Complexes comprising a nucleic acid-guided endonuclease, a sequence-specific targeting nucleic acid and an amphipathic helical peptide are provided. Compositions and methods for delivery of complexes comprising a nucleic acid-guided endonuclease, a sequence-specific targeting nucleic acid and an amphipathic helical peptide to mammals for both research and therapeutic use are provided. Methods of treating or reducing one or more symptoms of type 2 diabetes, prediabetes and/or gestational diabetes are provided.

Non-human animal cells and non-human animals comprising CRISPR/Cas synergistic activation mediator system components and methods of making and using such non-human animal cells and non-human animals are provided. Methods are provided for using such non-human animals to increase expression of target genes in vivo and to assess CRISPR/Cas synergistic activation mediator systems for the ability to increase expression of target genes in vivo.

Provided herein are compositions and methods of using a bicistronic vector for treating or preventing a lysosomal storage disorder (LSD) in a subject. The disclosed compositions comprise a bicistronic vector comprising a promoter, an Internal Ribosome Entry Site (IRES), a polynucleotide encoding a lysosomal enzyme and a polynucleotide encoding a modified GlcNAc-1 phosphotransferase (GlcNAc-1 PTase). The present methods comprise administering to the subject a pharmaceutical composition comprising the bicistronic vector as disclosed herein.

Provided is a method for preparing a diabetic dog model by means of gene editing technology, a diabetic dog model prepared therefrom, as well as cells and issues thereof. The method comprises the following steps: (1) obtaining a dog fertilized egg cell, which comprises a point mutation in GCK gene, for a diabetic dog model by means of gene editing; and (2) transplanting the dog fertilized egg cell into one fallopian tube of a female dog, in which both fallopian tubes have been flushed, to prepare a diabetic dog model comprising a point mutation in GCK gene.

Among the various aspects of the present disclosure relates to methods and compositions useful in convert inflammatory dietary fatty acids (omega 6) to anti-inflammatory fatty acids (omega 3). Specifically, the present disclosure provides methods and compositions for increasing n-3 desaturase expression or activity in a subject. The disclosure provides various compositions for providing increased n-3 desaturase expression or activity including a variety of viral vector and engineered microorganisms The disclosure provides, in part, methods for reducing local and/or systemic inflammation, improving wound healing, preventing premature cellular enescence, treating or preventing a disease, disorder, or condition related to inflammation or obesity and treating or preventing arthritis.

Methods are provided for treating a subject with a pain condition. Aspects of the methods include administering a gene therapy to the subject and/or a therapeutically effective amount of a composition that includes a gene therapy vector. Aspects of the vectors may include a nucleic acid sequence encoding a K-Cl cotransporter 2 (KCC2) polypeptide, including e.g., full-length and modified versions thereof. Methods are also provided for treating a subject by editing an endogenous KCC2 locus of the subject to encode a modified KCC2 polypeptide. Methods of detecting the presence of a pain condition are also provided, including where a pain condition detected in such methods is treated according to the methods described herein. Also provided are compositions, such as compositions including a gene therapy vector, such as a lentiviral vector, that includes a viral backbone nucleic acid comprising a sequence encoding a full-length human KCC2 polypeptide or a nucleic acid sequence encoding a modified KCC2 polypeptide.

The present invention provides a method of constituting a tissue construct in vitro using a tissue without depending on scaffold materials. A method of integrating a biological tissue with a vascular system in vitro, comprising coculturing a biological tissue with vascular cells and mesenchymal cells. A biological tissue which has been integrated with a vascular system by the above-described method. A method of preparing a tissue or an organ, comprising transplanting the biological tissue described above into a non-human animal and differentiating the biological tissue into a tissue or an organ in which vascular networks have been constructed. A method of regeneration or function recovery of a tissue or an organ, comprising transplanting the biological tissue described above into a human or a non-human animal and differentiating the biological tissue into a tissue or an organ in which vascular networks have been constructed. A method of preparing a non-human chimeric animal, comprising transplanting the biological tissue described above into a non-human animal and differentiating the biological tissue into a tissue or organ in which vascular networks have been constructed. A method of evaluating a drug, comprising using at least one member selected from the group consisting of the biological tissue described above, the tissue or organ prepared by the method described above, and the non-human chimeric animal prepared by the method described above. A composition for regenerative medicine, comprising a biological tissue which has been integrated with a vascular system by the method described above.

Methods and FSP27 compositions for treating and/or preventing metabolic disease and conditions associated insulin resistance, obesity, inflammation and dyslipidemia are described.

Non-human animal cells and non-human animals comprising CRISPR/Cas synergistic activation mediator system components and methods of making and using such non-human animal cells and non-human animals are provided. Methods are provided for using such non-human animals to increase expression of target genes in vivo and to assess CRISPR/Cas synergistic activation mediator systems for the ability to increase expression of target genes in vivo.

Materials and methods for regulating lipid abundance by modulating Protease Activated Receptor 1 (PAR1) and Protease Activated Receptor 2 (PAR2) levels arc provided herein. In a first aspect, this document features a method that includes (a) identifying a mammal as having a condition characterized at least by impaired lipid production, impaired cholesterol production, or both impaired lipid production and impaired cholesterol production; and (b) administering to the mammal an inhibitor of PAR1 and/or PAR2 in an amount effective to increase lipid production and/or cholesterol production in the mammal.