Systematic screening of viral entry inhibitors using surface plasmon resonance.

Viral binding and entry into host cells for various viruses have been studied extensively, yielding a detailed understanding of the overall viral entry process. As cell entry is an essential and requisite process by which a virus initiates infection, it is an attractive target for therapeutic intervention. The advantages of targeting viral entry are an extracellular target site, relatively easy access for biological interventions, and lower toxicity. Several cell-based strategies and biophysical techniques have been used to screen compounds that block viral entry. These studies led to the discovery of inhibitors against HIV, HCV, influenza, Ebola, and RSV. In recent years, several compounds screened by fragment-based drug discovery have been approved as drugs or are in the final stages of clinical trials. Among fragment screening technologies, surface plasmon resonance has been widely used because it provides accurate information on binding kinetics, allows real-time monitoring of ligand-drug interactions, requires very small sample amounts to perform analyses, and requires no modifications to or labeling of ligands. This review focuses on surface plasmon resonance-based schemes for screening viral entry inhibitors.

Aptamers that bind to the human complement component receptor hC5aR1 interfere with hC5aR1 interaction to its hC5a ligand.

The complement system plays an important role in inflammation and immunity. In this system, a potent inflammatory ligand is C5a, which initiates its effects by activating its core receptor C5aR1. Thus, compounds that interfere with the C5a-C5aR1 interaction could alleviate some inflammatory conditions. Consequently, several ligands that bind to either C5a or C5aR1 have previously been isolated and evaluated. In the present study, two RNA aptamers, aptamer 1 and aptamer 9, that specifically bind to hC5aR1 with much higher affinity than antibodies were isolated. These two aptamers were tested for their ability to interfere with the cognate ligand of hC5aR1, C5a, using a chemotaxis assay. Both aptamer 1 and 9 interfered with the C5a interaction, suggesting that the aptamers recognized the extracellular domain of hC5aR1 responsible for hC5a ligand binding. Considering the higher affinity of aptamers to the hC5aR1 and their interference with hC5a ligand binding, further study is warranted to explore not only their applications in the diagnosis of inflammatory diseases but also their usefulness in modulating hC5a and hC5aR1 interactions.

Physical interaction between bacterial heat shock protein (Hsp) 90 and Hsp70 chaperones mediates their cooperative action to refold denatured proteins.

In eukaryotes, heat shock protein 90 (Hsp90) is an essential ATP-dependent molecular chaperone that associates with numerous client proteins. HtpG, a prokaryotic homolog of Hsp90, is essential for thermotolerance in cyanobacteria, and in vitro it suppresses the aggregation of denatured proteins efficiently. Understanding how the non-native client proteins bound to HtpG refold is of central importance to comprehend the essential role of HtpG under stress. Here, we demonstrate by yeast two-hybrid method, immunoprecipitation assays, and surface plasmon resonance techniques that HtpG physically interacts with DnaJ2 and DnaK2. DnaJ2, which belongs to the type II J-protein family, bound DnaK2 or HtpG with submicromolar affinity, and HtpG bound DnaK2 with micromolar affinity. Not only DnaJ2 but also HtpG enhanced the ATP hydrolysis by DnaK2. Although assisted by the DnaK2 chaperone system, HtpG enhanced native refolding of urea-denatured lactate dehydrogenase and heat-denatured glucose-6-phosphate dehydrogenase. HtpG did not substitute for DnaJ2 or GrpE in the DnaK2-assisted refolding of the denatured substrates. The heat-denatured malate dehydrogenase that did not refold by the assistance of the DnaK2 chaperone system alone was trapped by HtpG first and then transferred to DnaK2 where it refolded. Dissociation of substrates from HtpG was either ATP-dependent or -independent depending on the substrate, indicating the presence of two mechanisms of cooperative action between the HtpG and the DnaK2 chaperone system.

RNA-directed amino acid coupling as a model reaction for primitive coded translation.

The stereochemical theory claims that primitive coded translation initially occurred in the RNA world by RNA-directed amino acid coupling. In this study, we show that the HIV Tat aptamer RNA is capable of recognizing two consecutive arginine residues within the Tat peptide, thus demonstrating how RNA might be able to position two amino acids for sequence-specific coupling. We also show that this RNA can act as a template to accelerate the coupling of a single arginine residue to the N-terminal arginine residue of a peptide primer. The results might have implications for our understanding of the origin of translation.

Biomolecular discrimination analyses by surface plasmon resonance.

Biomolecular discrimination is one of the most important ways to discriminate closely related species. In the past, several biomolecules have been observed with higher discrimination using different sensing systems. Herein, we have displayed discrimination of human and rabbit IgG and human clotting factors on Biacore-carboxymethylated dextran coated sensor chips.

Topical application of polyethylenimine as a candidate for novel prophylactic therapeutics against genital herpes caused by herpes simplex virus.

Herpes simplex virus types 1 (HSV-1) and 2 (HSV-2) cause genital herpes, which can enhance the acquisition of human immunodeficiency virus. The development of anti-HSV agents with novel mechanisms of action is urgently required in the topical therapy of genital herpes. In this study, the in vitro and in vivo anti-HSV effects of Epomin SP-012(®), a highly cationic polyethylenimine, were evaluated. When the in vitro antiviral effects of SP-012 were assessed, this compound showed potent activity against HSV-1 and HSV-2. It inhibited the attachment of HSV-2 to host cells and cell-to-cell spread of infection in a concentration-dependent manner and exerted a virucidal effect. No SP-012-resistant HSV-2 was found when the virus was successively passaged in the presence of SP-012. In a mouse genital herpes model, topically administered SP-012 inhibited the progression of the disease caused by HSV infection. These data illustrate that SP-012 may be a novel class of HSV inhibitor that would be acceptable for long-term topical application.

Alternative binding modes of l-histidine guided by metal ions for the activation of the antiterminator protein HutP of Bacillus subtilis.

Anti-terminator proteins control gene expression by recognizing control signals within cognate transcripts and then preventing transcription termination. HutP is such a regulatory protein that regulates the expression of the histidine utilization (hut) operon in Bacillus subtilis by binding to cis-acting regulatory sequences in hut mRNAs. During the anti-termination process, l-histidine and a divalent ion are required for hutP to bind to the specific sequence within the hut mRNA. Our previous crystal structure of the HutP-l-histidine-Mg(2+)-RNA ternary complex demonstrated that the l-histidine ligand and Mg(2+) bind together such that the backbone nitrogen and carboxyl oxygen of l-histidine coordinate with Mg(2+). In addition to the Mg(2+), other divalent ions are also known to efficiently support the l-histidine-dependent anti-termination of the hut operon, and the best divalent ion is Zn(2+). In this study, we determined the crystal structure of the HutP-l-histidine-Zn(2+) complex and found that the orientation of l-histidine coordinated to Zn(2+) is reversed relative to that of l-histidine coordinated to Mg(2+), i.e., the imidazole side chain nitrogen of l-histidine coordinates to Zn(2+). This alternative binding mode of the l-histidine ligand to a divalent ion provides further insight into the mechanisms responsible for the activation of RNA binding during the hut anti-termination process.

Analysis of compounds that interfere with herpes simplex virus-host receptor interactions using surface plasmon resonance.

The entry of herpes simplex virus into host cells involves a complex series of events that require concerted inputs from multiple HSV glycoproteins. Among these glycoproteins, the gD protein of HSV-1 and HSV-2 plays an important role for host receptor binding and membrane fusion. In the present study, we evaluated the ability of different sulfated saccharides to interfere with gD-host receptor (HVEM) interactions using our recently reported molecular assay (Gopinath, S. C. B.; Hayashi, K.; Kumar, P. K. R. J. Virol. 2012, 86, 6732-6744). Initially, we tested the ability of heparan sulfate to interfere with the HVEM-HSV-1 gD interaction and found that heparan sulfate is able to interfere efficiently, with an apparent EC50 of 2.1 µM. In addition, we tested different synthetic sulfated polysaccharides and natural sulfated polysaccharides from an edible alga, Sargassum horneri , after fractionation into different sizes and sulfate and uronic acid contents. Six polysaccharides isolated from S. horneri were found to efficiently interfere with the HVEM-gD interaction. Three others caused moderate interference, and five caused weak interference. These results were confirmed with plaque assays, and good agreement was found with the results of the SPR assay for the identification of compounds that interfere with HVEM-HSV-1 gD binding. These studies suggest that our molecular assay based on surface plasmon resonance is not only useful for the analysis of viral-host protein interactions but is also applicable for the routine screening of compounds to identify those that interfere with the first step of viral entry, thus facilitating the rapid development of novel antiviral compounds that target HSV.

Aptamer that binds to the gD protein of herpes simplex virus 1 and efficiently inhibits viral entry.

The ectodomain of the gD protein of herpes simplex viruses (HSVs) plays an important role in viral entry by binding to specific cellular coreceptors and mediating viral entry to the host cells. In the present study, we isolated RNA aptamers (aptamer-1 and aptamer-5) that specifically bind to the gD protein of HSV-1 with high affinity and are able to discriminate the gD protein of a different virus, HSV-2. Aptamer-1 efficiently interfered with the interaction between the gD protein and the HSV-1 target cell receptor (HVEM) in a dose-dependent manner. The 50% effective concentration (EC(50)) of aptamer-1 was estimated to be in the nanomolar range (60 nM). Furthermore, aptamer-1 was analyzed for anti-HSV-1 activity by using plaque assays, and it efficiently inhibited viral entry with an estimated K(i) of 0.8 µM. To expand the future applications of aptamer-1, a shorter variant was designed by using both mapping and boundary analyses, resulting in the mini-1 aptamer (44-mer). Compared to the full-length aptamer, mini-1 had at least as high an affinity, specificity, and ability to interfere with gD-HVEM interactions. These studies suggest that the mini-1 aptamer could be explored further as an anti-HSV-1 topical therapy designed to prevent the risk of acquiring HSV-1 infection through physical contact.

Structural basis of HutP-mediated anti-termination and roles of the Mg2+ ion and L-histidine ligand.

HutP regulates the expression of the hut structural genes of Bacillus subtilis by an anti-termination mechanism and requires two components, Mg2+ ions and L-histidine. HutP recognizes three UAG triplet units, separated by four non-conserved nucleotides on the terminator region. Here we report the 1.60-A resolution crystal structure of the quaternary complex (HutP-L-histidine-Mg2+-21-base single-stranded RNA). In the complex, the RNA adopts a novel triangular fold on the hexameric surface of HutP, without any base-pairing, and binds to the protein mostly by specific protein-base interactions. The structure explains how the HutP and RNA interactions are regulated critically by the l-histidine and Mg2+ ion through the structural rearrangement. To gain insights into these structural rearrangements, we solved two additional crystal structures (uncomplexed HutP and HutP-L-histidine-Mg2+) that revealed the intermediate structures of HutP (before forming an active structure) and the importance of the Mg2+ ion interactions in the complexes.

A BioDVD media with multilayered structure is suitable for analyzing biomolecular interactions.

A biomolecular interactive analysis with antibody-antigen and aptamer-protein was evaluated on Au-over layers deposited on the BioDVD surface. BioDVD consists of multilayered structures with Au layer on the top and it detects analytes by monitoring the changes in reflected light intensity due to analyte adsorption to the sensor surface, on which functional biomolecules are immobilized to bind specifically to the analytes. The BioDVD sensing instrument is based on a commercial digital versatile disc system, which allows the instrument to be small and inexpensive. The BioDVD platform can be fabricated utilizing mass production techniques with additional functional phase change layers that can serve both to enhance sensitivity by optimization of the interferometric cavity optical properties and also as a possible medium for the storage of test related information.

Evaluation of nucleic acid duplex formation on gold over layers in biosensor fabricated using Czochralski-grown single-crystal silicon substrate.

With a view to developing an economical and elegant biosensor chip, we compared the efficiencies of biosensors that use gold-coated single-crystal silicon and amorphous glass substrates. The reflectivity of light over a wide range of wavelengths was higher from gold layer coated single-crystal silicon substrates than from glass substrates. Furthermore, the efficiency of reflection from gold layers of two different thicknesses was examined. The thicker gold layer (100 nm) on the single-crystal silicon showed a higher reflectivity than the thinner gold film (10 nm). The formation of a nucleic acid duplex and aptamer-ligand interactions were evaluated on these gold layers, and a crystalline silicon substrate coated with the 100-nm-thick gold layer is proposed as an alternative substrate for studies of interactions of biomolecules.

Insights into anti-termination regulation of the hut operon in Bacillus subtilis: importance of the dual RNA-binding surfaces of HutP.

The anti-termination protein, HutP, regulates the gene expression of the hut (histidine utilization) operon of Bacillus subtilis, by destabilizing the hut terminator RNA located upstream of the coding region encoding l-histidine degradation enzymes. On the basis of biochemical, in vivo and X-ray structural analyses, we now report that HutP uses its dual RNA-binding surfaces to access two XAG-rich regions (sites I and II) within the terminator RNA to mediate the destabilization process. In this process, HutP initiates destabilization at the 5'-end of its mRNA by binding to the first XAG-rich region (site I) and then accesses the second XAG-rich region (site II), located downstream of the stable G-C-rich segment of the terminator stem. By this action, HutP appears to disrupt the G-C-rich terminator stem, and thus prevents premature termination of transcription in the RNA segment preceding the regions encoding for the histidine degradation enzymes.

Crystal structure of glutamine receptor protein from Sulfolobus tokodaii strain 7 in complex with its effector L-glutamine: implications of effector binding in molecular association and DNA binding.

Genome analyses have revealed that members of the Lrp/AsnC family of transcriptional regulators are widely distributed among prokaryotes, including both bacteria and archaea. These regulatory proteins are involved in cellular metabolism in both global and specific manners, depending on the availability of the exogenous amino acid effectors. Here we report the first crystal structure of glutamine receptor protein (Grp) from Sulfolobus tokodaii strain 7, in the ligand-free and glutamine-bound (Grp-Gln) forms. Although the overall structures of both molecules are similar, a significant conformational change was observed at the ligand [L-glutamine (Gln)] binding site in the effector domain, which may be essential for further stabilization of the octameric structure, and in turn for facilitating DNA binding. In addition, we predicted promoter for the grp gene, and these analyses suggested the importance of cooperative binding to the protein. To gain insights into the ligand-induced conformational changes, we mutated all of the ligand-binding residues in Grp, and revealed the importance of Gln binding by biochemical and structural analyses. Further structural analyses showed that Y77 is crucial for ligand binding, and that the residues T132 and T134, which are highly conserved among the Lrp family of proteins, fluctuates between the active and inactive conformations, thus affecting protein oligomerization for DNA binding.

Systematic Screening of Viral Entry Inhibitors Using Surface Plasmon Resonance.

Surface plasmon resonance (SPR) analytical method was initially used as biosensor for analyzing diverse biomolecular interactions and recently gained important place in the drug discovery. Here, I describe the procedures for screening of inhibitors against the viral proteins using the SPR. Using the described procedures, in the past, we were able to identify several antiviral products that interfere viral-host receptor proteins interactions.

A sensitive multilayered structure suitable for biosensing on the BioDVD platform.

Several technologies are currently available for the analysis of biomolecular interactions with high sensitivity and efficiency. However, these instruments are invariably expensive and, thus, are not suitable for bedside analyses. To circumvent this issue, we have previously reported a BioDVD platform that allowed us to use a DVD mechanism to monitor various biomolecular interactions [Gopinath et al., 2008, ACS Nano 2, 1885-1895]. In the present study, to improve the sensitivity of the BioDVD platform for various analyses, we have performed computer simulations to optimize the ZnS-SiO(2) layer thicknesses and determined an optimized optical interferometric response after adjusting the ZnS-SiO(2) layer thickness to 65 and 60 nm for the inner and outer layer thicknesses, respectively. Biomolecular interaction analyses performed with the optimized BioDVD disks revealed a 3-fold improvement in the sensitivity, compared to our previously reported multilayered structure. In this study, we have also shown that the BioDVD platform is suitable not only for analyzing nucleic acid hybridization and interactions between RNA-small ligands and RNA-proteins, but also for antigen-antibody interactions. Furthermore, our evaluations revealed that each sample required no more than 10 tracks of data to analyze the biomolecular interactions on the BioDVD platform, which permits a greater number of spots per BioDVD disk and also reduces the time needed to measure the biomolecular interactions.

Structural basis of HutP-mediated transcription anti-termination.

Bacteria often use anti-terminator proteins to sense a specific metabolite signal and direct RNA polymerase to either terminate transcription or transcribe the downstream genes of an operon. Although many proteins that regulate various operons using this mechanism have been identified, insights into their activation processes before cognate mRNA binding have remained obscure. HutP from Bacillus subtilis regulates the hut operon by an anti-termination mechanism. Recently, several crystal structures of HutP [apo-HutP, HutP-L-histidine (and histidine analog), HutP-L-histidine-Mg(2+) and HutP-L-histidine-Mg(2+)-RNA] have been reported. These structural and functional studies of HutP have revealed how the protein undergoes conformational changes in response to two key components: L-histidine and Mg(2+) ions.

Monitoring surface-assisted biomolecular assembly by means of evanescent-field-coupled waveguide-mode nanobiosensors.

Biological self-assembly is a natural process that involves various biomolecules, and finding the missing partner in these interactions is crucial for a specific biological function. Previously, we showed that evanescent-field-coupled waveguide-mode sensor in conjunction with a SiO(2) waveguide, the surfaces which contain cylindrical nanometric holes produced by atomic bombardment, allowed us to detect efficiently the biomolecular interactions. In the present studies, we showed that the assembly of biomolecules can be monitored using the evanescent-field-coupled waveguide-mode biosensor and thus provide a methodology in monitoring assembly process in macromolecular machines while they are assembling.

Crystal structure of an archaeal specific DNA-binding protein (Ape10b2) from Aeropyrum pernix K1.

DNA binding proteins are essential in all organisms, and they play important roles in both compacting and regulating the genetic material. All thermophilic and hyperthermophilic archaea encode one or more copies of Alba or Sso10b, which is a small, abundant, basic protein that binds DNA. Here, we present the crystal structure of Ape10b2 from Aeropyrum pernix K1 at 1.70 A. Although the overall structure resembles the known Alba protein fold, a significant conformational change was observed in the loop regions. Specifically, the L5 loop is slightly longer, as compared to those of other known proteins, and the flexibility of this loop may facilitate the interaction with double stranded DNA. In addition, we showed that Ape10b2 binds to 16 and 39 bp duplex DNAs with high affinity. On the basis of our analyses, we have created a putative protein-DNA complex model.

Influence of nanometric holes on the sensitivity of a waveguide-mode sensor: label-free nanosensor for the analysis of RNA aptamer-ligand interactions.

Evanescent-field-coupled (EFC) waveguide-mode sensors can be used to detect nucleic acids or proteins from the changes in the local index of refraction upon adsorption of the target molecule on a waveguide surface. We recently described an EFC waveguide-mode sensor in which nanometric holes on a waveguide film resulted in an improved sensitivity in the analysis of the interactions of biomolecules. In the present study, we have shown that sensitivity depends upon the diameter of the holes, where increase in diameter of holes increases spectral shift resulting in an improved sensitivity. Using this improved EFC waveguide-mode sensor, we could detect interactions between RNA and a small ligand, cyanocobalamin (vitamin B 12), and between RNA and a protein (human coagulation factor IXa). These two interactions were monitored on surfaces modified with biotin-streptavidin-biotin and N-(2-trifluoroethanesulfonatoethyl)- N-(methyl)triethoxysilylpropyl-3-amine, respectively.