The present disclosure relates to anti-CDCP1 antibodies, and antigen binding fragments thereof that specifically bind to the full length and cleaved forms CUB domain-containing protein 1 (CDCP1), and conjugates comprising anti-CDCP1 antibodies and uses thereof for treatment and detection of cancer.

Provided are an anti-Her2 nanobody and a coding sequence and the use thereof. In particular, provided is a nanobody combating human epidermal growth factor receptor-2 (Her2/ERBB2). Disclosed are the nanobody and the a gene sequence encoding the nanobody, a corresponding expression vector and a host cell capable of expressing the nanobody, and a method for producing the nanobody of the present invention and the related use thereof. The present invention may also provide an immunoconjugate of the nanobody and the use thereof, especially the use in the diagnosis and treatment of Her2 positive tumor.

Compositions and methods useful for the treatment of hemoglobinopathies and hematological diseases are disclosed herein. The compositions include an actinium-225 labeled anti-CD45 antibody (BC8) formulated as a single patient dose that is wholly deliverable to a patient in a single dose. The actinium-225 labeled anti-CD45 may be administered alone or in combination with additional therapeutic agents, such as other immunotherapeutics or a radiosensitizing agent, or additional therapeutic interventions, such as bone marrow transplant or adoptive cell therapies.

Described herein are protein-payload conjugates and compositions thereof that are useful, for example, for target-specific delivery of therapeutic and/or imaging agent moieties. In certain embodiments, provided are specific and efficient methods for producing protein-payload constructs (e.g., antibody-drug conjugates) utilizing a combination of transglutaminase and Diels-Alder techniques. Antibody-drug conjugates and compositions which comprise glutaminyl-modified antibodies, Diels-Alder adducts, and reactive payloads and are provided.

A targeted radiopharmaceutical comprising a targeting species chemically-bonded to a PCTA-chelated Q.sup.+3 trivalent radioactive ion of Formula I

##STR00001##

is disclosed. Six of R.sup.1 through R.sup.7 are H and the seventh is a reacted functionality, Z, that forms the chemical bond with the targeting species, T. “g” is a number whose average value is 1 to about 12. X.sup.1, X.sup.2, and X.sup.3, are substituent groups that can coordinate to the Q.sup.+3 ion and/or help neutralize the ionic charge. Anion Y.sup.− is optionally present to balance the ionic charge. A pharmaceutical composition comprising a theranostic effective amount of a targeted radiopharmaceutical of Formula I in a pharmaceutically acceptable diluent is also contemplated, as are a method for treating and/or diagnosing a mammalian host having a disease, disorder or condition characterized by undesired angiogenesis, tumor growth and/or tumor metastasis.

Radiolabeled anti-LAG3 antibodies and their use in immuno-PET imaging are provided herein. Included are methods of detecting the presence of LAG3 proteins in a patient or sample.

The present disclosure relates to an antigen specific binding domain which binds to RON (Macrophage Stimulating Protein Receptor or Recepteur d'Origine Nantais). The disclosure also extends to chimeric antigen receptors (and a cell expressing the same), antibody molecules (including full length antibodies and fragments thereof, as well as antibody conjugates) containing the antigen binding domains disclosed herein. Also disclosed herein are pharmaceutical compositions comprising the cells, antibody molecules as disclosed herein. The present disclosure also refers to the use of the antigen binding domains, the chimeric antigen receptors, the antibody molecules and the pharmaceutical compositions disclosed herein in therapy, more particularly in treating cancer. Also disclosed herein are radiolabelled antibody conjugates comprising the antigen binding domains as disclosed, and their use in methods of treatment or diagnosis.

Disclosed are general and “substantially pure” branched discrete polyethylene glycol constructs useful in attaching to a variety of biologically active groups, for example, preferential locators, as well as biologics like enzymes, for use in diagnostics, e.g. imaging, therapeutics, theranostics, and moieties specific for other applications. In its simplest intermediate state, a branched discrete polyethylene glycol construct is terminated at one end by a chemically reactive moiety, “A”, a group that is reactive with a biologic material that creates “A”, which is a biologically reactive group, connected through to a branched core (BC) which has attached at least two dPEG-containing chains, indicated by the solid line, , having terminal groups, which can be charged, non-reactive or reactable moieties and containing between about 2 and 64 dPEG residues.

The present invention provides methods for treating, reducing the severity, or inhibiting the growth of cancer (e.g., skin cancer). The methods of the present invention comprise administering to a subject in need thereof a therapeutically effective amount of a programmed death 1 (PD-1) antagonist (e.g., an anti-PD-1 antibody). In certain embodiments, the skin cancer is cutaneous squamous cell carcinoma or basal cell carcinoma.

The present invention relates to compositions and methods employing conjugates that include a self-assembly and disassembly (SADA) polypeptide and a binding domain. The present invention encompasses the recognition that conjugates with a SADA polypeptide have certain improved biological properties. SADA-conjugates are described, along with uses thereof (e.g., as therapeutic or diagnostic agents) and methods of manufacture.