Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Lecture 3 Ti plasmid derived vector system The simplest way to
Document related concepts
Non-coding DNA wikipedia , lookup
List of types of proteins wikipedia , lookup
Gene expression profiling wikipedia , lookup
Gene regulatory network wikipedia , lookup
Molecular evolution wikipedia , lookup
Genome evolution wikipedia , lookup
Plant breeding wikipedia , lookup
Promoter (genetics) wikipedia , lookup
Community fingerprinting wikipedia , lookup
DNA vaccination wikipedia , lookup
Silencer (genetics) wikipedia , lookup
Endogenous retrovirus wikipedia , lookup
Cre-Lox recombination wikipedia , lookup
Genetic engineering wikipedia , lookup
Vectors in gene therapy wikipedia , lookup
Transformation (genetics) wikipedia , lookup
Molecular cloning wikipedia , lookup
Transcript
Lecture 3 Ti plasmid derived vector system The simplest way to exploit Ti plasmid to genetically transform plants is just inserting the desired DNA sequence into the T-DNA region and then use the Ti plasmid and A.tumefaciens to deliver and insert this gene into the genome of the susceptible plant cell. Though Ti plasmids are effective natural vectors they had certain limitations. The phytohormone produced by transformed cells growing in culture prevents their regeneration into mature plants. Hence auxins and cytokinin genes must be removed from the Ti –plasmid derived cloning vector. The opine synthesis gene must be removed as it may divert plant resources into opine production in transgenic plant. Generally, Ti- plasmids are large in size (200-800 kb).For effective cloning, large segments of DNA that are not essential for cloning has to be removed. As Ti plasmid does not replicate in E.coli,Ti-plasmid based vectors require an ori that can be used in E.coli To overcome these constraints, Ti plasmid based vectors were organized with the following components: A selectable marker gene that confers resistance to transformed plant cells. As these marker genes are prokaryotic origin, it is necessary to put them under the eukaryotic control (plant) of post transcriptional regulation signals, including promoter and a termination- poly adenylation sequence, to ensure that it is efficiently expressed in transformed plant cells. An origin of replication that allows the plasmid to replicate in E.coli. The right border sequence of the T-DNA which is necessary for T-DNA integration into plant cell DNA. A polylinker (MCS) to facilitate the insertion of cloned gene into the region between T-DNA border sequences. As these cloning vectors so organized lacked vir genes, they cannot effect the transfer and integration of T-DNA region into host plant cell. So two Ti-plasmid derived vector systems were developed. They include: 1. Binary vector system 2. Co-integrate vector system 1. Binary vector system The binary vector system contains either E.coli or A.tumifaciens origins of DNA replication, i.e.an E.coli - A.tumifaciens shuttle vector or a single broad host range ori. In either case no vir genes are present on the binary cloning vector. All the cloning steps are carried out in E.coli before the vector is introduced into A.tumifaciens. The A.tumifaciens strain carries a modified (disarmed) Ti plasmid that contains a complete set of vir genes but lack portions of T-DNA region, so that this T-DNA cannot be transferred. With this system, the defective Ti plasmid synthesizes the vir gene products that mobilize the TDNA region of the binary cloning vector plasmid. By providing the proteins encoded by the vir genes, the defective Ti plasmid acts as helper plasmid ,enabling the T-DNA from binary cloning vector to be inserted into the plant chromosomal DNA. Since transfer of T-DNA is initiated from the right border, the selectable marker which will eventually be used to detect the presence of the T-DNA inserted into the plant chromosomal DNA is placed next to the left border. If selectable marker is present adjacent to the right border, only small portion of T-DNA will be transferred resulting in a plant with only selectable marker and no gene of interest. Few binary vectors are developed with selectable markers one adjacent to the right and the other adjacent to the left border. Ti plasmid vector systems are often working as binary vectors T DNA region removed Gene of interest Plant selectable marker Bacterial selectable marker Disarmed Ti plasmid ori for E.coli Virulence region ori for A. tumefaciens HELPER plasmid ori for A. tum DISADVANTAGE: Depending on the orientation, plasmids with two different origins of replication may be unstable in E. coli ADVANTAGE: small vectors are used, which increases transfer efficiency from E. coli to Agrobacterium. No intermolecular recombination is needed 2. Co-integrate vector system In the co integrate vector system the cloning vector has a plant selectable marker gene, the target gene, the right border, an E.coli origin of the DNA replication, and a bacterial selectable marker gene. The co-integrate vector recombines with the modified ( disarmed) Ti plasmid that lacks both the tumor producing genes and the right border of the T-DNA within A.tumifaciens, and the entire cloning vector becomes integrated into the disarmed Ti plasmid to form a recombinant Ti plasmid. The co-integrate cloning vector and the disarmed helper Ti plasmid both carry homologous DNA sequence that provide shared site for in vivo homologous recombination, normally these sequence lie inside the T-DNA region. Following recombination, the cloning vector becomes part of the disarmed Ti plasmid, which provides the vir genes necessary for the transfer of TDNA to host plant cell. The only way that this cloning vector can be maintained in A.tumifaciens is a part of the co-integrated structure. In this co-integrated configuration genetically engineered T-DNA region can be transferred to plant cells.
