Summary
Restriction fragment length polymorphism (RFLP) linkage maps have been constructed in several major diploid crops. However, construction of RFLP maps directly in polyploids has lagged behind for several reasons: (1) there are a large number of possible genotypes for each DNA probe expected in a segregating population, and these genotypes cannot always be identified readily by their banding phenotypes; and (2) the genome constitutions (allopolyploidy versus autopolyploidy) in many high polyploids are not clearly understood. We present here an analysis of these problems and propose a general method for mapping polyploids based on segregation of single-dose restriction fragments (SDRFS). SDRFs segregate 1:1 (presence: absence) in gametes of heterozygous plants. Hypothetical allopolyploid and autopolyploid species with four ploidy levels of 2n = 4x, 6x, 8x, and 10x, are used to illustrate the procedures for identifying SDRFs, detecting linkages among SDRFs, and distinguishing allopolyploid versus autopolyploids from polyploids of unknown genome constitution. Family size required, probability of linkage, and attributes of different mapping populations are discussed. We estimate that a population size of 75 is required to identify SDRFs with 98% level of confidence for the four ploidy levels. This population size is also adequate for detecting and estimating linkages in the coupling phase for both allopolyploids and autopolyploids, but linkages in the repulsion phase can be estimated only in allopolyploids. For autopolyploids, it is impractical to estimate meaningful linkages in repulsion because very large family sizes (>750) are required. For high-level polyploids of unknown genome constitution, the ratio between the number of detected repulsion versus coupling linkages may provide a crude measurement of preferential chromosome pairing, which can be used to distinguish allopolyploidy from autopolyploidy. To create a mapping population, one parent (P1) should have high heterozygosity to ensure a high frequency of SDRFs, and the second parent (P2) should have a low level of heterozygosity to increase the probability of detecting polymorphic fragments. This condition could be satisfied by choosing outcrossed hybrids as one parental type and inbreds, haploids, or doubled haploids as the other parental type.
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References
Allard RW (1956) Formulas and tables to facilitate the calculation of recombination values in Heredity. Hilgardia 24:235–278
Bernatzky R, Tanksley SD (1986) Toward a saturated linkage map in tomato based on isozymes and random cDNA sequences. Genetics 112:887–898
Bonierbale MW, Plaisted RL, Tanksley SD (1988) RFLP maps based on a common set of clones reveal modes of chromosomal evolution in potato and tomato. Genetics 120:1095–1103
Burr B, Burr FA, Thompson KH, Albertson MC, Stuber CW (1988) Gene mapping with recombinant inbreds in maize. Genetics 118:519–526
Helentjaris T, King G, Slocum M, Siedenstrang C, Wegman S (1985) Restriction fragment length polymorphisms as probes for plant diversity and their development as tools for applied plant breeding. Plant Mol Bol 5:109–118
Helentjaris T, Slocum M, Wright S, Schaefer A, Nienhuis J (1986) Construction of genetic linkage maps in maize and tomato using restriction fragment length polymorphism. Theor Appl Genet 72:761–769
Hoisington DA, Coe EH, Neuffer MG (1988) Gene list and linkage map of maize (Zea mays L.). Maize Genet Coop Newslett 62:125
Kam-Morgan LNW, Gill BS (1989) DNA restriction fragment length polymorphisms: a strategy for genetic mapping of D genome of wheat. Genome 32:724–732
Kimber G (1984) Evolutionary relationships and their influence on plant breeding. In: Gustafson JP (ed) Gene manipulation in plant improvement. Plenum Press, New York, pp 281–293
Landry BS, Kesseli RV, Farrara B, Michelmore RW (1987) A genetic map of lettuce (Lactuca sativa L.) with restriction fragment length polymorphism, isozyme, disease resistance and morphological markers. Genetics 116:331–337
Mather K (1951) The measurement of linkage in heredity. Methuen, London, p 149
McCouch SR, Kochert G, Yu ZH, Wang ZY, Khush GS, Coffman WR, Tanksley SD (1988) Molecular mapping of rice chromosomes. Theor Appl Genet 76:815–829
Nienhuis J, Helentjaris T, Slocum M, Ruggero B, Schaefer A (1987) Restriction fragment length polymorphism analysis of loci associated with insect resistance in tomato. Crop Sci 27:797–803
Osborn TD, Alexander DC, Fobes JF (1987) Identification of restriction fragment length polymorphisms linked to genes controlling soluble solids content in tomato fruit. Theor Appl Genet 73:350–356
Paterson AH, Lander ES, Hewitt JD, Paterson S, Lincoln SE, Tanksley SD (1988) Resolution of quantitative traits into Mendelian factors by using a complete RFLP linkage map. Nature 335:721–726
Simmonds NW (1979) Principles of crop improvement. Longman, New York, p 408
Silver J (1985) Confidence limits for estimates of gene linkage based on analysis of recombinant inbred strains. J Hered 76:436–440
Snape JW (1988) The detection and estimation of linkage using doubled haploid or single seed descent populations. Theor Appl Genet 76:125–128
Sreenivasan TV, Ahloowalia BS, Heinz DJ (1987) Cytogenetics. In: Heinz DJ (ed) Sugarcane improvement through breeding. Elsevier, New York, pp 211–253
Tanksley SD, Miller J, Paterson A, Bernasky R (1988a) Molecular mapping of plant chromosomes. In: Gustafson JP, Appels R (eds) Chromosome structure and function. Plenum Press, New York, pp 157–173
Tanksley SD, Bernatzky R, Lapitan NL, Prince JP (1988b) Conservation of gene repertoire but not gene order in pepper and tomato. Proc Natl Acad Sci USA 85:6419–6423
Tanksley SD, Young ND, Paterson AH, Bonierbale MW (1989) RFLP mapping in plant breeding: new tools for an old science. Bio/Technol 7:257–264
Wet JMJ de (1980) Origins of polyploids. In: Lewis WH (ed) Polyploidy biological relevance. Plenum Press, New York, pp 3–7
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Communicated by A. L. Kahler
Published as Paper No. 730 in the Journal Series of the Experiment Station, Hawaiian Sugar Planters' Association, and as Paper No. 792 in the Plant Breeding Series of Cornell University, Ithaca, NY 14853, USA
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Wu, K.K., Burnquist, W., Sorrells, M.E. et al. The detection and estimation of linkage in polyploids using single-dose restriction fragments. Theoret. Appl. Genetics 83, 294–300 (1992). https://doi.org/10.1007/BF00224274
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DOI: https://doi.org/10.1007/BF00224274