Animal cells and plant cells

Animal cells

In contrast to the wide variety of plasmid and phage vectors available for cloning in prokaryotic cells, relatively few vectors are available for introducing foreign genes into animal cells. The most commonly used are derived from simian virus 40 (SV40). Normal SV40 cannot be used as a vector, since there is a physical limit to the amount of DNA that can be packaged into the virus capsid, and the addition of foreign DNA would generate a DNA molecule too large to be packaged. However, SV40 mutants lacking portions of the genome can be propagated in mixed infections in which a “helper” virus supplies the missing function.

Plant cells

Two systems for the delivery and integration of foreign genes into the plant genome are the Ti plasmid of the soil bacterium Agrobacterium and the DNA plant virion cauliflower mosaic virus. The Ti plasmid is a natural gene transfer vector carried by A. tumefaciens, a pathogenic bacterium that causes crown gall tumor formation in dicotyledonous plants. A T-DNA segment present in the Ti plasmid becomes stably integrated into the plant cell genome during infection. This property of the Ti plasmid has been exploited to show that DNA segments inserted in the T-DNA region can be cotransferred to plant DNA.

Applications

Recombinant DNA technology has permitted the isolation and detailed structural analysis of a large number of prokaryotic and eukaryotic genes. This contribution is especially significant in the eukaryotes because of their large genomes. The methods outlined above provide a means of fractionating and isolating individual genes, since each clone contains a single sequence or a few DNA sequences from a very large genome. Isolation of a particular sequence of interest has been facilitated by the ability to generate a large number of clones and to screen them with the appropriate “probe” (radioactively labeled RNA or DNA) molecules.

Genetic engineering techniques provide pure DNAs in amounts sufficient for mapping, sequencing, and direct structural analyses. Furthermore, gene structure-function relationships can be studied by reintroducing the cloned gene into a eukaryotic nucleus and assaying for transcriptional and translational activities. The DNA sequences can be altered by mutagenesis before their reintroduction in order to define precise functional regions.

Genetic engineering methodology has provided means for the large-scale production of polypeptides and proteins. It is now possible to produce a wide variety of foreign proteins in E. coli. These range from enzymes useful in molecular biology to a vast range of polypeptides with potential human therapeutic applications, such as insulin, interferon, growth hormone, immunoglobins, and enzymes involved in the dynamics of blood coagulation.