Abstract: The disclosure provides a fusion polypeptide specific for both CD137 and GPC3, which fusion polypeptide can be useful for directing CD137 clustering and activation to GPC3-positive tumor cells. Such fusion polypeptide can be used in many pharmaceutical applications, for example, as anti-cancer agents and/or immune modulators for the treatment or prevention of human diseases such as a variety of tumors. The present disclosure also concerns methods of making the fusion polypeptide described herein as well as compositions comprising such fusion polypeptide. The present disclosure further relates to nucleic acid molecules encoding such fusion polypeptide and to methods for generation of such fusion polypeptide and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of such fusion polypeptide as well as compositions comprising one or more of such fusion polypeptides.

Abstract: The present disclosure provides human tear lipocalin muteins that specifically bind to LAG-3, which can be used in pharmaceutical applications, for example, as anti-cancer agents and/or immune modulators for the treatment or prevention of human diseases such as cancer, infectious diseases, and autoimmune diseases. The present disclosure further shows the human lipocalin muteins can inhibit the binding of LAG-3 to MHC class II on cells overexpressing MHC class II. The present disclosure also concerns methods of making LAG-3 binding lipocalin muteins described herein as well as compositions comprising such lipocalin muteins. The present disclosure further relates to nucleic acid molecules encoding such lipocalin muteins and to methods for generation of such lipocalin muteins and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of these lipocalin muteins as well as compositions comprising one or more of such lipocalin muteins.

Abstract: The present disclosure relates to methods of treating, ameliorating or preventing a disorder comprising administering a therapeutically effective amount of a composition comprising a protein which inhibits the ligand of Uniprot #P05112 and/or the ligand of Uniprot #P35225 from binding to their respective receptors to a subject in need thereof. In some embodiments, the disorder is preferably associated with an increase of the Th2 immune response. In some embodiments, administration is preferably locally to the lung in order to treat, ameliorate or prevent allergic asthma, rhinitis, conjunctivitis, lung fibrosis, cystic fibrosis, chronic obstructive pulmonary disease, pulmonary alveolar proteinosis or adult respiratory distress syndrome.

Abstract: Lipocalin muteins specific to a predetermined antigen can be transduced into a T cell to bring therapeutic benefits to patients in need. In one example, a lipocalin mutein specific to a predetermined antigen (e.g., a target differentially expressed on the surface of a tumor cell) can be transduced into a T cell membrane to serve as an antigen receptor, offering benefits over conventionally deployed antibody-derived protein moieties such as a single chain variable fragment (scFv). Benefits include a more stable structure, leading to superior target engagement, for example. Further, lipocalin muteins specific to a predetermined antigen (e.g. an immunomodulatory target such as an immune checkpoint or costimulatory molecule) can be transduced into a T cell for secretion thereby, bringing an added therapeutic benefit. Specific examples of such modified T cells and methods of making and using the same are provided herein.

Abstract: The present invention relates to inhaled administration of a lipocalin mutein to a subject, wherein the administration provides for local exposure to the lipocalin mutein in the respiratory tract. The present invention also relates to inhalative administration of a lipocalin mutein to a subject, wherein the administration provides for systemic exposure to the lipocalin mutein.

Abstract: The present invention relates to novel, specific-binding therapeutic and/or diagnostic polypeptides directed against the target of Swiss Prot Q16552 and novel, specific-binding therapeutic and/or diagnostic polypeptides directed against the target of Swiss Prot Q9NPF7. In addition, the present invention relates to novel, specific-binding therapeutic and/or diagnostic polypeptides directed against one or both of Swiss Prot Q16552 and Swiss Prot Q9NPF7. The invention also relates to nucleic acid molecules encoding such polypeptides and to methods for generation of such polypeptides and nucleic acid molecules. In addition, the invention is directed to compositions comprising the polypeptides, and therapeutic and/or diagnostic uses of these polypeptides.

Abstract: The present disclosure provides human lipocalin muteins that bind CD137 and can be used in pharmaceutical applications, for example, as anti-cancer agents and/or immune modulators for the treatment or prevention of human diseases such as cancer, infectious diseases, and autoimmune diseases. The present disclosure also concerns methods of making CD137 binding lipocalin muteins described herein as well as compositions comprising such lipocalin muteins. The present disclosure further relates to nucleic acid molecules encoding such lipocalin muteins and to methods for generation of such lipocalin muteins and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of these lipocalin muteins as well as compositions comprising one or more of such lipocalin muteins.

Abstract: The present disclosure provides human tear lipocalin muteins that specifically bind to LAG-3, which can be used in pharmaceutical applications, for example, as anti-cancer agents and/or immune modulators for the treatment or prevention of human diseases such as cancer, infectious diseases, and autoimmune diseases. The present disclosure further shows the human lipocalin muteins can inhibit the binding of LAG-3 to MHC class II on cells overexpressing MHC class II. The present disclosure also concerns methods of making LAG-3 binding lipocalin muteins described herein as well as compositions comprising such lipocalin muteins. The present disclosure further relates to nucleic acid molecules encoding such lipocalin muteins and to methods for generation of such lipocalin muteins and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of these lipocalin muteins as well as compositions comprising one or more of such lipocalin muteins.

Abstract: The present disclosure provides hNGAL muteins that bind CGRP and can be used in various application including pharmaceutical applications, for example, migraine. The present disclosure also concerns methods of making one or more muteins described herein as well as compositions and combinations comprising one or more of such muteins. The present disclosure further relates to nucleic acid molecules encoding such muteins and to methods for generation of such muteins and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of these muteins as well as compositions and combinations comprising one or more of such muteins.

Abstract: The present disclosure provides hNGAL muteins that bind Ang-2 and can be used in various application including pharmaceutical applications, for example, to inhibit or reduce angiogenesis. The present disclosure also concerns methods of making one or more muteins described herein as well as compositions and combinations comprising one or more of such muteins. The present disclosure further relates to nucleic acid molecules encoding such muteins and to methods for generation of such muteins and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of these muteins as well as compositions and combinations comprising one or more of such muteins.

Abstract: The present invention relates to fusion molecules that have binding specificity for pyoverdine type I, II and III and pyochelin and can be used in various applications, including diagnostic and/or therapeutic applications, for example, to inhibit or reduce growth of P. aeruginosa and/or to prevent or treat P. aeruginosa biofilm infection as well as diseases or disorders associated with P. aeruginosa biofilm infection. The present invention also concerns methods of producing the fusion molecules described herein as well as compositions and kits comprising such fusion molecules. The present invention further relates to nucleic acid molecules encoding the fusion molecules described herein.

Abstract: The present disclosure provides human tear lipocalin muteins that specifically bind to LAG-3, which can be used in pharmaceutical applications, for example, as anti-cancer agents and/or immune modulators for the treatment or prevention of human diseases such as cancer, infectious diseases, and autoimmune diseases. The present disclosure further shows the human lipocalin muteins can inhibit the binding of LAG-3 to MHC class II on cells overexpressing MHC class II. The present disclosure also concerns methods of making LAG-3 binding lipocalin muteins described herein as well as compositions comprising such lipocalin muteins. The present disclosure further relates to nucleic acid molecules encoding such lipocalin muteins and to methods for generation of such lipocalin muteins and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of these lipocalin muteins as well as compositions comprising one or more of such lipocalin muteins.

Abstract: The disclosure provides a multi-specific polypeptide with a first moiety specific for a tumor-associated antigen on tumor cell surface and a second moiety specific for an immune checkpoint protein, which multi-specific polypeptide can be useful for biasing a T-cell-mediated response to a tumor micro-environment. For example, the polypeptide may contain: a) a first binding domain, for example, a full-length antibody or an antigen-binding domain of an antibody, specifically recognizing a tumor-associated antigen on tumor cell surface, and b) a second binding domain, such as a lipocalin mutein, capable of stimulating T-cell proliferation e.g., by inhibiting a protein receptor that down-regulates the immune system. The first binding domain may be genetically linked (i.e., peptide bond at its N- or C-terminus) to the second binding domain. The multispecific polypeptide also may contain a third or yet additional specific binding moieties, any of which can specifically bind a distinct immune checkpoint protein.

Abstract: The disclosure provides a fusion polypeptide specific for both CD137 and GPC3, which fusion polypeptide can be useful for directing CD137 clustering and activation to GPC3-positive tumor cells. Such fusion polypeptide can be used in many pharmaceutical applications, for example, as anti-cancer agents and/or immune modulators for the treatment or prevention of human diseases such as a variety of tumors. The present disclosure also concerns methods of making the fusion polypeptide described herein as well as compositions comprising such fusion polypeptide. The present disclosure further relates to nucleic acid molecules encoding such fusion polypeptide and to methods for generation of such fusion polypeptide and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of such fusion polypeptide as well as compositions comprising one or more of such fusion polypeptides.

Abstract: The disclosure provides a fusion polypeptide specific for both CD137 and HER2/neu, which fusion polypeptide can be useful for directing CD137 clustering and activation to HER2/neu-positive tumor cells. Such fusion polypeptide can be used in many pharmaceutical applications, for example, as anti-cancer agents and/or immune modulators for the treatment or prevention of human diseases such as a variety of tumors. The present disclosure also concerns methods of making the fusion polypeptide described herein as well as compositions comprising such fusion polypeptide. The present disclosure further relates to nucleic acid molecules encoding such fusion polypeptide and to methods for generation of such fusion polypeptide and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of such fusion polypeptide as well as compositions comprising one or more of such fusion polypeptides.

Abstract: The present disclosure relates to novel, specific-binding therapeutic and/or diagnostic proteins directed against Glypican-3 (GPC3), which proteins preferably are muteins of a lipocalin protein, more preferably of lipocalin 2 (Lcn2 or NGAL). Present disclosure also relates to nucleic acid molecules encoding such proteins and to methods for generation and use of such proteins and nucleic acid molecules. Accordingly, present disclosure also is directed to pharmaceutical and/or diagnostic compositions comprising such lipocalin proteins, including uses of these proteins.

Abstract: The present invention relates to novel, specific-binding therapeutic and/or diagnostic polypeptides directed against the target of Swiss Prot Q16552 and novel, specific-binding therapeutic and/or diagnostic polypeptides directed against the target of Swiss Prot Q9NPF7. In addition, the present invention relates to novel, specific-binding therapeutic and/or diagnostic polypeptides directed against one or both of Swiss Prot Q16552 and Swiss Prot Q9NPF7. The invention also relates to nucleic acid molecules encoding such polypeptides and to methods for generation of such polypeptides and nucleic acid molecules. In addition, the invention is directed to compositions comprising the polypeptides, and therapeutic and/or diagnostic uses of these polypeptides.

Abstract: The present invention relates to a novel library for the generation of muteins and to novel muteins derived from human lipocalin 2 (Lcn2, hNGAL) and related proteins that bind a given target with detectable affinity. The invention also relates to corresponding nucleic acid molecules encoding such a mutein and to a method for their generation. The invention further relates to a method for producing such a mutein. For example, such muteins may serve to bind and deplete pathological forms of natural biomolecules such as the amyloid beta peptide in Alzheimer's disease or may target the fibronectin extra-domain B, which is associated with tumor neovasculature.

Abstract: The present disclosure provides hNGAL muteins that bind Ang-2 and can be used in various application including pharmaceutical applications, for example, to inhibit or reduce angiogenesis. The present disclosure also concerns methods of making one or more muteins described herein as well as compositions and combinations comprising one or more of such muteins. The present disclosure further relates to nucleic acid molecules encoding such muteins and to methods for generation of such muteins and nucleic acid molecules. In addition, the application discloses therapeutic and/or diagnostic uses of these muteins as well as compositions and combinations comprising one or more of such muteins.

Abstract: The present invention relates to novel, specific-binding therapeutic and/or diagnostic polypeptides directed against the target of Swiss Prot Q16552 and novel, specific-binding therapeutic and/or diagnostic polypeptides directed against the target of Swiss Prot Q9NPF7. In addition, the present invention relates to novel, specific-binding therapeutic and/or diagnostic polypeptides directed against one or both of Swiss Prot Q16552 and Swiss Prot Q9NPF7. The invention also relates to nucleic acid molecules encoding such polypeptides and to methods for generation of such polypeptides and nucleic acid molecules. In addition, the invention is directed to compositions comprising the polypeptides, and therapeutic and/or diagnostic uses of these polypeptides.