Provided herein, in some embodiments, are methods of purifying a nucleic acid preparation. The methods may comprise contacting a nucleic acid preparation comprising messenger ribonucleic acid with an RNase III enzyme that is immobilized on a solid support and binds to double-stranded RNA contaminants.

The present invention relates to compositions, kits and methods for making and using RNA compositions comprising in vitro-synthesized ssRNA inducing a biological or biochemical effect in a mammalian cell or organism into which the RNA composition is repeatedly or continuously introduced. In certain embodiments, the invention provides compositions and methods for changing the state of differentiation or phenotype of a human or other vertebrate cell. For example, the present invention provides mRNA and methods for reprogramming cells that exhibit a first differentiated state or phenotype to cells that exhibit a second differentiated state or phenotype, such as to reprogram human somatic cells to pluripotent stem cells.

Described are methods for increasing the expression of a transgene in eukaryotic cells by reducing RNA interference (RNAi), and variant cells produce by the method. The methods and variant cells are useful, for example, for the efficient production of therapeutic and industrial polypeptides in eukaryotic cells.

The present invention relates to compositions, kits and methods for making and using RNA compositions comprising in vitro-synthesized ssRNA inducing a biological or biochemical effect in a mammalian cell or organism into which the RNA composition is repeatedly or continuously introduced. In certain embodiments, the invention provides compositions and methods for changing the state of differentiation or phenotype of a human or other vertebrate cell. For example, the present invention provides mRNA and methods for reprogramming cells that exhibit a first differentiated state or phenotype to cells that exhibit a second differentiated state or phenotype, such as to reprogram human somatic cells to pluripotent stem cells.

The object of the invention is a Mini-III RNase with amino acid sequence comprising an acceptor part, and a transplantable a4 helix, and a transplantable a5b-a6 loop, which form structures of a4 helix and a5b-a6 loop, respectively, in the Mini-III RNase structure, wherein the fragments which form structures of a4 helix and a5b-a6 loop, respectively, correspond structurally to respective structures of a4 helix and a5b-a6 loop formed by amino acid sequence fragments 46-52 and 85-98, respectively, of Mini-III RNase from Bacillus stubtilis shown in SEQ ID NO: 1, wherein the said Mini-III RNase exhibits sequence specificity in dsRNA cleavage being dependent only on a ribonucleotide sequence of the substrate, and independent from an occurrence of secondary structures in the substrate's structure, and independent from a presence of other assisting proteins, and wherein the Mini-III RNase is not the Mini-III protein from Bacillus stubtilis of SEQ ID NO: 1, nor SEQ ID NO: 1 with D94R mutation. The invention also relates to a method of obtaining a chimeric Mini-III RNase, a Mini-III RNase encoding construct, a cell with a Mini-III RNase encoding gene, use of Mini-III RNase for dsRNA cleavage, as well as a method of dsRNA cleavage depending only on a ribonucleotide sequence.

The present invention relates to compositions, kits and methods for making and using RNA compositions comprising in vitro-synthesized ssRNA inducing a biological or biochemical effect in a mammalian cell or organism into which the RNA composition is repeatedly or continuously introduced. In certain embodiments, the invention provides compositions and methods for changing the state of differentiation or phenotype of a human or other vertebrate cell. For example, the present invention provides mRNA and methods for reprogramming cells that exhibit a first differentiated state or phenotype to cells that exhibit a second differentiated state or phenotype, such as to reprogram human somatic cells to pluripotent stem cells.

An inclusion body mediated method for double-stranded RNA producing. The method includes: transforming the vector to bacteria; culturing and inducing the bacteria expressed an inclusion body; and extracting the inclusion body by the sonication or high-pressure lysis of the collected bacteria, wherein the vector at least includes a nucleic acid sequence encoding a siRNA-binding polypeptide that corporate p19 protein with protein 1.

The present disclosure provides methods and compositions to selectively modulate RNA processing. The methods and compositions selectively enhance or repress RNA processing by up- or down-regulating Drosha expression and/or by providing RNA sequences with mismatches introduced or removed 5 and/or 9-12 nucleotide positions from the Drosha cutting site. Therapeutic uses of the methods and compositions are also described.

The present invention relates to compositions, kits and methods for making and using RNA compositions comprising in vitro synthesized ssRNA inducing a biological or biochemical effect in a mammalian cell or organism into which the RNA composition is repeatedly or continuously introduced. In certain embodiments, the invention provides compositions and methods for changing the state of differentiation or phenotype of a human or other vertebrate cell. For example, the present invention provides mRNA and methods for reprogramming cells that exhibit a first differentiated state or phenotype to cells that exhibit a second differentiated state or phenotype, such as to reprogram human somatic cells to pluripotent stem cells.

Embodiments are directed to: (i) neutrophil secreted factors that have the capacity to kill a broad range of cancer cells without affecting the viability of non-cancer cells. Two neutrophil killing factors have been identified by the inventors: (1) eosinophil cationic protein (ECP) and (2) neutrophil elastase (ELANE); or (ii) therapeutic compositions that include CD95 degrading polypeptide components and methods of treating cancer with the same.