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Disease resistance. Stem Rust Resistance.

Sr2

Contributed by W. Spielmeyer, R. Mago, E.S. Lagudah, J. Ellis (CSIRO Plant Industry, Canberra, Australia)

Markers for Sr2

Sr2 is a stem rust resistance gene that has been used in breeding for around 60 years as a source of durable and broad-spectrum adult plant resistance, which includes resistance to Ug99 and its related isolates. Sr2 is located on the short arm of chromosome 3B and confers partial resistance only in the homozygous state (recessive resistance gene). It was originally transferred from Yaroslav emmer wheat into hexaploid wheat.

Traditional breeding with Sr2 has been difficult because of its recessive nature and the fact that its phenotype is only evident at the adult plant stage and can be influenced by the genetic background and the environment. One partially dominant morphological marker linked to Sr2, pseudo-black chaff (PBC), has been used for years in breeding programs. PBC is a dark pigmentation that occurs on the glumes, peduncle and below stem internodes, but its levels of expression vary with genetic backgrounds and environments. In 2003 Spielmeyer et al (1) determined that a 120-bp allele of the microsatellite locus Xgwm533 was tightly linked to Sr2 in several lines. This marker is complicated to use because there are two different Xgwm533 on 3BS: several lines that did not carry Sr2 also amplified a 120-bp product for Xgwm533, which actually was another SSR allele that differed in sequence. Hayden et al (2) developed sequence-tagged microsatellites (STM) markers that could differentiate between the different Xgwm533 variants. Later, McNeil et al (3) using physically ordered BAC clones near Sr2 found three new SSR loci that mapped closer to Sr2 than Xgwm533 did, but they were quite polymorphic among lines with or without the resistance gene. Some of them could be useful for breeding but in any case a careful check of the parents is needed.

Also, a set of KASP markers was developed in 2013. The information on the primers needed is detailed at the bottom of this section below, along with the expected polymorphisms.

The CAPS marker presented here, csSr2, was derived from the Sr2 locus and detects three different alleles of Sr2 with a high accuracy (Fig. 1):

  1. ‘null’ allele or lack of amplification, associated with most Australian non-Sr2 wheats
  2. Marquis type allele:  Two fragments (225 bp and 112 bp) after amplification and cutting with the appropriate restriction enzyme (BspHI). This allele is associated with non-Sr2 wheats prevalent in North America and CIMMYT.
  3. Hope type allele: Three fragments (172 bp, 112 bp and 53 bp) after amplification and cutting with BspHI enzyme. This allele is associated with the presence of Sr2.
Primers sequences:
   csSr2-F   5'- CAA GGG TTG CTA GGA TTG GAA AAC -3’
   csSr2-R   5'- AGA TAA CTC TTA TGA TCT TAC ATT TTT CTG -3’   
PCR conditions:
PCR mix and CAPS conditions

Reaction volume: 20µl

For CAPS analysis an additional 5µl of a mix consisting of 2.5ml of 10x NEB buffer 4 and 0.5µl of BspHI (10U/µl; NEB) was added once the PCR was completed and the tubes incubated at 37° for 1 hour.

Expected products and validation

The CAPS product was separated on a 2.5% (w/v) agarose gel (Fig.1). csSr2 was tested on 122 diverse wheat lines from around the world including 78 Australian past and present cultivars (Table 1). The marker is associated with the presence or absence of the gene in 95% of the lines tested. Its accuracy increased to 100% in lines that were considered to lack Sr2. Potential discrepancies were observed in a few lines that were predicted to carry Sr2 but failed to show the CAPS marker. It is possible that some lines presumed to carry Sr2, were wrongly classified and lack the gene and that these lines were correctly identified as such by the marker. It is also not uncommon that wheat varieties released by breeders consist of mixtures and are heterogenous for important traits such as disease resistance or seed storage proteins. Alternatively, the marker associated with resistance may have mutated or recombined with the gene and is therefore not diagnostic for Sr2 in these lines. Future genetic studies of populations derived from these lines could clarify if the marker lacked accuracy or if wheat lines were wrongly classified.

scSr2
Figure 1. Alleles of csSr2: Three alleles detected by csSr2: Lanes 1 and 3 show the ‘null’ allele, lanes 4, 6, 7 and 8 show the Marquis type allele and lanes 2, 5 and 9 show the Hope type allele.

 

Table 1. Allele survey of diverse wheat germplasm with known (or presumed) Sr2 status using SSR marker gwm533 and CAPS marker csSr2
Country Wheat line
Sr2 resistance
gwm533 allele
csSr2 allele
BspHI SNP
Australia  
  Angas
-
120
null
  Aroona
-
120
null
  Arrino
-
155
null
  Babbler
-
null
null
  Banks
-
null
null
  Bindawarra
-
120
+
-
  Brookton
-
155
null
  Braewood
-
120
null
  Cadoux
-
null
null
  Camm
-
null
null
  Chara
-
null
null
  Cocomba
-
null
null
  Condor
-
null
null
  Cook
-
null
null
  Currawong
-
null
null
  Dagger
-
155
null
  Datatine
-
null
  Ega-hume
-
null
null
  Ega-Jaegar
-
null
null
  Federation
-
155
null
  Frame
-
155
null
  Gabo
-
120
null
  Gladius
-
120
null
  Grebe
-
null
null
  Gutha
-
null
null
  H45
-
null
null
  Halberd
-
155
null
  Janz
-
null
null
  Katunga
-
155
null
  Kelalac
-
null
null
  Kite
-
null
null
  Krichauff 
-
120
null
  Meering
-
null
null
  Mitre
-
null
null
  Molineux
-
120
null
  Oxley
-
null
null
  Perouse
-
null
null
  Qual2000
-
null
  Quarrion
-
null
null
  Rosella
-
null
null
  Spear
-
155
null
  Stiletto
-
155
null
  Sunland
-
null
null
  Sunvale
-
null
null
  Swift
-
null
null
  Tasman
-
120
null
  Tincurrin
-
null
  Trident
-
155
null
  Westonia
-
120
null
  Wyalkatchem
-
120
null
  Yaralinka
-
120
null
  Yitpi
-
155
null
  Baxter
+
120
+
+
  Brennan
+
120
+
+
  Carnamah
+
120
+
+
  Crusader
+
+
+
  Derrimut
+
120
+
-
  Diamondbird
+
120
+
+
  Dollarbird
+
120
+
+
  Drysdale
+
120
+
+
  Ega-Wiley
+
120
+
+
  Ellison
+
120
+
-
  Eradu
+
120
+
+
  Hartog
+
120
+
+
  Houtman
+
120
+
+
  Kukri
+
120+155
+
-
  Leichardt
+
120
null
  Longreach crus
+
120
+
+
  Lowan
+
120
+
+
  Machete
+
120
+
+
  Pelsart
+
120
+
+
  Rowan
+
120
+
+
  Sunbrook
+
120
+
+
  Suneca
+
120
+
+
  Sunstate
+
120
+
+
  Sunzell
+
120
+
+
  Timgalen
+
120
+
+
  Cranbrook
+
120
+
+
  Ventura
+
120
+
+
North America  
Canada  
  Glenlea
-
120
null
  Marquis
-
120
+
-
  RL-6058
-
120
+
-
  RL-6071
-
120
+
-
  Thatcher
-
120
+
-
  Lancer
+
120
+
+
  Pembina
+
120
+
+
  Redman
+
120
+
+
  Renown
+
120
+
+
  Selkirk
+
120
+
+
USA  
  Langdon
-
null
null
  Abe
-
null
+
-
  Arthur
+
+
+
  Arthur71
+
120
+
-
  Yaroslav emmer
+
120
+
+
  Hope
+
120
+
+
  Oasis
+
120
+
+
  Ottawa
+
120
+
+
  Scout
+
120
+
+
  Sullivan
+
120
+
+
CIMMYT  
  Anza
-
null
null
  Avocet
-
155
null
  Bluebird
+
+
+
  Ciano67
+
120
+
+
  Kingbird
+
+
+
  Kiritati
+
+
+
  Lerma Rojo
+
120
+
+
  Nuri70
+
120
+
+
  Opata
-
120
+
-
  Parula
+
120
+
+
  Pastor
+
+
-
  Pavon76
+
120
+
+
  Siete-Cerros
+
120
+
-
Others  
Brazil Frontana
+
+
+
Chile Forno
-
120
+
-
China Chinese Spring
-
155
null
India Sonalika
+
120
+
+
Kenya Kenya Page
+
120
+
+
  Kenya Plume
+
120
+
-
UK Excalibur
-
155
null


KASP markers for Sr2 .

Information kindly provided by Gina Brown Guedira.

SNP ID

wMAS000005

Gene

Sr2

Evidence

linked

Primer Allele FAM

GTGCGAGACATCCAACACTCAC

Primer Allele VIC

GTGCGAGACATCCAACACTCAT

Primer Common

CTCAAATGGTCGAGCACAAGCTCTA

FAM allele

G

VIC allele

A

FAM phenotype

susceptible

VIC phenotype

resistant

This markers were developed based on the work of Mago et al. (4). For more information on KASP protocols, please check visit this link.

Conditions presented here should be considered only as a starting point of the PCR optimization for individual laboratories.

References

1. Identification and validation of markers linked to broad-spectrum stem rust resistance gene Sr2 in wheat (Triticum aestivum L.). Spielmeyer W, Sharp PJ, Lagudah ES. In: Crop Science, 2003, 43:333–336. DOI:10.2135/cropsci2003.0333.

2. Sequence tagged microsatellites for the Xgwm533 locus provide new diagnostic markers to select for the presence of stem rust resistance gene Sr2 in bread wheat (Triticum aestivum L.). Hayden MJ, Kuchel H, Chalmers KJ. In:Theoretical and Applied Genetics, 2004, 109:1641–1647. DOI:10.1007/s00122-004-1787-5.

3. BAC-derived markers for assaying the stem rust resistance gene, Sr2, in wheat breeding programs. McNeil MD,  Kota R,  Paux E,  Dunn D,  McLean R,   Feuillet C, Li D,   Kong X,  Lagudah E,  Zhang JC, Jia JZ,  Spielmeyer W, Bellgard M,  Appels R. In: Molecular Breeding, 2008, 22:15–24. DOI:10.1007/s11032-007-9152-4.

4. An accurate DNA marker assay for stem rust resistance gene Sr2 in wheat. Mago R, Brown-Guedira G, Dreisigacker S, Breen J, Jin Y, Singh R, Appels R, S. Lagudah ES, Ellis J, Spielmeyer W. In: Theoretical and Applied Genetics, 2011, 122:735-744. DOI:0.1007/s00122-010-1482-7.


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