Abstract: Methods for modification of target nucleic acids. The method involves a construct in which guide RNA is covalently linked to donor RNA (fusion NA) to be introduced into the target nucleic acid by homologous recombination and is based on the introduction of a nuclease, e.g. CRISPR or TALEN, into the cell containing the target nucleic acid. The fusion NA may be introduced as a DNA vector.

Abstract: Methods for modification of target nucleic acids. The method involves a construct in which guide RNA is covalently linked to donor RNA (fusion NA) to be introduced into the target nucleic acid by homologous recombination and is based on the introduction of a nuclease, e.g. CRISPR or TALEN, into the cell containing the target nucleic acid. The fusion NA may be introduced as a DNA vector.

Abstract: Methods for modification of target nucleic acids. The method involves a construct in which guide RNA is covalently linked to donor RNA (fusion NA) to be introduced into the target nucleic acid by homologous recombination and is based on the introduction of a nuclease, e.g. CRISPR or TALEN, into the cell containing the target nucleic acid. The fusion NA may be introduced as a DNA vector.

Abstract: Methods for modification of target nucleic acids. The method involves a construct in which guide RNA is covalently linked to donor RNA (fusion NA) to be introduced into the target nucleic acid by homologous recombination and is based on the introduction of a nuclease, e.g. CRISPR or TALEN, into the cell containing the target nucleic acid. The fusion NA may be introduced as a DNA vector.

Abstract: Methods for modification of target nucleic acids. The method involves a construct in which guide RNA is covalently linked to donor RNA (fusion NA) to be introduced into the target nucleic acid by homologous recombination and is based on the introduction of a nuclease, e.g. CRISPR or TALEN, into the cell containing the target nucleic acid. The fusion NA may be introduced as a DNA vector.

Abstract: Methods for modification of target nucleic acids. The method involves a construct in which guide RNA is covalently linked to donor RNA (fusion NA) to be introduced into the target nucleic acid by homologous recombination and is based on the introduction of a nuclease, e.g. CRISPR or TALEN, into the cell containing the target nucleic acid. The fusion NA may be introduced as a DNA vector.

Abstract: The present invention relates to T-DNA vectors and methods for obtaining transgenic eukaryotes using said vectors. The transgenic eukaryotes are characterized in that they contain the T-DNA but not the illegitimately transferred vector backbone sequence. This is achieved by modifying the T-DNA borders such that they are more efficiently nicked or such that they allow elimination of illegitimately transferred vector backbone sequences by means of recombination.

Abstract: The present invention relates to T-DNA vectors and methods for obtaining transgenic eukaryotes using said vectors. The transgenic eukaryotes are characterized in that they contain the T-DNA but not the illegitimately transferred vector backbone sequence. This is achieved by modifying the T-DNA borders such that they are more efficiently nicked or such that they allow elimination of illegitimately transferred vector backbone sequences by means of recombination.

Abstract: The present invention relates to T-DNA vectors and methods for obtaining transgenic eukaryotes using said vectors. The transgenic eukaryotes are characterized in that they contain the T-DNA but not the illegitimately transferred vector backbone sequence. This is achieved by modifying the T-DNA borders such that they are more efficiently nicked or such that they allow elimination of illegitimately transferred vector backbone sequences by means of recombination.

Abstract: The present invention relates to the easy cloning of multiple DNA fragments at multiple places in the vector by a single step recombination reaction. More specifically the present invention discloses the use of two recombination sites each having the same pair of recombination sequences and the recombination sites are placed in opposite direction, in order to prevent the recombination between the sites themselves, and offering the opportunity to clone different or the same DNA fragments in multiple sites of the vector. This method is very useful for high throughput cloning of for example a co-suppression vector, or a gene combination vector, or a promoter combination vector or a promoter-gene combination vector, or a gene silencing vector, or a polycistronic RNA vector, or a gene stacking vector, or a biderectional promoter, or combinatorial expression cassettes or a fusion protein.

Abstract: The present invention relates to T-DNA vectors and methods for obtaining transgenic eukaryotes using said vectors. The transgenic eukaryotes are characterized in that they contain the T-DNA but not the illegitimately transferred vector backbone sequence. This is achieved by modifying the T-DNA borders such that they are more efficiently nicked or such that they allow elimination of illegitimately transferred vector backbone sequences by means of recombination.