This disclosure relates to modified immunoglobulins.

The present disclosure provides T-cell modulatory multimeric polypeptides (T-Cell-MMP) and their epitope conjugates comprising at least one immunomodulatory polypeptide (“MOD”) that may be selected to exhibit reduced binding affinity to a cognate co-immunomodulatory polypeptide (“Co-MOD”). The epitope may be, for example, a cancer-associated epitope, an infectious disease-associated epitope, or a self-epitope. The T-Cell-MMP-epitope conjugates are useful for modulating the activity of a T-cell by delivering immunomodulatory peptides, such as IL-2 or IL-2 variants that exhibit reduced binding affinity for the IL-2R, to T-cells in an epitope selective/specific manner, and accordingly, for treating individuals with a cancer, infectious disease or autoimmune disorder.

The present disclosure provides humanized antibodies, including antibodies comprising an ultralong CDR3 and uses thereof.

Multispecific antagonists for targeting angiogenesis pathways are disclosed. The multispecific antagonists may be used for the treatment of disorders associated with angiogenesis pathways.

Antitumor antagonists that bind specifically to immune checkpoint regulator and/or components of the angiogenesis pathways and/or components of the TGF pathway are disclosed. Also disclosed is a method of treating proliferative disorders with the antitumor antagonists.

The present invention relates to the field of structural biology. More specifically, the present invention relates to an antigen-binding chimeric protein, called a MegaBody™, specifically binding a nanodisc, more specifically a membrane-scaffold protein (MSP)n which may be part of the nanodisc. The invention further provides for methods and uses of said nanodisc-specific antigen-binding chimeric proteins in three-dimensional high-resolution structural analysis of membrane proteins assembled within nanodiscs. The MSP-binding MegaBodies of the invention provide for a generic tool in membrane protein structural biology, more particular in Cryo-EM, by reducing preferred particle orientation of nanodiscs and of the entrapped target membrane proteins.

Provided are chimeric cytokine modified antibodies containing an ultralong CDR3, such as based on a bovine antibody sequence or a humanized sequence thereof, in which a portion of the CDR3 of the heavy chain is replaced by an interleukin (IL-15) or IL-2, and related antibodies. Among provided antibodies are chimeric IL-15 cytokine modified antibody molecules that are further linked or complexed with an extracellular portion of the IL15Rα, such as the IL15Rα sushi domain. Also provided are methods of making and using the chimeric cytokine modified antibodies.

The present disclosure provides T-cell modulatory multimeric polypeptides (T-Cell-MMP) and their epitope conjugates comprising at least one immunomodulatory polypeptide (“MOD”) that may be selected to exhibit reduced binding affinity to a cognate co-immunomodulatory polypeptide (“Co-MOD”). The epitope may be, for example, a cancer-associated epitope, an infectious disease-associated epitope, or a self-epitope. The T-Cell-MMP-epitope conjugates are useful for modulating the activity of a T-cell by delivering immunomodulatory peptides, such as IL-2 or IL-2 variants that exhibit reduced binding affinity for the IL-2R, to T-cells in an epitope selective/specific manner, and accordingly, for treating individuals with a cancer, infectious disease or autoimmune disorder.

Antibodies that bind to ανβ8 are provided.

The present invention relates to masked IL-2 cytokines, comprising an IL-2 cytokine or functional fragment thereof, a masking moiety and a proteolytically cleavable linker. The masking moiety masks the IL-2 cytokine or functional fragment thereof thereby reducing or preventing binding of the IL-cytokine or functional fragment thereof to its cognate receptor, but upon proteolytic cleavage of the cleavable linker at a target site, the IL-2 cytokine or functional fragment thereof becomes activated, which renders it capable or more capable of binding to its cognate receptor.