Transfer DNA

The infection process of T-DNA into the host cell and integration into its nucleus involve multiple steps. First, the bacteria multiply in the wound sap before infection and then attach to the plant cell walls. The bacterial virulence genes' expression of approximately 10 operons is activated by perception of phenolic compounds such as acetosyringone emitted by wounded plant tissue and follows cell-cell contact. Then this process proceeds with the macromolecular translocation from Agrobacterium to cytoplasm of host cell, transmission of T-DNA along with associated proteins (called T-complex) to the host cell nucleus followed by disassembly of the T-complex, stable integration of T-DNA into host plant genome, and eventual expression of the transferred genes. The integration of T-DNA into a host genome involves the formation of a single-stranded nick in the DNA at the right border of the Ti plasmid. This nick creates a region of single stranded DNA from the left border of the T-DNA gene over to the right border which was cut. Then, single stranded binding proteins attach to the single stranded DNA. DNA synthesis displaces the single stranded region and then a second nick at the left border region releases the single stranded T-DNA fragment. Further this fragment can be incorporated into a host genome. Agrobacterium has been known to evolve a control system that uses plant host factors and cellular processes for several pathways of host-plant defense response to invade the host cell nucleus. For the integration of T-DNA into the target host genome, Agrobacterium carries out multiple interactions with host-plant factors. VirE2 is the single-stranded DNA binding protein that presumably coats the T- strand in the host cytoplasm by cooperative binding. It is then directed into the nucleus via interactions with the host cell proteins such as importin a, bacterial VirE3, and dynein-like proteins. Several other bacterial virulence effectors like VirB5, VirB7 (the minor components of the T-complex), VirD5, VirE2, VirE3, and VirF that may also interact with proteins of host plant cells. == Uses in biotechnology ==

Agrobacterium-mediated T-DNA transfer is widely used as a tool in biotechnology. For more than two decades, Agrobacterium tumefaciens has been exploited for introducing genes into plants for basic research as well as for commercial production of transgenic crops. In genetic engineering, the tumor-promoting and opine-synthesis genes are removed from the T-DNA and replaced with a gene of interest and/or a selection marker, which is required to establish which plants have been successfully transformed. Examples of selection markers include neomycin phosphotransferase, hygromycin B phosphotransferase (which both phosphorylate antibiotics) and phosphinothricin acetyltransferase (which acetylates and deactivates phosphinothricin, a potent inhibitor of glutamine synthetase) or a herbicide formulations such as Basta or Bialophos. Another selection system that can be employed is usage of metabolic markers such as phospho-mannose isomerase. Agrobacterium is then used as a vector to transfer the engineered T-DNA into the plant cells where it integrates into the plant genome. This method can be used to generate transgenic plants carrying a foreign gene. Agrobacterium tumefaciens is capable of transferring foreign DNA to both monocotyledons and dicotyledonous plants efficiently while taking care of critically important factors like the genotype of plants, types and ages of tissues inoculated, kind of vectors, strains of Agrobacterium, selection marker genes and selective agents, and various conditions of tissue culture. the affected gene, thus allowing for its isolation as T-DNA flanking sequences. A reporter gene can be linked to the right end of the T-DNA to be transformed along with a plasmid replicon and a selectable antibiotic (such as hygromycin)-resistance gene and can explicit approximately 30% of average efficiency having successful T-DNA inserts induced gene fusions in Arabidopsis thaliana. Reverse genetics involves testing the presumed function of a gene that is known by disrupting it and then looking for the effect of that induced mutation on the organismal phenotype. T-DNA tagging mutagenesis involves screening of populations by T-DNA insertional mutations. Collections of known T-DNA mutations provide resources to study the functions of individual genes, as developed for the model plant Arabidopsis thaliana. Examples of T-DNA insertion mutations in Arabidopsis thaliana include those associated many classes of phenotypes including seedling-lethals, size variants, pigment variants, embryo-defectives, reduced-fertility, and morphologically or physiologically aberrant plants. == See also ==