This disclosure provides compositions, methods, and systems comprising a papillomaviral delivery vehicle for the delivery of gene editing material to cells. The papillomaviral delivery vehicle comprises a papillomavirus-derived capsid and DNA encoding a gene editing material encapsulated by the capsid. The papillomaviral delivery vehicle can be transduced into a cell under conditions conducive for the cell to synthesize the gene editing material. The cell can comprise a polynucleotide target and the gene editing material can target the polynucleotide target. The polynucleotide target can be a DNA polynucleotide target or RNA polynucleotide target.

This disclosure provides compositions, methods, and systems comprising a papillomaviral delivery vehicle for the delivery of gene editing material to cells. The papillomaviral delivery vehicle comprises a papillomavirus-derived capsid and DNA encoding a gene editing material encapsulated by the capsid. The papillomaviral delivery vehicle can be transduced into a cell under conditions conducive for the cell to synthesize the gene editing material. The cell can comprise a polynucleotide target and the gene editing material can target the polynucleotide target. The polynucleotide target can be a DNA polynucleotide target or RNA polynucleotide target.

CRISPR RNA-guided nucleases are routinely used for sequence-specific manipulation of DNA. While CRISPR-based DNA editing has become routine, analogous methods for editing RNA have yet to be established. Here we repurpose the type III-A CRISPR RNA-guided nuclease for sequence-specific cleavage of the SARS-CoV-2 genome. The type III cleavage reaction is performed in vitro using purified viral RNA, resulting in sequence-specific excision of 6, 12, 18 or 24 nucleotides. Ligation of the cleavage products is facilitated by a DNA splint that bridges the excision and RNA ligase is used to link the RNA products before transfection into mammalian cells. The SARS-CoV-2 RNA is infectious and standard plaque assays are used to recover viral clones. Collectively, this work demonstrates how type III CRISPR systems can be repurposed for sequence-specific editing of RNA viruses including SARS-CoV-2 and more generally for gene therapy.

CRISPR RNA-guided nucleases are routinely used for sequence-specific manipulation of DNA. While CRISPR-based DNA editing has become routine, analogous methods for editing RNA have yet to be established. Here we repurpose the type III-A CRISPR RNA-guided nuclease for sequence-specific cleavage of the SARS-CoV-2 genome. The type III cleavage reaction is performed in vitro using purified viral RNA, resulting in sequence-specific excision of 6, 12, 18 or 24 nucleotides. Ligation of the cleavage products is facilitated by a DNA splint that bridges the excision and RNA ligase is used to link the RNA products before transfection into mammalian cells. The SARS-CoV-2 RNA is infectious and standard plaque assays are used to recover viral clones. Collectively, this work demonstrates how type III CRISPR systems can be repurposed for sequence-specific editing of RNA viruses including SARS-CoV-2 and more generally for gene therapy.

The present disclosure describes a CRISPR nuclease cascade assay that can detect one or more target nucleic acids of interest of interest at attamolar (aM) (or lower) limits in about 10 minutes or less without the need for amplifying the target nucleic acids of interest. The CRISPR cascade assays utilize signal amplification mechanisms comprising various components including CRISPR nucleases, guide RNAs (gRNAs), blocked nucleic acid molecules, blocked primer molecules, and reporter moieties.

The present disclosure provides engineered Class 1 Type I CRISPR-Cas (Cascade) systems that comprise multi-protein effector complexes, nucleoprotein complexes comprising Type I CRISPR-Cas subunit proteins and nucleic acid guides, polynucleotides encoding Type I CRISPR-Cas subunit proteins, and guide polynucleotides. Also, disclosed are methods for making and using the engineered Class 1 Type I CRISPR-Cas systems of the present invention.

The present disclosure provides engineered Class 1 Type I CRISPR-Cas (Cascade) systems that comprise multi-protein effector complexes, nucleoprotein complexes comprising Type I CRISPR-Cas subunit proteins and nucleic acid guides, polynucleotides encoding Type I CRISPR-Cas subunit proteins, and guide polynucleotides. Also, disclosed are methods for making and using the engineered Class 1 Type I CRISPR-Cas systems of the present invention.

This disclosure relates to methods for producing immune cells with enhanced function. More specifically, disclosed herein is a method for enhancing the function of an immune cell comprising modifying an immune cell to inhibit the function of at least one gene selected from the group consisting of RC3H1, RC3H2, A2AR, FAS, TGFBR1, and TGFBR2. Also disclosed herein is a method comprising modifying a stem or progenitor cell capable of differentiating into an immune cell to inhibit the function of at least one gene selected from the group consisting of RC3H1, RC3H2, A2AR, FAS, TGFBR1, and TGFBR2. Also disclosed herein are immune cells or stem cells made by the present methods, as well as the use of immune cells in therapeutic treatment.

This disclosure relates to methods for producing immune cells with enhanced function. More specifically, disclosed herein is a method for enhancing the function of an immune cell comprising modifying an immune cell to inhibit the function of at least one gene selected from the group consisting of RC3H1, RC3H2, A2AR, FAS, TGFBR1, and TGFBR2. Also disclosed herein is a method comprising modifying a stem or progenitor cell capable of differentiating into an immune cell to inhibit the function of at least one gene selected from the group consisting of RC3H1, RC3H2, A2AR, FAS, TGFBR1, and TGFBR2. Also disclosed herein are immune cells or stem cells made by the present methods, as well as the use of immune cells in therapeutic treatment.

The present application relates to a nucleic acid molecule comprising a first nucleic acid sequence comprising at least a portion of a 5′ untranslated region (5′ UTR) of a carboxylesterase gene and a second nucleic acid sequence encoding a protein of interest, where the second nucleic acid sequence is heterologous to and operatively coupled to the first nucleic acid sequence. Also disclosed are methods of expressing a protein of interest in a target cell, methods of treating subject for cardiac ischemia or hepatic ischemia, and methods of identifying a nucleic acid sequence capable of selectively enhancing translation of a heterologous protein of interest in a target cell.