Crystal structure and biochemical analysis suggest that YjoB ATPase is a putative substrate-specific molecular chaperone.

AAA+ ATPases are ubiquitous proteins associated with most cellular processes, including DNA unwinding and protein unfolding. Their functional and structural properties are typically determined by domains and motifs added to the conserved ATPases domain. Currently, the molecular function and structure of many ATPases remain elusive. Here, we report the crystal structure and biochemical analyses of YjoB, a Bacillus subtilis AAA+ protein. The crystal structure revealed that the YjoB hexamer forms a bucket hat-shaped structure with a porous chamber. Biochemical analyses showed that YjoB prevents the aggregation of vegetative catalase KatA and gluconeogenesis-specific glyceraldehyde-3 phosphate dehydrogenase GapB but not citrate synthase, a conventional substrate. Structural and biochemical analyses further showed that the internal chamber of YjoB is necessary for inhibition of substrate aggregation. Our results suggest that YjoB, conserved in the class Bacilli, is a potential molecular chaperone acting in the starvation/stationary phases of B. subtilis growth.

Structural analysis of the regulation of blue-light receptors by GIGANTEA.

In Arabidopsis, GIGANTEA (GI), together with the blue-light receptors ZTL, LKP2, and FKF1, regulates degradation of the core clock protein TOC1 and the flowering repressor CDFs, thereby controlling circadian oscillation and flowering. Despite the significance of GI in diverse plant physiology, its molecular function is not much understood because of technical problems in protein preparation and a lack of structural information. Here, we report the purification of the GI monomer and the crystal structure of the GI/LKP2 complex. The crystal structure reveals that residues 1-813 of GI possess an elongated rigid structure formed by stacking hydrophobic α-helices and that the LOV domain of LKP2 binds to the middle region of the GI (residues 563-789). Interaction analysis further shows that LOV homodimers are converted to monomers by GI binding. Our results provide structural insights into the regulation of the circadian clock and photoperiodic flowering by GI and ZTL/LKP2/FKF1.

Crystal structure of a tandem B-box domain from Arabidopsis CONSTANS.

CONSTANS is a central protein in the regulation of photoperiodic flowering, which is expressed in response to day length and promotes the expression of Flowering Locus T. The tandem B-box domain in CONSTANS mediates interactions with various proteins to regulate the expression of Flowering Locus T. Although most plants, including Arabidopsis, have multiple B-box proteins, their B-box structures have not been elucidated. Here, we report the crystal structure of a tandem B-box domain from Arabidopsis CONSTANS. The crystal structure shows that each B-box adopts a canonical B-box fold and coordinates two zinc atoms. Furthermore, the crystal structure reveals that the B-box domain has a unique structure that distinguishes it from animal B-boxes at the monomer and dimer level.

Crystal structure of the DNA-binding domain of Bacillus subtilis CssR.

Bacteria utilize two-component systems to regulate gene expression in response to changes in environmental stimuli. CssS/CssR, a two-component system in Bacillus subtilis, is responsible for overcoming envelope stresses caused by heat shock and secretion overload. During stress, the sensor component CssS is auto-phosphorylated and transfers the phosphoryl group to the response regulator CssR. Phosphorylated CssR then directly regulates the transcription of genes required to counteract the stress. Here, the crystal structure of the DNA-binding domain of CssR, determined at 1.07 Å resolution, is reported. The structure shows that the DNA-binding domain of CssR harbors a winged helix-turn-helix motif that is conserved in the OmpR/PhoB subfamily of response regulators. Based on the crystal structure, the dimeric architecture of the full-length CssR and its DNA-binding mode were suggested.

Structural insights into stressosome assembly.

The stressosome transduces environmental stress signals to SigB to upregulate SigB-dependent transcription, which is required for bacterial viability. The stressosome core is composed of RsbS and at least one of the RsbR paralogs. A previous cryo-electron microscopy (cryo-EM) structure of the RsbRA-RsbS complex determined under a D2 symmetry restraint showed that the stressosome core forms a pseudo-icosahedron consisting of 60 STAS domains of RsbRA and RsbS. However, it is still unclear how RsbS and one of the RsbR paralogs assemble into the stressosome. Here, an assembly model of the stressosome is presented based on the crystal structure of the RsbS icosahedron and cryo-EM structures of the RsbRA-RsbS complex determined under diverse symmetry restraints (nonsymmetric C1, dihedral D2 and icosahedral I envelopes). 60 monomers of the crystal structure of RsbS fitted well into the I-restrained cryo-EM structure determined at 4.1 Šresolution, even though the STAS domains in the I envelope were averaged. This indicates that RsbS and RsbRA share a highly conserved STAS fold. 22 protrusions observed in the C1 envelope, corresponding to dimers of the RsbRA N-domain, allowed the STAS domains of RsbRA and RsbS to be distinguished in the stressosome core. Based on these, the model of the stressosome core was reconstructed. The mutation of RsbRA residues at the binding interface in the model (R189A/Q191A) significantly reduced the interaction between RsbRA and RsbS. These results suggest that nonconserved residues in the conserved STAS folds between RsbS and RsbR paralogs determine stressosome assembly.

Structural analysis of the recognition of the -35 promoter element by SigW from Bacillus subtilis.

Sigma factors are key proteins that mediate the recruitment of RNA polymerase to the promoter regions of genes, for the initiation of bacterial transcription. Multiple sigma factors in a bacterium selectively recognize their cognate promoter sequences, thereby inducing the expression of their own regulons. In this paper, we report the crystal structure of the σ4 domain of Bacillus subtilis SigW bound to the -35 promoter element. Purine-specific hydrogen bonds of the -35 promoter element with the recognition helix α9 of the σ4 domain occurs at three nucleotides of the consensus sequence (G-35, A-34, and G'-31 in G-35A-34A-33A-32C-31C-30T-29). The hydrogen bonds of the backbone with the α7 and α8 of the σ4 domain occurs at G'-30. These results elucidate the structural basis of the selective recognition of the promoter by SigW. In addition, comparison of SigW structures complexed with the -35 promoter element or with anti-sigma RsiW reveals that DNA recognition and anti-sigma factor binding of SigW are mutually exclusive.