Abstract: The invention pertains to ligands that bind to CD81 and that inhibit or block Plasmodium attachment to CD81, compositions and methods for preventing, inhibiting or treating infection by Plasmodium and ligands that target a Plasmodium binding site on CD81 and methods of making and using them. A series of ligand binding sites on the large extracellular loop of the open conformation of CD81 have been identified. Several important sites were located in regions identified by mutational studies to be the site of Plasmodium binding. Ligands that recognize these sites were identified. Linking together two or three ligands that bind with low or moderate affinities to different structurally unique sites on a target protein were used to generate small molecule ligand conjugates that exhibit very high affinities to their CD81 targets. Hybrid ligand molecules were also designed using fragment-based drug design methods to generate analogs of the ligands that bind more tightly to the protein than the parent compounds.

Abstract: The invention pertains to ligands that bind to CD81 and that inhibit or block Plasmodium attachment to CD81, compositions and methods for preventing, inhibiting or treating infection by Plasmodium and ligands that target a Plasmodium binding site on CD81 and methods of making and using them. A series of ligand binding sites on the large extracellular loop of the open conformation of CD81 have been identified. Several important sites were located in regions identified by mutational studies to be the site of Plasmodium binding. Ligands that recognize these sites were identified. Linking together two or three ligands that bind with low or moderate affinities to different structurally unique sites on a target protein were used to generate small molecule ligand conjugates that exhibit very high affinities to their CD81 targets. Hybrid ligand molecules were also designed using fragment-based drug design methods to generate analogs of the ligands that bind more tightly to the protein than the parent compounds.

Abstract: Hepatitis C Virus (HCV) infects 200 million individuals worldwide. Although several FDA approved drugs targeting the HCV serine protease and polymerase have shown promising results, there is a need for better drugs that are effective in treating a broader range of HCV genotypes and subtypes without being used in combination with interferon and/or ribavirin. Recently, the crystal structure of the core of the HCV E2 protein (E2c) has been determined, providing structural information that can now be used to target the E2 protein and develop drugs that disrupt the early stages of HCV infection by blocking E2's interaction with different host factors. By targeting sites containing conserved E2 amino acids in the CD81 binding site on HCV E2, one might also be able to develop drugs that block HCV infection in a genotype-independent manner.

Abstract: Ligands that target the HCV-E2 binding site and methods of making and using them. A series of ligand binding sites on the large extracellular loop of the open conformation of CD81 have been identified. Several important sites were located in regions identified by mutational studies to be the site of E2 binding. Ligands that recognize these sites were identified. Linking together two or three ligands that bind with low or moderate affinities to different structurally unique sites on a target protein were used to generate small molecule ligand conjugates that exhibit very high affinities to their CD81 targets. Hybrid ligand molecules were also designed using fragment-based drug design methods to generate analogs of the ligands that bind more tightly to the protein than the parent compounds. Identification and design of groups of compounds that bind to CD81 for use as therapeutics for treating patients infected by Hepatitis C virus and other viruses that interact with CD81.

Abstract: This invention provides polydentate selective high affinity ligands (SHALs) that can be used in a variety of applications in a manner analogous to the use of antibodies. SHALs typically comprise a multiplicity of ligands that each binds different regions on the target molecule. The ligands are joined directly or through a linker thereby forming a polydentate moiety that typically binds the target molecule with high selectivity and avidity.

Abstract: This invention provides novel polydentate selective high affinity ligands (SHALs) that can be used in a variety of applications in a manner analogous to the use of antibodies. SHALs typically comprise a multiplicity of ligands that each bind different region son the target molecule. The ligands are joined directly or through a linker thereby forming a polydentate moiety that typically binds the target molecule with high selectivity and avidity.

Abstract: This invention provides novel polydentate selective high affinity ligands (SHALs) that can be used in a variety of applications in a manner analogous to the use of antibodies. SHALs typically comprise a multiplicity of ligands that each bind different region son the target molecule. The ligands are joined directly or through a linker thereby forming a polydentate moiety that typically binds the target molecule with high selectivity and avidity.

Abstract: This invention provides novel polydentate selective high affinity ligands (SHALs) that can be used in a variety of applications in a manner analogous to the use of antibodies. SHALs typically comprise a multiplicity of ligands that each bind different region son the target molecule. The ligands are joined directly or through a linker thereby forming a polydentate moiety that typically binds the target molecule with high selectivity and avidity.

Abstract: A method and apparatus with the sensitivity to detect and identify single target molecules through the localization of dual, fluorescently labeled probe molecules. This can be accomplished through specific attachment of the taget to a surface or in a two-dimensional (2D) flowing fluid sheet having approximate dimensions of 0.5 ?m×100 ?m×100 ?m. A device using these methods would have 103-104 greater throughput than previous one-dimensional (1D) micro-stream devices having 1 ?m3 interrogation volumes and would for the first time allow immuno- and DNA assays at ultra-low (femtomolar) concentrations to be performed in short time periods (˜10 minutes). The use of novel labels (such as metal or semiconductor nanoparticles) may be incorporated to further extend the sensitivity possibly into the attomolar range.