Plant Biotechnology and Genetics: Principles, Techniques and Applications

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engineered plant cell. All the phyto-oncogenes (tumor-inducing genes) have been removed
(Fig. 7.7).
These plant vectors are known asbinary vectorsbecause they require the interaction of a
second, disarmed Ti plasmid lacking a T-DNA. This second plasmid contains thevir
region, allowing the T-DNA containing the transgenes on the binary vector to be transferred
and stably integrated into the host nuclear genome (a more detailed description of plant
transformation can be found in Chapter 10).
Plant binary vectors are constructed and amplified with the aid ofE. coli, the workhorse
organism in molecular biology. Once construction is completed inE. coli, such plasmid
vectors are transferred toA. tumefaciens, the organism responsible for transferring genes
to the nuclear genome of plant cells. These vectors therefore contain origins of replication
that function inA. tumefaciensandE. coli. The pVS1 origin is derived from aPseudomonas
plasmid and is stably maintained in a wide variety of proteobacteria, including
Pseudomonas,Agrobacterium,Rhizobium, andBurkholderia. For this reason, the pVS1
origin has been widely used to construct cloning vectors that are suitable for use in
plant-associated bacteria.A. tumefaciensuses the repABC operon to stringently control
plasmid replication and the partitioning of plasmid DNA to daughter cells. This operon
is not only present on large plasmids of low copy number derived fromAgrobacterium
but is also encoded by the chromosomes ofAgrobacterium. Unfortunately,E. colidoes
not use the repABC operon for plasmid replication, so plasmids containing only the
pVS1 origin do not replicate inE. coli. Binary vectors designed to shuttle between
E. coliandA. tumefaciensmust, therefore, also contain anE. coli–compatibleori, most
commonly the ColE1 origin (providing relaxed replication) (Fig. 7.8).
Since plant binary vectors provide no selective advantage to the bacteria, the vectors
must be engineered to encode selectable marker genes for their propagation inE. coli
andA. tumefaciens(examples of commonly used bacterial selectable marker genes are
shown in Table 7.2).
A broadly active bacterial promoter must be used to transcribe the antibiotic resistance
gene, so that bacteria containing the vector can survive and amplify the recombinant DNA.
The same selection criteria are used forE. coliandA. tumefaciens. However, the T-DNA
that is transferred to the plant cell must also contain a selectable marker, this time under the
control of a broadly active plant promoter, allowing the identification and propagation of
transformed plant cells (Fig. 7.8) (marker genes and the promoters that drive them are dis-
cussed in detail in Chapter 9).


7.2.2 Components for Efficient Gene Expression in Plants


The requirements for the successful introduction and efficient expression of foreign genes
in plant cells have developed with our understanding of the mechanisms of plant gene


Figure 7.7.T-DNA used to genetically engineer plants frequently contains a selectable marker gene
under the transcriptional control of a constitutively and ubiquitously active promoter to ensure gene
expression in all tissues at all stages of development, together with the gene of interest (GOI)
providing a novel phenotype for the plant.


7.2. DNA VECTORS 167
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