Access the full text.
Sign up today, get DeepDyve free for 14 days.
S. Yun, L. Gyenis, P. Hayes, I. Matus, Kevin Smith, B. Steffenson, G. Muehlbauer (2005)
Quantitative Trait Loci for Multiple Disease Resistance in Wild BarleyCrop Science, 45
R. Joehanes, J. Nelson (2008)
QGene 4.0, an extensible Java QTL-analysis platformBioinformatics, 24 23
M. Maroof, S. Scoyoc, Y. Yu, E. Stromberg (1993)
Gray leaf spot disease of maize: rating methodology and inbred line evaluation.Plant Disease, 77
KJ Williams (2003)
The molecular genetics of disease resistance in barleyAust J Agric Res, 54
S. Lim, D. White (1978)
Estimates of heterosis and combining ability for resistance of maize to Colletotrichum graminicola.Phytopathology, 68
S. Flint-Garcia, S. Flint-Garcia, L. Darrah, Michael McMullen, B. Hibbard (2003)
Phenotypic versus marker-assisted selection for stalk strength and second-generation European corn borer resistance in maizeTheoretical and Applied Genetics, 107
S. Milligan, J. Bodeau, Jafar Yaghoobi, I. Kaloshian, P. Zabel, V. Williamson (1998)
The Root Knot Nematode Resistance Gene Mi from Tomato Is a Member of the Leucine Zipper, Nucleotide Binding, Leucine-Rich Repeat Family of Plant GenesPlant Cell, 10
Hui Cao, Xin Li, Xinnian Dong (1998)
Generation of broad-spectrum disease resistance by overexpression of an essential regulatory gene in systemic acquired resistance.Proceedings of the National Academy of Sciences of the United States of America, 95 11
J. Ribaut, M. Ragot (2006)
Marker-assisted selection to improve drought adaptation in maize: the backcross approach, perspectives, limitations, and alternatives.Journal of experimental botany, 58 2
Vladimir Kanazin, Laura Marek, R. Shoemaker (1996)
Resistance gene analogs are conserved and clustered in soybean.Proceedings of the National Academy of Sciences of the United States of America, 93 21
R. Wisser, S. Murray, J. Kolkman, H. Ceballos, R. Nelson (2008)
Selection Mapping of Loci for Quantitative Disease Resistance in a Diverse Maize PopulationGenetics, 180
J. Faris, Wanlong Li, D. Liu, Pei-du Chen, B. Gill (1999)
Candidate gene analysis of quantitative disease resistance in wheatTheoretical and Applied Genetics, 98
M. Goodman (2005)
Broadening the U.S. maize germplasm baseMaydica, 50
C. Venard, L. Vaillancourt (2007)
Penetration and colonization of unwounded maize tissues by the maize anthracnose pathogen Colletotrichum graminicola and the related nonpathogen C. sublineolum.Mycologia, 99
M. Dickinson, David Jones, Jonathan Jones (1993)
Close linkage between the Cf-2/Cf-5 and Mi resistance loci in tomato.Molecular plant-microbe interactions : MPMI, 6 3
T Weldekidan, JA Hawk (1993)
Inheritance of anthracnose stalk rot resistance in maizeMaydica, 38
M. Carson (1998)
Aggressiveness and Perennation of Isolates of Cochliobolus heterostrophus from North Carolina.Plant disease, 82 9
P. Freymark, Michael Lee, W. Woodman, C. Martinson (1993)
Quantitative and qualitative trait loci affecting host-plant response to Exserohilum turcicum in maize (Zea mays L.)Theoretical and Applied Genetics, 87
H. Welz, X. Xia, P. Bassetti, A. Melchinger, T. Lübberstedt (1999)
QTLs for resistance to Setosphaeria turcica in an early maturing Dent×Flint maize populationTheoretical and Applied Genetics, 99
Jianming Yu, J. Holland, M. McMullen, E. Buckler (2008)
Genetic Design and Statistical Power of Nested Association Mapping in MaizeGenetics, 178
C. López, I. Acosta, C. Jara, F. Pedraza, Eliana Gaitán-Solís, G. Gallego, S. Beebe, J. Tohme (2003)
Identifying resistance gene analogs associated with resistances to different pathogens in common bean.Phytopathology, 93 1
J. Borevitz, J. Chory (2004)
Genomics tools for QTL analysis and gene discovery.Current opinion in plant biology, 7 2
J. Poland, R. Nelson (2011)
In the eye of the beholder: the effect of rater variability and different rating scales on QTL mapping.Phytopathology, 101 2
R. Wisser, J. Kolkman, M. Patzoldt, J. Holland, Jianming Yu, M. Krakowsky, R. Nelson, P. Balint-Kurti (2011)
Multivariate analysis of maize disease resistances suggests a pleiotropic genetic basis and implicates a GST geneProceedings of the National Academy of Sciences, 108
V. Njiti, T. Doubler, R. Suttner, L. Gray, P. Gibson, D. Lightfoot (1998)
Resistance to Soybean Sudden Death Syndrome and Root Colonization by Fusarium solani f. sp. glycine in Near‐Isogenic LinesCrop Science, 38
S. Mideros, G. Windham, W. Williams, R. Nelson (2009)
Aspergillus flavus Biomass in Maize Estimated by Quantitative Real-Time Polymerase Chain Reaction Is Strongly Correlated with Aflatoxin Concentration.Plant disease, 93 11
Michael McMullen, S. Kresovich, Hector Villeda, Peter Bradbury, Huihui Li, Qi Sun, S. Flint-Garcia, Jeffry Thornsberry, Charlotte Acharya, Christopher Bottoms, Patrick Brown, C. Browne, M. Eller, Katherine Guill, Carlos Harjes, Dallas Kroon, N. Lepak, S. Mitchell, Brooke Peterson, G. Pressoir, Susan Romero, Marco Rosas, S. Salvo, Heather Yates, Mark Hanson, Elizabeth Jones, Stephen Smith, J. Glaubitz, M. Goodman, Doreen Ware, James Holland, E. Buckler (2009)
Genetic Properties of the Maize Nested Association Mapping PopulationScience, 325
J. Pataky, M. Bohn, J. Lutz, P. Richter (2008)
Selection for quantitative trait loci associated with resistance to Stewart's wilt in sweet corn.Phytopathology, 98 4
M. Tuinstra, G. Ejeta, P. Goldsbrough (1997)
Heterogeneous inbred family (HIF) analysis: a method for developing near-isogenic lines that differ at quantitative trait lociTheoretical and Applied Genetics, 95
Chia-Lin Chung, J. Longfellow, E. Walsh, Zura Kerdieh, G. Esbroeck, P. Balint-Kurti, R. Nelson (2010)
Resistance loci affecting distinct stages of fungal pathogenesis: use of introgression lines for QTL mapping and characterization in the maize - Setosphaeria turcica pathosystemBMC Plant Biology, 10
Yunbi Xu, J. Crouch (2008)
Marker-Assisted Selection in Plant Breeding: From Publications to PracticeCrop Science, 48
J. Keurentjes, L. Bentsink, C. Alonso‐Blanco, C. Hanhart, H. Vries, S. Effgen, D. Vreugdenhil, M. Koornneef (2007)
Development of a Near-Isogenic Line Population of Arabidopsis thaliana and Comparison of Mapping Power With a Recombinant Inbred Line PopulationGenetics, 175
H. Welz, H. Geiger (2000)
Genes for resistance to northern corn leaf blight in diverse maize populations.Plant Breeding, 119
C. Venard, L. Vaillancourt (2007)
Colonization of Fiber Cells by Colletotrichum graminicola in Wounded Maize Stalks.Phytopathology, 97 4
D. Zaitlin, S. Demars, M. Gupta (1992)
Linkage of a second gene for NCLB resistance to molecular markers in maize, 66
J Lee, B Hardin (1997)
GEM searches for treasures in exotic maizeAgric Res, 45
S. Szalma, B. Hostert, J. LeDeaux, C. Stuber, J. Holland (2007)
QTL mapping with near-isogenic lines in maizeTheoretical and Applied Genetics, 114
Shizhong Xu (2003)
Estimating polygenic effects using markers of the entire genome.Genetics, 163 2
P. Balint‐Kurti, Michael Blanco, M. Millard, S. Duvick, J. Holland, M. Clements, R. Holley, M. Carson, M. Goodman (2006)
Registration of 20 GEM Maize Breeding Germplasm Lines Adapted to the Southern USACrop Science, 46
D. Bubeck, M. Goodman, W. Beavis, D. Grant (1993)
Quantitative trait loci controlling resistance to gray leaf spot in maize.Crop Science, 33
M. Pumphrey, R. Bernardo, J. Anderson (2007)
Validating the Fhb1 QTL for fusarium head blight resistance in near-isogenic wheat lines developed from breeding populationsCrop Science, 47
K. Simcox, J. Bennetzen (1993)
The use of molecular markers to study Setosphaeria turcica resistance in maizePhytopathology, 83
G. Yousef, J. Juvik (2001)
Comparison of Phenotypic and Marker-Assisted Selection for Quantitative Traits in Sweet CornCrop Science, 41
E. Buckler, J. Holland, Peter Bradbury, C. Acharya, P. Brown, C. Browne, E. Ersoz, S. Flint-Garcia, Arturo Garcia, J. Glaubitz, M. Goodman, Carlos Harjes, Katherine Guill, Dallas Kroon, S. Larsson, N. Lepak, Huihui Li, S. Mitchell, G. Pressoir, Jason Peiffer, Marco Rosas, T. Rocheford, M. Romay, Susan Romero, S. Salvo, Hector Villeda, H. Silva, Qi Sun, Feng Tian, N. Upadyayula, D. Ware, Heather Yates, Jianming Yu, Zhiwu Zhang, S. Kresovich, M. McMullen (2009)
The Genetic Architecture of Maize Flowering TimeScience, 325
Guijuan Wang, Yu Chen, Jiufeng Zhao, Lin Li, S. Korban, Feng Wang, Jiansheng Li, J. Dai, Mingliang Xu (2007)
Mapping of Defense Response Gene Homologs and Their Association with Resistance Loci in MaizeJournal of Integrative Plant Biology, 49
A. Schechert, H. Welz, H. Geiger (1999)
QTL for Resistance to Setosphaeria turcica in Tropical African MaizeCrop Science, 39
Wanlong Li, J. Faris, J. Chittoor, J. Leach, S. Hulbert, D. Liu, Pei-du Chen, B. Gill (1999)
Genomic mapping of defense response genes in wheatTheoretical and Applied Genetics, 98
A. Kraja, John Dudley, Donald White (2000)
Identification of tropical and temperate Maize populations having favorable alleles for disease resistanceCrop Science, 40
(2006)
The plant immune system
M. Zuber (1981)
Effect of Anthracnose Leaf Blight on Stalk Rind Strength and Yield in F1Single Crosses in MaizePlant Disease, 65
S. Alvarez, Jason Goodger, E. Marsh, Sixue Chen, V. Asirvatham, D. Schachtman (2006)
Characterization of the maize xylem sap proteome.Journal of proteome research, 5 4
T. Helentjaris, B. Burr (1989)
Development and Application of Molecular Markers to Problems in Plant Genetics
E. Hilaire, Scott Young, L. Willard, J. Mcgee, Teresa Sweat, J. Chittoor, J. Guikema, J. Leach (2001)
Vascular defense responses in rice: peroxidase accumulation in xylem parenchyma cells and xylem wall thickening.Molecular plant-microbe interactions : MPMI, 14 12
S. Krattinger, E. Lagudah, W. Spielmeyer, R. Singh, J. Huerta-Espino, H. Mcfadden, E. Bossolini, L. Selter, B. Keller (2009)
A Putative ABC Transporter Confers Durable Resistance to Multiple Fungal Pathogens in WheatScience, 323
S. Kaeppler (1997)
Quantitative trait locus mapping using sets of near-isogenic lines: relative power comparisons and technical considerationsTheoretical and Applied Genetics, 95
Liping Zhang, A. Khan, D. Niño-Liu, M. Foolad (2002)
A molecular linkage map of tomato displaying chromosomal locations of resistance gene analogs based on a Lycopersicon esculentum x Lycopersicon hirsutum cross.Genome, 45 1
N. Keller, G. Bergstrom (1988)
Developmental predisposition of maize to anthracnose stalk rotPlant Disease, 72
M. Dixon, K. Hatzixanthis, David Jones, K. Harrison, Jonathan Jones (1998)
The Tomato Cf-5 Disease Resistance Gene and Six Homologs Show Pronounced Allelic Variation in Leucine-Rich Repeat Copy NumberPlant Cell, 10
E. Pahlich, Chr. Gerlitz (1980)
A rapid DNA isolation procedure for small quantities of fresh leaf tissuePhytochemistry, 19
Y. Jo, R. Barker, W. Pfender, S. Warnke, S. Sim, G. Jung (2008)
Comparative analysis of multiple disease resistance in ryegrass and cereal cropsTheoretical and Applied Genetics, 117
O. Loudet, Virginie Gaudon, A. Trubuil, F. Daniel-vedele (2005)
Quantitative trait loci controlling root growth and architecture in Arabidopsis thaliana confirmed by heterogeneous inbred familyTheoretical and Applied Genetics, 110
RD Wilcoxson, AH Atif, B Skovmand (1974)
Slow rusting of wheat varieties in the field correlated with stem rust severity on detached leaves in the greenhousePlant Dis Rep, 58
A. Edreva, D. Kostoff (2005)
PATHOGENESIS-RELATED PROTEINS: RESEARCH PROGRESS IN THE LAST 15 YEARS
J. Ramalingam, C. Cruz, K. Kukreja, Jaishree Chittoor, Jian-li Wu, Sulgi Lee, M. Baraoidan, M. George, M. Cohen, S. Hulbert, J. Leach, H. Leung (2003)
Candidate defense genes from rice, barley, and maize and their association with qualitative and quantitative resistance in rice.Molecular plant-microbe interactions : MPMI, 16 1
M. Jung, M. Jung, T. Weldekidan, D. Schaff, A. Paterson, A. Paterson, S. Tingey, J. Hawk (1994)
Generation-means analysis and quantitative trait locus mapping of anthracnose stalk rot genes in maizeTheoretical and Applied Genetics, 89
D. White (1999)
Compendium of corn diseases
S. Szalma, S. Szalma, Edward Buckler, M. Snook, Michael McMullen (2005)
Association analysis of candidate genes for maysin and chlorogenic acid accumulation in maize silksTheoretical and Applied Genetics, 110
Y. Eshed, D. Zamir (1995)
An introgression line population of Lycopersicon pennellii in the cultivated tomato enables the identification and fine mapping of yield-associated QTL.Genetics, 141 3
K. Leonard (1976)
Effects of Temperature and Host Maturity on Lesion Development of Colletotrichum graminicola on CornPhytopathology, 66
S. Balasubramanian, Christopher Schwartz, Anandita Singh, N. Warthmann, M. Kim, J. Maloof, O. Loudet, Gabriel Trainer, T. Dabi, J. Borevitz, J. Chory, D. Weigel (2009)
QTL Mapping in New Arabidopsis thaliana Advanced Intercross-Recombinant Inbred LinesPLoS ONE, 4
R. Wisser, P. Balint-Kurti, R. Nelson (2006)
The genetic architecture of disease resistance in maize: a synthesis of published studies.Phytopathology, 96 2
Jacob Dam, I. Levin, P. Struik, D. Levy (2003)
Identification of epistatic interaction affecting glycoalkaloid content in tubers of tetraploid potato (Solanum tuberosum L.)Euphytica, 134
R. Ming, J. Brewbaker, H. Moon, T. Musket, R. Holley, J. Pataky, M. McMullen (1999)
Identification of RFLP markers linked to a major gene, sw1, conferring resistance to Stewart's wilt in maize.Maydica, 44
Wenming Wang, A. Devoto, J. Turner, Shunyuan Xiao (2007)
Expression of the membrane-associated resistance protein RPW8 enhances basal defense against biotrophic pathogens.Molecular plant-microbe interactions : MPMI, 20 8
Sohei Kobayashi, E. Araki, M. Osaki, G. Khush, Y. Fukuta (2006)
Localization, validation and characterization of plant-type QTLs on chromosomes 4 and 6 in rice (Oryza sativa L.)Field Crops Research, 96
M. Schuelke (2000)
An economic method for the fluorescent labeling of PCR fragmentsNature Biotechnology, 18
S. Wang, X. Xiao (2002)
Isolation and linkage mapping of disease-resistance-like sequences from various rice cultivars, containing different recognition specificitiesPlant Breeding, 121
A. Muimba-Kankolongo, G. Bergstrom (1990)
Transitory wound predisposition of maize to anthracnose stalk rot.Canadian Journal of Plant Pathology-revue Canadienne De Phytopathologie, 12
Hyunggon Mang, K. Laluk, E. Parsons, D. Kosma, B. Cooper, H. Park, Synan AbuQamar, C. Boccongelli, Saori Miyazaki, F. Consiglio, G. Chilosi, H. Bohnert, R. Bressan, T. Mengiste, M. Jenks (2009)
The Arabidopsis RESURRECTION1 Gene Regulates a Novel Antagonistic Interaction in Plant Defense to Biotrophs and Necrotrophs1[W][OA]Plant Physiology, 151
R. Wisser, Qi Sun, S. Hulbert, S. Kresovich, R. Nelson (2005)
Identification and Characterization of Regions of the Rice Genome Associated With Broad-Spectrum, Quantitative Disease ResistanceGenetics, 169
R. Büschges, K. Hollricher, R. Panstruga, G. Simons, M. Wolter, A. Frijters, R. Daelen, T. Lee, P. Diergaarde, J. Groenendijk, S. Töpsch, P. Vos, F. Salamini, P. Schulze-Lefert (1997)
The Barley Mlo Gene: A Novel Control Element of Plant Pathogen ResistanceCell, 88
N. Young (1996)
QTL mapping and quantitative disease resistance in plants.Annual review of phytopathology, 34
M. Carson, C. Stuber, M. Senior (2004)
Identification and Mapping of Quantitative Trait Loci Conditioning Resistance to Southern Leaf Blight of Maize Caused by Cochliobolus heterostrophus Race O.Phytopathology, 94 8
Michael Lee, N. Sharopova, W. Beavis, D. Grant, Maria Katt, Deborah Blair, A. Hallauer (2002)
Expanding the genetic map of maize with the intermated B73 × Mo17 (IBM) populationPlant Molecular Biology, 48
H. Welz, A. Schechert, H. Geiger (1999)
Dynamic gene action at QTLs for resistance to Setosphaeria turcica in maizeTheoretical and Applied Genetics, 98
J. Poland, P. Balint-Kurti, R. Wisser, R. Pratt, R. Nelson (2009)
Shades of gray: the world of quantitative disease resistance.Trends in plant science, 14 1
Qiu, Fu-lin, Wang, He-he, Chen, Jie, Zhuang, Jie-yun, Leung, Cheng, Shi-hua, Wu, Jian-li (2006)
A Rapid DNA Mini-prep Method for Large-Scale Rice Mutant Screening, 13
Chia-Lin Chung, T. Jamann, J. Longfellow, R. Nelson (2010)
Characterization and fine-mapping of a resistance locus for northern leaf blight in maize bin 8.06Theoretical and Applied Genetics, 121
K. Williams (2003)
The molecular genetics of disease resistance in barleyCrop & Pasture Science, 54
To capture diverse alleles at a set of loci associated with disease resistance in maize, heterogeneous inbred family (HIF) analysis was applied for targeted QTL mapping and near-isogenic line (NIL) development. Tropical maize lines CML52 and DK888 were chosen as donors of alleles based on their known resistance to multiple diseases. Chromosomal regions (“bins”; n = 39) associated with multiple disease resistance (MDR) were targeted based on a consensus map of disease QTLs in maize. We generated HIFs segregating for the targeted loci but isogenic at ~97% of the genome. To test the hypothesis that CML52 and DK888 alleles at MDR hotspots condition broad-spectrum resistance, HIFs and derived NILs were tested for resistance to northern leaf blight (NLB), southern leaf blight (SLB), gray leaf spot (GLS), anthracnose leaf blight (ALB), anthracnose stalk rot (ASR), common rust, common smut, and Stewart’s wilt. Four NLB QTLs, two ASR QTLs, and one Stewart’s wilt QTL were identified. In parallel, a population of 196 recombinant inbred lines (RILs) derived from B73 × CML52 was evaluated for resistance to NLB, GLS, SLB, and ASR. The QTLs mapped (four for NLB, five for SLB, two for GLS, and two for ASR) mostly corresponded to those found using the NILs. Combining HIF- and RIL-based analyses, we discovered two disease QTLs at which CML52 alleles were favorable for more than one disease. A QTL in bin 1.06–1.07 conferred resistance to NLB and Stewart’s wilt, and a QTL in 6.05 conferred resistance to NLB and ASR.
TAG Theoretical and Applied Genetics – Springer Journals
Published: Jul 1, 2011
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.