OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

PLOS ONE 2014

Species Origin of Genomic Factors in Nicotiana nudicaulis Watson Controlling Hybrid Lethality in Interspecific Hybrids between N. nudicaulis Watson and N. tabacum L

DOI: 10.1371/journal.pone.0097004

Hongshuo Liu, Wataru Marubashi

Full-Text Cite this paper Add to My Lib

Abstract:

Hybrid lethality is expressed at 28°C in the cross Nicotiana nudicaulis×N. tabacum. The S subgenome of N. tabacum has been identified as controlling this hybrid lethality. To clarify the responsible genomic factor(s) of N. nudicaulis, we crossed N. trigonophylla (paternal progenitor of N. nudicaulis) with N. tabacum, because hybrids between N. sylvestris (maternal progenitor of N. nudicaulis) and N. tabacum are viable when grown in a greenhouse. In the cross N. trigonophylla×N. tabacum, approximately 50% of hybrids were vitrified, 20% were viable, and 20% were nonviable at 28°C. To reveal which subgenome of N. tabacum was responsible for these phenotypes, we crossed N. trigonophylla with two progenitors of N. tabacum, N. sylvestris (SS) and N. tomentosiformis (TT). In the cross N. sylvestris×N. trigonophylla, we confirmed that over half of hybrids of N. sylvestris×N. trigonophylla were vitrified, and none of the hybrids of N. trigonophylla×N. tomentosiformis were. The results imply that the S subgenome, encoding a gene or genes inducing hybrid lethality in the cross between N. nudicaulis and N. tabacum, has one or more genomic factors that induce vitrification. Furthermore, in vitrified hybrids of N. trigonophylla×N. tabacum and N. sylvestris×N. trigonophylla, we found that nuclear fragmentation, which progresses during expression of hybrid lethality, was accompanied by vitrification. This observation suggests that vitrification has a relationship to hybrid lethality. Based on these results, we speculate that when N. nudicaulis was formed approximately 5 million years ago, several causative genomic factors determining phenotypes of hybrid seedlings were inherited from N. trigonophylla. Subsequently, genome downsizing and various recombination-based processes took place. Some of the causative genomic factors were lost and some became genomic factor(s) controlling hybrid lethality in extant N. nudicaulis.

References

[1]	Stebbins GL (1966) Reproductive isolation and the origin of species. In: Processes of organic evolution. New Jersey: Prentice-Hall. 85–112.
[2]	Tezuka T (2012) Hybrid lethality in the genus Nicotiana. In: Mworia JK, editor. Botany. Rijeka: InTech. 191–210.
[3]	Bomblies K, Lempe J, Epple P, Warthmann N, Lanz C, et al. (2007) Autoimmune response as a mechanism for a Dobzhansky-Muller-type incompatibility syndrome in plants. PLoS Biol 5: e236.
[4]	Krüger J, Thomas CM, Golstein C, Dixon MS, Smoker M, et al. (2002) A tomato cysteine protease required for Cf-2-dependent disease resistance and suppression of autonecrosis. Science 296: 744–747.
[5]	Jeuken MJW, Zhang NW, McHale LK, Pelgrom K, den Boer E, et al. (2009) Rin4 causes hybrid necrosis and race-specific resistance in an interspecific lettuce hybrid. Plant Cell 21: 3368–3378.
[6]	Bomblies K, Weigel D (2007) Hybrid necrosis: autoimmunity as a potential gene-flow barrier in plant species. Nat Rev Genet 8: 382–393.
[7]	Yamada T, Marubashi W, Niwa M (1999) Detection of four lethality types in interspecific crosses among Nicotiana species through the use of three rescue methods for lethality. Breed Sci 49: 203–210.
[8]	Tezuka T, Marubashi W (2012) Genes in S and T subgenomes are responsible for hybrid lethality in interspecific hybrids between Nicotiana tabacum and Nicotiana occidentalis.. PLoS One 7: e36204.
[9]	Knapp S, Chase MW, Clarkson JJ (2004) Nomenclatural changes and a new sectional classification in Nicotiana (Solanaceae). Taxon 53: 73–82.
[10]	Gray JC, Kung SD, Wildman SG, Sheen SJ (1974) Origin of Nicotiana tabacum L. detected by polypeptide composition of Fraction I protein. Nature (London) 252: 226–227.
[11]	Sheen SJ (1972) Isozymic evidence bearing on the origin of Nicotiana tabacum L. Evolution. 26: 143–154.
[12]	Kenton A, Parokonny AS, Gleba YY, Bennett MD (1993) Characterization of the Nicotiana tabacum L. genome by molecular cytogenetics. Mol Gen Genet 240: 159–169.
[13]	Lim KY, Matyásek R, Lichtenstein CP, Leitch AR (2000) Molecular cytogenetic analyses and phylogenetic studies in the Nicotiana section Tomentosae. Chromosoma 109: 245–258.
[14]	Murad L, Lim KY, Christopodulou V, Matyasek R, Lichtenstein CP, et al. (2002) The origin of tobacco’s T genome is traced to a particular lineage within Nicotiana tomentosiformis (Solanaceae). Am J Bot 89: 921–928.
[15]	Murad L, Bielawski JP, Matyasek R, Kovarík A, Nichols RA, et al. (2004) The origin and evolution of geminivirus-related DNA sequences in Nicotiana.. Heredity (Edinb) 92: 352–358.
[16]	Chase MW, Knapp S, Cox AV, Clarkson JJ, Butsko Y, et al. (2003) Molecular systematics, GISH and the origin of hybrid taxa in Nicotiana (Solanaceae). Ann Bot (Lond) 92: 107–127.
[17]	Clarkson JJ, Kelly LJ, Leitch AR, Knapp S, Chase MW (2010) Nuclear glutamine synthetase evolution in Nicotiana: Phylogenetics and the origins of allotetraploid and homoploid (diploid) hybrids. Mol Phylogenet Evol 55: 99–112.
[18]	DeVerna JW, Myers JR, Collins GB (1987) Bypassing prefertilization barriers to hybridization in Nicotiana using in vitro pollination and fertilization. Theor Appl Genet 73: 665–671.
[19]	Inoue E, Marubashi W, Niwa M (1994) Simple method for overcoming the lethality observed in the hybrid between Nicotiana suaveolens and N. tabacum. Breed Sci 44: 333–336.
[20]	Inoue E, Marubashi W, Niwa M (1996) Genomic factors controlling the lethality exhibited in the hybrid between Nicotiana suaveolens Lehm. and N. tabacum L. Theor Appl Genet 93: 341–347.
[21]	Marubashi W, Kobayashi M (2002) Temperature-dependent apoptosis detected in hybrids between Nicotiana debneiyi and N. tabacum expressing lethality. Plant Biotechnol 19: 267–270.
[22]	Tezuka T, Kuboyama T, Matsuda T, Marubashi W (2010) Seven of eight species in Nicotiana section Suaveolentes have common factors leading to hybrid lethality in crosses with Nicotiana tabacum. Ann Bot 106: 267–276.
[23]	Laskowska D, Berbe？ A (2012) Production and characterization of amphihaploid hybrids between Nicotiana wuttkei Clarkson et Symon and N. tabacum L. Euphytica. 183: 75–82.
[24]	Marubashi W, Onosato K (2002) Q chromosome controls the lethality of interspecific hybrids between Nicotiana tabacum and N. suaveolens. Breed Sci 52: 137–142.
[25]	Tezuka T, Marubashi W (2006) Genomic factors lead to programmed cell death during hybrid lethality in interspecific hybrids between Nicotiana tabacum and N. debneyi. SABRAO J Breed Genet 38: 69–81.
[26]	Tezuka T, Marubashi W (2006) Hybrid lethality in interspecific hybrids between Nicotiana tabacum and N. suaveolens: Evidence that the Q chromosome causes hybrid lethality based on Q-chromosome-specific DNA markers. Theor Appl Genet 112: 1172–1178.
[27]	Tezuka T, Kuboyama T, Matsuda T, Marubashi W (2007) Possible involvement of genes on the Q chromosome of Nicotiana tabacum in expression of hybrid lethality and programmed cell death during interspecific hybridization to Nicotiana debneyi. Planta 226: 753–764.
[28]	Matsuo C, Iizuka T, Marubashi W, Oda M, Tezuka T (2011) Identification of the chromosome responsible for hybrid lethality in interspecific hybrids (Nicotiana tabacum×N. ingulba) by Q-chromosome-specific SSR markers. Breed Res 13 (Suppl. 1)90 (in Japanese)..
[29]	Bindler G, Plieske J, Bakaher N, Gunduz I, Ivanov N (2011) A high-density genetic map of tobacco (Nicotiana tabacum L.) obtained from large scale microsatellite marker development. Theor Appl Genet 123: 219–230.
[30]	Tezuka T, Matsuo C, Iizuka T, Oda M, Marubashi W (2012) Identification of Nicotiana tabacum linkage group corresponding to the Q chromosome gene(s) involved in hybrid lethality. PLoS One 7: e37822.
[31]	Iizuka T, Kuboyama T, Marubashi W, Oda M, Tezuka T (2012) Nicotiana debneyi has a single dominant gene causing hybrid lethality in crosses with N. tabacum. Euphytica 186: 321–328.
[32]	Clarkson JJ, Knapp S, Garcia VF, Olmstead RG, Leitch AR, et al. (2004) Phylogenetic relationships in Nicotiana (Solanaceae) inferred from multiple plastid DNA regions. Mol Phylogenet Evol 33: 75–90.
[33]	Clarkson JJ, Lim KY, Kovarik A, Chase MW, Knapp S, et al. (2005) Long-term genome diploidization in allopolyploid Nicotiana section Repandae (Solanaceae). New Phytol 168: 241–252.
[34]	Leitch IJ, Hanson L, Lim KY, Kovarik A, Chase MW, et al. (2008) The ups and downs of genome size evolution in polyploid species of Nicotiana (Solanaceae). Ann Bot (Lond) 101: 805–814.
[35]	Parisod C, Mhiri C, Lim KY, Clarkson J, Chase MW, et al. (2012) Differential dynamics of transposable elements during long-term diploidization of Nicotiana section Repandae (Solanaceae) allopolyploid genomes. PLoS One 7: e50352.
[36]	Reed SM, Collins GB (1978) Interspecific hybrids in Nicotiana through in vitro culture of fertilized ovules. J Hered 69: 311–315.
[37]	Kobori S, Marubashi W (2004) Programmed cell death detected in interspecific hybrids of Nicotiana repanda×N. tomentosiformis expressing hybrid lethality. Breed Sci 54: 347–350.
[38]	Liu H, Hoshio M, Masaki Y, Mori Y, Marubashi W (2013) Hybrid lethality with programmed cell death results from reciprocal interspecific crosses between Nicotiana nudicaulis Watson and N. tabacum L. Plant Biotechnol. 30: 179–184.
[39]	Liu H, Mabubashi W (2013) Identification of genomic factors responsible for hybrid lethality in hybrids between Nicotiana nudicaulis Watson and N. tabacum L. Plant Biotechnol. 30: 347–355.
[40]	Olmo HP (1935) Genetical studies of monosomic types of Nicotiana tabacum. Genetics 20: 286–300.
[41]	Clausen RE, Cameron DR (1944) Inheritance in Nicotiana tabacum. XVIII. Monosomic analysis. Genetics 29: 447–477.
[42]	Kerr JFR, Wyllie AH, Currie AR (1972) Apoptosis: a basic biological phenomenon with wide-ranging implications in tissue kinetics. Br J Cancer 26: 239–257.
[43]	Wylie AH, Morris RG, Smith AL, Dunlop D (1984) Chromatin cleavage in apoptosis: Association with condensed chromatin morphology and dependence on macromolecular synthesis. J Pathol 142: 67–77.
[44]	Cohen JJ (1993) Overview: Mechanisms of apoptosis. Immunol Today 14: 126–130.
[45]	Ziv M (1991) Quality of micropropagated plants–vitrification. In Vitro Cell Dev Biol 27: 64–69.
[46]	Chung SC, Nakajima T, Takeda D (1988) Interspecific hybridization between Nicotiana trigonophylla Dun. and N. tabacum L. through ovule culture. Jpn J Breed 38: 319–326.
[47]	Murashige T, Skoog F (1962) A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiol Plant 15: 473–497.
[48]	Marubashi W, Nakajima T (1985) Overcoming cross-incompatibility between Nicotiana tabacum L. and N. rustica L. by test tube pollination and ovule culture. Jpn J Breed 35: 429–437.
[49]	Murray MG, Thompson WF (1980) Rapid isolation of high molecular weight plant DNA. Nucleic Acids Res 8: 4321–4325.
[50]	Michaelson MJ, Price HJ, Ellison JR, Johnston JS (1991) Comparison of plant DNA contents determined by Feulgen microspectrophotometry and laser flow cytometry. Am J Bot 78: 183–188.
[51]	Debergh PC, Harbaoui Y, Lemeur R (1981) Mass propagation of globe artichoke: evaluation of different hypotheses to overcome vitrification with special reference to water potential. Physiol Plant 53: 181–187.
[52]	Debergh PC (1983) Effects of agar brand and concentration on the tissue culture medium. Physiol Plant 59: 270–276.
[53]	Hakkaart FA, Versluijs JMA (1983) Some factors affecting glassiness in carnation meristem tip culture. Neth J Plant Pathol 89: 47–53.
[54]	Pasqualetto PL, Zimmerman RH, Fordham I (1986) Gelling agent and growth regulator effects on shoot vitrification of Gala apple in vitro. J Am Soc Hortic Sci 111: 976–980.
[55]	Ziv M, Meir G, Halevy AH (1983) The development of glaucous hardened carnation plants in vitro. Plant Cell Tissue Organ Cult 2: 55–65.
[56]	Zimmerman TW, Cobb BG (1989) Vitrification and soluble carbohydrate levels in petunia leaves as influenced by media Gelrite and sucrose concentrations. Plant Cell Rep 8: 358–360.
[57]	Leitch IJ, Bennett MD (2004) Genome downsizing in polyploid plants. Biol J Linn Soc 82: 651–663.
[58]	Renny-Byfield S, Kovarik A, Kelly LK, Macas J, Novak P, et al. (2013) Diploidization and genome size change in allopolyploids is associated with differential dynamics of low- and high-copy sequences. Plant J 74: 829–839.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133