 in HU homologues characterized by shorter binding sites and that its surface exposure, and hence a longer binding site, may correlate with absence of this aspartate.