An isolated antibody or fragment thereof, which specifically binds to a gamma variable 4 (Vγ4) chain of a γδ T cell receptor (TCR) and not to a gamma variable 2 (Vγ2) chain of a γδ TCR is provided herein. Methods of treatment and other uses of said antibodies are also provided along with methods of producing said antibodies.

The present invention relates to a fetal cell capture module, a microfluidic chip for fetal cell capture, and methods for using the same. The fetal cell capture module comprises a cell capture carrier and recognition molecule(s) for specific capture the cell(s). The recognition molecule is attached to the surface of the carrier via an organic conjugate L comprising disulfide bonds. The surface of the chip is modified with recognition molecules that specifically capture fetal cells via organic conjugates comprising disulfide bonds. The recognition molecule, after capturing the cell, achieves the release of the cell by chemically cleaving the disulfide bonds in the organic coupling conjugate. The present invention enables the capture of fetal cell(s) from whole blood without pre-treatment with a high capture rate, low cell loss, simple and accurate cell release operation, and the efficient and noninvasive release of fetal cells and whole genome analysis.

The disclosure features isolated polynucleotides, such as mRNAs, encoding a polypeptide that disrupts immune cell activity, such as T cell or B cell activity, including mRNAs comprising one or more modified nucleobase. The immune cell disruptor polynucleotides encode a polypeptide that comprises a first domain that mediates association of the polypeptide with an immune cell component and a second domain that mediates inhibition of immune cell activity when the polypeptide is expressed in the immune cell. The disclosure also features methods of using the same, for example, for inhibiting immune responses when administered to a subject, such as to inhibit autoimmune reactions.

The present disclosure provides methods and compositions for microglia replacement therapy in a subject in need thereof. In some cases, the method involves administering myeloid cells to the central nervous system of a subject. In some cases, the myeloid cells are derived from embryonic or extraembryonic tissue. In some cases, the myeloid cells are genetically modified. The genetic modification may include a colony stimulating factor 1 receptor (CSF1R) variant that is resistant to a CSF1R inhibitor, yet retains sensitivity to its ligand (e.g., CSF1, IL34).

Genomic safe harbors (GSH) for genetic therapies in human stem cells and engineered nanoparticles to provide targeted genetic therapies are described. The GSH and/or associated nanoparticles can be used to safely and efficiently treat a variety of genetic, infectious, and malignant diseases.

The disclosure provides antibody molecules that bind to TCR Vβ regions and multispecific molecules comprising said antibody molecules. Additionally, disclosed are nucleic acids encoding the same, methods of producing the aforesaid molecules, pharmaceutical compositions comprising aforesaid molecules, and methods of treating a cancer using the aforesaid molecules.

ILC2 cells play a role in the pathogenesis of graft versus host disease (GvHD) and idiopathic pneumonia syndrome (IPS), both conditions associated with allogeneic stem cell transplantation. Infusion of IL-33 activated ILC2 cells into patients with ongoing GvHD or IPS, or prior to onset of GvHD or IPS in susceptible patients, substantially ameliorates the disease and improves survival.

A hydrogel capsule comprising a stem cell core that has been induced to differentiate into a hematopoietic lineage cell, and methods for the production of hematopoietic lineage cells from stem cells encapsulated in a hydrogel.

The present invention provides isolated immune cells, immune cell populations and compositions, as well as markers, marker signatures and molecular targets characterising the immune cells. The cell products, substances, compositions, markers, marker signatures, molecular targets, kits of parts and methods of the present invention provide for new ways to characterise, evaluate and modulate the immune system and immune responses.

A method of treating neurodegenerative diseases using hUCB plasma is presented herein. hUCB plasma attenuated the hyperactive response (Group III) and potentiated the normal response in Group I ALS patients, but did not alter that of the non-responders to PHA (Group II). The elevated activity of caspase 3/7 observed in the MNCs from ALS patients was significantly reduced by hUCB plasma treatment. The ability of hUCB plasma to modulate the mitogen cell response and reduce caspase activity suggest that the use of hUCB plasma alone, or with stem cells, may prove useful as a therapeutic in ALS patients. hUCB plasma was shown to increase therapeutic efficacy of MNCs as well as decrease apoptosis of MNCs. The cytokine profile of hUCB plasma supports its usefulness as a sole therapeutic as well as an additive to MNCs.