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Legumes (Fabaceae) are the third largest family of flowering plants, with many economically important species such as soybean (Glycine max) and alfalfa (Medicago sativa). Legume plants can interact with nitrogen-fixing soil bacteria, generally called Rhizobia to develop root nodules in which the atmospheric dinitrogen is reduced to ammonia for use by the host plant. As such, cultivation of legume crops requires little input of nitrogen fertilizers and thus contributes to sustainable agriculture. Legume crops produce leaves and seeds with high protein content, serving as excellent forage and grain crops. However, cultivated legume species generally have complex genome structures, making functional studies of genes that play key roles in legume-specific processes cumbersome. Medicago truncatula has been widely adopted as a model species for legume studies primarily because (1) it has a diploid genome with a relatively small haploid genome size (~550 Mbp); (2) plants can be stably transformed for gene functional studies; and (3) it is closely related to alfalfa (M. sativa), the queen of forages, and many other economically important crops for translational studies. Recently, the genome sequence of M. truncatula cv Jemalong A17 has been released1,2. Annotation of the genome shows that there are more than 50,000 predicted genes or gene models in the genome. To determine the function of most of the genes in the M. truncatula genome is a challenging task. To facilitate functional studies of genes, a comprehensive collection of mutants in the range of over 150,000 M1 lines has been generated using fast neutron bombardment (FNB) mutagenesis in M. truncatula cv Jemalong A173,4. Fast neutron, a high energy ionization mutagen, has been used in generating mutants in many plant species including Arabidopsis5,6, rice (Oryza sativa)7, tomato (Solanum lycopersicum), soybean (Glycine soja; G. max)8,9, barley (Hordeum vulgare), and Lotus japonicus10. A large portion of mutations derived from FNB mutagenesis are due to DNA deletions that range in size from a few base pairs to mega base pairs9,11. Many phenotype-associated genes have been successfully identified and characterized4,12,13,14,15,16,17,18,19. Previously, molecular cloning of the underlying genes from FNB mutants relied on a map-based approach, which is time consuming and limits the number of mutants to be characterized at the molecular level. Recently, several complimentary approaches including transcript-based methods, genome tiling array-based comparative genomic hybridization (CGH) for DNA copy number variation detection, and whole genome sequencing, have been employed to facilitate the characterization of deletion mutants in diverse organisms including animals and plants20,21,22,23,24,25,26,27,28,29,30,31.
To facilitate the characterization of FNB mutants in M. truncatula, a whole-genome array-based comparative genomic hybridization (CGH) platform has been developed and validated. As reported in animal systems, the array-based CGH platform allows detection of copy number variations (CNVs) at the whole genome level in M. truncatula FNB mutants. Furthermore, lesions can be confirmed by PCR and deletion borders can be identified by sequencing. Overall, the array CGH platform is an efficient and effective tool in identifying lesions in M. truncatula FNB mutants. Here, the array CGH procedure and PCR characterization of deletion borders in an M. truncatula FNB mutant are illustrated.
The following protocol provides experimental steps and information about reagents, equipment and analysis tools for researchers who are interested in carrying out whole genome array-based comparative genomic hybridization (CGH) analysis of copy number variations in plants. As an example, Medicago truncatula FN6191 mutant was used to identify deletion regions and candidate genes associated with mutant phenotypes. M. truncatula FN6191 mutant, originally isolated from a fast neutron bombardment-induced deletion mutant collection32 (see Table of Materials), exhibited a hyper-nodulation phenotype after inoculation with the soil bacterium, Sihorhizobium meliloti Sm1021, in contrast to wild type plants.