Shan-Ho Chou

Base pairing geometry in GA mismatches depends entirely on the neighboring sequence

We have synthesized nine self-complementary DNA oligomers containing different flanking sequences adjacent to a pair of contiguous GA mismatches, and have used high resolution nuclear magnetic resonance (n.m.r.) to investigate the GpA phosphodiester backbone conformation and mismatch pairing schemes in these duplexes. We found dramatic effects of the flanking base pair on the hydrogen bonding and backbone conformation, which appear to be coupled. Thus the Ganti-Aanti base pairing scheme in a NAGATN sequence switches to a more stable sheared GA base pairing scheme in a NCGAGN or NTGAAN context, while no duplex is formed (or only GA bulges occur) when NAGATN is changed to NGGACN. Furthermore, the more stable sheared GA pairing in NPyGAPuN sequences is associated with a BII rather than BI backbone conformation for the phosphodiester between the adjacent mismatched GA pairs. The overall stability of these adjacent GA mismatches as measured by imino proton n.m.r. studies is Py-GA-Pu > A-GA-T > G-GA-C.

Diversity of Cyclic Di-GMP-Binding Proteins and Mechanisms

Cyclic di-GMP (c-di-GMP) synthetases and hydrolases (GGDEF, EAL, and HD-GYP domains) can be readily identified in bacterial genome sequences by using standard bioinformatic tools. In contrast, identification of c-di-GMP receptors remains a difficult task, and the current list of experimentally characterized c-di-GMP-binding proteins is likely incomplete. Several classes of c-di-GMP-binding proteins have been structurally characterized; for some others, the binding sites have been identified; and for several potential c-di-GMP receptors, the binding sites remain to be determined. We present here a comparative structural analysis of c-di-GMP-protein complexes that aims to discern the common themes in the binding mechanisms that allow c-di-GMP receptors to bind it with (sub)micromolar affinities despite the 1,000-fold excess of GTP. The available structures show that most receptors use their Arg and Asp/Glu residues to bind c-di-GMP monomers, dimers, or tetramers with stacked guanine bases. The only exception is the EAL domains that bind c-di-GMP monomers in an extended conformation. We show that in c-di-GMP-binding signature motifs, Arg residues bind to the O-6 and N-7 atoms at the Hoogsteen edge of the guanine base, while Asp/Glu residues bind the N-1 and N-2 atoms at its Watson-Crick edge. In addition, Arg residues participate in stacking interactions with the guanine bases of c-di-GMP and the aromatic rings of Tyr and Phe residues. This may account for the presence of Arg residues in the active sites of every receptor protein that binds stacked c-di-GMP. We also discuss the implications of these structural data for the improved understanding of the c-di-GMP signaling mechanisms.

Sequence-specific recognition of DNA: Nuclear magnetic resonance assignments and structural comparison of wild-type and mutant λ OR3 operator DNA

The resonances of all the base protons and most of the sugar protons in both strands of the 17 base-pair OR3 operator of the phage lambda, and of the vC3 single base-pair mutant, have been assigned using two-dimensional nuclear magnetic resonance methods. The chemical shift and nuclear Overhauser effect data for these two DNA sequences reveal no structural perturbation at sites distal to the mutation, neither are there significant changes in structure immediately surrounding the altered base-pair in the mutant sequence. These results are consistent with the model proposed by Ohlendorf et al. (1982), based on crystallographic data on the cro protein, for the OR3-cro protein interaction. The data from these solution studies are examined and discussed in the light of this model. This work demonstrates that nuclear magnetic resonance chemical shifts and nuclear Overhauser effect intensities provide a method for comparing the solution structures of DNA molecules. From the resolution available in the spectra of the 17 base-pair operators studied, it is clear that DNA duplexes of up to 30 or more base-pairs can be studied using phase-sensitive methods.

The structure and inhibition of a GGDEF diguanylate cyclase complexed with (c-di-GMP)2 at the active site

Cyclic diguanosine monophosphate (c-di-GMP) is a key signalling molecule involved in regulating many important biological functions in bacteria. The synthesis of c-di-GMP is catalyzed by the GGDEF-domain-containing diguanylate cyclase (DGC), the activity of which is regulated by the binding of product at the allosteric inhibitory (I) site. However, a significant number of GGDEF domains lack the RxxD motif characteristic of the allosteric I site. Here, the structure of XCC4471(GGDEF), the GGDEF domain of a DGC from Xanthomonas campestris, in complex with c-di-GMP has been solved. Unexpectedly, the structure of the complex revealed a GGDEF-domain dimer cross-linked by two molecules of c-di-GMP at the strongly conserved active sites. In the complex (c-di-GMP)(2) adopts a novel partially intercalated form, with the peripheral guanine bases bound to the guanine-binding pockets and the two central bases stacked upon each other. Alteration of the residues involved in specific binding to c-di-GMP led to dramatically reduced K(d) values between XCC4471(GGDEF) and c-di-GMP. In addition, these key residues are strongly conserved among the many thousands of GGDEF-domain sequences identified to date. These results indicate a new product-bound form for GGDEF-domain-containing proteins obtained via (c-di-GMP)(2) binding at the active site. This novel XCC4471(GGDEF)-c-di-GMP complex structure may serve as a general model for the design of lead compounds to block the DGC activity of GGDEF-domain-containing proteins in X. campestris or other microorganisms that contain multiple GGDEF-domain proteins.

A cyclic GMP-dependent signalling pathway regulates bacterial phytopathogenesis

Cyclic guanosine 3′,5′‐monophosphate (cyclic GMP) is a second messenger whose role in bacterial signalling is poorly understood. A genetic screen in the plant pathogen Xanthomonas campestris (Xcc) identified that XC_0250, which encodes a protein with a class III nucleotidyl cyclase domain, is required for cyclic GMP synthesis. Purified XC_0250 was active in cyclic GMP synthesis in vitro. The linked gene XC_0249 encodes a protein with a cyclic mononucleotide‐binding (cNMP) domain and a GGDEF diguanylate cyclase domain. The activity of XC_0249 in cyclic di‐GMP synthesis was enhanced by addition of cyclic GMP. The isolated cNMP domain of XC_0249 bound cyclic GMP and a structure–function analysis, directed by determination of the crystal structure of the holo‐complex, demonstrated the site of cyclic GMP binding that modulates cyclic di‐GMP synthesis. Mutation of either XC_0250 or XC_0249 led to a reduced virulence to plants and reduced biofilm formation in vitro. These findings describe a regulatory pathway in which cyclic GMP regulates virulence and biofilm formation through interaction with a novel effector that directly links cyclic GMP and cyclic di‐GMP signalling.

Nucleotide binding by the widespread high-affinity cyclic di-GMP receptor MshEN domain

C-di-GMP is a bacterial second messenger regulating various cellular functions. Many bacteria contain c-di-GMP-metabolizing enzymes but lack known c-di-GMP receptors. Recently, two MshE-type ATPases associated with bacterial type II secretion system and type IV pilus formation were shown to specifically bind c-di-GMP. Here we report crystal structure of the MshE N-terminal domain (MshEN1-145) from Vibrio cholerae in complex with c-di-GMP at a 1.37 Å resolution. This structure reveals a unique c-di-GMP-binding mode, featuring a tandem array of two highly conserved binding motifs, each comprising a 24-residue sequence RLGxx(L/V/I)(L/V/I)xxG(L/V/I)(L/V/I)xxxxLxxxLxxQ that binds half of the c-di-GMP molecule, primarily through hydrophobic interactions. Mutating these highly conserved residues markedly reduces c-di-GMP binding and biofilm formation by V. cholerae. This c-di-GMP-binding motif is present in diverse bacterial proteins exhibiting binding affinities ranging from 0.5 μM to as low as 14 nM. The MshEN domain contains the longest nucleotide-binding motif reported to date.

Insights into the Alkyl Peroxide Reduction Pathway of Xanthomonas campestris Bacterioferritin Comigratory Protein from the Trapped Intermediate―Ligand Complex Structures

Considerable insights into the oxidoreduction activity of the Xanthomonas campestris bacterioferritin comigratory protein (XcBCP) have been obtained from trapped intermediate/ligand complex structures determined by X-ray crystallography. Multiple sequence alignment and enzyme assay indicate that XcBCP belongs to a subfamily of atypical 2-Cys peroxiredoxins (Prxs), containing a strictly conserved peroxidatic cysteine (C(P)48) and an unconserved resolving cysteine (C(R)84). Crystals at different states, i.e. Free_SH state, Intra_SS state, and Inter_SS state, were obtained by screening the XcBCP proteins from a double C48S/C84S mutant, a wild type, and a C48A mutant, respectively. A formate or an alkyl analog with two water molecules that mimic an alkyl peroxide substrate was found close to the active site of the Free_SH or Inter_SS state, respectively. Their global structures were found to contain a novel substrate-binding pocket capable of accommodating an alkyl chain of no less than 16 carbons. In addition, in the Intra_SS or Inter_SS state, substantial local unfolding or complete unfolding of the C(R)-helix was detected, with the C(P)-helix remaining essentially unchanged. This is in contrast to the earlier observation that the C(P)-helix exhibits local unfolding during disulfide bond formation in typical 2-Cys Prxs. These rich experimental data have enabled us to propose a pathway by which XcBCP carries out its oxidoreduction activity through the alternate opening and closing of the substrate entry channel and the disulfide-bond pocket.

XC1028 from Xanthomonas campestris adopts a PilZ domain-like structure without a c-di-GMP switch.

The crystal structure of XC1028 from Xanthomonas campestris has been determined to a resolution of 2.15 Å using the multiple anomalous dispersion approach. It bears significant sequence identity and similarity values of 64.10% and 70.09%, respectively, with PA2960, a protein indispensable for type IV pilus‐mediated twitching motility, after which the PilZ motif was first named. However, both XC1028 and PA2960 lack detectable c‐di‐GMP binding capability. Although XC1028 adopts a structure comprising a five‐stranded β‐barrel core similar to other canonical PilZ domains with robust c‐di‐GMP binding ability, considerable differences are observed in the N‐terminal motif; XC1028 assumes a compact five‐stranded β‐barrel without an extra long N‐terminal motif, whereas other canonical PilZ domains contain a long N‐terminal sequence embedded with an essential “c‐di‐GMP switch” motif. In addition, a β‐strand (β1) in the N‐terminal motif, running in exactly opposite polarity to that of XC1028, is found inserted into the parallel β3/β1′ strands, forming a completely antiparallel β4↓β3↑β1↓β1′↑ sheet in the canonical PilZ domains. Such dramatic structural differences at the N‐terminus may account for the diminished c‐di‐GMP binding capability of XC1028, and suggest that interactions with additional proteins are necessary to bind c‐di‐GMP for type IV fimbriae assembly. Proteins 2009.

Structural polymorphism of c‐di‐GMP bound to an EAL domain and in complex with a type II PilZ‐domain protein

Cyclic di-GMP (c-di-GMP) is a novel secondary-messenger molecule that is involved in regulating a plethora of important bacterial activities through binding to an unprecedented array of effectors. Proteins with a canonical PilZ domain that bind c-di-GMP play crucial roles in regulating flagellum-based motility. In contrast, noncanonical type II PilZ domains that do not effectively bind c-di-GMP regulate twitching motility, which is dependent on type IV pili (T4P). Recent data indicate that T4P biogenesis is initiated via the interaction of a noncanonical type II PilZ protein with the GGDEF/EAL-domain protein FimX and the pilus motor protein PilB at high c-di-GMP concentrations. However, the molecular details of such interactions remain to be elucidated. In this manuscript, the first hetero-complex crystal structure between a type II PilZ protein and the EAL domain of the FimX protein (FimX(EAL)) from Xanthomonas campestris pv. campestris (Xcc) in the presence of c-di-GMP is reported. This work reveals two novel conformations of monomeric c-di-GMP in the XccFimX(EAL)-c-di-GMP and XccFimX(EAL)-c-di-GMP-XccPilZ complexes, as well as a unique interaction mode of a type II PilZ domain with FimX(EAL). These findings indicate that c-di-GMP is sufficiently flexible to adjust its conformation to match the corresponding recognition motifs of different cognate effectors. Together, these results represent a first step towards an understanding of how T4P biogenesis is controlled by c-di-GMP at the molecular level and also of the ability of c-di-GMP to bind to a wide variety of effectors.

Xanthomonas campestris PqqD in the pyrroloquinoline quinone biosynthesis operon adopts a novel saddle‐like fold that possibly serves as a PQQ carrier

Xanthomonas campestris PqqD in the pyrroloquinoline quinone biosynthesis operon adopts a novel saddle-like fold that possibly serves as a PQQ carrier Tung-Yi Tsai, Chao-Yu Yang, Hui-Ling Shih, Andrew H.-J. Wang, and Shan-Ho Chou* 1 Institute of Biochemistry, National Chung-Hsing University, Taichung, 40227, Taiwan, Republic of China 2 Core Facility for Protein Crystallography, Academia Sinica, Nankang, Taipei, Taiwan, Republic of China 3 Institute of Biological Chemistry, Academia Sinica, Nankang, Taipei, Taiwan, Republic of China 4 National Chung Hsing University Biotechnology Center, National Chung-Hsing University, Taichung, 40227, Taiwan, Republic of China