Genomic regions influencing resistance to the parasitic weed Striga hermonthica in two recombinant inbred populations of sorghum

Haussmann, Bettina I. G.; Hess, D. E.; Omanya, G.; Folkertsma, R.T.; Reddy, Belum V. S.; Kayentao, M.; Welz, H. G.; Geiger, H. H.

doi:10.1007/s00122-004-1706-9

Cited by 102 publications

(140 citation statements)

References 40 publications

(41 reference statements)

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“…These accessions may be useful potential sources of resistance to Striga as such or in a backcross breeding program. It would be interesting to confirm whether the mechanical type of Striga resistance that has been mapped using Quantitative Trait Loci (QTL) and reported elsewhere [10] would be found in genotypes with low stimulants production. In order to consolidate this resistance, these accessions of low stimulant production could be crossed with the already identified backcrosses with intro-gressed Striga resistance QTL from a previous study [6].…”

Section: Resultsmentioning

confidence: 99%

“…Several mechanisms of resistance to Striga in sorghum have been reported that probably operate singly or in various combinations [9] [10]. Using in-vitro laboratory techniques, four specific mechanisms of resistance to Striga which included low production of germination stimulant, low production of the haustoria initiation factor, hypersensi-tive response, and incompatible response were reported in cultivated sorghums and some wild accessions [5] [11].…”

Section: Introductionmentioning

confidence: 99%

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Genotypic Variation for Low Striga Germination Stimulation in Sorghum “<i>Sorghum bicolor</i> (L.) Moench” Landraces from Eritrea

Yohannes¹,

Ngugi²,

Ariga³

et al. 2016

AJPS

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Sorghum (Sorghum bicolour (L.) Moench), the second most important staple crop in Sub-Saharan Africa (SSA) after maize, is well adapted to marginal environments of drought stress and high temperatures. But besides drought stress, the obligate root-parasitic flowering plant Striga hermonthica is an equally economically important biotic stress in agro-ecological zones where soils are marginal. Notwithstanding widespread and intense Striga infestation, genetic variations in defence mechanisms against the parasite have been reported. Sorghum variants, producing low levels of chemical stimulants such as sorgolactones that deter the advance of Striga seed germination and are therefore deemed resistant to the parasite, have been also reported in a few studies. But the existence of sorghum genetic variation for this resistance especially among farmers' landraces is yet to be demonstrated. The objective of this study was therefore to determine the levels of Striga germination stimulants in response to each of the 111 collected sorghum landraces and their progenies from Eritrea. The ability of a sorghum genotype to cause germination of a Striga seed as a measure of the amount of the germination stimulant produced was used to assess the resistance of these accessions. The data were recorded as Striga germination percentage by counting the number of germinated Striga seeds. Landraces EG47, EG1261, EG830, EG1076, EG54 and EG746 with 14.68%, 15.32%, 11.85%, 13.05%, 15.74% and 16.5% germination percentages respectively were found to stimulate low levels of Striga germination percentage compared to commercial checks, IS9830, SRN39, Framida, with 22.46%, 22.67%, 23.27% germination respectively. While these variants did not show complete resistance against Striga seed germination, the low level How to cite this paper: Yohannes, T., Ngugi, K., Ariga, E., Abraha, T., Yao, N., Asami, P. and Ahonsi, M. 2471production of stimulant indicated their high level of resistance to Striga. These results implied that these accessions are likely potential sources of resistance against Striga infestation in SSA sorghum breeding programs.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Genotypic Variation for Low Striga Germination Stimulation in Sorghum “<i>Sorghum bicolor</i> (L.) Moench” Landraces from Eritrea

Yohannes¹,

Ngugi²,

Ariga³

et al. 2016

AJPS

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“…QTL mapping for Striga resistance has resulted in identification of many genes/QTLs spread across the genome. Haussmann et al (2004) mapped several QTLs for Striga resistance in sorghum and reported 9 and 11 QTLs explaining respectively 77% and 82% of the phenotypic variation in a recombinant inbred line (RIL) population. The most significant QTL has been identified to correspond to the major gene locus lgs, which was recently fine-mapped on the chromosome 5 (Satish et al, 2012).…”

Section: Marker-assisted Selectionmentioning

confidence: 99%

Striga

Kountche

Al‐Babili

Haussmann

2016

Biotic Stress Resistance in Millets

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“…The invention of molecular markers has enhanced the effectiveness of breeding for resistance. Five genomic regions (QTLs) with linked markers associated with Striga resistance were mapped in sorghum variety N13 by [10]. In this study, to increase the efficiency of marker-assisted selection (MAS), 27 EST-SSR markers in close association with Striga resistance QTLs were also identified and mapped.…”

Section: Introductionmentioning

confidence: 99%

“…In the past, five QTLs underlying different Striga resistant phenotypes and molecular SSR markers associated with specific region have been identified and assigned to their specific chromosomal location [10]. These regions and associated SSR markers have been used in advanced backcross populations allowing exploitation of diverse resistance sources [20].…”

Section: Introductionmentioning

confidence: 99%

First products of DNA marker-assisted selection in sorghum released for cultivation by farmers in sub-saharan Africa

Mohamed¹,

Ali²,

Elhassan³

et al. 2014

J Plant Sci Mol Breed

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Striga hermonthica (Del.) Benth. is the major biotic constraint to sorghum production. Its control is difficult and can only be achieved through integrated management strategies that depend mainly on host plant resistance and enhanced soil fertility. However, breeding for resistance is hampered by the complexity of host parasite interactions and lack of reliable screening methods. The invention of molecular markers has enhanced the effectiveness of breeding for resistance. Five genomic regions (QTLs) with linked markers associated with Striga resistance were mapped in sorghum variety N13 by [10]. In this study, to increase the efficiency of marker-assisted selection (MAS), 27 EST-SSR markers in close association with Striga resistance QTLs were also identified and mapped. Populations of backcross (BC 3 S 4 ) derived from N13 (Striga resistant) X three farmer preferred sorghum cultivars: Tabat, Wad Ahmed and AG-8 (Striga susceptible) were generated. Thirty-one lines (BC 3 S 4 ) with confirmed Striga field resistance were genotyped with foreground and background selection makers. Twenty resistant lines, with two or more major QTLs were selected for regional evaluation. Of these 10 lines were selected and advanced for multi-location testing, together with Wad Ahmed, Tabat, AG-8, N13, SRN39 and IS9830 as checks. Standard variety trials were conducted in Striga sick plots over three seasons (2009)(2010)(2011) in Sudan, Gezira Research Station, Damazine, Sinnar, and Gedarif. Results revealed that four lines (T1BC 3 S 4 , AG6BC 3 S 4 , AG2BC 3 S 4 and W2BC 3 S 4 ) were Striga resistant and agronomically superior with yields ranging from 180% to 298% higher relative to their recurrent parents. This Striga resistance coupled with superior attributes of the recurrent parent (including very high yield potentials, high grain quality and drought tolerance) will provide adaptation and stability across a wide range of environments. These are the first products of DNA markerassisted selection (MAS) in sorghum released for cultivation by farmers in sub-Saharan Africa.

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Genomic regions influencing resistance to the parasitic weed Striga hermonthica in two recombinant inbred populations of sorghum

Cited by 102 publications

References 40 publications

Genotypic Variation for Low Striga Germination Stimulation in Sorghum “<i>Sorghum bicolor</i> (L.) Moench” Landraces from Eritrea

Genotypic Variation for Low Striga Germination Stimulation in Sorghum “<i>Sorghum bicolor</i> (L.) Moench” Landraces from Eritrea

Striga

First products of DNA marker-assisted selection in sorghum released for cultivation by farmers in sub-saharan Africa

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Genomic regions influencing resistance to the parasitic weed Striga hermonthica in two recombinant inbred populations of sorghum

Cited by 102 publications

References 40 publications

Genotypic Variation for Low Striga Germination Stimulation in Sorghum “&lt;i&gt;Sorghum bicolor&lt;/i&gt; (L.) Moench” Landraces from Eritrea

Genotypic Variation for Low Striga Germination Stimulation in Sorghum “&lt;i&gt;Sorghum bicolor&lt;/i&gt; (L.) Moench” Landraces from Eritrea

Striga

First products of DNA marker-assisted selection in sorghum released for cultivation by farmers in sub-saharan Africa

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Product

Resources

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Genotypic Variation for Low Striga Germination Stimulation in Sorghum “<i>Sorghum bicolor</i> (L.) Moench” Landraces from Eritrea

Genotypic Variation for Low Striga Germination Stimulation in Sorghum “<i>Sorghum bicolor</i> (L.) Moench” Landraces from Eritrea