The invention provides novel personalized therapies, kits, transmittable forms of information and methods for use in treating patients having cancer, wherein the cancer is MTAP-deficient and/or MTA-accumulating and thus amenable to therapeutic treatment with a PRMT5 inhibitor. Kits, methods of screening for candidate PRMT5 inhibitors, and associated methods of treatment are also provided.

In certain embodiments, the present disclosure provides compounds and methods of increasing the amount or activity of a target protein in a cell. In certain embodiments, the compounds comprise a translation suppression element inhibitor. In certain embodiments, the translation suppression element inhibitor is a uORF inhibitor. In certain embodiments, the uORF inhibitor is an antisense compound.

In certain embodiments, the present disclosure provides compounds and methods of increasing the amount or activity of a target protein in a cell. In certain embodiments, the compounds comprise a translation suppression element inhibitor. In certain embodiments, the translation suppression element inhibitor is a uORF inhibitor. In certain embodiments, the uORF inhibitor is an antisense compound.

The invention provides lipid A mimics in which one or both of the sugar residues of a natural lipid A disaccharide backbone has been replaced with an aromatic group. These lipid A mimics may further differ from a natural lipid A molecule with respect to other structural characteristics, such as, a different number of phosphate groups present, changes in the number, structure and location of lipid chains and/or changes in the spacing and linkage of the sugar residues (or their aromatic replacements). The lipid A mimics may be lipid A agonists and as such may be useful as immunostimulatory agents in inducing or patenting an antibody and/or cell-mediated immune response, or may be lipid A antagonists and as such may be useful in treating or preventing a lipopolysaccharide (LPS)/lipid A-mediated disease or disorder. Also provided are methods for preparing the lipid A mimics.

The present invention includes methods and compositions for increasing longevity of a cell and increasing cellular resistance to stress. In certain embodiments, the invention includes a method to induce gene expression of a homolog of Pachytene Checkpoint 2 (pch-2) or bmk-1 gene. The present invention also includes methods to treat oxidative stress or induce cellular death or apoptosis by administering a composition comprising a modulator of pch-2 or bmk-1 homolog gene expression.

The present invention includes methods and compositions for increasing longevity of a cell and increasing cellular resistance to stress. In certain embodiments, the invention includes a method to induce gene expression of a homolog of Pachytene Checkpoint 2 (pch-2) or bmk-1 gene. The present invention also includes methods to treat oxidative stress or induce cellular death or apoptosis by administering a composition comprising a modulator of pch-2 or bmk-1 homolog gene expression.

The invention relates to a botulinum neurotoxin-encoding nucleic acid for therapeutic use. The invention further relates to the transfection of skeletal muscle cells and smooth muscle cells and the glands of the skin, and of other skin cells with botulinum neurotoxin (BoNT)-encoding nucleic acids (RNA or DNA) with or without the use of a secretory signal, for therapeutic and/or cosmetic purposes.

RNA encoding an immunogen is co-delivered to non-immune cells as the site of delivery and also to immune cells which infiltrate the site of delivery. The responses of these two cell types to the same delivered RNA lead to two different effects, which interact to produce a strong immune response against the immunogen. The non-immune cells translate the RNA and express the immunogen. Infiltrating immune cells respond to the RNA by expressing type I interferons and pro-inflammatory cytokines which produce a local adjuvant effect which acts on the immunogen-expressing non-immune cells to upregulate major histocompatibility complex expression, thereby increasing presentation of the translated protein to T cells. The effects on the immune and non-immune cells can be achieved by a single delivery of a single RNA e.g., by a single injection.

RNA encoding an immunogen is co-delivered to non-immune cells as the site of delivery and also to immune cells which infiltrate the site of delivery. The responses of these two cell types to the same delivered RNA lead to two different effects, which interact to produce a strong immune response against the immunogen. The non-immune cells translate the RNA and express the immunogen. Infiltrating immune cells respond to the RNA by expressing type I interferons and pro-inflammatory cytokines which produce a local adjuvant effect which acts on the immunogen-expressing non-immune cells to upregulate major histocompatibility complex expression, thereby increasing presentation of the translated protein to T cells. The effects on the immune and non-immune cells can be achieved by a single delivery of a single RNA e.g., by a single injection.

Lipid particles containing a nucleic acid, devices and methods for making the lipid particles, and methods for using the lipid particles.