The invention relates to a companion diagnostic antibody-like binding protein based on the humanized monoclonal antibody, DS6, to be used as diagnostic tool for in vivo detection and quantification of the tumor-associated MUC1-sialoglycotope, CA6.

A suite of novel anti-CD33 antibodies is described. The provided antibodies are pan-binders, binding the C2-set Ig-like domain in the presence or absence of the V-set Ig-like domain of CD33; are C2-set specific binders, binding the C2-set Ig-like domain only in the absence of the V-set Ig-like domain of CD33; or are V-set binders, binding the V-set Ig-like domain of CD33. The antibodies provide novel therapeutic and diagnostic tools against CD33-related disorders, such as acute myeloid leukemia (AML).

The present invention relates to a bispecific antibody against CLDN18.2 and CD3. The bispecific antibody effectively binds to CLDN18.2 and CD3 antigens.

The present disclosure provides single domain antibodies that bind to CD19, and chimeric antigen receptors comprising same. Further provided are engineered immune effector cells (such as T cells) comprising the chimeric antigen receptors. Pharmaceutical compositions, kits and methods of treating a disease or disorder are also provided.

Described herein methods of using antigen-binding constructs to treat HER2+ tumors in a subject such as breast, lung, or head and neck tumors. In some aspects, the tumor volume in the subject after receiving at least seven doses of the antigen binding construct is less than the tumor volume of a control subject receiving an equivalent amount of trastuzumab. In some aspects, the survival of the subject receiving the antigen binding construct is increased as compared to a control subject receiving an equivalent amount of a non-specific control antibody or as compared to a control subject not receiving treatment.

The present invention concerns methods and compositions for treatment of HIV infection in a subject, utilizing a DNL® complex comprising at least one anti-HIV therapeutic agent, attached to an antibody, antibody fragment or PEG. In a preferred embodiment, the antibody or fragment binds to an antigen selected from gp120, gp41, CD4 and CCR5. In a more preferred embodiment the antibody is P4/D10 or 2G12, although other anti-HIV antibodies are known and may be utilized. In a most preferred embodiment, the anti-HIV therapeutic agent is a fusion inhibitor, such as T20, T61, T651, T1249, T2635, CP32M or T-1444, although other anti-HIV therapeutic agents are known and may be utilized. The DNL® complex may be administered alone or may be co-administered with one or more additional anti-HIV therapeutic agents.

The present invention relates to peptides that bind with high specificity and which functionally interact with the transferrin receptor (“TfR”) and which may be used in making molecular vehicles that carry biomolecules across membranes, including, e.g., across the blood brain barrier or the gastrointestinal tract. TfR specific binding moieties may also be used alone or as components in specific molecules that target the transferrin/transferrin receptor transport system. The invention relates more specifically to VNAR single chain antibodies derived from nurse shark that bind to TfR, compounds and compositions comprising a TfR specific VNAR binding moiety, methods for preparing them, diagnostic and therapeutic methods of use in vitro or in vivo, e.g., to diagnose, treat and/or prevent a pathological condition, disorder or disease in which it is beneficial to deliver a heterologous biomolecule across the blood brain barrier by association with a TfR specific VNAR binding moiety. Other uses for TfR specific VNAR binding moieties of the invention include, e.g., regulating the interaction of iron-charged transferrin with TfR (receptor cycling or cell surface presentation), such as may be therapeutic in treatment of certain cancer cells and tumors of various tissue types.

Herein is reported a polypeptide comprising a first polypeptide and a second polypeptide each comprising in N-terminal to C-terminal direction at least a portion of an immunoglobulin hinge region, which comprises one or more cysteine residues, an immunoglobulin CH2-domain and an immunoglobulin CH3-domain, wherein the first, the second, or the first and the second polypeptide comprise the mutation Y436A (numbering according to the EU index).

The present invention relates to the fields of molecular medicine and targeted delivery of therapeutic or diagnostic agents to cells outside the vascular system and into the parenchymal tissue of organs within the body. More specifically, the present invention relates to improved TfR-binding moieties based on shark VNARs capable of crossing the blood brain barrier (BBB) and capable of carrying and releasing cargo specifically targeted to the parenchymal tissue of the brain.

The invention relates to a bispecific antibody targeting TfR1 and a soluble antigen. The inventors demonstrate that the unique mode of interaction of the bispecific antibody with TfR1 increases its persistence in vivo through an FcRn-like mechanism. It has been demonstrated on MCF7 cell line that the bispecific antibody induces soluble antigen (IL6) uptake through TfR1 mediated endocytosis. Effects of the bispecific antibody on XG6 cell lines viability have been demonstrated, notably on iron and IL-6 deprivation. Hence, the inventors design an improved sweeping antibody which can specifically target tumors and inflammatory cells expressing TfR1. By its unique mode of interaction with TfR1, its ability to induce soluble uptake antigen through TfR1 mediated endocytosis and its capacity to deprive cells of iron, known for being required in tumors growth and progression and development of inflammatory pathologies, the bispecific antibody can be used in the treatment of cancer and inflammatory pathologies.