Abstract
Stem rust resistance genes have been found in four different sources of Aegilops speltoides. These include diploid accessions AEG357-4 and AEG874-60 and the amphiploids Chinese Spring/Ae. speltoides TA8026 and TS01. Stem rust resistance was mapped to the 2S chromosomes derived from each of these lines. The previously reported 2B-2S#3 translocation derived from AEG357-4 was found to carry two stem rust resistance genes, here temporarily named SrAes2t and SrAes3t. The resistance genes found on the 2S chromosomes each derived from TA8026, TS01 and AEG874-60 are named SrAes4t, SrAes5t and SrAes6t, respectively. Lines carrying genes SrAes2t and SrAes3t are being distributed to wheat breeding programs around the world.
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Introduction
The fungal disease stem rust, caused by Puccinia graminis f. sp. tritici, has long been a scourge of wheat crops since the beginnings of agriculture. Uredia have even been found on ancient wheat spikelets estimated at 3,300 years old (Kislev 1982). Recently, the appearance and spread of mutants of the Ug99 stem rust lineage (summarized in Mago et al. 2013) has raised the awareness of the need to search for new resistance genes for use in wheat cultivars. Most of the currently named stem rust genes in wheat originate from related species (e.g., Secale cereale, Triticum monococcum, T. turgidum, T. timopheevii, Thinopyrum ponticum, Aegilops speltoides, Ae. tauschii and Ae. ventricosum). Many of these genes (e.g., Sr2, Sr22, Sr24, Sr26, Sr36 and Sr38) are widely used in agriculture.
The diploid species Ae. speltoides Tausch. (2n = 2x = 14) has provided several resistance genes against stem rust, namely Sr32, Sr39, Sr47, SrAes1t and SrAes7t (summarized in Mago et al. 2013), and leaf rust (caused by P. triticina), namely Lr28, Lr35, Lr36, Lr47, Lr51 and Lr66 (summarized in McIntosh et al. 2013). To date, none of these genes are deployed in agriculture. This work describes the discovery of potentially new stem rust resistance genes in four different sources of Ae. speltoides.
Materials and Methods
Diploid accessions of Aegilops speltoides AEG357-4 and AEG874-60 were provided courtesy of the The Harold and Adele Lieberman Germplasm Bank, Tel Aviv University, Israel. Amphidiploids of Chinese Spring/Ae. speltoides TS01 and TA8026 were provided courtesy of the Weizmann Institute, Rehovot, Israel and Wheat Genetics Resource Center, Kansas State University, USA, respectively.
Diploid Ae. speltoides accessions were crossed with cultivar Angas (from Dr Hugh Wallwork, Urrbrae, Australia) using wheat as the female parent. F1 seedlings were treated with 0.07 % colchicine (described in Dundas et al. 2008). Hybrids were crossed as females with Angas and later with cv. Westonia up to BC5. The amphiploid accessions were crossed with Angas then backcrossed with Westonia as the female parent to BC5.
Identification of backcrossed plants carrying each of the Ae. speltoides S-genome chromosomes using RFLP markers has been described in Dundas et al. (2008). PCR markers for 2S chromosomes were obtained from Mago et al. (2009) (Sr39#22r) and Seyfarth et al. (1999) (35R2/ BCD260F1). Backcrossed lines carrying S-genome chromosomes were tested for stem rust resistance at the University of Sydney (Pgt 34-1,2,3,4,5,6,7) and at Urrbrae (Pgt 343-1,2,3,5,6). Selected lines were screened against Ug99 races TTKSK, TTKST (+Sr24) and TTTSK (+Sr36) at the USDA Cereal Disease Laboratory, St. Paul, USA. Genomic in situ hybridization (GISH) was conducted on mitotic chromosome spreads using the procedure described in Mago et al. (2013).
Results and Discussion
Ae. speltoides AEG357-4
Lines carrying the T2BS-2S#3S.2S#3L-2BL recombinant chromosome derived from AEG357-4 (Dundas et al. 2008) showed the loss of distal Ae. speltoides 2S#3 chromosome segments and the retention of proximal 2S#3 chromosome segments (Figs. 5.1a and 5.2). This line was found to be resistant to stem rust pathotypes Pgt 34-1,2,3,4,5,6,7, Pgt 343-1,2,3,5,6 (Dundas et al. 2008) and TTKST (pers. comm., Professor Z. Pretorius, University of Free State, Bloemfontein, South Africa). After crossing this recombinant line with Sears’ ph1b mutant, we selected five lines derived from a F3 population of 155 seedlings showing confirmed dissociation of RFLP and PCR markers specific for the 2S#3 chromosome (Fig. 5.2). All lines showed resistance to Australian stem rust pathotypes and Ug99 races TTKSK, TTKST and TTTSK (Table 5.1). The dissociation plants #3 and #20 showed only 2S#3S markers indicating that a stem rust resistance gene locates on the short arm of the 2S#3 chromosome (Fig. 5.2). Dissociation plant #27 showed only 2S#3L markers suggesting that a stem rust resistance gene is located on the long arm of the 2S#3 chromosome (Fig. 5.2).
GISH studies on the five stem rust resistant secondary recombinants failed to reveal 2S#3 chromatin, which suggested that very small segments of 2S#3 chromatin were present on these secondary recombinants. We temporarily name the resistance gene on the short arm of the 2S#3 chromosome as SrAes2t and the gene on the long arm as SrAes3t.
Chinese Spring/Ae. speltoides Amphiploid TA8026
Stem rust resistant backcrossed lines derived from TA8026 were isolated which carried only the group 2 long arm RFLP markers BCD111, ABG072 and ABC252 specific for the 2S#4 chromosome. Group 2 short arm probes ABG058, BCD221 and ABC454 did not detect the presence of 2S chromatin. GISH analysis of these lines showed the presence of either a wheat-2S#4L translocation or 2S#4L telocentric chromosome (Fig. 5.1b). The line carrying the telocentric 2S#4L chromosome was resistant to Australian and Ug99 stem rust races (Table 5.1). The stem rust resistance gene on the 2S#4L chromosome has been temporarily named SrAes4t.
Chinese Spring/Ae. speltoides Amphiploid TS01
Backcrossed lines derived from the amphiploid TS01 were isolated which carried group 2 RFLP markers for the probes ABG002, ABC358 and ABC454, the PCR marker Sr39#22r (short arm), and RFLP markers for probes BCD111, ABG072 and PCR marker 35R2/ BCD260F1 (long arm), specific for the 2S#5 chromosome. Rust tests showed these lines to be resistant to Australian stem rust and Ug99 pathotypes (Table 5.1). GISH analysis of the line showed the presence of an apparently entire Ae. speltoides 2S#5 chromosome (Fig. 5.1c). The stem rust resistance gene on that chromosome is here named as SrAes5t.
Ae. speltoides AEG874-60
Dundas et al. (2008) reported that the diploid accession AEG874-60 was resistant to stem rust races Pgt 34-2,12,13, Pgt 34-1,2,3,4,5,6,7 and Pgt 98-1,2,3,5,6. BC5 plants with cv. Westonia were isolated carrying only the 2S#6 chromosome from AEG874-60 and carried Ae. speltoides-specific markers ABG058, BCD221, ABG002, ABG358, ABC454 and Sr39#22r (short arm) and BCD111, ABG072, ABC252 and 35R2/BCD260F1 (long arm). Plants with the 2S#6 chromosome were resistant to stem rust Pgt 34-1,2,3,4,5,6,7 and Pgt 343-1,2,3,5,6 (Table 5.1). GISH analysis showed an entire 2S#6 chromosome present (Fig. 5.1d). The stem rust resistance gene on that chromosome is here named as SrAes6t.
It is unknown if the stem rust resistance genes described herein are different from those previously reported on Ae. speltoides 2S chromosomes (namely Sr32, SrAes1t, SrAes7t, Sr39 and Sr47). Lines carrying the T2BS-2S#3S.2S#3L-2BL chromosome with genes SrAes2t and SrAes3t are being distributed to many wheat breeding programs around the World.
References
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Acknowledgments
This work was partly funded by the Grains Research and Development Corporation (Australia), and the Bill and Melinda Gates Foundation (USA) and DFID (UK) through a sub-agreement with Cornell University (USA). We thank Dr. Moshe Feldman (Weizmann Institute, Rehovot, Israel) for providing seeds of amphiploid TS01.
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Dundas, I., Verlin, D., Zhang, P., Jin, Y., Manisterski, J., Islam, R. (2015). Transfer to Wheat of Potentially New Stem Rust Resistance Genes from Aegilops speltoides . In: Ogihara, Y., Takumi, S., Handa, H. (eds) Advances in Wheat Genetics: From Genome to Field. Springer, Tokyo. https://doi.org/10.1007/978-4-431-55675-6_5
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