Dynamics of fluoroquinolones induced resistance in DNA gyrase of Mycobacterium tuberculosis

DNA gyrase is a validated target of fluoroquinolones which are key components of multidrug resistance tuberculosis (TB) treatment. Most frequent occurring mutations associated with high level of resistance to fluoroquinolone in clinical isolates of TB patients are A90V, D94G, and A90V–D94G (double mutant [DM]), present in the larger subunit of DNA Gyrase. In order to explicate the molecular mechanism of drug resistance corresponding to these mutations, molecular dynamics (MD) and mechanics approach was applied. Structure-based molecular docking of complex comprised of DNA bound with Gyrase A (large subunit) and Gyrase C (small subunit) with moxifloxacin (MFX) revealed high binding affinity to wild type with considerably high Glide XP docking score of ?7.88 kcal/mol. MFX affinity decreases toward single mutants and was minimum toward the DM with a docking score of ?3.82 kcal/mol. Docking studies were also performed against 8-Methyl-moxifloxacin which exhibited higher binding affinity against wild and mutants DNA gyrase when compared to MFX. Molecular Mechanics/Generalized Born Surface Area method predicted the binding free energy of the wild, A90V, D94G, and DM complexes to be ?55.81, ?25.87, ?20.45, and ?12.29 kcal/mol, respectively. These complexes were further subjected to 30 ns long MD simulations to examine significant interactions and conformational flexibilities in terms of root mean square deviation, root mean square fluctuation, and strength of hydrogen bond formed. This comparative drug interaction analysis provides systematic insights into the mechanism behind drug resistance and also paves way toward identifying potent lead compounds that could combat drug resistance of DNA gyrase due to mutations.     

Architecture of Microcin B17 Synthetase: An Octameric Protein Complex Converting a Ribosomally Synthesized Peptide into a DNA Gyrase Poison

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Functional Relationship of ATP Hydrolysis,Presynaptic Filament Stability,and Homologous DNA Pairing Activity of the Human Meiotic Recombinase DMC1

DMC1 and RAD51 are conserved recombinases that catalyze homologous recombination. DMC1 and RAD51 share similar properties in DNA binding, DNA-stimulated ATP hydrolysis, and catalysis of homologous DNA strand exchange. A large body of evidence indicates that attenuation of ATP hydrolysis leads to stabilization of the RAD51-ssDNA presynaptic filament and enhancement of DNA strand exchange. However, the functional relationship of ATPase activity, presynaptic filament stability, and DMC1-mediated homologous DNA strand exchange has remained largely unexplored. To address this important question, we have constructed several mutant variants of human DMC1 and characterized them biochemically to gain mechanistic insights. Two mutations, K132R and D223N, that change key residues in the Walker A and B nucleotide-binding motifs ablate ATP binding and render DMC1 inactive. On the other hand, the nucleotide-binding cap D317K mutant binds ATP normally but shows significantly attenuated ATPase activity and, accordingly, forms a highly stable presynaptic filament. Surprisingly, unlike RAD51, presynaptic filament stabilization achieved via ATP hydrolysis attenuation does not lead to any enhancement of DMC1-catalyzed homologous DNA pairing and strand exchange. This conclusion is further supported by examining wild-type DMC1 with non-hydrolyzable ATP analogues. Thus, our results reveal an important mechanistic difference between RAD51 and DMC1.     

The influence of C-terminal extension on the structure of the "J-domain" in E. coli DnaJ

Two different recombinant constructs of the N-terminal domain in Escherichia coli DnaJ were uniformly labeled with nitrogen-15 and carbon-13. One, DnaJ(1-78), contains the complete "J-domain," and the other, DnaJ(1-104), contains both the "J-domain" and a conserved "G/F" extension at the C-terminus. The three-dimensional structures of these proteins have been determined by heteronuclear NMR experiments. In both proteins the "J-domain" adopts a compact structure consisting of a helix-turn-helix-loop-helix-turn-helix motif. In contrast, the "G/F" region in DnaJ(1-104) does not fold into a well-defined structure. Nevertheless, the "G/F" region has been found to have an effect on the packing of the helices in the "J-domain" in DnaJ(1-104). Particularly, the interhelical angles between Helix IV and other helices are significantly different in the two structures. In addition, there are some local conformational changes in the loop region connecting the two central helices. These structural differences in the "J-domain" in the presence of the "G/F" region may be related to the observation that DnaJ (1-78) is incapable of stimulating the ATPase activity of the molecular chaperone protein DnaK despite evidence that sites mediating the binding of DnaJ to DnaK are located in the 1-78 segment.     

Defining the ATPase center of bacteriophage T4 DNA packaging machine: requirement for a catalytic glutamate residue in the large terminase protein gp17

Double-stranded DNA packaging in icosahedral bacteriophages is driven by an ATPase-coupled packaging machine constituted by the portal protein and two non-structural packaging/terminase proteins assembled at the unique portal vertex of the empty viral capsid. Recent studies show that the N-terminal ATPase site of bacteriophage T4 large terminase protein gp17 is critically required for DNA packaging. It is likely that this is the DNA translocating ATPase that powers directional translocation of DNA into the viral capsid. Defining this ATPase center is therefore fundamentally important to understand the mechanism of ATP-driven DNA translocation in viruses. Using combinatorial mutagenesis and biochemical approaches, we have defined the catalytic carboxylate residue that is required for ATP hydrolysis. Although the original catalytic carboxylate hypothesis suggested the presence of a catalytic glutamate between the Walker A (SRQLGKT(161-167)) and Walker B (MIYID(251-255)) motifs, none of the four candidate glutamic acid residues, E198, E208, E220 and E227, is required for function. However, the E256 residue that is immediately adjacent to the putative Walker B aspartic acid residue (D255) exhibited a phenotypic pattern that is consistent with the catalytic carboxylate function. None of the amino acid substitutions, including the highly conservative D and Q, was tolerated. Biochemical analyses showed that the purified E256V, D, and Q mutant gp17s exhibited a complete loss of gp16-stimulated ATPase activity and in vitro DNA packaging activity, whereas their ATP binding and DNA cleavage functions remained intact. The data suggest that the E256 mutants are trapped in an ATP-bound conformation and are unable to catalyze the ATP hydrolysis-transduction cycle that powers DNA translocation. Thus, this study for the first time identified and characterized a catalytic glutamate residue that is involved in the energy transduction mechanism of a viral DNA packaging machine.     

Molecular Dynamics Simulation in Solvent of the Estrogen Receptor Protein DNA Binding Domain in Complex with a Non-Consensus Estrogen Response Element DNA Sequence

Abstract

We investigated protein/DNA interactions, using molecular dynamics simulations computed between a 10 Angstom water layer model of the estrogen receptor (ER) protein DNA binding domain (DBD) amino acids and DNA of a non-consensus estrogen response element (ERE) consisting of 29 nucleotide base pairs. This ERE nucleotide sequence occurs naturally upstream of the Xenopus laevis Vitelligenin AI gene. The ER DBD is encoded by three exons. Namely, exons 2 and 3 which encode the two zinc binding motifs and a sequence of exon 4 which encodes a predicted alpha helix. We generated a computer model of the ER DBD using atomic coordinates derived from the average of 30 nuclear magnetic resonance (NMR) spectroscopy coordinate sets. Amino acids on the carboxyl end of the ER DBD were disordered in both X-ray crystallography and NMR determinations and no coordinates were reported. This disordered region includes 10 amino acids of a predicted alpha helix encoded in exon 4 at the exon 3/4 splice junction. These amino acids are known to be important in DNA binding and are also believed to function as a nuclear translocation signal sequence for the ER protein. We generated a computer model of the predicted alpha helix consisting of the 10 amino acids encoded in exon 4 and attached this helix to the carboxyl end of the ER DBD at the exon 3/4 splice junction site. We docked the ER DBD model within the DNA major groove halfsites of the 29 base pair non-consensus ERE and flanking nucleotides. We constructed a solvated model with the ER DBD/ERE complex surrounded by a ten Angstrom water layer and conducted molecular dynamics simulations. Hydrogen bonding interactions were monitored. In addition, van der Waals and electrostatic interaction energies were calculated. Amino acids of the ER DBD DNA recognition helix formed both direct and water mediated hydrogen bonds at cognate codon-anticodon nucleotide base and backbone sites within the ERE DNA right major groove halfsite. Amino acids of the ER DBD exon 4 encoded predicted alpha helix formed direct and water mediated H-bonds with base and backbone sites of their cognate codon-anticodon nucleotides within the minor grooves flanking the ERE DNA major groove halfsites. These interactions together induced bending of the DNA into the protein.     

Structure of the Mycobacterium tuberculosis OmpATb protein: a model of an oligomeric channel in the mycobacterial cell wall

The pore-forming outer membrane protein OmpATb from Mycobacterium tuberculosis is a virulence factor required for acid resistance in host phagosomes. In this study, we determined the 3D structure of OmpATb by NMR in solution. We found that OmpATb is composed of two independent domains separated by a proline-rich hinge region. As expected, the high-resolution structure of the C-terminal domain (OmpATb(198-326)) revealed a module structurally related to other OmpA-like proteins from Gram-negative bacteria. The N-terminal domain of OmpATb (73-204), which is sufficient to form channels in planar lipid bilayers, exhibits a fold, which belongs to the α+β sandwich class fold. Its peculiarity is to be composed of two overlapping subdomains linked via a BON (Bacterial OsmY and Nodulation) domain initially identified in bacterial proteins predicted to interact with phospholipids. Although OmpATb(73-204) is highly water soluble, current-voltage measurements demonstrate that it is able to form conducting pores in model membranes. A HADDOCK modeling of the NMR data gathered on the major monomeric form and on the minor oligomeric populations of OmpATb(73-204) suggest that OmpATb(73-204) can form oligomeric rings able to insert into phospholipid membrane, similar to related proteins from the Type III secretion systems, which form multisubunits membrane-associated rings at the basal body of the secretion machinery.     

Fast detection of quadruplex structure in DNA by the intrinsic fluorescence of a single-stranded DNA binding protein

Single-stranded guanine-rich (G-rich) DNA can fold into a four-stranded G-quadruplex structure and such structures are implicated in important biological processes and therapeutic applications. So far, bioinformatic analysis has identified up to several hundred thousand of putative quadruplex sequences in the genome of human and other animal. Given such a large number of sequences, a fast assay would be desired to experimentally verify the structure of these sequences. Here we describe a method that identifies the quadruplex structure by a single-stranded DNA binding protein from a thermoautotrophic archaeon. This protein binds single-stranded DNA in the unfolded, but not in the folded form. Upon binding to DNA, its fluorescence can be quenched by up to 70%. Formation of quadruplex greatly reduces fluorescence quenching in a K+-dependent manner. This structure-dependent quenching provides simple and fast detection of quadruplex in DNA at low concentration without DNA labelling.     

Role of AP‐endonuclease (Ape1) active site residues in stabilization of the reactant enzyme‐DNA complex

Apurinic/apyrimidinic endonuclease 1 (Ape1) is an important metal‐dependent enzyme in the base excision repair mechanism, responsible for the backbone cleavage of abasic DNA through a phosphate hydrolysis reaction. Molecular dynamics simulations of Ape1 complexed to its substrate DNA performed for models containing 1 or 2 Mg²⁺‐ions as cofactor located at different positions show a complex with 1 metal ion bound on the leaving group site of the scissile phosphate to be the most likely reaction‐competent conformation. Active‐site residue His309 is found to be protonated based on pKa calculations and the higher conformational stability of the Ape1‐DNA substrate complex compared to scenarios with neutral His309. Simulations of the D210N mutant further support the prevalence of protonated His309 and strongly suggest Asp210 as the general base for proton acceptance by a nucleophilic water molecule.     

Complex of the herpes simplex virus type 1 origin binding protein UL9 with DNA as a platform for the design of a new type of antiviral drugs

The herpes simplex virus type 1 origin-binding protein, OBP, is a DNA helicase encoded by the UL9 gene. The protein binds in a sequence-specific manner to the viral origins of replication, two OriS sites and one OriL site. In order to search for efficient inhibitors of the OBP activity, we have obtained a recombinant origin-binding protein expressed in Escherichia coli cells. The UL9 gene has been amplified by PCR and inserted into a modified plasmid pET14 between NdeI and KpnI sites. The recombinant protein binds to Box I and Box II sequences and possesses helicase and ATPase activities. In the presence of ATP and viral protein ICP8 (single-strand DNA-binding protein), the initiator protein induces unwinding of the minimal OriS duplex (≈80?bp). The protein also binds to a single-stranded DNA (OriS^?) containing a stable Box I-Box III hairpin and an unstable AT-rich hairpin at the 3′-end. In the present work, new minor groove binding ligands have been synthesized which are capable to inhibit the development of virus-induced cytopathic effect in cultured Vero cells. Studies on binding of these compounds to DNA and synthetic oligonucleotides have been performed by fluorescence methods, gel mobility shift analysis and footprinting assays. Footprinting studies have revealed that Pt-bis-netropsin and related molecules exhibit preferences for binding to the AT-spacer in OriS. The drugs stabilize structure of the AT-rich region and inhibit the fluctuation opening of AT-base pairs which is a prerequisite to unwinding of DNA by OBP. Kinetics of ATP-dependent unwinding of OriS in the presence and absence of netropsin derivatives have been studied by measuring the efficiency of Forster resonance energy transfer (FRET) between fluorophores attached to 5′- and 3′- ends of an oligonucleotide in the minimal OriS duplex. The results are consistent with the suggestion that OBP is the DNA Holiday junction (HJ) binding helicase. The protein induces conformation changes (bending and partial melting) of OriS duplexes and stimulates HJ formation in the absence of ATP. The antiviral activity of bis-netropsins is coupled with their ability to inhibit the fluctuation opening of АТ base pairs in the А?+?Т cluster and their capacity to stabilize the structure of the АТ-rich hairpin in the single-stranded oligonucleotide corresponding to the upper chain in the minimal duplex OriS. The antiviral activities of bis-netropsins in cell culture and their therapeutic effects on HSV1-infected laboratory animals have been studied.     

Cooperative DNA Binding of the Plasmid Partitioning Protein TubR from the Bacillus cereus pXO1 Plasmid

Tubulin/FtsZ-like GTPase TubZ is responsible for maintaining the stability of pXO1-like plasmids in virulent Bacilli. TubZ forms a filament in a GTP-dependent manner, and like other partitioning systems of low-copy-number plasmids, it requires the centromere-binding protein TubR that connects the plasmid to the TubZ filament. Systems regulating TubZ partitioning have been identified in Clostridium prophages as well as virulent Bacillus species, in which TubZ facilitates partitioning by binding and towing the segrosome: the nucleoprotein complex composed of TubR and the centromere. However, the molecular mechanisms of segrosome assembly and the transient on–off interactions between the segrosome and the TubZ filament remain poorly understood. Here, we determined the crystal structure of TubR from Bacillus cereus at 2.0-Å resolution and investigated the DNA-binding ability of TubR using hydroxyl radical footprinting and electrophoretic mobility shift assays. The TubR dimer possesses 2-fold symmetry and binds to a 15-bp palindromic consensus sequence in the tubRZ promoter region. Continuous TubR-binding sites overlap each other, which enables efficient binding of TubR in a cooperative manner. Interestingly, the segrosome adopts an extended DNA–protein filament structure and likely gains conformational flexibility by introducing non-consensus residues into the palindromes in an asymmetric manner. Together, our experimental results and structural model indicate that the unique centromere recognition mechanism of TubR allows transient complex formation between the segrosome and the dynamic polymer of TubZ.     

The Structure of the FnIII Tandem A77-A78 Points to a Periodically Conserved Architecture in the Myosin-Binding Region of Titin

Titin is a large intrasarcomeric protein that, among its many roles in muscle, is thought to modulate the in vivo assembly of the myosin motor filament. This is achieved through the molecular template properties of its A-band region, which is composed of fibronectin type III (FnIII) and immunoglobulin (Ig) domains organized into characteristic 7-domain (D-zone) and 11-domain (C-zone) superrepeats. Currently, there is little knowledge on the structural details of this region of titin. Here we report the conformational characterization of three FnIII tandems, A77-A78, A80-A82, and A84-A86, which are components of the representative fourth C-zone superrepeat. The structure of A77-A78 has been elucidated by X-ray crystallography to 1.65 Å resolution, while low-resolution models of A80-A82 and A84-A86 have been calculated using small-angle X-ray scattering. A77-A78 adopts an extended “up-down” domain arrangement, where domains are connected by a hydrophilic three-residue linker sequence. The linker is embedded in a rich network of polar contacts at the domain interface that results in a stiff molecular conformation. The models of A80-A82 and A84-A86, which contain hydrophobic six-residue-long interdomain linkers, equally showed elongated molecular shapes, but with slightly coiled or zigzagged conformations. Small-angle X-ray scattering data further suggested that the long linkers do not result in a noticeable increase in molecular flexibility but lead to semibent domain arrangements. Our findings indicate that the structural characteristics of FnIII tandems from A-band titin contrast markedly with those of poly-Ig tandems from the elastic I-band, which exhibit domain interfaces depleted of interactions and compliant conformations. Furthermore, the analysis of sequence conservation in FnIII domains from A-band titin points to the existence of conformationally defined interfaces at specific superrepeat positions, possibly leading to a periodic and locally ordered architecture supporting the molecular scaffold properties of this region of titin.     

Role of intrinsic flexibility in signal transduction mediated by the cell cycle regulator, p27 Kip1

p27^Kip1 (p27), which controls eukaryotic cell division through interactions with cyclin-dependent kinases (Cdks), integrates and transduces promitogenic signals from various nonreceptor tyrosine kinases by orchestrating its own phosphorylation, ubiquitination and degradation. Intrinsic flexibility allows p27 to act as a “conduit” for sequential signaling mediated by tyrosine and threonine phosphorylation and ubiquitination. While the structural features of the Cdk/cyclin-binding domain of p27 are understood, how the C-terminal regulatory domain coordinates multistep signaling leading to p27 degradation is poorly understood. We show that the 100-residue p27 C-terminal domain is extended and flexible when p27 is bound to Cdk2/cyclin A. We propose that the intrinsic flexibility of p27 provides a molecular basis for the sequential signal transduction conduit that regulates p27 degradation and cell division. Other intrinsically unstructured proteins possessing multiple sites of posttranslational modification may participate in similar signaling conduits.     

Comparison of Molecular Dynamics Averaged Structures for Complexes of Normal and Oncogenic ras-p21 with SOS Nucleotide Exchange Protein, Containing Computed Conformations for Three Crystallographically Undefined Domains, Suggests a Potential Role of These Domains in ras Signaling

ras-p21 protein binds to the son-of-sevenless (SOS) guanine nucleotide-exchange promoter that allows it to exchange GDP for GTP. Previously, we performed molecular dynamics calculations on oncogenic (Val 12-) and wild-type ras-p21 bound to SOS. By superimposing the average structures of these two complexes, we identified four domains (residues 631-641, 676-691, 718-729, and 994-1004) in SOS that change conformation and were candidates for being effector domains. These calculations were performed in the absence of three crystallographically undefined loops (i.e., residues 591-596, 654-675, and 742-751). We have now modeled these loops into the SOS structure and have re-performed the dynamics calculations. We find that all three loop domains undergo large changes in conformation that involve mostly changes in their positioning and not their individual conformations. We have also identified another potential effector domain (i.e., residues 980-989). Overall, our current results suggest that SOS interactions with oncogenic ras-p21 may enhance ras-p21 mitogenic signaling through prolonging its activation by maintaining its binding to GTP and by allowing its effector domains to interact with intracellular targets.