The present invention provides: a novel method for the production of truly fully human monoclonal antibodies against specific antigens of our choice using isolated human blood cells. These antigens may include but are not limited to peptide sequences found in c-met and TMX2 proteins; an antibody specific for c-met protein produced with said method; an antibody specific for TMX2 protein produced with said method; and a new means and method for the diagnosis, prevention and/or cancer treatment by means of the aforementioned antibodies.

The various embodiments of the disclosure relate generally to processes, methods, and systems for generating functional B cells ex vivo. It is particularly useful for ex vivo generation of antigen-specific germinal-center (GC) like B cells that are capable of efficient B cell expansion, immunoglobulin (Ig) class switching/class switching recombination (CSR), expression of germinal B cell phenotypes, antibody secretion, and somatic hypermutation (SHM) and resulting affinity maturation center phenotypes.

Disclosed are means, methods and compositions of matter for treatment of Graves’ Disease using non-modified and/or modified fibroblasts for promotion of immunological tolerance, and/or stimulation of antigen-specific tolerance. In some embodiments, fibroblasts are administered together with antigens associated with Graves’ Disease such as the thyrotropin receptor protein and/or peptides and/or altered peptide ligands derived thereof. In some embodiments, co-administration refers to administration simultaneously or within temporal proximity of each other. In some embodiments, co-administration refers to loading of fibroblasts with antigens and/ or epitopes of antigens associated with Graves’ Disease.

The present disclosure relates to the in vitro differentiation of memory B cells to plasmablasts or plasma cells and genetic modification of these cells to express a protein of interest, such as a specific antibody or other protein therapeutic.

Provided herein, inter alia, are compositions and methods for reprogramming immune cells for treating or preventing immune disorders. The methods include contacting immune cells with antigens, and administering the resultant immune cells to a subject who has an immune disorder.

The present invention relates to an isolated cellular targeted delivery system comprising a CD45.sup.+ leukocyte cell comprising within said cell a complex of one or more iron binding proteins and an active ingredient as well as methods for producing such isolated cellular targeted delivery system and uses of such system for therapy, in particular for therapy of cancer.

The present invention relates to an isolated cellular targeted delivery system comprising a CD45+ leukocyte cell comprising within said cell a complex of one or more iron binding proteins and an active pharmaceutically active substance and/or label as well as methods for producing such isolated cellular targeted delivery system and uses of such system for prophylaxis, therapy, diagnosis or theragnosis, in particular for prophylactic or therapeutic vaccination, therapy of cancer, particularly metastatic cancer or inflammatory diseases.

Provided here methods of generating human alveolar macrophage-like cells in-vitro from blood-derived monocytes by culturing them in a cell culture medium containing a mixture of a surfactant and two or more cytokines. This mixture can contain calfactant, granulocyte-macrophage colony-stimulating factor, transforming growth factor beta, and interleukin-10.

The present invention relates to an isolated cellular targeted delivery system comprising a CD45+ leukocyte cell comprising within said cell a complex of one or more iron binding proteins and/or a label as well as methods for producing such isolated cellular targeted delivery system and uses of such system for therapy diagnosis and in particular for diagnosis of cancer, particularly metastatic cancer, in particular for therapy of cancer.

Many cell types in the body can remove apoptotic and cellular debris from tissues; however, the professional phagocyte, or antigen presenting cell (“APC”), has a high capacity to do so. The recognition of apoptotic cells (“ACs”) occurs via a series of evolutionarily-conserved, AC associated molecular-pattern receptors (“ACAMPRs”) on APCs that recognize and bind corresponding apoptotic-cell-associated molecular patterns (“ACAMPs”). These receptors recognize ligands such as phosphotidyl serine and oxidized lipids found on apoptotic cells. Savill et al. (2002); and Gregory et al. (2004).