Some embodiments of the method and compositions provided herein relate to methods of preparing cells expressing bispecific T cell engagers (BTCEs), and the use of such cells in certain therapies. In some embodiments, the cells are B cells or B cell precursors.

Some embodiments of the method and compositions provided herein relate to methods of preparing cells expressing bispecific T cell engagers (BTCEs), and the use of such cells in certain therapies. In some embodiments, the cells are B cells or B cell precursors.

The present disclosure relates to a mammalian cell which is modified to express on the surface of its membrane a binding domain which binds to a target molecule. The disclosure also relates to protein constructs and nucleic acids for producing such modified mammalian cells, and to methods for using the mammalian cells to deliver therapeutic agents to target cells or tissues in vivo.

The present disclosure relates to a mammalian cell which is modified to express on the surface of its membrane a binding domain which binds to a target molecule. The disclosure also relates to protein constructs and nucleic acids for producing such modified mammalian cells, and to methods for using the mammalian cells to deliver therapeutic agents to target cells or tissues in vivo.

Provided herein are methods for treatment and uses involving dosing of compositions containing NK cells deficient in expression of FcR chain (g-NK cells) engineered with a recombinant chimeric antigen receptor (CAR) in combination with a monoclonal antibody. Among the provided methods and uses are methods and uses for treating cancer, such as multiple myeloma or lymphoma.

Provided herein are methods for treatment and uses involving dosing of compositions containing NK cells deficient in expression of FcR chain (g-NK cells) engineered with a recombinant chimeric antigen receptor (CAR) in combination with a monoclonal antibody. Among the provided methods and uses are methods and uses for treating cancer, such as multiple myeloma or lymphoma.

CD38 is also expressed in a variety of malignant hematological diseases, including multiple myeloma. In the present invention, the inventors have generated a new antibody against CD38 that could be suitable for producing bispecific antibodies as well as CAR-T cells. In particular, the inventors report the development of Bi38-3, a new bispecific T cell engager that targeted CD38 on MM cells and recruited cytotoxic T cells through the CD3. Bi38-3 lacked the Fc region of natural mAb, which contributes to resistance processes, but triggered T cells to proliferate, release cytokine and lyse CD38 positive MM cells in vitro. Similarly, Bi38-3 induced autologous T cells to eliminate tumor plasma cells isolated from MM patients both at diagnosis and at relapse. The cytotoxicity triggered by Bi38-3 was restricted to cells expressing high levels of CD38 and preserved the integrity of T, B and NK lymphocytes in vitro. Importantly, Bi38-3 rapidly reduced tumor cells in an MM1.S xenograft mouse model of human MM. Taken together, the results show that the antibody of the present invention is an effective reagent to specifically eliminate CD38 positive malignant cells without significantly affecting CD38 lowly expressing cells and represents a promising novel immunotherapeutic tool for the treatment of malignant hematological diseases, and especially multiple myeloma.

CD38 is also expressed in a variety of malignant hematological diseases, including multiple myeloma. In the present invention, the inventors have generated a new antibody against CD38 that could be suitable for producing bispecific antibodies as well as CAR-T cells. In particular, the inventors report the development of Bi38-3, a new bispecific T cell engager that targeted CD38 on MM cells and recruited cytotoxic T cells through the CD3. Bi38-3 lacked the Fc region of natural mAb, which contributes to resistance processes, but triggered T cells to proliferate, release cytokine and lyse CD38 positive MM cells in vitro. Similarly, Bi38-3 induced autologous T cells to eliminate tumor plasma cells isolated from MM patients both at diagnosis and at relapse. The cytotoxicity triggered by Bi38-3 was restricted to cells expressing high levels of CD38 and preserved the integrity of T, B and NK lymphocytes in vitro. Importantly, Bi38-3 rapidly reduced tumor cells in an MM1.S xenograft mouse model of human MM. Taken together, the results show that the antibody of the present invention is an effective reagent to specifically eliminate CD38 positive malignant cells without significantly affecting CD38 lowly expressing cells and represents a promising novel immunotherapeutic tool for the treatment of malignant hematological diseases, and especially multiple myeloma.

Disclosed are compositions and methods for targeted treatment of SSTR-expressing cancers. For example, disclosed herein are Bispecific T-Cell Engaging (BiTE) molecules (fusion polypeptides) (also referred to herein as bispecific molecules) that are able to crosslink CD3 complex on immune effector cells with SSTR2 on NETs. Also disclosed are chimeric antigen receptor (CAR) polypeptides that can be used with adoptive cell transfer to target and kill SSTR-expressing cancers. Also disclosed are immune effector cells, such as T cells or Natural Killer (NK) cells, that are engineered to express these CARs. Therefore, also disclosed are methods of providing an anti-tumor immunity in a subject with a SSTR-expressing cancer, such as a neuroendocrine tumor, that involves adoptive transfer of the disclosed immune effector cells engineered to express the disclosed CARs.

Disclosed are compositions and methods for targeted treatment of SSTR-expressing cancers. For example, disclosed herein are Bispecific T-Cell Engaging (BiTE) molecules (fusion polypeptides) (also referred to herein as bispecific molecules) that are able to crosslink CD3 complex on immune effector cells with SSTR2 on NETs. Also disclosed are chimeric antigen receptor (CAR) polypeptides that can be used with adoptive cell transfer to target and kill SSTR-expressing cancers. Also disclosed are immune effector cells, such as T cells or Natural Killer (NK) cells, that are engineered to express these CARs. Therefore, also disclosed are methods of providing an anti-tumor immunity in a subject with a SSTR-expressing cancer, such as a neuroendocrine tumor, that involves adoptive transfer of the disclosed immune effector cells engineered to express the disclosed CARs.