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Identification of alien chromatin specifying resistance to wheat streak mosaic and greenbug in wheat germ plasm by C-banding and in situ hybridization

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Summary

The chromosome constitutions of eight wheat streak mosaic virus (WSMV)-resistant lines, three of which are also greenbug resistant, derived from wheat/ Agropyron intermedium/Aegilops speltoides crosses were analyzed by C-banding and in situ hybridization. All lines could be traced back to CI15092 in which chromosome 4A is substituted for by an Ag. intermedium chromosome designated 4Ai-2, and the derived lines carry either 4Ai-2 or a part of it. Two (CI17881, CI17886) were 4Ai-2 addition lines. CI17882 and CI17885 were 4Ai-2-(4D) substitution lines. CI17883 was a translocation substitution line with a pair of 6AL.4Ai-2S and a pair of 6AS.4Ai-2L chromosomes substituting for chromosome pairs 4D and 6A of wheat. CI17884 carried a 4DL.4Ai-2S translocation which substituted for chromosome 4D. CI17766 carried a 4AL.4Ai-2S translocation substituting for chromosome 4A. The results show that the 4Ai-2 chromosome is related to homoeologous group 4 and that the resistance gene(s) against WSMV is located on the short arm of 4Ai-2. In addition, CI17882, CI17884, and CI17885 contained Ae. speltoides chromosome 7S substituting for chromosome 7A of wheat. The greenbug resistance gene Gb5 was located on chromosome 7S.

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References

  • Arriaga HO (1954) Resistencia a la toxemia de Schizaphis graminum (Rond) en cereales fmos. Univ Nac de Eva Peron, Rev Fac Agron (Terecera Epoca) 30:65–101

    Google Scholar 

  • Cauderon Y, Saigne B, Dange M (1973) The resistance of wheat rusts of Agropyron intermedium and its use in wheat improvement. In: Sears ER, Sears LMS (eds) Proc 4th Int Wheat Genet Symp. University of Missouri, Columbia, Mo. pp 401–407

    Google Scholar 

  • Dewey DR (1984) The genomic system of classification as a guide to intergeneric hybridization with the perennial Triticeae. In: Gustafson JP (ed) Gene manipulation in plant improvement. Plenum Publ, New York, pp 209–280

    Google Scholar 

  • Driscoll CJ, Bielig LM (1968) Map** of the Transec wheat-rye translocation. Can J Genet Cytol 10:421–425

    Google Scholar 

  • Driscoll CJ, Sears ER (1965) Map** of a wheat-rye translocation. Genetics 51:439–443

    Google Scholar 

  • Forster BP, Reeder SM, Forsyth SA, Koebner RMD, Miller TE, Gale MD, Cauderon Y (1987) An assessment of the homoeology of six Agropyron intermedium chromosomes added to wheat. Genet Res Camb 50:91–97

    Google Scholar 

  • Friebe B, Larter EN (1988) Identification of a complete set of isogenic wheat/rye D-genome substitution lines by means of Giemsa C-banding. Theor Appl Genet 76:474–479

    Google Scholar 

  • Gill BS (1987) Chromosome banding methods, standard chromosome band nomenclature, and applications in cytogenetic analysis. In: Heyne EG (ed) Wheat and wheat improvement, 2nd edn. ASA Monograph, Madison, Wisconsin, pp 243–254

  • Gill BS, Sharma HC, Raupp WJ, Browder LE, Hatchett JH, Harvey TL, Moseman JG, Waines JG (1985) Evaluation of Aegilops species for resistance to wheat powdery mildew, wheat leaf rust, Hessian fly, and greenbug. Plant Dis 69:314–316

    Google Scholar 

  • Gill BS, Raupp WJ, Sharma HC, Browder LE, Hatchett JH, Harvey TL, Waines JG (1986) Resistance in Aegilops squar-rosa to wheat leaf rust, wheat powdery mildew, greenbug, and Hessian fly. Plant Dis 70: 553–556

    Google Scholar 

  • Giraldez R, Cermeno MC, Oreleana J (1979) Comparison of C-banding pattern in the chromosomes of inbred lines and open pollinated varieties of rye, Secale cereale L. Z Pflanzenzuecht 83:40–48

    Google Scholar 

  • Hart GE (1973) Homoeologous gene evolution in hexaploid wheat. In: Sears ER and Sears LMS (eds) Proc 4th Int Wheat Genet Symp. University of Missouri, Columbia, Mo., pp 805–810

    Google Scholar 

  • Harvey TL, Martin TJ, Livers RW (1980) Resistance to biotype C greenbug in synthetic hexaploid wheats derived from Triticum tauschii. J Econ Entomol 73:387–389

    Google Scholar 

  • Heun M, Friebe B, Introgression of powdery mildew resistance from rye into wheat. Phytopathology (in press)

  • Hollenhorst MM, Joppa LR (1983) Chromosomal location of genes for resistance to greenbug in ‘Largo’ and ‘Amigo’ wheats. Crop Sci 23:91–95

    Google Scholar 

  • Joppa LR, Timian RG, Williams ND (1980) Inheritance to greenbug toxicity in an amphiploid of Triticum turgidum/T. tauschii. Crop Sci 20:343–344

    Google Scholar 

  • Kota RS (1980) A cytogenetic and agronomic study of induced translocation lines of common wheat (Triticum aestivum L. em Thell) immune from wheat streak mosaic virus. MSc thesis. South Dakota State University, S.D., USA

    Google Scholar 

  • Larson RI, Atkinson TG (1970) Identity of the wheat chromosomes replaced by Agropyron chromosomes in a triple alien chromosome substitution line immune to wheat streak mosaic. Can J Genet Cytol 12:145–150

    Google Scholar 

  • Lay CL, Wells DG, Gardner WAS (1971) Immunity from wheat streak mosaic virus in irradiated Agrotricum progenies. Crop Sci 11:431–432

    Google Scholar 

  • Liang GH, Wang RC, Niblett CL, Heyne EG (1979) Registration of B-6–37–1 wheat germ plasm. Crop Sci 19:421

    Google Scholar 

  • Lukaszewski AS, Gustafson JP (1983) Translocations and modifications of chromosomes in Triticale×wheat hybrids. Theor Appl Genet 64:239–284

    Google Scholar 

  • Martin TJ (1978) Procedures for evaluating wheat streak mosaic virus resistance. Plant Dis Rep 62:1062–1066

    Google Scholar 

  • Martin TJ, Harvey TL, Livers RW (1976) Resistance to wheat streak mosaic virus and its vector, Aceria tulipae. Phytopathology 66:346–349

    Google Scholar 

  • McKinney HH, Sando WJ (1951) Susceptibility and resistance to the wheat streak mosaic virus in the genera Triticum, Agropyron, Secale, and certain hybrids. Plant Dis Rep 35:476–478

    Google Scholar 

  • Naranjo T, Roca A, Goicoechea PG, GIraldez R (1987) Arm homoeology of wheat and rye chromosomes. Genome 29:873–882

    Google Scholar 

  • Rayburn AL, Gill BS (1985a) Use of biotin-labeled probes to map specific DNA sequences on wheat chromosomes. J Hered 76:78–81

    Google Scholar 

  • Rayburn AL, Gill BS (1985b) Molecular evidence for the origin and evolution of chromosome 4A in polyploid wheats. Can J Genet Cytol 27:246–250

    Google Scholar 

  • Sebesta EE, Bellingham RC (1963) Wheat viruses and their genetic control. In: Proc 2nd Int Wheat Genet Symp. Lund, Sweden. Hereditas [Suppl] 2:184–201

  • Sebesta EE, Wood EA Jr (1978) Transfer of greenbug resistance from rye to wheat with X-rays. Agron Abstr 61–62

  • Sebesta EE, Young HC, Wood EA (1972) Wheat streak mosaic virus resistance. Annu Wheat Newsl 18:136

    Google Scholar 

  • Sharma HC, Gill BS, Uyemoto JK (1984) High level of reistance in Agropyron species to barley yellow dwarf and wheat streak mosaic virus. Phytopathol Z 110:143–147

    Google Scholar 

  • Shepherd KW, Islam AKMR (1988) Fourth compendium of wheat-alien chromosome lines. In: Miller TE, Koebner RMD (eds) Proc 7th Int Wheat Genet Symp. Cambridge, England, pp 1373–1398

  • Sim IV T, Willis WG, Eversmeyer MG (1988) Kansas plant disease survey. Plant Dis 72:832–836

    Google Scholar 

  • Slykhuis JT (1955) Aceria tulipae Kiefer (Acarina eriophyidae) in relation to spread of wheat streak mosaic. Phytopathology 45:116–128

    Google Scholar 

  • Somsen HW, Sill Jr WH (1970) The wheat curl mite, Aceria tulipae Keifer, in relation to epidemiology and control of wheat streak mosaic. Kans State Univ Agric Exp Sta Res Publ 162

  • Stoddard SL, Gill BS, Lommel SA (1987a) Genetic expression of wheat streak mosaic virus resistance in two wheat-wheat-grass hybrids. Crop Sci 27:514–519

    Google Scholar 

  • Stoddard SL, Lommel SA, Gill BS (1987b) Evaluation of wheat germ plasm for resistance to wheat streak mosaic virus by symptomatology, ELISA, and slot-blot hybridization. Plant Dis 71:714–719

    Google Scholar 

  • Tyler JM, Webster JA, Smith EL (1985) Biotype E greenbug resistance in wheat streak mosaic virus-resistant wheat germ plasm lines. Crop Sci 25:686–688

    Google Scholar 

  • Tyler JM, Webster JA, Sebesta EE, Smith EL (1986) Inheritance of biotype E greenbug resistance in bread wheat CI17882 and its relationship with wheat streak mosaic virus resistance. Euphytica 35:615–620

    Google Scholar 

  • Tyler JM, Webster JA, Merkle OG (1987) Designation of genes in wheat germplasm conferring greenbug resistance. Crop Sci 27:526–527

    Google Scholar 

  • Tyler JM, Webster JA, Merkle OG (1988) Identification of rye genotypes resistant to biotypes B, C, E, and F of the greenbug. Euphytica 37:65–68

    Google Scholar 

  • Uyemoto JK, Ferguson MW (1980) Wheat streak mosaic virus: Increased yields of purified virus from corn. Plant Dis 64:460–462

    Google Scholar 

  • Wang RC, Liang GH (1977) Cytogenetic location of genes for resistance to wheat streak mosaic in an Agropyron substitution line. J Hered 68:375–378

    Google Scholar 

  • Wang RC, Liang GH, Heyne EG (1977) Effectiveness of ph gene in inducing homoeologous chromosome pairing in Agrotricum. Theor Appl Genet 51:139–142

    Google Scholar 

  • Wells DG, Wong R, Sze-Chung, Lay CL, Gardner WAS, Buchenau GW (1973) Registration of C.I. 15092 and C.I. 15093 wheat germ plasm. Crop Sci 13:776

    Google Scholar 

  • Wells DG, Kota RS, Sandhu HS, Gardner WAS, Finney KF (1982) Registration of one disomic substitution line and five translocation lines of winter wheat germ plasm resistant to wheat streak mosaic virus. Crop Sci 22:1277–1278

    Google Scholar 

  • Wood EA Jr, Sebesta EE, Starks KJ (1974) Resistance of ‘Gaucho’ triticale to Schizaphis graminum. Environ Entomol 3:720–721

    Google Scholar 

Download references

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Authors and Affiliations

  1. Institute of Plant Breeding, Technical University of Munich-Weihenstephan, Munich, Germany

    B. Triebe

  2. Department of Biology, Osaka Kyoiku University, Ikeda, Osaka, Japan

    Y. Mukai

  3. P.A.U. Regional Research Station, Gurdaspur, Punjab, India

    H. S. Dhaliwal

  4. Hays Experiment Station, 67601, Hays, KS, USA

    T. J. Martin

  5. Department of Plant Pathology, Throckmorton Hall, Kansas State University, 66506-5502, Manhattan, KS, USA

    B. S. Gill

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  1. B. Triebe
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  2. Y. Mukai
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  3. H. S. Dhaliwal
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  4. T. J. Martin
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  5. B. S. Gill
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Communicated by J.W. Snape

Contribution No. 90-515-J from the Kansas Agricultural Experiment Station, Kansas State University, Manhattan, Kan., USA

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Triebe, B., Mukai, Y., Dhaliwal, H.S. et al. Identification of alien chromatin specifying resistance to wheat streak mosaic and greenbug in wheat germ plasm by C-banding and in situ hybridization. Theoret. Appl. Genetics 81, 381–389 (1991). https://doi.org/10.1007/BF00228680

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  • DOI: https://doi.org/10.1007/BF00228680

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