Noncanonical DNA-binding mode of repressor and its disassembly by antirepressor.

DNA-binding repressors are involved in transcriptional repression in many organisms. Disabling a repressor is a crucial step in activating expression of desired genes. Thus, several mechanisms have been identified for the removal of a stably bound repressor (Rep) from the operator. Here, we describe an uncharacterized mechanism of noncanonical DNA binding and induction by a Rep from the temperate Salmonella phage SPC32H; this mechanism was revealed using the crystal structures of homotetrameric Rep (92-198) and a hetero-octameric complex between the Rep and its antirepressor (Ant). The canonical method of inactivating a repressor is through the competitive binding of the antirepressor to the operator-binding site of the repressor; however, these studies revealed several noncanonical features. First, Ant does not compete for the DNA-binding region of Rep. Instead, the tetrameric Ant binds to the C-terminal domains of two asymmetric Rep dimers. Simultaneously, Ant facilitates the binding of the Rep N-terminal domains to Ant, resulting in the release of two Rep dimers from the bound DNA. Second, the dimer pairs of the N-terminal DNA-binding domains originate from different dimers of a Rep tetramer (trans model). This situation is different from that of other canonical Reps, in which two N-terminal DNA-binding domains from the same dimeric unit form a dimer upon DNA binding (cis model). On the basis of these observations, we propose a noncanonical model for the reversible inactivation of a Rep by an Ant.

Structural and functional insights into the regulation mechanism of CK2 by IP6 and the intrinsically disordered protein Nopp140.

Protein kinase CK2 is a ubiquitous kinase that can phosphorylate hundreds of cellular proteins and plays important roles in cell growth and development. Deregulation of CK2 is related to a variety of human cancers, and CK2 is regarded as a suppressor of apoptosis; therefore, it is a target of anticancer therapy. Nucleolar phosphoprotein 140 (Nopp140), which is an intrinsically disordered protein, interacts with CK2 and inhibits the latter's catalytic activity in vitro. Interestingly, the catalytic activity of CK2 is recovered in the presence of d-myo-inositol 1,2,3,4,5,6-hexakisphosphate (IP6). IP6 is widely distributed in animal cells, but the molecular mechanisms that govern its cellular functions in animal cells have not been completely elucidated. In this study, the crystal structure of CK2 in complex with IP6 showed that the lysine-rich cluster of CK2 plays an important role in binding to IP6. The biochemical experiments revealed that a Nopp140 fragment (residues 568-596) and IP6 competitively bind to the catalytic subunit of CK2 (CK2α), and phospho-Ser574 of Nopp140 significantly enhances its interaction with CK2α. Substitutions of K74E, K76E, and K77E in CK2α significantly reduced the interactions of CK2α with both IP6 and the Nopp140-derived peptide. Our study gives an insight into the regulation of CK2. In particular, our work suggests that CK2 activity is inhibited by Nopp140 and reactivated by IP6 by competitive binding at the substrate recognition site of CK2.

Structural insights into the efficient CO2-reducing activity of an NAD-dependent formate dehydrogenase from Thiobacillus sp. KNK65MA.

CO2 fixation is thought to be one of the key factors in mitigating global warming. Of the various methods for removing CO2, the NAD-dependent formate dehydrogenase from Candida boidinii (CbFDH) has been widely used in various biological CO2-reduction systems; however, practical applications of CbFDH have often been impeded owing to its low CO2-reducing activity. It has recently been demonstrated that the NAD-dependent formate dehydrogenase from Thiobacillus sp. KNK65MA (TsFDH) has a higher CO2-reducing activity compared with CbFDH. The crystal structure of TsFDH revealed that the biological unit in the asymmetric unit has two conformations, i.e. open (NAD(+)-unbound) and closed (NAD(+)-bound) forms. Three major differences are observed in the crystal structures of TsFDH and CbFDH. Firstly, hole 2 in TsFDH is blocked by helix α20, whereas it is not blocked in CbFDH. Secondly, the sizes of holes 1 and 2 are larger in TsFDH than in CbFDH. Thirdly, Lys287 in TsFDH, which is crucial for the capture of formate and its subsequent delivery to the active site, is an alanine in CbFDH. A computational simulation suggested that the higher CO2-reducing activity of TsFDH is owing to its lower free-energy barrier to CO2 reduction than in CbFDH.

The N-terminal domain of EzrA binds to the C terminus of FtsZ to inhibit Staphylococcus aureus FtsZ polymerization.

Bacterial cytokinesis is accompanied by a macro-molecular complex called the "divisome." The divisome consists of two major components involving positive regulators and negative regulators that regulate the polymerization of an essential cytoskeleton protein FtsZ, which plays a key role in bacterial cell division by assembling the Z-ring, and therefore has been identified as a target for antibiotics. The negative regulators prevent the Z-ring assembly by inhibiting FtsZ polymerization. In Staphylococcus aureus, a pandemic human pathogen, one of the negative regulators, EzrA, contains a trans-membrane anchor region at the N-terminus and has five predicted coiled-coils. Recent reports indicate that the polymerization of FtsZ can be inhibited by forming a complex with EzrA. In this study, we attempted to locate the binding site for the interaction between EzrA and FtsZ in S. aureus (SaEzrA and SaFtsZ, respectively), by generating various constructs of SaEzrA and SaFtsZ proteins based on limited proteolysis. Various constructs of SaEzrA and SaFtsZ proteins were expressed and homogeneously purified. A GST pull-down assay indicated that the N-terminal domain of SaEzrA interacts with the C-terminal tail of SaFtsZ, and the elongated shape of EzrA was predicted based on the Stokes radius of each construct.

Crystallization and preliminary X-ray crystallographic analysis of Z-ring-associated protein (ZapD) from Escherichia coli.

Bacterial cytokinesis is accomplished by the Z-ring, which is a polymeric structure that includes the tubulin homologue FtsZ at the division site. ZapD, a Z-ring-associated protein, directly binds to FtsZ and stabilizes the polymerization of FtsZ to form a stable Z-ring during cytokinesis. Structural analysis of ZapD from Escherichia coli was performed to investigate the mechanism of ZapD-mediated FtsZ stabilization and polymerization. ZapD was crystallized using a reservoir solution consisting of 1.5 M lithium sulfate, 0.1 M HEPES pH 7.8, 2%(v/v) polyethylene glycol 400. X-ray diffraction data were collected to 2.95 Å resolution. The crystals belonged to the hexagonal space group P64, with unit-cell parameters a = b = 109.5, c = 106.7 Å, γ = 120.0°. Two monomers were present in the asymmetric unit, resulting in a crystal volume per protein mass (VM) of 3.25 Å(3) Da(-1) and a solvent content of 62.17%.