Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.

Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.

Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.

Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.

Abstract: Provided herein are machine learning-based methods for assessing the combined impact of multiple genetic variants, as well as the uses of such methods for various applications, such as in synthetic biology, personalized medicine, agricultural breeding, and genetic engineering. Also provided herein are exemplar computer-readable storage media and electronic devices for performing such methods.

Abstract: Use of CRISPR/Cas12d systems in eukaryotic organisms including plants and eukaryotic cells for genome engineering, and compositions used in such methods are disclosed.

Abstract: Methods for obtaining plant cells, plants, and plant parts, including soybean plant cells, plants, and plant parts, comprising synthetic polynucleotides that provide for increased expression of encoded RNA-guided endonucleases (RGEs), RNA guided nickase (RGNs), and RNA guided DNA binding proteins are disclosed. Also provided are soybean plant cells, plants, and plant parts comprising synthetic polynucleotides that provide for increased expression of encoded RNA-guided endonucleases (RGEs), RNA guided nickase (RGNs), and RNA guided DNA binding proteins.

Abstract: Provided herein is a method of delivering a biological material, including a genome-editing agent, to the interior of a plant cell wherein the method includes contacting the plant cell with a complex comprising the biological material and a fluorous agent. Also provided herein are compositions and reagents for practicing the method.

Abstract: The present disclosure relates to base-editing systems including a fusion protein including a DNA-binding domain and a cytidine deaminase domain and a non-protein uracil-DNA glycosylase inhibitor, and methods of using the same. The DNA-binding domains of base-editing systems of the present disclosure include domains with a variety of target region possibilities, which increase the number and type of sequences that can be edited. The npUGIs of the base-editing systems of the present disclosure improve UDG inhibition (e.g., UDG inhibition is more complete) and are suitable for use in a wide range of organisms.

Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.

Abstract: This disclosure provides compositions, recombinant expression constructs, and engineered systems that include a polynucleotide including or encoding a Cas12a tracrRNA, and methods for their use. The materials and methods of the disclosure are especially suited to sequence-specific genome editing of eukaryotic genomic sequences.

Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.

Abstract: This disclosure provides compositions, recombinant expression constructs, and engineered systems that include a polynucleotide including or encoding a Cas12a tracrRNA, and methods for their use. The materials and methods of the disclosure are especially suited to sequence-specific genome editing of eukaryotic genomic sequences.

Abstract: This disclosure provides compositions that include a polynucleotide including or encoding a Cas12a tracrRNA, and methods for their use in sequence-specific genome editing, especially of eukaryotic genomic sequences. In particular, this disclosure provides Cas12a tracrRNA-containing compositions and methods for their use in Cas12a-mediated editing of a target sequence, wherein the editing efficiency is increased in comparison to controls lacking the Cas12a tracrRNA.

Abstract: This disclosure provides compositions that include a polynucleotide including or encoding a Cas12a tracrRNA, and methods for their use in sequence-specific genome editing, especially of eukaryotic genomic sequences. In particular, this disclosure provides Cas12a tracrRNA-containing compositions and methods for their use in Cas12a-mediated editing of a target sequence, wherein the editing efficiency is increased in comparison to controls lacking the Cas12a tracrRNA.

Abstract: This disclosure provides compositions, recombinant expression constructs, and engineered systems that include a polynucleotide including or encoding a Cas12a tracrRNA, and methods for their use. The materials and methods of the disclosure are especially suited to sequence-specific genome editing of eukaryotic genomic sequences.

Abstract: This disclosure provides compositions that include a polynucleotide including or encoding a Cas12a tracrRNA, and methods for their use in sequence-specific genome editing, especially of eukaryotic genomic sequences. In particular, this disclosure provides Cas12a tracrRNA-containing compositions and methods for their use in Cas12a-mediated editing of a target sequence, wherein the editing efficiency is increased in comparison to controls lacking the Cas12a tracrRNA.

Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.

Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.

Abstract: Compositions and methods related to Cas proteins, nucleic acids encoding the Cas proteins, and modified host cells comprising the Cas proteins and/or encoding nucleic acids are disclosed. Cas proteins are useful in a variety of applications. Cas proteins bind guide RNAs that in turn provide functional specificity to the Cas proteins, nucleic acids encoding the Cas guide RNAs, and modified host cells comprising the Cas guide RNAs and/or encoding nucleic acids. The Cas polypeptides and corresponding guide RNAs can be used in a variety of applications.