Provided herein are compounds, compositions, conjugates and methods for the treatment of diseases, and/or conditions such as, but not limited to, proliferative diseases. In certain embodiments, compounds, compositions, and conjugates are provided, which include cyclodextrin-based linker-payloads and protein conjugates thereof, and/or in combination with other agents. By administering these compounds, compositions, and conjugates as described herein to specific target cells, side-effects due to non-specific binding phenomena, for example, to non-target cells are reduced.

Disclosed herein are immunoconjugates comprising a CD46 binding domain and effector agent. Further provided herein are methods of treating cancer comprising administering to a subject having cancer a pharmaceutical composition comprising immunoconjugates comprising a CD46 binding domain and effector agent.

The present disclosure provides antibody-drug conjugates comprising (i) antibodies that specifically bind to Mer Tyrosin Kinase (MERTK) (e.g., human MERTK, or both human and mouse MERTK), and (ii) cytotoxic agents conjugated directly to the antibodies or conjugated to the antibodies via linkers, and compositions comprising such antibody-drug conjugates, wherein the antibodies contained in the antibody-drug conjugates agonize MERTK signaling of endothelial cells. The present disclosure also provides methods for treating cancer, by administering an antibody-drug conjugate that comprises (i) an antibody that specifically binds to MERTK and agonizes MERTK signaling of endothelial cells, and (ii) a cytotoxic agent conjugated directly to the antibody or conjugated to the antibody via a linker.

By inserting cysteine (C) into a heavy chain and/or a light chain of a target antibody at specific insertion site, and performing a site-specific conjugation through a free thiol group (—SH) from the site-specific inserted cysteine and a linker conjugated with a highly potent small molecule cytotoxin, a cysteine modified antibody-drug conjugate with good homogeneity is provided. The specific insertion sites of cysteine are position 205 and/or position 206 (Kabat numbering scheme) of the light chain of the antibody, and/or position 439 (Kabat numbering scheme) of the heavy chain.

The invention provides anti-CD30 antibody-drug conjugates, such as brentuximab vedotin, and their use for the treatment of lymphoma, such as diffuse large B-cell lymphoma. The invention also provides the use of anti-CD30 antibody-drug conjugates, such as brentuximab vedotin, in combination with lenalidomide and/or anti-CD20 antibodies, such as rituximab, for the treatment of lymphoma, such as diffuse large B-cell lymphoma.

An isolated monoclonal antibody (mAb) or antigen-binding fragment thereof having a binding specificity to human CD19, wherein the isolated mAb or antigen-binding fragment comprises an amino acid sequence having an identity with a sequence selected from SEQ ID NO. 1, 3, 5, 7, 9, 11, 13, 15, 17, 19, 21, 23, 91, or 93, wherein the identity is not less than at least 95%.

Cysteine engineered antibodies comprising a free cysteine amino acid in the heavy chain or light chain are prepared by mutagenizing a nucleic acid sequence of a parent antibody and replacing one or more amino acid residues by cysteine to encode the cysteine engineered antibody; expressing the cysteine engineered antibody; and isolating the cysteine engineered antibody.

The present invention concerns novel and improved antibody-conjugates for targeting HER2. The inventors found that when antibody-conjugates were prepared using a specific mode of conjugation, they exhibit an improved therapeutic index. The mode of conjugation comprises a first step (i) of contacting a glycoprotein comprising 1-4 core N-acetylglucosamine moieties with a compound of the formula S(F.sup.1).sub.x—P in the presence of a catalyst, wherein S(F.sup.1).sub.x is a sugar derivative comprising x functional groups F1 capable of reacting with a functional group Q.sup.1, x is 1 or 2 and P is a nucleoside mono- or diphosphate, and wherein the catalyst is capable of transferring the S(F.sup.1).sub.x moiety to the core-GlcNAc moiety, to obtain a modified antibody; and a second step (ii) of reacting the modified antibody with a linker-conjugate comprising a functional group Q.sup.1 capable of reacting with functional group F.sup.1 and a target molecule D connected to Q.sup.1 via a linker L.sup.2 to obtain the antibody-conjugate wherein linker L comprises S—Z.sup.3-L.sup.2 and wherein Z.sup.3 is a connecting group resulting from the reaction between Q.sup.1 and F.sup.1. The invention also relates to a use for improving the therapeutic index of an antibody-conjugate and to a method for targeting HER2-expressing cells.

The response of subjects suffering from cancer to MAPK inhibitors is dramatically impaired by secondary resistances and rapid relapse. So far, the molecular mechanisms driving these resistances are not completely understood. The inventors show that expression of 10 SLITRK6 (SLIT and NTRK-like family, member 6) is induced by a MAPK inhibitor (e.g. Vemurafenib) and the inhibition of its induction in presence of the MAPK inhibitor induces synthetic lethality. Thus, the only inhibition of SLITRK6 by an inhibitor of activity or expression should potentiate the antitumor effect of the MAPK inhibitors and avoid the emergence of a resistance to those compounds. Furthermore the specific expression of 15 SLITRK6 also paves the way of strategies based on depletion of the residual cancer cells by targeting them with anti-SLITRK6 antibodies capable of mediating ADCC or antibody-drug conjugates binding to SLITRK6.

The present invention provides specific sites for modifying antibodies or antibody fragments by replacing at least one native amino acid in the constant region of a parental antibody or antibody fragment with cysteine, which can be used as a site of attachment for a payload or linker-payload combination.