Independent and interchangeable multimerization domains of the AbrB, Abh, and SpoVT global regulatory proteins

The global regulators AbrB, Abh, and SpoVT are paralogous proteins showing their most extensive sequence homologies in the DNA-binding amino-terminal regions (about 50 residues). The carboxyl-terminal portion of AbrB has been hypothesized to be a multimerization domain with little if any role in DNA-binding recognition or specificity. To investigate the multimerization potentials of the carboxyl-terminal portions of AbrB, Abh, and SpoVT we utilized an in vivo multimerization assay system based upon fusion of the domains to the DNA binding domain of the lambda cI repressor protein. The results indicate that the N and C domains of all three paralogues are independent dimerization modules and that the intact Abh and SpoVT proteins are most probably tetramers. Chimeric proteins consisting of the AbrB N-terminal DNA-binding domain fused to the C domain of either Abh or SpoVT are indistinguishable from wild-type AbrB in their ability to regulate an AbrB target promoter in vivo.     

AbrB-like transcription factors assume a swapped hairpin fold that is evolutionarily related to double-psi beta barrels

AbrB is a key transition-state regulator of Bacillus subtilis. Based on the conservation of a betaalphabeta structural unit, we proposed a beta barrel fold for its DNA binding domain, similar to, but topologically distinct from, double-psi beta barrels. However, the NMR structure revealed a novel fold, the "looped-hinge helix." To understand this discrepancy, we undertook a bioinformatics study of AbrB and its homologs; these form a large superfamily, which includes SpoVT, PrlF, MraZ, addiction module antidotes (PemI, MazE), plasmid maintenance proteins (VagC, VapB), and archaeal PhoU homologs. MazE and MraZ form swapped-hairpin beta barrels. We therefore reexamined the fold of AbrB by NMR spectroscopy and found that it also forms a swapped-hairpin barrel. The conservation of the core betaalphabeta element supports a common evolutionary origin for swapped-hairpin and double-psi barrels, which we group into a higher-order class, the cradle-loop barrels, based on the peculiar shape of their ligand binding site.     

Revised structure of the AbrB N-terminal domain unifies a diverse superfamily of putative DNA-binding proteins

New relationships found in the process of updating the structural classification of proteins (SCOP) database resulted in the revision of the structure of the N-terminal, DNA-binding domain of the transition state regulator AbrB. The dimeric AbrB domain shares a common fold with the addiction antidote MazE and the subunit of uncharacterized protein MraZ implicated in cell division and cell envelope formation. It has a detectable sequence similarity to both MazE and MraZ thus providing an evolutionary link between the two proteins. The putative DNA-binding site of AbrB is found on the same face as the DNA-binding site of MazE and appears similar, both in structure and sequence, to the exposed conserved region of MraZ. This strongly suggests that MraZ also binds DNA and allows for a consensus model of DNA recognition by the members of this novel protein superfamily.     

The DNA-binding domain in the Bacillus subtilis transition-state regulator AbrB employs significant motion for promiscuous DNA recognition

AbrB is a Bacillus subtilis protein responsible for regulating a diverse array of unrelated genes during periods of sub-optimal growth conditions. DNA binding by AbrB is unique in that sequence recognition is specific, yet no obvious consensus sequence of bound promoter regions is apparent. The N-terminal domain is a recently characterized representative of a novel class of DNA-binding proteins that possess a looped-hinge helix DNA-binding topology. Although the structural characterization of this DNA-binding topology contributed to an understanding of the architectural basis for recognition of DNA target sequences, specific mechanisms responsible for promiscuity in DNA sequence recognition still were not apparent. Analysis of (15)N backbone relaxation parameters shows that dynamic motion of regions directly linked to DNA binding show concerted motion on the microsecond-millisecond timescale. Furthermore, dynamic motion of the hinge region suggests that the DNA-binding region is capable of conformational orientations that allow it to accommodate DNA sequence variability in the cognate binding sites.     

Molecular characterization of the transition state regulator AbrB from Bacillus stearothermophilus

The Bacillus subtilis transition state regulator AbrB(su) is a DNA-binding protein that acts on several genes either as activator, repressor, or preventer. However, among genes under its control, neither common binding sites could be identified nor could the structural features of this broad and specific interaction be elucidated. Attempts to elucidate these interesting features by crystallizing AbrB(su) have failed so far. Therefore, to solve this problem, we focused in this work on identifying an AbrB(su) homologue from Bacillus stearothermophilus. Using a novel method, the entire abrB(st) gene of B. stearothermophilus was cloned and sequenced. The gene encodes a 95 amino acid protein that shows 77% identity and 85% similarity to the mesophilic B. subtilis protein. A calmodulin binding peptide-tagged fusion of the thermophilic gene was constructed for overexpression and efficient affinity column purification of the AbrB(st) protein. The purified protein showed, after removal of the tag, an oligomerization behavior through hexamer formation that is essential for its DNA binding activity.     

DNA-binding activity of amino-terminal domains of the Bacillus subtilis AbrB protein

Two truncated variants of AbrB, comprising either its first 53 (AbrBN53) or first 55 (AbrBN55) amino acid residues, were constructed and purified. Noncovalently linked homodimers of the truncated variants exhibited very weak DNA-binding activity. Cross-linking AbrBN55 dimers into tetramers and higher-order multimers (via disulfide bonding between penultimate cysteine residues) resulted in proteins having DNA-binding affinity comparable to and DNA-binding specificity identical to those of intact, wild-type AbrB. These results indicate that the DNA recognition and specificity determinants of AbrB binding lie solely within its N-terminal amino acid sequence.     

Macromolecular assembly of the transition state regulator AbrB in its unbound and complexed states probed by microelectrospray ionization mass spectrometry

The Bacillus subtilis global transition-state regulator AbrB specifically recognizes over 60 different DNA regulatory regions of genes expressed during cellular response to suboptimal environments. Most interestingly the DNA regions recognized by AbrB share no obvious consensus base sequence. To more clearly understand the functional aspects of AbrB activity, microelectrospray ionization mass spectrometry has been employed to resolve the macromolecular assembly of unbound and DNA-bound AbrB. Analysis of the N-terminal DNA binding domain of AbrB (AbrBN53, residues 1-53) demonstrates that AbrBN53 is a stable dimer, showing no apparent exchange with a monomeric form as a function of pH, ionic strength, solvent, or protein concentration. AbrBN53 demonstrates a capacity for DNA binding, underscoring the role of the N-terminal domain in both DNA recognition and dimerization. Full-length AbrB is shown to exist as a homotetramer. An investigation of the binding of AbrBN53 and AbrB to the natural DNA target element sinIR shows that AbrBN53 binds as a dimer and AbrB binds as a tetramer. This study represents the first detailed characterization of the stoichiometry of a transition-state regulator binding to one of its target promoters.