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Marker assisted selectionMarker assisted selection or marker aided selection (MAS) is a process whereby a marker (morphological, biochemical or one based on DNA/RNA variation) is used for indirect selection of a genetic determinant or determinants of a trait of interest (i.e. productivity, disease resistance, abiotic stress tolerance, and/or quality). This process is used in plant and animal breeding. Additional recommended knowledgeOverviewConsiderable developments in biotechnology have led plant breeders to develop more efficient selection systems to replace traditional phenotypic-pedigree-based selection systems. Marker assisted selection (MAS) is indirect selection process where a trait of interest is selected not based on the trait itself but on a marker linked to it[1] [2] [3] [4]. For example if MAS is being used to select individuals with a disease, the level of disease is not quantified but rather a marker allele which is linked with disease is used to determine disease presence. The assumption is that linked allele associates with the gene and/or quantitative trait locus (QTL) of interest. MAS can be useful for traits that are difficult to measure, exhibit low heritbility, and/or are expressed late in development. A coordinated effort to implement wheat (Triticum turgidum and Triticum aestivum) marker assisted selection in the U.S. as well as a resource for marker assisted selection exists at the Wheat CAP (Coordinated Agricultural Project) website. Marker typesA marker may be:
Gene vs markerThe gene of interest is directly related with production of protein(s) that produce certain phenotypes whereas markers should not influence the trait of interest but are genetically linked (and so go together during segregation of gametes due to the concomitant reduction in homologous recombination between the marker and gene of interest). In many traits genes are discovered and can be directly assayed for their presence with a high level of confidence. However, if a gene is not isolated marker's help is taken to tag a gene of interest. In such case there may be some false positive results due to recombination between marker of interest and gene (or QTL). A perfect marker would elicit no false positive results. Important properties of ideal markers for MASAn ideal marker:
Demerits of morphological markersMorphological markers are associated with several general deficits that reduce their usefulness including:
To avoid problems specific to morphological markers, the DNA-based markers have been developed. They are highly polymorphic, simple inheritance (often codomimant), abundantly occur throughout the genome, easy and fast to detect, minimum pleiotropic effect and detection is not dependent on the developmental stage of the organism. Numerous markers have been mapped to different chromosomes in several crops including rice, wheat, maize, soybean and several others. Those markers have been used in diversity analysis, parentage detection, DNA fingerprinting, and prediction of hybrid performance. Molecular markers are useful in indirect selection processes, enabling manual selection of individuals for further propagation. Selection for major genes linked to markersThe major genes which are responsible for economically important characteristics are frequent in the Plant Kingdom. Such characteristics include disease resistance, male sterility, self-incompatibility, others related to shape, color, and architecture of whole plants and are often of mono- or oligogenic in nature. The marker loci which are tightly linked to major genes can be used for selection and are sometimes more efficient than direct selection for the target gene. Such vantages in efficiency may be due for example, to higher expression of the marker mRNA in such cases that the marker is actually a gene. Alternatively, in such cases that the target gene of interest differs between two alleles by a difficult-to-detect single nucleotide polymorphism, an external marker (be it another gene or a polymorphism that is easier to detect, such as a short tandem repeat) may present as the most realistic option. Situations that are favorable for molecular marker selectionThere are several indications for the use of molecular markers in the selection of a genetic trait. In such situations that:
The cost of genotyping (an example of a molecular marker assay) is reducing while the cost of phenotyping is increasing[citation needed] particularly in developed countries thus increasing the attractiveness of MAS as the development of the technology continues. Steps for MASGenerally the first step is to map the gene or quantitative trait locus (QTL) of interest first by using different techniques and then use this information for marker assisted selection. Generally, the markers to be used should be close to gene of interest (<5 recombination unit or cM) in order to ensure that only minor fraction of the selected individuals will be recombinants. Generally, not only a single marker but rather two markers are used in order to reduce the chances of an error due to homologous recombination. For example, if two flanking markers are used at same time with an interval between them of approximately 20cM, there is higher probability (99%) for recovery of the target gene. QTL mapping techinquesIn plants QTL mapping is generally achieved using bi-parental cross populations; a cross between two parents which have a contrasting phenotype for the trait of interest are developed. Commonly used populations are recombinant inbred lines (RILs), doubled haploids (DH), back cross and F2. Linkage between the phenotype and markers which have already been mapped is tested in these populations in order to determine the position of the QTL. Such techniques are based on linkage and are therefore referred to as "linkage mapping". However non-traditional techniques to plants as association mapping are underway. Similarly family-based populations where multi-parental populations are developed have been produced.[5] Single step MAS and QTL mappingIn contrast to two-step QTL mapping and MAS, a single-step method for breeding typical plant populations has been developed [5]. In such an approach, in the first few breeding cycles, markers linked to the trait of interest are identified by QTL mapping and later the same information in used in the same population. In this approach, pedigree structure are created from families that are created by crossing number of parents (in three-way or four way crosses). Both phenotyping and genotyping is done using molecular markers mapped the possible location of QTL of interest. This will identify markers and their favorable alleles. Once these favorable marker alleles are identified, the frequency of such alleles will be increased and response to marker assisted selection is estimated. Marker allele(s) with desirable effect will be further used in next slection cycle or other experiments. Use of MAS for backcross breedingA minimum of five or six-backcross generations are required to transfer a gene of interest from a donor (may not be adopted) to a recipient (recurrent – adopted cultivar). The recovery of the recurrent genotype can be accelerated with the use of molecular markers. If the F1 is heterozygous for the marker locus, individuals with the recurrent parent allele(s) at the marker locus in first or subsequent backcross generations will also carry a chromosome tagged by the marker. Marker assisted gene pyramidingGene pyramiding has been proposed and applied to enhance resistance to disease and insects by selecting for two or more than two genes at a time. For example in rice such pyramids have been developed against bacterial blight and blast. The advantage of use of markers in this case allows to select for QTL-allele-linked markers that have same phenotypic effect. MAS has also been proved useful for livestock improvement [6]. Refrences
4. review application of MAS in crop improvement 7. Collard B.C., D.J. Mackill . 2007. Marker-assisted selection: an approach for precision plant breeding in the twenty-first century.Philos Trans R Soc Lond B Biol Sci. 2007 (in press) 9. Dubcovsky, J. 2004. Marker-Assisted Selection in Public Breeding Programs: The Wheat Experience. Crop Sci. 44:6. 10. Goodman, M.M. 2004. Plant Breeding Requirements for Applied Molecular Biology. Crop Sci. 44:6. See also |
This article is licensed under the GNU Free Documentation License. It uses material from the Wikipedia article "Marker_assisted_selection". A list of authors is available in Wikipedia. |