Described herein are methods and related compositions for inducing differentiation of human pluripotent stem cells (hPSCs) into hemogenic endothelium with pan-myeloid potential or restricted potential, by forced expression in the hPSCs of a combination of transcription factors as described herein.

The invention involves inducing 3-50 or more mutations (e.g., any whole number between 3 and 50 of mutations, with it noted that in some embodiments there can be up to 16 different RNA(s), e.g., sgRNAs each having its own a promoter, in a vector, such as AAV, and that when each sgRNA does not have its own promoter, there can be twice to thrice that amount of different RNA(s), e.g., sgRNAs, e.g., 32 or even 48 different guides delivered by one vector) in transgenic Cas9 eukaryotes to model genetic disease, e.g. cancer. The invention comprehends testing putative treatments with such models, e.g., testing putative chemical compounds that may be pharmaceutically relevant for treatment or gene therapy that may be relevant for treatment, or combinations thereof. The invention allows for the study of genetic diseases and putative treatments to better understand and alleviate a genetic disease or a condition, e.g., cancer.

Provided herein are cell penetrating conjugates. The conjugates include a non-cell penetrating protein attached to a phosphorothioate nucleic acid or phosphorothioate polymer backbone through a non-covalent linker including abiotin-binding domain and a biotin domain, wherein the phosphorothioate nucleic acid or phosphorothioate polymer backbone enhances intracellular delivery of the non-cell penetrating protein. Also provided are compositions and kits comprising the conjugates.

Disclosed are methods of treating cancer of the intraperitoneal cavity using compositions comprising nanoparticles without targeting agents. In addition, nanoparticles are described that comprise a highly toxic anticancer agent (e.g., an anticancer agent having an IC.sub.50 less than 1 nM) covalently bound via a linker to a triblock copolymer. Other nanoparticles that comprise Pt(IV) and an anticancer agent are also described. Also disclosed are nanoparticles comprising imaging agents non-covalently associated with a polymer, and methods of imaging cancer of the intraperitoneal cavity using compositions comprising nanoparticles without targeting agents.

A lipidated secondary antibody is disclosed. Particles comprising same are also disclosed.

A lipidated secondary antibody is disclosed. Particles comprising same are also disclosed.

Provided herein are micellic assemblies comprising a plurality of copolymers. In certain instauces, micellic assemblies provided herein are pH sensitive particles.

The present invention provides nucleic acid constructs, expression vectors, transgenic cell and methods of making and using the same, wherein the nucleic acid construct includes a synthetic promoter designed from the endogenous promoter of BIRC5 and LAMC2. In illustrative working embodiments of the invention, an exogenous nucleic acid fragment encoding thymidine kinase is operably linked to the synthetic promoter which is then shown to regulate the expression of this polypeptide.

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.

A photocaged DNA nano-tweezer and methods of using said photocaged DNA nano-tweezer are described. In particular, provided herein is a DNA nano-tweezer comprising a hairpin with a single-stranded loop that comprises a first arm and a second arm; and a trigger strand complementary to the single-stranded loop and comprising at least one photocaged residue with a protecting group.