SOME ASPECTS OF GENETIC MAPS CREATION

Construction of genetic maps has a principal value upon practical using revealed associations “marker-character”. Wide using molecular DNA-markers as well as application methodology identification and localization on chromosomes of QTL (quantitative trait loci) even in the case when it were no appearance new direction in science significantly allowed broadening of biological investigations, including precision and scalability in construction of genetic linkage maps. At the present investigation of gene linkage is one of most useful approach using for genome mapping as well as for genetic and breeding. Saturation of genetic maps gives possibility of compilation on map many segregated loci in one population up to full genome saturation. At the same time, effects of interaction “genotypeenvironment” can be as basis for variability, which is one of main reason why different populations some of the species not revealed identical length of the maps and differences can reach up to 20%. Gene, loci or even full-length chromosomes mapped in organism of one taxon with high percent of significance can be evaluate and identify with the aim conservative molecular markers mapped in other organism as a rule from the related taxon. Moreover, if it are carried out interspecies comparisons of prediction on arrangement and mapping of genes or QTL, which was made for one species can be apply to other relative to him species.

1. Chesnokov Yu.V. Quantitative trait loci mapping in plants. SPb.,: VIR. 2009. - 100 p.

2. Zhuchenko A.A., Korol A.B. Recombination in evolution and breeding. М.: Nauka. 1985. – 400 p.

3. Chesnokov Yu.V. Molecular and genetic markers and its using in prebreeding investigations. SPb: AFI. 2013. - 116 p.

4. Burr B., Burr F.A., Matx E.C., Romero-Severson J. Pinning down loose ends: mapping telomeres and factors affecting their length // The Plant Cell. - 1992. – Vol. 4. – P. 953-960

5. Chakravarti A., Lasher L.A., Reefer J.E. A maximum likelihood method for estimating genome length using linkage data // Genetics. - 1991. - Vol. 128. – P. 175-182

6. Hulbert S.H., Hott T.W., Legg E.J., Lincoln S.E., Lander E.S., Michelmore R.W. Genetic analysis of the fungus, Bremia lactucae, using restriction length polymorphism // Genetics. - 1988. – Vol. 120. - P. 947-958

7. Gerber S., Rodolphe F. An estimation of the genome length of maritime pine (Pinus pinaster Ait.) // Theor. Appl. Genet. - 1994b. - Vol.88. – P. 289-292

8. Burr B., Burr F.A. Recombinant inbreds for molecular mapping in maize // Trends Genet. -1991. – Vol. 7. - P. 55-60

9. Gardiner J.M., Coe E.H., Melia-Hancock S., Hoisington D.A., Chao S. Development of a core RFLP map using an immortalized F2 population // Genetics. - 1993. - Vol. 134. – P. 917-930

10. De Vicente M.C., Tanksley S.D. Genome-wide reduction in recombination of backcross progeny derived from male versus female gametes in an interspecific cross of tomato // Theor. Appl. Genet. - 1991. - Vol. 83. – P. 173-178

11. Graner A., Jahorr A., Schondelmaier J., Siedler H., Pileen K., Fishbeck G., Wenzel G., Herrmann R.G. Construction of an RFLP map of barley // Theor. Appl. Genet. - 1991. – Vol. 83. –P. 250-256

12. Vizir I., Korol A.B. Sex difference in recombination frequency in Arabidopsis // Heredity. - 1990.– Vol. 65. – P. 379-383

13. Rick C.M. Controlled introgression of chromosomes of Solanum penneli into Lycopersicon esculentum: segregation and recombination // Genetics. - 1969. – Vol. 62. - P. 753-768

14. Bonierbale M.W., Plaisted R.L., Tanksley S.D. RFLP maps based on a common set of clones reveal modes of chromosomal evolution in potato and tomato // Genetics. - 1988. – Vol. 120. – P. 1095-1103

15. Gebhardt C., Ritter E., Barone A., Debener T., Walkemeier B., Schachtschabel U., Kaufmann

16. H., Thompson R.D., Bonierbale M.W., Ganal M.W., Tanksley S.D., Salamini F. RFLP maps of potato and their alignment with the homologous tomato genome // Theor. Appl. Genet. - 1991. - Vol.83. – P. 49-57

17. Paterson A.H., Lander E.S., Hewitt J.D., Peterson S., Loncoln S.E. Tanksley S.D. Resolution of quantitative traits into Mendelian factors by using a complete linkage map of restriction fragment length polymorphisms // Nature. - 1988. – Vol. 335. – P. 721-726

18. Causse M.A., Fulton T.M., Cho Y.G., Ahn S.N., Chunwongse J., Wu K., Xiao J., Yu Z., Ronald P.C., Herrington S.E., Second G., McCouch S.R., Tanksley S.D. Saturated molecular map of the rice genome based on an interspecific backcross population // Genetics. - 1994. – Vol. 138. – P. 1251-1274

19. Borts R.H., Haber J.E. Meiotic recombination in yeast: alteration by multiple heterozygosities // Science. - 1987. – Vol. 237. - P. 1459-1465

20. Beavis W.D., Grant D. A linkage map based on information from F2 populations of maize (Zea mays L.) // Theor. Appl. Genet. - 1991. – Vol. 82. – P. 636-644

21. Burr B., Burr F.A., Thompson K.H., Albertsen M.C., Stuber C.W. Gene mapping with recombinant inbreeds in maize // Genetics. - 1988. – Vol. 118. – P. 519-526

22. Arumuganathan K., Earle E.D. Nuclear DNA content of some important plant species // Plant Mol. Biol. Rep. - 1991. – Vol. 9. P. 208-218

23. Bennett M.D., Smith J.B. Nuclear DNA amount in angiosperms // Proc. R. Soc. Lond. B. -1991. – Vol. 334. – P. 309-345

24. Kaback D.B., Guacci V., Barber D., Mahon J.W. Chromosome size dependent control of meiotic recombination // Science. - 1992. – Vol. 256. - P. 228-232

25. Flavell R.B. Chromosome architecture: the distribution of recombination sites, the structure of ribosomal DNA loci and the multiplicity of sequences containing inverted repeats. In: Molecular Form and Function of the Plant Genome. Van Vloten-Dtin L., Groot G.S.P., Hall I.C. (eds.). NATO ASI, 83. Plenum Press. New York. - 1985. - P. 1-14

26. Oliver S.G., Van der Aart Q.J., Agostoni-Garbone M.L., Aigle M., Alberghina L., Alexandraki D., Antoine G. et al. The complete DNA sequence of yeast chromosome III // Nature. - 1992. – Vol. 357. – P. 38-46

27. Donner H.K. Genetic fine structure of the bronze locus in maze // Genetics. - 1986. – Vol. 113.P. 1021-1036

28. Schmidt R., West J., Love K., Lenehan Z., Lister C., Thompson H., Bouchez D., Dean C. Physical map and organization of Arabidopsis thaliana chromosome 4 // Science. - 1995. – Vol. 270. – P. 480-483

29. Rocher J.P., Prioul J.L., Lecharny A., Reyss A., Joussaume M. Genetic variability in carbon fixation, sucrose-P-synthase and ADP glucose pyrophosphorylase in maize plants of differing growth rate // Plant Physiol. - 1989. – Vol. 89. – P. 416-420

30. Slocum M.K., Figdore S.S., Kennard W.C., Suzuki J.Y., Osborn T.C. Linkage arrangement of restriction fragment length polymorphism loci in Brassica oleracea // Theor. Appl. Genet. - 1990.– Vol. 80. – P. 57-64

31. Song K.M., Suzuki J.Y., Slocum M.K., Williams P.H., Osborn T.C. A linkage map of Brassica rapa (syn. campestris) based on restriction length polymorphism loci // Theor. Appl. Genet. - 1991.– Vol. 82. – P. 296-304

32. Kishimoto N., Higo H., Abe K., Arai S., Siato A., Higo G. Identification of the duplicated segments in rice chromosomes 1 and 5 by linkage analysis of cDNA markers of known functions // Theor. Appl. Genet. - 1994. – Vol. 88. – P. 722-726

33. Blanc G., Barakat A., Guyot R., Cooke R., Denseny M. Extensive duplication and reshuffling in the Arabidopsis genome // Plant Cell. - 2000. – Vol. 12. – P. 1093-1101

34. Grant D., Cregan P., Schoemaker R.C. Genome organization in dicots: genome duplication in Arabidopsis and synteny between soybean and Arabidopsis // Proc. Natl. Acad. Sci. USA. - 2000.– Vol. 97. – P. 4168-4173

35. Lyon M.F. Dunn and mouse genetic mapping // Genetics. - 1990. – Vol. 125. – P. 231-236

36. Morizot D.C. Use fish gene maps to predict ancestral vertebrate genome organization. In: Isozymes: Structure, Function and Use in Biology and medicine. Ogita Z.I., Marker C.L. (eds.). Liss, Wiley, New York. - 1990. - P. 207-234

37. Tanksley S.D., Ganal M.W., Prince J.P., De Vicente M.C., Bonierbale M.W., Broun P., Fulton T.M., Giovannoni J.J., Grandillo S., Martin G.B., Messeguer R., Miller L., Paterson A.H., Pinedo O., Roder M.S., Wing R.A., Wu W., Young N.D. High density molecular linkage maps of the tomato and potato genomes // Genetics. - 1992. – Vol. 132. – P. 1141-1160

38. Lefebvre V., Palloux A., Caranta C., Pochard E. Construction of an intraspecific integrated linkage map of pepper using molecular markers and double haploid progenies // Genome. - 1995. – Vol. 38. P. 112-121

39. Livingstone K.D., Lackney V.K., Blauth J.R., Van Wijk R., Jahn M.K. Genome mapping in Capsicum and the evolution of genome structure in the Solanaceae // Genetics. - 1999. – Vol. 152.– P. 1183-1202

40. Tanksley S.D., Bernatzky R., Lapitan N.L., Prince J.P. Conservation of gene repertoire but not gene order in paper and tomato // Proc. Natl. Acad. Sci. USA. - 1988. - Vol. 85. P. 6419-6423

41. Weeden N.F., Muehlbauer F.J., Ladizinsky G. Extensive conservation of linkage relationships between pea and lentil genetic maps // J. Hered. - 1992. – Vol. 83. – P. 123-129

42. Devos K.M., Atkinsin M.D., Chinoy C.N., Liu C.J., Gale M.D. RFLP-based genetic map of the homoeologous group 3 chromosomes of wheat and rye // Theor. Appl. Genet. - 1992. – Vol. 83.– P. 931-939

43. Sharp P.J., Kreis M., Shewry P.R., Gale M.D. Location of β-amilase sequences in wheat and its relatives // Theor. Appl. Genet. - 1988. – Vol. 75. – P. 286-290

44. Wang M.L., Atkinson M.D., Chinoy C.N., Devos K.M., Gale M.D. Comparative RFLP-based genetic maps of barley chromosome 5 1H and rye chromosome 1R // Theor. Appl. Genet. - 1992.– Vol. 84. – P. 339-344

45. Melake-Berhan A., Hulbert S.H., Bultmer L.G., Bennetzen J.L. Structure and evolution of the genomes of sorghum bicolor and Zea mays // Theor. Appl. Genet. - 1993. – Vol. 86. – P. 598-604

46. Whitkus R., Doebley J., Lee M. Comparative genome mapping of sorghum and maize // Genetics. - 1992. – Vol. 132. – P. 1119-1130

47. Grivet L., DґHont A., Dufour P., Hamon P., Roques D., Glaszmann J.C. Comparative genome mapping of sugar cane with other species within the Andropogoneae tribe // Heredity. - 1994. – Vol. 73. – P. 500-508

48. Ahn S., Anderson J.A., Sorrells M.E., Tanksley S.D. Homoeologous relationships of rice, wheat and maize chromosomes // Mol. Gen. Genet. - 1993. – Vol. 241. – P. 483-490

49. Ahn S., Tanksley S.D. Comparative linkage maps of the rice and maize genomes // Proc. Natl. Acad. Sci. USA. - 1993. – Vol. 90. – P. 7980-7984

50. Kurata N., Moore G., Nagamura Y., Foote T., Yano M., Minobe Y., Gale M. Conservation of genome structure between rice and wheat // BioTechnology. - 1994. – Vol. 12. – P. 276-278

51. Vavilov N.I. The law of homological rows in hereditable variation. In: Theoretical basis of plant breeding. М., L. - 1935. - V.1. - P.75-128

52. Plaschke J., Boerner A., Xie D.X., Koebner R.M.D., Schlegel R., Gale M.D. RFLP mapping of genes affecting plant height and growth habit in rye // Theor. Appl. Genet. - 1993. – Vol. 85. – P. 1049-1054

53. Bennetzen J.L., Freeling M. Grasses as a single genetic system: genome composition, collinearity and compatibility // Trends in Genet. - 1993. – Vol. 9. – P. 259-261

54. Freeling M. Grasses as a single genetic system: reassessment // Plant Physiol. - 2001. – Vol. 125. – P. 1191-1197

55. Asnaghi C., Paulet F., Kaye C., Grivet L., Deu M., Glaszmann J.C., DґHont A. Application of synteny across Poaceae to determine the map location of a sugar cane rust resistance gene // Theor. Appl. Genet. - 2000. - Vol. 101. – P. 962-969.

56. Robert L.S., Robson F., Sharpe A., Lyndiate D., Coupland G. Conserved structure and function of the Arabidopsis flowering time gene CONSTANS in Brassica napus // Plant Mol. Biol. -1998. – Vol. 37. – P. 763-772.