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Citations (26)
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Roshan Regmi, Toby E. Newman, Yuphin Khentry, Lars G. Kamphuis & Mark C. Derbyshire. (2023) Genome-wide identification of Sclerotinia sclerotiorum small RNAs and their endogenous targets. BMC Genomics 24:1.
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Toby E. Newman, Haseong Kim, Yuphin Khentry, Kee Hoon Sohn, Mark C. Derbyshire & Lars G. Kamphuis. (2023)
The broad host range pathogen
Sclerotinia sclerotiorum
produces multiple effector proteins that induce host cell death intracellularly
. Molecular Plant Pathology 24:8, pages 866-881.
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Preetesh Kumari, Kaushal Pratap Singh & Pramod Kumar Rai. (2023) Identification of new resistance source for Sclerotinia stem rot in backcross population of B. juncea + S. alba allohexaploids: key to manage disease through host resistance. Euphytica 219:7.
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Pippa J. Michael, Ashmita Rijal Lamichhane & Sarita Jane Bennett. (2023) Temperature and Isolate Are Important Determinants of Brassica napus Susceptibility to Aggressive Sclerotinia sclerotiorum Isolates. Agronomy 13:6, pages 1606.
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Toby E. Newman, Yuphin Khentry, Audrey Leo, Kurt D. Lindbeck, Lars G. Kamphuis & Mark C. Derbyshire. (2023)
Association Mapping Combined with Whole Genome Sequencing Data Reveals Candidate Causal Variants for Sclerotinia Stem Rot Resistance in
Brassica napus
. Phytopathology® 113:5, pages 800-811.
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Govind Singh Saharan, Naresh K. Mehta & Prabhu Dayal MeenaGovind Singh Saharan, Naresh K. Mehta & Prabhu Dayal Meena. 2023. Genomics of Crucifer's Host- Pathosystem. Genomics of Crucifer's Host- Pathosystem
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Manjeet Singh, Ram Avtar, Neeraj Kumar, Rakesh Punia, Nita Lakra, Nisha Kumari, Mahavir Bishnoi, Rohit Rohit, Raju Ram Choudhary, Rajbir Singh Khedwal, Ravindra Kumar Meena, Ankit Dhillon & Vivek K. Singh. (2022) Assessment of Sclerotinia Stem and Leaf Rot Resistance and its Association with Physical Strength Attributes in Brassicaceae with Special Emphasis on Brassica Juncea. Journal of Plant Growth Regulation.
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Mark C. Derbyshire, Toby E. Newman, Yuphin Khentry & Akeem Owolabi Taiwo. (2022)
The evolutionary and molecular features of the broad‐host‐range plant pathogen
Sclerotinia sclerotiorum
. Molecular Plant Pathology 23:8, pages 1075-1090.
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Virginia W. Mwape, Kelvin H. P. Khoo, Kefei Chen, Yuphin Khentry, Toby E. Newman, Mark C. Derbyshire, Diane E. Mather & Lars G. Kamphuis. (2022) Identification of Sclerotinia stem rot resistance quantitative trait loci in a chickpea (. Functional Plant Biology 49:7, pages 634-646.
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Lone Buchwaldt, Harsh Garg, Krishna D. Puri, Jonathan Durkin, Jennifer Adam, Myrtle Harrington, Debora Liabeuf, Alan Davies, Dwayne D. Hegedus, Andrew G. Sharpe & Krishna Kishore Gali. (2022) Sources of genomic diversity in the self-fertile plant pathogen, Sclerotinia sclerotiorum, and consequences for resistance breeding. PLOS ONE 17:2, pages e0262891.
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Roshan Regmi, Toby E. Newman, Lars G. Kamphuis & Mark C. Derbyshire. (2021) Identification of Brassica napus small RNAs responsive to infection by a necrotrophic pathogen. BMC Plant Biology 21:1.
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Virginia W. Mwape, Fredrick M. Mobegi, Roshan Regmi, Toby E. Newman, Lars G. Kamphuis & Mark C. Derbyshire. (2021) Analysis of differentially expressed Sclerotinia sclerotiorum genes during the interaction with moderately resistant and highly susceptible chickpea lines. BMC Genomics 22:1.
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Akeem O. Taiwo, Lincoln A. Harper & Mark C. Derbyshire. (2021) Impacts of fludioxonil resistance on global gene expression in the necrotrophic fungal plant pathogen Sclerotinia sclerotiorum. BMC Genomics 22:1.
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Kusum Rana, Yijuan Ding, Surinder S. Banga, Hongmei Liao, Siqi Zhao, Yang Yu & Wei Qian. (2021)
Sclerotinia sclerotiorum Thioredoxin1 (SsTrx1)
is required for pathogenicity and oxidative stress tolerance
. Molecular Plant Pathology 22:11, pages 1413-1426.
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Katharina Belt, Rhonda C. Foley, Cathryn A. O’Sullivan, Margaret M. Roper, Karam B. Singh & Louise F. Thatcher. (2021) A Plant Stress-Responsive Bioreporter Coupled With Transcriptomic Analysis Allows Rapid Screening for Biocontrols of Necrotrophic Fungal Pathogens. Frontiers in Molecular Biosciences 8.
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Virginia W. Mwape, Yuphin Khentry, Toby. E. Newman, Matthew Denton-Giles, Mark C. Derbyshire, Kefei Chen, Jens Berger & Lars G. Kamphuis. (2021)
Identification of Sources of
Sclerotinia sclerotiorum
Resistance in a Collection of Wild
Cicer
Germplasm
. Plant Disease 105:9, pages 2314-2324.
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Cathryn A. O’Sullivan, Katharina Belt & Louise F. Thatcher. (2021) Tackling Control of a Cosmopolitan Phytopathogen: Sclerotinia. Frontiers in Plant Science 12.
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Mark C Derbyshire, Yuphin Khentry, Anita Severn‐Ellis, Virginia Mwape, Nur Shuhadah Mohd Saad, Toby E Newman, Akeem Taiwo, Roshan Regmi, Lone Buchwaldt, Matthew Denton‐Giles, Jacqueline Batley & Lars G Kamphuis. (2021) Modeling first order additive × additive epistasis improves accuracy of genomic prediction for sclerotinia stem rot resistance in canola. The Plant Genome 14:2.
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Sarita Jane Bennett, Ashmita Rijal Lamichhane, Linda L. Thomson, King Yin Lui & Pippa J. Michael. (2021) Impact of Fungicide Application and Host Genotype on Susceptibility of Brassica napus to Sclerotinia Stem Rot across the South-Western Australian Grain Belt: A Genotype × Environment × Management Study. Agronomy 11:6, pages 1170.
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Pippa J. Michael, King Yin Lui, Linda L. Thomson, Ashmita Rijal Lamichhane & Sarita J. Bennett. (2021)
Impact of Preconditioning Temperature and Duration Period on Carpogenic Germination of Diverse
Sclerotinia sclerotiorum
Populations in Southwestern Australia
. Plant Disease 105:6, pages 1798-1805.
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Govind Singh Saharan, Naresh K. Mehta & Prabhu Dayal MeenaGovind Singh Saharan, Naresh K. Mehta & Prabhu Dayal Meena. 2021. Genomics of Crucifer’s Host-Resistance. Genomics of Crucifer’s Host-Resistance
65
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Pippa J. Michael, King Yin Lui, Linda L. Thomson, Katia Stefanova & Sarita J. Bennett. (2020)
Carpogenic Germinability of Diverse
Sclerotinia sclerotiorum
Populations Within the Southwestern Australian Grain Belt
. Plant Disease 104:11, pages 2891-2897.
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Manjeet Singh, Ram Avtar, Ajay Pal, Rakesh Punia, Vivek K. Singh, Mahavir Bishnoi, Anoop Singh, Raju Ram Choudhary & Shiwani Mandhania. (2020) Genotype-Specific Antioxidant Responses and Assessment of Resistance Against Sclerotinia sclerotiorum Causing Sclerotinia Rot in Indian Mustard. Pathogens 9:11, pages 892.
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Linh Bao Ton, Ting Xiang Neik & Jacqueline Batley. (2020) The Use of Genetic and Gene Technologies in Shaping Modern Rapeseed Cultivars (Brassica napus L.). Genes 11:10, pages 1161.
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Jefferson Allan, Roshan Regmi, Matthew Denton-Giles, Lars G. Kamphuis & Mark C. Derbyshire. (2019) The host generalist phytopathogenic fungus Sclerotinia sclerotiorum differentially expresses multiple metabolic enzymes on two different plant hosts. Scientific Reports 9:1.
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David Lane, Matthew Denton-Giles, Mark Derbyshire & Lars G. Kamphuis. (2019) Abiotic conditions governing the myceliogenic germination of Sclerotinia sclerotiorum allowing the basal infection of Brassica napus. Australasian Plant Pathology 48:2, pages 85-91.
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