Abstract: Disclosed herein are is a leukocyte-selective delivery agent comprising, a targeting moiety that selectively binds LFA-I, a protein carrier moiety covalently linked to the targeting moiety, and a therapeutic agent associated with the carrier moiety. The delivery agent may be further selective for activated leukocytes, wherein the targeting moiety selectively binds LFA-I in its activated conformation. The targeting moiety comprises an antibody or functional fragment thereof, such as an scFV. Examples of antibodies or fragments thereof which selectively bind LFA-I activated conformation bind to the locked open I domain of LFA-I, or binds to the leg domain of the ?2 subunit of LFA-I ((ILP2)—The antibody or functional fragment thereof may alternatively bind non-selectively to both low affinity and high affinity LFA-I. Examples of a non-protein carrier are a basic polypeptide such as protamine or a functional fragment thereof. One such fragment is RSQSRSRYYRQRQRSRRRRRRS.

Abstract: The disclosure provides, inter alia, binding proteins (e.g., antibodies) that bind to an integrin in an activated conformation, e.g., activated LFA-1 (“aLFA-1 ”), e.g., relative to a non-activated conformation of LFA-1. In one embodiment, the binding proteins inhibit at least one function of an aLFA-1, e.g., inhibit a binding interaction between aLFA-1 and a cognate ligand of aLFA-1, e.g., an ICAM protein. The binding proteins can be used to treat or prevent an inflammatory disorder or other disorder.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where crysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. The invention also provides modified integrin I-domain polypeptides that are stabilized in a desired conformation. The invention further provides screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention.

Abstract: Fusion protein-siRNA complexes that specifically target activated T cells, and methods of use thereof, are described.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where crysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. The invention also provides modified integrin I-domain polypeptides that are stabilized in a desired conformation. The invention further provides screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention.

Abstract: The disclosure provides, inter alia, binding proteins (e.g., antibodies) that bind to an integrin in an activated conformation, e.g., activated LFA-1 (“aLFA-1”), e.g., relative to a non-activated conformation of LFA-1. In one embodiment, the binding proteins inhibit at least one function of an aLFA-1, e.g., inhibit a binding interaction between aLFA-1 and a cognate ligand of aLFA-1, e.g., an ICAM protein. The binding proteins can be used to treat or prevent an inflammatory disorder or other disorder.

Abstract: The present invention generally relates to methods and compositions for the simultaneous delivery of at least one insoluble agent and at least one soluble agent to a cell. In particular the present invention relates to methods and compositions for the dual delivery of an insoluble agent and a soluble agent to a particular target cell, for example, a leukocyte or endothelial cell. In particular, methods and compositions for simultaneous delivery of a hydrophilic (i.e. soluble) agent and/or a hydrophobic (i.e. insoluble) agent to a leukocyte cell or endothelia cell are disclosed.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where cysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. The invention also provides modified integrin I-domain polypeptides that are stabilized in a desired conformation. The invention further provides screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where cysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. The invention also provides modified integrin I-domain polypeptides that are stabilized in a desired conformation. The invention further provides screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention.

Abstract: The disclosure provides, inter alia, binding proteins (e.g., antibodies) that bind to an integrin in an activated conformation, e.g., activated LFA-1 (“aLFA-1”), e.g., relative to a non-activated conformation of LFA-1. In one embodiment, the binding proteins inhibit at least one function of an aLFA-1, e.g., inhibit a binding interaction between aLFA-1 and a cognate ligand of aLFA-1, e.g., an ICAM protein. The binding proteins can be used to treat or prevent an inflammatory disorder or other disorder.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where cysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired conformation. The invention also provides modified integrin I-domain polypeptides that are stabilized in a desired conformation. The invention further provides screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention.

Abstract: In one aspect, the invention relates to the treatment and/or prevention of inflammation by inhibition of cyclin D1. In one embodiment, Th1-mediated inflammation is selectively inhibited or reduced by a method comprising administering an agent that inhibits cyclin D1. In another embodiment, an autoimmune disease or a disorder characterized by or involving a Th1 inflammatory response is treated or prevented in a subject by a method comprising administering to the subject an agent that inhibits cyclin D1.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where cysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. The invention also provides modified integrin I-domain polypeptides that are stabilized in a desired conformation. The invention further provides screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where cysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. Modified integrin I-domain polypeptides stabilized in a desired conformation are also provided, as well as screening assays and therapeutic methods utilizing the modified integrin I-domain polypeptides.

Abstract: Disclosed are delivery agents for selective delivery to leukocytes. The leukocyte-selective delivery agents comprise a targeting moiety that selectively binds LFA-I, a non-protein carrier moiety covalently linked to the targeting moiety and a therapeutic agent associated with the carrier moiety. The non-protein carrier moiety comprises a liposome, a micelle, or a polymeric nanoparticle comprised of PLA or PLGA. The delivery agent may be further selective for activated leukocytes by using a targeting moiety that selectively binds LFA-I in its activated conformation. The targeting moiety may comprise an antibody or functional fragment thereof such as an scFV. Appropriate therapeutic agents include a nucleic acid, a small molecule, a polypeptide, and an antibody or functional fragment thereof. Additional examples of therapeutic agents are a small RNA, an antagomir, an LNA, or an antisense oligonucleotide. One such therapeutic agent is an RNA interference molecule such as siRNA, dsRNA, stRNA, shRNA, miRNA.

Abstract: The invention provides a method for a multi-layered lipid particles in the form of liposomes that are coated first with a cryoprotectant followed by a targeting moiety over the coat of cryoprotectant, and a method for encapsulating drugs and agents in the multi-layered coated liposomes. In addition, ready-to-use liposome kits for coating with targeting agent of choice and for drug and/or agent encapsulation.

Abstract: The disclosure provides, inter alia, binding proteins (e.g., antibodies) that bind to an integrin in an activated conformation, e.g., activated LFA-1 (“aLFA-1”), e.g., relative to a non-activated conformation of LFA-1. In one embodiment, the binding proteins inhibit at least one function of an aLFA-1, e.g., inhibit a binding interaction between aLFA-1 and a cognate ligand of aLFA-1, e.g., an ICAM protein. The binding proteins can be used to treat or prevent an inflammatory disorder or other disorder.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where cysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. The invention also provides modified integrin I-domain polypeptides that are stabilized in a desired conformation. The invention further provides screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where cysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. Modified integrin I-domain polypeptides that are stabilized in a desired conformation are also provided. Finally, screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention are also provided.

Abstract: The present invention provides a method for stabilizing a protein in a desired conformation by introducing at least one disulfide bond into the polypeptide. Computational design is used to identify positions where cysteine residues can be introduced to form a disulfide bond in only one protein conformation, and therefore lock the protein in a given conformation. Accordingly, antibody and small molecule therapeutics are selected that are specific for the desired protein conformation. The invention also provides modified integrin I-domain polypeptides that are stabilized in a desired conformation. The invention further provides screening assays and therapeutic methods utilizing the modified integrin I-domains of the invention.