The present invention relates to a biologic that inhibits angiogenesis. In particular, the present invention relates to fusion proteins that inhibit the integrin activated pathway and one other angiogenic factor-activated pathway as well as formulation compositions of such fusion proteins, as well as methods for producing and using the same.

Described herein are modified integrin α and/or β headpiece polypeptides, and crystallizable integrin polypeptide dimers comprising a modified integrin α and/or β headpiece polypeptide and a disulfide bond linking the two integrin headpiece polypeptide subunits. Methods for using the modified integrin α and/or β headpiece polypeptides and the integrin polypeptide dimers are also provided herein. For example, methods for characterizing integrin-ligand interaction and identifying integrin ligands are also provided herein. In some embodiments, the identified integrin ligands can be used as inhibitors of integrins.

Disclosed herein are compositions and methods for inhibiting collagen production mediated by the Fused in Sarcoma (FUS) ribonucleoprotein. As disclosed herein, the C terminal domain of FUS contains an uncommon nuclear localization sequence (NLS) motif called PY-NLS that binds the nuclear import receptor transportin. Phosphorylation of FUS leads to its association with transportin and nuclear translocation with consequent increased in collagen production. Therefore, disclosed herein is an isolated peptide having a transportin-binding moiety, which inhibits FUS from binding transportin, linked to a membrane translocating motif. These compositions and methods can be used to inhibit FUS-mediated collagen production, and treat fibrotic disease involving FUS-mediated collagen accumulation in kidneys and other organs displaying fibrotic diseases.

Described herein are modified integrin α and/or β headpiece polypeptides, and crystallizable integrin polypeptide dimers comprising a modified integrin α and/or β headpiece polypeptide and a disulfide bond linking the two integrin headpiece polypeptide subunits. Methods for using the modified integrin α and/or β headpiece polypeptides and the integrin polypeptide dimers are also provided herein. For example, methods for characterizing integrin-ligand interaction and identifying integrin ligands are also provided herein. In some embodiments, the identified integrin ligands can be used as inhibitors of integrins.

Recombinant viruses and viral nucleic acids are contemplated that provide to the infected cell various regulatory molecules that stimulate T-cell and NK-cell activity and that suppress inhibition of T-cell and NK-cell activity. Most preferably, the virus and viral nucleic acid will further include a human cancer-associated sequence, and especially a sequence that encodes a plurality of cancer associated antigens, cancer specific antigens, and/or patient and tumor specific neoantigens. Especially preferred regulatory molecules include CD80 (B7.1), CD86 (B7.2), CD54 (ICAM-1/BB2), CD11 (LFA-1), and an inhibitor of CTLA-4.

Compositions and methods of enhancing the potency and efficacy of adoptive cell therapy using integrin-ligand stabilizers, wherein the integrin is selected from the group consisting of α4β1, α5β1, α4β7, αvβ3 and αLβ2, and contacting the effector cells ex vivo with agonists or stabilizers having the general Formula (I); methods of treating integrin-expressing cells with such stabilizers to enhance tumor infiltration; and therapeutic methods comprising administering stabilizer or agonist-treated cells to a mammal requiring treatment of solid tumors, hematologic cancers.

Provided herein are macrophages engineered for treating fibrosis and ameliorating the effects of fibrotic lesions in various organs and tissues. Certain embodiments are directed to genetically-engineered macrophages capable of treating fibrosis or reducing fibrotic lesions. In certain aspects macrophages can be genetically-engineered to (1) target extracelluar matrix (ECM) or components thereof, (2) enhance degradation of ECM, or (3) target ECM and enhance degradation of ECM. Further provided is a cellular therapy product comprising a genetically-engineered macrophage comprising at least one of a recombinant targeting protein and a recombinant catalytic enzyme. Further provided is a method of treating an individual for fibrosis comprising administering the cellular therapy product.

The present invention in various aspects and embodiments involves pharmaceutical compositions prepared by contacting a candidate α- or β-integrin-binding molecule, or panel thereof, with an integrin heterodimer, and quantifying heterodimer disruption by the candidate molecule. An integrin-binding molecule, or derivative thereof, that disrupts the integrin heterodimer is selected and is formulated into a pharmaceutical composition for administration to a subject, e.g., who has a disease or disorder related to abnormal vascularization.

The present invention provides a method of treating cancer with an integrin-binding-Fc fusion protein alone or in combination with IL-2 and/or an immune stimulant (i.e., an immune checkpoint stimulator), and/or an immune checkpoint inhibitor. The invention also provides composition for use in such methods.

The present invention provides fusion proteins for targeted delivery of plasminogen activators to platelet-VWF complexes, or alternatively to the site where these are located, in a fibrin-independent manner. The fusion protein of the invention are for use in methods for the prevention or treatment of diseases or conditions associated with such platelet-VWF complexes, which may cause microvascular thrombosis in diseases such as e.g. thrombotic thrombocytopenic purpura. Preferred targeting agents for incorporation into the fusion proteins are e.g. nanobodies against VWF or platelets. Preferred plasminogen activators for use in the fusion proteins comprise the protease domains of uPA or tPA. The invention further pertains to nucleic acid molecule encoding the fusion proteins of the invention, e.g. a gene therapy vector, and to pharmaceutical compositions comprising the fusion proteins of the invention or such gene therapy vectors.