Progress of chromosome engineering mediated by asymmetric somatic hybridization

Guangmin Xia^,

Key Laboratory of Plant Cell Engineering and Germplasm Innovation of Education Ministry, School of Life Sciences, Shandong University, Jinan 250100, China

More Information

Corresponding author: E-mail address: xiagm@sdu.edu.cn (Guangmin Xia)

摘要

- /
- /
- /
Abstract: Plant somatic hybridization has progressed steadily over the past 35 years. Many hybrid plants have been generated from fusion combinations of different phylogenetic species, some of which have been utilized in crop breeding programs. Among them, asymmetric hybrid, which usually contains a fraction of alien genome, has received more attention because of its importance in crop improvement. However, few studies have dealt with the heredity of the genome of somatic hybrid for a long time, which has limited the progress of this approach. Over recent ten years, along with the development of an effective cytogenetical tool “in situ hybridization (ISH)”, asymmetric fusion of common wheat (Triticum aestivum L.) with different grasses or cereals has been greatly developed. Genetics, genomes, functional genes and agricultural traits of wheat asymmetric hybrids have been subject to systematic investigations using gene cloning, genomic in situ hybridization (GISH) and molecular makers. The future goal is to fully elucidate the functional relationships among improved agronomic traits, the genes and underlying molecular mechanisms, and the genome dynamics of somatic introgression lines. This will accelerate the development of elite germplasms via somatic hybridization and the application of these materials in the molecular improvement of crop plants.
- asymmetric somatic hybrids /
- GISH /
- alien introgression /
- wheat breading

HTML全文

参考文献(97)

[1]	Bauer-Weston, B., Keller, W., Webb, J. et al. Theor. Appl. Genet., 86 (1993),pp. 150-158
[2]	Begum, F., Paul, S., Bag, N. et al. Theor. Appl. Genet., 91 (1995),pp. 1167-1172
[3]	Cai, Y.F., Xiang, F.N., Zhi, D.Y. et al. Plant Cell Rep., 26 (2007),pp. 1809-1819
[4]	Carlson, P.S., Smith, H.H., Dearing, R. Parasexual interspecific plant hybridization Proc. Natl. Acad. Sci. USA, 69 (1972),pp. 2292-2294
[5]	Chen, F.G., Luo, Z., Zhang, Z.G. et al. Mol. Breeding, 20 (2007),pp. 141-152
[6]	Chen, F.G., Xu, C.H., Chen, M.Z. et al. Mol. Breeding., 22 (2008),pp. 675-685
[7]	Chen, S.Y., Luo, Z., Quan, T.Y. et al. J. Trop. Subtrop. Bot., 10 (2003),pp. 263-266
[8]	Chen, S.Y., Xia, G.M., Quan, T.Y. et al. Plant Sci., 167 (2004),pp. 773-779
[9]	Chen, S.Y., Liu, S.W., Xu, C.H. et al. Heredity of chloroplast and nuclear genomes of asymmetric somatic hybrid lines between wheat and couch grass Acta Botan. Sin., 46 (2004),pp. 110-115
[10]	Cheng, A.X., Xia, G.M., Zhi, D.Y. et al. Cell Res., 14 (2004),pp. 86-91
[11]	Cheng, A.X., Xia, G.M. Plant Sci., 166 (2004),pp. 1219-1226
[12]	Cheng, A.X., Cui, H.F., Xia, G.M. Plant Bio., 8 (2006),pp. 673-679
[13]	Cui, H.F., Yu, Z.Y., Deng, J.Y. et al. Introgression of bread wheat chromatin into tall wheatgrass via somatic hybridization Planta, 229 (2009),pp. 323-330
[14]	Deng, J.Y., Cui, H.F., Zhi, D.Y. et al. Plant Cell Rep., 26 (2007),pp. 1233-1241
[15]	Dong, F., Tek, A.L., Frasca, A.B. et al. Cytogenet. Genome Res., 109 (2005),pp. 368-372
[16]	Dudits, D., Fejer, G., Hadlaezdy, C. et al. Intergeneric gene transfer mediated by plant protoplast fusion Mol. Gen. Genet., 179 (1980),pp. 283-288
[17]	Feng, D.S., Zhao, S.Y., Chen, F.G. et al. Theor. Appl. Genet., 110 (2004),pp. 136-144
[18]	Forsberg, J., Dixelius, C., Lagercrantz, U. et al. Plant Sci., 131 (1998),pp. 65-76
[19]	Friebe, B., Jiang, J., Raupp, W.J. et al. Chatacterization of wheat-alien translocations conferring resistance to diseases and pests: Current status Euphtica, 91 (1996),pp. 59-87
[20]	Gavrilenko, T., Thieme, R., Rokka, V.M. Theor. Appl. Genet., 103 (2001),pp. 231-239
[21]	Gleba, Y.U., Sytnik, K.
[22]	Grosser, J.W., Ollitrault, P., Olivares-Fuster, O. Cell Dev. Biol. Plant, 36 (2000),pp. 434-449
[23]	Guo, G.Q., Xia, G.M., Li, Z.Y. Sci China Ser. B, 34 (1990),pp. 438-445
[24]	Guo, W.W., Grosser, J.W. Plant Sci., 168 (2005),pp. 1541-1545
[25]	Guo, W.W., Wu, R.C., Cheng, Y.J. et al. Plant Breed., 126 (2007),pp. 72-76
[26]	Hall, R.D., Rouwendal, G.J.A., Krens, F.A. Mol. Gen. Genet., 234 (1992),pp. 306-314
[27]	Hall, R.D., Rouwendal, G.J.A., Krens, F.A. Mol. Genet. Gen., 234 (1992),pp. 315-324
[28]	Han, L., Zhou, C.E., Shi, J.Y. et al. Ginsenoside Rb1 in asymmetric somatic hybrid calli of Daucus carota with Panax quinquefolius Plant. Cell. Rep., 28 (2009),pp. 627-638
[29]	Hattori, G., Gulyas, G., Kim, H. et al. Plant Biotech., 25 (2008),pp. 177-182
[30]	Hinnisdaels, S., Bariller, L., Mouras, A. et al. Theor. Appl. Genet., 82 (1991),pp. 609-614
[31]	Iovene, M., Savarese, S., Cardi, T. et al. Genome, 50 (2007),pp. 443-450
[32]	Jauhar, P.P. Theor. Appl. Genet., 90 (1995),pp. 865-871
[33]	Jauhar, P.P. Modern biotechnology as an integral supplement to conventional plant breeding: The prospects and challenges Crop Sci., 46 (2006),pp. 1841-1859
[34]	Jiang, J.M., Gill, B.S. Genome, 37 (1994),pp. 717-725
[35]	Le, H.T., Armstrong, K.C., Miki, B. Detection of rye DNA in wheat-rye hybrids and wheat translocation stocks using total genomic DNA as a probe Plant Mol. Biol. Rep., 7 (1989),pp. 150-158
[36]	Leino, M., Teixeira, R., Landgren, M. et al. Theor. Appl. Genet., 106 (2003),pp. 1156-1163
[37]	Leino, M., Thyselius, S., Landgren, M. et al. Theor. Appl. Genet., 109 (2004),pp. 272-279
[38]	Li, C.L., Xia, G.M., Xiang, F.N. et al. Regeneration of asymmetric somatic hybrid plants from the fusion of two types of wheat with Russian wildrye Plant Cell Rep., 23 (2004),pp. 461-467
[39]	Li, Y.G., Stoutjestiik, P.A., Delves, A.C. et al.
[40]	Liu, H., Shi, L., Zhao, J.S. et al. Genetic characteristic of HMW-GS in somatic hybrid wheat lines-potential application to wheat breeding J. Agric. Food Chem., 54 (2006),pp. 5007-5013
[41]	Liu, H., Liu, S.W., Xia, G.M. Generation of high frequency of novel alleles of the high molecular weight glutenin in somatic hybridization between bread wheat and tall wheatgrass Theor. Appl. Genet., 118 (2009),pp. 1193-1198
[42]	Liu, J.H., Xu, X.Y., Deng, X.X. Intergeneric somatic hybridization and its application to crop genetic improvement Plant Cell Tiss. Organ Cult., 82 (2005),pp. 19-44
[43]	Liu, S.W., Zhao, S.Y., Chen, F.G. et al. BMC Evol. Biol., 7 (2007),pp. 76-83
[44]	Liu, S.W., Gao, X., Xia, G.M. Theor. Appl. Genet., 116 (2008),pp. 325-334
[45]	Louzada, E., Grosser, J., Gmitter, F.J. Plant Cell Rep., 12 (1993),pp. 687-690
[46]	Luo, Z., Chen, F.G., Feng, D.S. et al. Theor. Appl. Genet., 111 (2005),pp. 272-280
[47]	Mohapatra, T., Kirti, P.B., Kumar, V.D. et al. Plant Cell Rep., 17 (1998),pp. 814-818
[48]	Munns, R., Tester, M. Mechanisms of salinity tolerance Annu. Rev. Plant Biol., 59 (2008),pp. 65-181
[49]	Parokonny, A.S., Kenton, A.Y., Gleba, Y.Y. et al. Plant J., 2 (1992),pp. 863-874
[50]	Sakai, T., Imamura, J. Theor. Appl. Genet., 84 (1992),pp. 923-929
[51]	Schwarzacher, T., Leitch, A.R., Bennett, M.D. et al. Ann. Bot., 64 (1989),pp. 315-324
[52]	Sears, E.R. Use of radiation to transfer alien chromosome segments to wheat Crop Sci., 33 (1993),pp. 897-901
[53]	Shan, L., Zhao, S.Y., Quan, T.Y. et al. Chin. High Tech. Lett., 14 (2004),pp. 29-33
[54]	Shan, L., Zhao, S.Y., Chen, F. et al. Screening and localization of SSR markers related to salt tolerance of somatic hybrid wheat Shanrong No.3 Sci. Agric. Sin., 39 (2006),pp. 225-230
[55]	Shan, L., Li, C.L., Chen, F. et al. A Bowman-Birk type protease inhibitor is involved in the tolerance to salt stress in wheat Plant Cell Environ., 31 (2008),pp. 1128-1137
[56]	Sherraf, I., Tizroutine, S., Chaput, M.H. et al. Plant Cell Tiss. Organ Cult., 37 (1994),pp. 137-144
[57]	Shewry, P.R., Halford, N.G., Lafiandra, D. Genetics of wheat gluten proteins Adv. Genet., 49 (2003),pp. 111-184
[58]	Skarzhinskaya, M., Fahleson, J., Glimelius, K. et al. Genome, 41 (1998),pp. 691-701
[59]	Smith, M.V., Pay, A., Dudits, D. Analysis of chloroplast and mitochondrial DNAs in asymmetric hybrids between tobacco and carrot Theor. Appl. Genet., 77 (1989),pp. 641-644
[60]	Song, X.Q., Xia, G.M., Zhou, A.F. et al. Chin. Sci. Bull., 44 (1999),pp. 1382-1386
[61]	Spangenberg, G., Valles, M.P., Wang, Z.Y. et al. Theor. Appl. Genet., 88 (1994),pp. 509-519
[62]	Szarka, B., Göntér, I., Mlonár-láng, M. et al. Mixing of maize and wheat genomic DNA by somatic hybridization in regenerated sterile maize plants Theor. Appl. Genet., 105 (2002),pp. 1-7
[63]	Thieme, R., Rakosy-Tican, E., Gavrilenko, T. et al. Theor. Appl. Genet., 116 (2008),pp. 691-700
[64]	Vlahova, M., Hinnisdaels, S., Frulleux, F. et al. Theor. Appl. Genet., 94 (1997),pp. 184-191
[65]	Waara, S., Glimelius, K. The potential of somatic hybridization in crop breeding Euphytica, 85 (1995),pp. 217-233
[66]	Wang, J., Xiang, F.N., Xia, G.M. Sci. China Ser. C, 47 (2004),pp. 434-441
[67]	Wang, J., Xiang, F.N., Xia, G.M. Planta., 221 (2005),pp. 277-286
[68]	Wang, M.C., Peng, Z.Y., Li, C.L. et al. Proteomics, 8 (2008),pp. 1470-1489
[69]	Wang, M.Q., Xia, G.M., Peng, Z.Y. Plant Sci., 168 (2005),pp. 593-600
[70]	Wang, Y.P., Sonntag, K., Rudloff, E. Theor. Appl. Genet, 106 (2003),pp. 1147-1155
[71]	Wang, Y.P., Sonntag, K., Rudloff, E. et al. Plant Cell Rep., 25 (2006),pp. 35-40
[72]	Wang, Y.P., Snowdon, R.J., Rudloff, E. et al. Genome, 47 (2004),pp. 724-731
[73]	Wolters, A.M.A., Jacobsen, E.O., Connell, M. et al. Somatic hybridization as a tool for tomato breeding Euphytica, 79 (1994),pp. 265-277
[74]	Wolters, A.M.A., Schoenmakers, H.C.H., Koornneef, M. Theor. Appl. Genet., 90 (1995),pp. 285-293
[75]	Xia, G.M., Chen, H.M. Plant Sci., 120 (1996),pp. 197-203
[76]	Xia, G.M., Wang, H., Chen, H.M. Chin. Sci. Bull., 41 (1996),pp. 1382-1386
[77]	Xia, G.M., Li, Z.Y., Zhou, A.F. et al. Plant regeneration of wheat protoplasts prepared from different composition of suspension culture Chinese Journal of Biotechnology, 11 (1995),pp. 63-66
[78]	Xia, G.M., Xiang, F.N., Zhou, A.F. et al. Theor. Appl. Genet., 107 (2003),pp. 299-305
[79]	Xia, G.M., Li, Z.Y., Wang, S.L. et al. Plant Sci., 137 (1998),pp. 217-223
[80]	Xiang, F.N., Xia, G.M., Chen, H.M. Sci. China Ser. C, 46 (2003),pp. 243-252
[81]	Xiang, F.N., Xia, G.M., Chen, H.M. Plant Sci., 164 (2003),pp. 697-707
[82]	Xiang, F.N., Xia, G.M., Zhi, D.Y. Genome, 47 (2004),pp. 680-688
[83]	Xu, C.H., Xia, G.M., Zhi, D.Y. et al. Integration of maize nuclear and mitochondrial DNA into the wheat genome through somatic hybridization Plant Sci., 165 (2003),pp. 1001-1008
[84]	Xu, X.Y., Hu, Z.Y., Li, J.F. et al. Plant Cell Rep., 26 (2007),pp. 1263-1273
[85]	Yamagishi, H., Landgren, M., Forsberg, J. et al. Theor. Appl. Genet., 104 (2002),pp. 959-964
[86]	Yue, W., Xia, G.M. Plant Sci., 161 (2001),pp. 256-262
[87]	Zhang, Q.L., Xia, G.M., Quan, T.Y. et al. Acta Trit. Crops, 25 (2005),pp. 11-14
[88]	Zhang, X.Y., Dong, Y.C., Li, P. et al. Acta Genetica Sinica, 25 (1998),pp. 131-141
[89]	Zhao, D., Chen, S.Y., Xia, G.M. Journal of Shandong University (Natural Science), 37 (2002),pp. 272-275
[90]	Zhao, Z.G., Hu, T.T., Ge, X.H. et al. Plant Cell Rep., 27 (2008),pp. 1611-1621
[91]	Zhong, G.Z., Mu, S.M., Zhang, Z.B.
[92]	Zhou, A.F., Xia, G.M. Plant Cell Rep., 24 (2005),pp. 289-296
[93]	Zhou, A.F., Xia, G.M., Chen, H.M. Sci. China Ser. C, 39 (1996),pp. 617-626
[94]	Zhou, A.F., Xia, G.M., Chen, X.L. et al. Acta Botanica Sinica, 44 (2002),pp. 1004-1008
[95]	Zhou, A.F., Xia, G.M., Zhang, X. et al. Mol. Genet. Genomics, 265 (2001),pp. 387-393
[96]	Zhou, C.E., Xia, G.M., Zhi, D.Y. et al. Planta, 223 (2006),pp. 714-724
[97]	Zubko, M.K., Zubko, E.I., Adler, K. et al. Ann. Bot., 92 (2003),pp. 281-288