Systems and kits are disclosed herein for genetic engineering (such as for DNA cleavage and gene-editing), which include catalytic nucleic acids and catalytic nucleic acid-assisting reagents. Methods of genetic engineering are also described, in which both catalytic nucleic acid-assisting reagents and catalytic nucleic acids are specific for a target site, thus, providing high-fidelity genetic engineering.

Systems and kits are disclosed herein for genetic engineering (such as for DNA cleavage and gene-editing), which include catalytic nucleic acids and catalytic nucleic acid-assisting reagents. Methods of genetic engineering are also described, in which both catalytic nucleic acid-assisting reagents and catalytic nucleic acids are specific for a target site, thus, providing high-fidelity genetic engineering.

RNA-guided programmable cytosine and adenine base editors are a powerful class of genome editing tool for the introduction of localized base transitions without generating a double-stranded DNA break. Base editors (BE) have an optimal window of activity relative to the PAM recognized by the Cas9 enzyme and these constructs are strand selective. Here we demonstrate that fusion of a programmable DNA-binding domain (pDBD) or another Cas9 orthologue to spCas9-BE, we can produce an RNA-programmable Cas9-BE-pDBD chimera or Cas9-BE-Cas9 chimeras with dramatically improved activities and increased targeting range. Cas9-pDBD or Cas9-Cas9 fusion base editors display an expanded targeting repertoire and achieve highly specific genome editing, which can be tailored to achieve extremely precise genome editing at nearly any genomic locus.

The present disclosure provides methods of promoting a persistent effector function of immune cells, comprising modifying the cells to overexpress c-Jun and reduced levels of a NR4A gene and/or protein. Also provided are modified cells, e.g., immune cell, which have been modified to overexpress c-Jun and express reduced levels of NR4A gene and/or protein. Overexpressing c-Jun and simultaneously reducing expression levels of a NR4A gene and/or protein leads to exhaustion/dysfunction resistant cells, which are apoptosis resistant and also immune checkpoint resistant, and also to the maintenance of anti-tumor function in tumor microenvironments.

The present disclosure provides siRNA that suppresses proliferation of new coronaviruses (SARS-CoV-2). The siRNA disclosed herein includes: a sense strand; and an antisense strand. The sense strand includes a target sequence comprising 19 to 23 bases in which a base at a 5′ terminal is guanine (G) or cytosine (C), and an overhang comprising 2 to 4 bases added to a 3′ terminal side of the target sequence. The antisense strand includes a sequence complementary to the target sequence, and an overhang comprising 2 to 4 bases added to a 3′ terminal side of the complementary sequence. Here, at least a part of the target sequence contains at least a part of a base sequence encoding a signal peptide region of a spike protein (S protein) of SARS-CoV-2.

The present disclosure relates to systems, compositions and methods for modifying target nucleic acid sequences.

The present disclosure relates to systems, compositions and methods for modifying target nucleic acid sequences.

This disclosure concerns an engineered polynucleotide that interacts with a pre-mRNA and a spliceosome to regulate gene expression. The engineered polynucleotide may have stem-loop structure that recruits the spliceosome and targeting sequences that are complementary to a target sequence at an exon-intron splice junction and may include nucleotides with 2′ modifications and phorphorothioate linkages.

This disclosure concerns an engineered polynucleotide that interacts with a pre-mRNA and a spliceosome to regulate gene expression. The engineered polynucleotide may have stem-loop structure that recruits the spliceosome and targeting sequences that are complementary to a target sequence at an exon-intron splice junction and may include nucleotides with 2′ modifications and phorphorothioate linkages.

Novel NTRK1 fusion molecules, detection reagents, and uses and kits for evaluating, identifying, assessing and/or treating a subject having a cancer are disclosed.