The present invention is directed to transduced T cells expressing at least 100,000 molecules of human somatostatin receptor 2 (SSTR2), which improves PET/CT imaging sensitivity. The present invention is also directed to transduced T cells expressing SSTR2 and chimeric antigen receptor (CAR). In one embodiment, the CAR is specific to human ICAM-1 and the CAR comprises a binding domain that is scFv of anti-human ICAM-1, or an I domain of the αL subunit of human lymphocyte function-associated antigen-1. In another embodiment, the CAR is specific to human CD19, and the CAR comprises a binding domain that is scFv of anti-human CD19. The present invention is further directed to using the above transduced T cells for monitoring T cell distribution in a patient by PET/CT imaging and/or treating cancer.

The present application provides nucleated cells comprising a protein or fragment thereof, methods of manufacturing such nucleated cells comprising the protein or fragment thereof, and methods of using such modified nucleated cells (e.g., immune cells) for stimulating an immune response in a HLA agnostic manner.

A methodology to obtain large numbers of allospecific human Tr1 lymphocytes in vitro differentiated with phenotype and suppressive function stability in presence of proinflammatory cytokines, by using donor tolerogenic dendritic cells (DC10) derived from donor monocytes and from a not related receptor (allogeneic) naîve T cells cocultures. The obtained cells with the present methodology are characterized by the expression of a Tr1 regulatory phenotype (CD4+, CD49b+, LAG-3+), being high IL-10 producers, and also they express additional co-inhibitory molecules as PD1, TIM-3, CD39, CTLA-4 y TIGIT. Moreover, the cellular product obtained by this methodology is able to maintain a stable phenotype and suppressive function in presence of proinflammatory cytokines (IL-1β, IL-6, IFN-γ y TNF-α). The numbers, purity, and stability of the Tr1 obtained by this methodology, make them great candidates for their use as therapeutic tools in transplantation.

Provided herein are engineered red blood cells expressing rare blood antigen group profiles, and methods of making use the same, are described. Also provided are recombinant reagent red blood cells that express or lack the expression of at least one protein (e.g., a blood group antigen) on its surface and uses thereof.

The invention provides methods of modulating follicular regulatory T (TFR) cell-mediated immune responses and the use of those methods in the treatment of diseases or conditions such as viral, bacterial, pathogenic, or fungal infections or cancer. Such methods provide for boosting of antibody production through the use of IL-21 to overcome TFR cell suppression of antibody production.

Disclosed are means, methods and compositions of matter useful for treatment of inflammatory and/or viral mediated disease through administration of cellular populations subsequent to modulation of complement pathway. In one embodiment, patients with COVID-19 who are eligible for stem cell therapy are pretreated with modulators of complement activity in order to reduce inflammation and to augment activity of said stem cell therapy. Activity of said stem cell therapy includes protection of pulmonary cells from dysfunction/death, stimulation of regenerative/trophic activities, reduction of inflammation, and induction of immune modulation.

The present invention relates to a poxvirus vector comprising a nucleic acid sequence encoding a fusion protein comprising: (i) a peanut allergen selected from list consisting of at least two peanut allergens from ara h 1, ara h 2, ara h 3, ara h 4, ara h 5, ara h 6. ara h 7, ara h 8, ara h 9, ara h I O and ara h I I or a derivative or part thereof having at least 70% sequence identity thereto, and (ii) a profeasome degradation tag to enhance intracellular degradation of the fusion protein. Methods of desensitizing or inducing tolerance to a peanut allergen and/or suppressing an allergic response to a peanut allergen are also disclosed.

Provided herein are novel therapeutic compositions and methods that keep cellular immunotherapies in the circulation or at the site of injection for extended periods of time without resorting to the use of cytotoxic preconditioning. For example, the compositions and methods herein lymphodeplete and reduce or ablate sites in the secondary lymphatics where the cellular immunotherapy is bound and sequestered, without the use of cytotoxic preconditioning.

The present disclosure provides compositions and methods for the generation of an antibody or immunogenic composition, such as a vaccine, through epitope focusing by variable effective antigen surface concentration. Generally, the composition and methods of the disclosure comprise three steps: a “design process” comprising one or more in silico bioinformatics steps to select and generate a library of potential antigens for use in the immunogenic composition; a “formulation process”, comprising in vitro testing of potential antigens, using various biochemical assays, and further combining two or more antigens to generate one or more immunogenic compositions; and an “administering” step, whereby the immunogenic composition is administered to a host animal, immune cell, subject or patient. Further steps may also be included, such as the isolation and production of antibodies raised by host immune response to the immunogenic composition.

The invention includes compositions and methods related to multimodal therapies, e.g., for treating a cancer. A multimodal therapy described herein provides and/or administers a plurality of agents that function in a coordinated manner to provide a therapeutic benefit to a subject in need thereof, e.g., a subject having a cancer.