Amino acid substitution in the C-terminal arm domain of HU-2 results in an enhanced affinity for DNA

Arginine-55 in the beta-arm is essential for the activity of DNA-binding protein HU from Bacillus stearothermophilus

DNA-binding protein HU (BstHU) from Bacillus stearothermophilus is a homodimeric protein which binds to DNA in a sequence-nonspecific manner. In order to identify the Arg residues essential for DNA binding, four Arg residues (Arg-53, Arg-55, Arg-58, and Arg-61) within the beta-arm structure were replaced either by Gln, Lys, or Glu residues, and the resulting mutants were characterized with respect to their DNA-binding activity by a filter-binding analysis and surface plasmon resonance analysis. The results indicate that three Arg residues (Arg-55, Arg-58, and Arg-61) play a crucial role in DNA binding as positively charged recognition groups in the order of Arg-55 > Arg-58 > Arg-61 and that these are required to decrease the dissociation rate constant for BstHU-DNA interaction. In contrast, the Arg-53 residue was found to make no contribution to the binding activity of BstHU.

Characterization of the binding of HU and IHF, homologous histone-like proteins of Escherichia coli, to curved and uncurved DNA

The binding of E. coli histone-like protein HU to curved and uncurved DNA fragments containing adenine tracts was characterized by relative binding affinity assay, and compared with that of other homologous histone-like protein integration host factor (IHF). Both HU and IHF have about 3- to 5-fold higher affinity for overall curved DNA fragments such as (A6N4)11 and (A3T3N4)12 compared to a standard duplex fragment with mixed sequence. The binding manner of HU to the curved fragments was highly cooperative. However, loss of overall curvature for shorter fragments (< approximately 100 bp) reduced the preference of HU binding to curved (A3T3N4)n over uncurved (T3A3N4)n, indicating that the binding specificity of HU to curved DNA is length-dependent. Thus, the curved DNA configuration of the whole molecule facilitates the binding of several HU molecules to form the hierarchy of HU-DNA complex. Furthermore, it was shown that HU and IHF bind less well to (A6N9)n, which has a zig-zag straight structure, whereas they preferentially bind to uncurved (T3A3N4)14. These results suggested that not only intrinsically overall curvature but also the preferred orientations for DNA bending in the protein-DNA complex are important factors for affinities of HU and IHF.

Role of HU proteins in forming and constraining supercoils of chromosomal DNA in Escherichia coli

Induction of supercoiling in plasmid DNA by HU heterotypic and homotypic dimers, a mutant HU-2 (HupAN12), HBs and HB1 proteins with different DNA-binding affinities was investigated in vitro. The abilities of these proteins to induce supercoiling in DNA correlated with their affinities for DNA. Stoichiometrical analysis of HU heterodimers bound to DNA in the complex restraining the negative torsional tension of DNA showed that 12-13 dimers account for a single superhelical turn. The number of supercoils in the plasmid in vivo decreased on inhibition of DNA gyrase with coumermycin, reaching a steady-state level that indicated the existence of a compartment of restrained supercoils. The size of the restrained compartment was reduced in the absence of HU, indicating the participation of HU in constituting this fraction, and was larger on overproduction of HU-2 in the cells. An increased level of DNA gyrase, expressed from a plasmid carrying both gyr genes, in the cells did not compensate for the deficit of the restrained supercoils caused by HU deficiency, indicating seeming distinct and unrelated action of HU and DNA gyrase in introducing and constraining supercoiling of intracellular DNA.

Histones, HMG, HU, IHF: Même combat

In this review article we present a compilation of the proteins homologous to Escherichia coli HU: the HU-like family. Two of these, HU and IHF from E coli have been extensively characterized genetically and biochemically. Due to their DNA binding activities, these proteins confer a condensed shape to the chromosome and regulate the transcription of selected sets of its genes. The parallel between the dual function of the HU-like proteins and the roles described for eukaryotic histone and HMG proteins is striking, especially in the view that they are evolutionary unrelated.