(cell and molecular biology) An experimental method in which information from cloned deoxyribonucleic acid (DNA) or protein sequences is used to find or to produce mutations that help identify the function of a gene or protein (in contrast to classical genetics in which a known function or trait is traced back to a particular gene.
Reverse genetics
| Sci-Tech Dictionary: reverse genetics |
(ri¦vərs jə′ned·iks)
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| Veterinary Dictionary: reverse genetics |
Methods such as antisense nucleic acids and site-directed mutagenesis that are used to selectively study gene function. Contrasts with classical genetics which depends on the isolation and analysis of cells (animals) with random mutations that can be identified.
| Wikipedia: Reverse genetics |
Reverse genetics is an approach to discovering the function of a gene that proceeds in the opposite direction of so called forward genetic screens of classical genetics. Simply put, while forward genetics seeks to find the genetic basis of a phenotype or trait, reverse genetics seeks to find the possible phenotypes that may derive from a specific genetic sequence obtained by DNA sequencing.
Automated DNA sequencing generates large volumes of genomic sequence data relatively rapidly. Many genetic sequences are discovered in advance of other, less easily obtained, biological information. Reverse genetics attempts to connect a given genetic sequence with specific effects on the organism.
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Techniques used in reverse genetics
To learn the influence a sequence has on phenotype, or to discover its biological function, researchers can engineer a change or disruption in the DNA. After this change has been made a researcher can look for the effect of such alterations in the whole organism. There are several different methods of reverse genetics that have proved useful:
Directed deletions and point mutations
Site-directed mutagenesis is a sophisticated technique that can either change regulatory regions in the promoter of a gene or make subtle codon changes in the open reading frame to identify important amino residues for protein function.
Alternatively, the technique can be used to create null alleles so that the gene is not functional. For example, deletion of a gene by gene knockout can be done in some organisms, such as yeast, mice and moss. Unique among plants, in Physcomitrella patens, gene knockout via homologous recombination is nearly as efficient as in yeast [1]. In the case of the yeast model system directed deletions have been created in every non-essential gene in the yeast genome [2]. In the case of the plant model system huge mutant libraries have been created based on gene disruption constructs [3].
In some cases conditional alleles can be used that have normal function until the allele is activated. This is known as gene knock-in. This might entail ‘knocking in’ recombinase sites (such as lox or frt sites) that will cause a deletion at the gene of interest when a specific recombinase (such as CRE, FLP) is induced. Cre or Flp recombinases can be induced with chemical treatments, heat shock treatments or be restricted to a specific subset of tissues.
Gene silencing
The discovery of gene silencing using double stranded RNA, also known as RNA interference (RNAi), and the development of gene knockdown using Morpholino oligos have made disrupting gene expression an accessible technique for many more investigators. This method is often referred to as a gene knockdown since the effects of these reagents are generally temporary, in contrast to gene knockouts which are permanent.
RNAi creates a specific knockout effect without actually mutating the DNA of interest. In C. elegans, RNAi has been used to systematically interfere with the expression of most genes in the genome. RNAi acts by directing cellular systems to degrade target messenger RNA (mRNA).
While RNA interference relies on cellular components for efficacy (e.g. the Dicer proteins, the RISC complex) a simple alternative for gene knockdown is Morpholino antisense oligos. Morpholinos bind and block access to the target mRNA without requiring the activity of cellular proteins and without necessarily accelerating mRNA degradation. Morpholinos are effective in systems ranging in complexity from cell-free translation in a test tube to in vivo studies in large animal models.
Interference using transgenes
A molecular genetic approach is the creation of transgenic organisms that overexpress a normal gene of interest. The resulting phenotype may reflect the normal function of the gene.
Alternatively it is possible to overexpress mutant forms of a gene that interfere with the normal (wildtype) genes function. For example, over expression of a mutant gene may result in high levels of a non-functional protein resulting in a dominant negative interaction with the wildtype protein. In this case the mutant version will out compete for the wildtype proteins partners resulting in a mutant phenotype.
Other mutant forms can result in a protein that is abnormally regulated and constitutively active (‘on’ all the time). This might be due to removing a regulatory domain or mutating a specific amino residue that is reversibly modified (by phosphorylation methylation or ubiquitination). Either change is critical for modulating protein function and often result in informative phenotypes.
References
- ^ Ralf Reski (1998): Physcomitrella and Arabidopsis: the David and Goliath of reverse genetics. Trends Plant in Science 3, 209–210. [1]
- ^ Winzeler, EA; et al. (1999). "Functional characterization of the Saccharomyces cervisiae genome by precise deletion and parallel analysis". Science 285 (5429): 901–6. doi:.
- ^ G. Schween, T. Egener, D. Fritzkowsky, J. Granado, M.-C. Guitton, N. Hartmann, A. Hohe, H. Holtorf, D. Lang, J.M. Lucht, C. Reinhard, S.A. Rensing, K. Schlink, J. Schulte, Ralf Reski (2005): Large-scale analysis of 73329 Physcomitrella plants transformed with different gene disruption libraries: Production parameters and mutant phenotypes. Plant Biology 7, 228–237. [2]
External links
- From the National Institute of Allergy and Infectious Diseases (NIAID) site:
- From theNational Center for Biotechnology Information (NCBI) site:
- "Reverse Genetics for the Control of Avian Influenza" in Avian Diseases
- "An improved reverse genetics system for influenza A virus generation and its implications for vaccine production" in the Proceedings of the National Academy of Sciences
- "Generation of High-Yielding Influenza A Viruses in African Green Monkey Kidney (Vero) Cells by Reverse Genetics" in the Journal of Virology
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