A new DNA knock-in approach is provided based on the usage of three single guide RNA (sgRNA) to increase the integration efficiency of donor DNA based on the CRISRP-Cas system. The approach uses a pair of universal sgRNAs complementary to the donor DNA and a single sgRNA that targets the locus of interest. In various embodiments, targeting is achieved by pre-forming a DNA:RNA:protein (DNA:RNP) complex in vitro and introducing the complex into the embryo or cells of interest either by microinjection or transfection.

A new DNA knock-in approach is provided based on the usage of three single guide RNA (sgRNA) to increase the integration efficiency of donor DNA based on the CRISRP-Cas system. The approach uses a pair of universal sgRNAs complementary to the donor DNA and a single sgRNA that targets the locus of interest. In various embodiments, targeting is achieved by pre-forming a DNA:RNA:protein (DNA:RNP) complex in vitro and introducing the complex into the embryo or cells of interest either by microinjection or transfection.

Provided are nucleic acid constructs, Toxoplasma comprising same, pharmaceutical compositions comprising same and methods using same for delivering a protein-of-interest to a tissue-of-interest of a subject, such as the CNS and further treating a pathology which is treatable by administration of a therapeutic polypeptide in a central nervous system of the subject.

Provided are nucleic acid constructs, Toxoplasma comprising same, pharmaceutical compositions comprising same and methods using same for delivering a protein-of-interest to a tissue-of-interest of a subject, such as the CNS and further treating a pathology which is treatable by administration of a therapeutic polypeptide in a central nervous system of the subject.

A cassette sequence for the transformation of a host cell includes at least: a first nucleotide sequence encoding a peptide or protein of interest to be produced by the host cell. The first sequence is linked to a second nucleotide sequence providing resistance to a toxin or encoding an antitoxin peptide to the toxin. The nucleotide sequences are organized in such a way that production of the peptide encoded by the second nucleotide sequence(s) is translationally coupled to production of the peptide encoded by the first nucleotide sequence.

A cassette sequence for the transformation of a host cell includes at least: a first nucleotide sequence encoding a peptide or protein of interest to be produced by the host cell. The first sequence is linked to a second nucleotide sequence providing resistance to a toxin or encoding an antitoxin peptide to the toxin. The nucleotide sequences are organized in such a way that production of the peptide encoded by the second nucleotide sequence(s) is translationally coupled to production of the peptide encoded by the first nucleotide sequence.

The present invention is directed to fluorescent rhodamine dyes having spectral properties suited to the creation of multiplex assay systems for use in molecular biology, cell biology and molecular genetics. The rhodamine dyes have the following structure:

This disclosure concerns compositions and methods for promoting transcription of a nucleotide sequence in a plant or plant cell, employing a Zea mays GRMZM2G138258 promoter. Some embodiments relate to a Zea mays GRMZM2G138258 promoter that functions in plants to promote transcription of operably linked nucleotide sequences. Other embodiments relate to a Zea mays GRMZM2G138258 3′UTR that functions in plants to terminate transcription of operably linked nucleotide sequences.

Methods and compositions for Ochrobactrum-mediated transformation of plants are provided. Methods include but are not limited to using an Ochrobactrum strain to transfer a polynucleotide of interest to a plant cell. These include VirD2-dependent methods. Compositions include an Ochrobactrum strain, transfer DNAs, constructs and/or plasmids. These include Ochrobactrum strains having a plasmid comprising one or more virulence gene(s), border region, and/or origin of replication. Plant cells, tissues, plants, and seeds comprising a polynucleotide of interest produced by the methods are also provided.

Methods and compositions for Ochrobactrum-mediated transformation of plants are provided. Methods include but are not limited to using an Ochrobactrum strain to transfer a polynucleotide of interest to a plant cell. These include VirD2-dependent methods. Compositions include an Ochrobactrum strain, transfer DNAs, constructs and/or plasmids. These include Ochrobactrum strains having a plasmid comprising one or more virulence gene(s), border region, and/or origin of replication. Plant cells, tissues, plants, and seeds comprising a polynucleotide of interest produced by the methods are also provided.