Your search keyword '"Farooqi, Arifa"' showing total 4 results

1. Identification of molecular markers for resistance to Fusarium head blight in wheat

Author

Farooqi, Arifa

Subjects

633.1, SB Plant culture

Abstract

Fusarium head blight (FHB) is a devastating fungal disease of wheat and small grain cereals worldwide, causing yield losses, reducing grain quality, and leading to mycotoxin contamination of grain. Breeding for resistance to FHB by conventional selection is feasible, but the main challenge is to identify new genotypic variations and increase resistance by pyramiding multiple traits and quantitative trait loci (QTL). The aim of this work was to determine the physiological traits related to passive resistance and identify QTL conferring active resistance to the FHB. Double haploid (DH) wheat lines were ground inoculated in field experiments to enable passive disease traits to be expressed under natural rainfall and artificially misted conditions whilst ear inoculated glasshouse experiments were used to test if any of the assessed traits were associated with genetic resistance. Spikelet density was identified as a potential ear trait in the field contributing consistently to increased FHB progression. Flag leaf length and tiller number influencing pathogen dispersal and spread within the canopy were the most consistently significant traits, positively related to FHB development indicating a potential underlying genetic linkage which was not confirmed in subsequent QTL analysis. Instead these traits were associated with increased susceptibility and were negatively affecting any passive resistance mechanisms such as disease escape. To identify QTLs for canopy and ear traits, and resistance to FHB and Septoria tritici blotch (STB), a DH population of 107 lines was evaluated in two Fusarium and Microdochium ground inoculated, artificially misted and two Microdochium seed inoculated, non-misted experiments. A coinciding QTL for AUDPC and bleaching was found on chromosome 7D and a second QTL on 2B. An overlapping QTL for FHB lesions was detected on 5B and a second QTL on 4A conferring resistance to M. majus and fungal biomass accumulation in grain and in anthers. F .graminearum DNA in grain and anthers was conferred by a distinct QTL on 4B. QTLs for resistance to accumulation of deoxynivalenol (DON) and zearalenone (ZON) were detected on 5A and 6B, respectively. This study is the first to report the coexistence of resistance QTL for fungal biomass accumulation in grain and anthers and novel QTL for ZON in wheat. A QTLs for STB was found on chromosome 2A, for awns length on 5A. A QTL for flag leaf length on 3A and coincided QTLs for flag leaf length and flag leaf width on 7B failed to coincide with disease traits suggesting that the identified canopy traits were not genetically linked with disease but of rather epidemiological significance. The study identified separate QTLs conferring resistance to different Fusarium and Microdochium species indicating that resistance is distinctly regulated and likely to be species specific. To identify novel ear traits and determine the role of anthers and pollen in resistance to initial infection (Type I) or FHB susceptibility, ear inoculated glasshouse experiments using selected wheat genotypes and a point inoculated growth room experiment using fertile barley line (cv. Golden Promise) and cytoplasmic male sterile (CMS) lines (HvMS1 and HvDYT1) were conducted. The most consistent traits in glasshouse experiment were ear length, number of spikelets per ear and anther extrusion. Sugar concentrations in wheat anthers was quantified to observe the potential nutritional role played by different sugars for spore germination and infection by F. graminearium. Results from in vitro anther-fungal bioassays indicated that fungal spores utilize sucrose and fructose during germination and glucose for growth and infection. The role of anthers and pollen and possible biochemical substrate stimulating spore germination and fungal growth in wheat and barley in addition to Arabidopsis wild ecotypes (Columbia and Landsberg erecta) and mutants ABORTED MICROSPORES (AMS) producing non-viable pollen, MALE STERILITY1 (MS1) producing no pollen and MS35 non-dehiscing anther was investigated in a series of bioassays. CMS lines with infertile anthers were more resistant to FHB infection than wild type (WT). Spore germination was significantly reduced in the presence of wheat anthers containing no pollen while barley CMS line HvMS1 and HvDYT1 with sterile anthers also showed reduced spores germination. In Arabidopsis WT spore germination was significantly higher in the presence of fertile anthers compared to the mutants MS1 and MS35. Releasing MS35 pollen significantly increased spore germination. Reduction in spore germination was observed in all heat stressed replicates, irrespective of the anther and pollen presence or absence. These results indicate that the presence of fertile anthers and subsequent release of pollen are an important part of the infection pathway and of susceptibility to FHB while heat stress can destroy any substance in anthers and pollen stimulating Fusarium spores in-vitro. The current research findings show that FHB resistance type I (resistance to initial infection), type II (resistance to spread) and type III (resistance to mycotoxin accumulation) in wheat is conferred by a combination of active and passive resistance traits whereas active resistance is also associated with alleles determining the morphological, physiological and biochemical plant characteristics. Moreover, the expression of active and passive resistance is highly influenced by the environmental interactions, inoculum source, pathogen species and virulence under field conditions. Consequently, selection for desirable canopy and ear morphology traits conferring improved type I resistance in combination with cultivars with substantial levels of type II resistance can improve the overall FHB resistance in wheat.

Published

2018

2. Aggressiveness and mycotoxin profile of Fusarium avenaceum isolates causing Fusarium seedling blight and Fusarium head blight in UK malting barley.

Author

Inbaia, Safieddin, Farooqi, Arifa, and Ray, Rumiana V.

Subjects

LIQUID chromatography-mass spectrometry, FUSARIOSIS, FUSARIUM, BARLEY farming

Abstract

Introduction: Fusarium avenaceum causing Fusarium seedling blight (FSB) and Fusarium head blight (FHB) on barley is associated with economic losses of crop yield and quality, and the accumulation of mycotoxins including the enniatins (ENNs) A, A1, B and B1. Although F. avenaceum is the main producer of ENNs, studies on the ability of isolates to cause severe Fusarium diseases or produce mycotoxins in barley are limited. Methods: In this work, we investigated the aggressiveness of nine isolates of F. avenaceum to two cultivars of malting barley, Moonshine and Quench, and defined their ENN mycotoxin profiles in in vitro and in planta experiments. We assessed and compared the severity of FSB and FHB caused by these isolates to disease severity by F. graminearum, F. tricinctum and F. poae. Quantitative realtime polymerase chain reaction and Liquid Chromatography Tandem Mass Spectrometry assays were used to quantify pathogen DNA and mycotoxin accumulation, respectively, in barley heads. Results: Isolates of F. avenaceum were equally aggressive to barley stems and heads and caused the most severe FSB symptoms resulting in up to 55% reductions of stem and root length. Fusarium graminearum caused the most severe FHB disease, followed by the isolates of F. avenaceum with the most aggressive F. avenaceum isolates capable of causing similar bleaching of barley heads as F. avenaceum. Fusarium avenaceum isolates produced ENN B as the predominant mycotoxin, followed by ENN B1 and A1 in vitro. However, only the most aggressive isolates produced ENN A1 in planta and none produced ENN A or beauvericin (BEA) either in planta or in vitro. Discussion: The capacity of F. avenaceum isolates to produce ENNs was related to the accumulation of pathogen DNA in barley heads, whilst FHB severity was related to the synthesis and accumulation of ENN A1 in planta. Cv. Moonshine was significantly more resistant than Quench to FSB or FHB, caused by any Fusarium isolate, and to the accumulation of pathogen DNA, ENNs or BEA. In conclusion, aggressive F. avenaceum isolates are potent ENN producers causing severe FSB and FHB with ENN A1 requiring further investigation as potential virulence factor for F. avenaceum in cereals. [ABSTRACT FROM AUTHOR]

Published

2023

3. Population dynamics of Rhizoctonia, Oculimacula, and Microdochium species in soil, roots, and stems of English wheat crops

Author

Brown, Matthew, Woodhall, James W., Nielsen, Linda K., Tomlinson, Daniel, Farooqi, Arifa, and Ray, Rumiana V.

Subjects

Genetics, food and beverages, Plant Science, Horticulture, Agronomy and Crop Science

Abstract

© 2020 The Authors. Plant Pathology published by John Wiley & Sons Ltd on behalf of British Society for Plant Pathology This study aimed to elucidate the population dynamics of Rhizoctonia, Oculimacula, and Microdochium species, causing the stem base disease complex of sharp eyespot, eyespot, and brown foot rot in cereals. Pathogen DNA in soil, roots, and stem fractions, and disease expression were quantified in 102 English wheat fields in two seasons. Weather data for each site was collected to determine patterns that correlate with assessed diseases. Oculimacula spp. (66%) and R. solani AG 2-1 (63%) were most frequently detected in soil, followed by R. cerealis (54%) and Microdochium spp. (33%). Oculimacula spp. (89%) and R. cerealis (56%) predominated on roots and soil but were not associated with root rot symptoms, suggesting that these species used soil and roots for survival and as inoculum source. M. nivale was more frequently detected than M. majus on stems up to GS 21–30 and co-occurred on plant samples with O. acuformis. O. yallundae had higher DNA concentration than O. acuformis at the lower 5cm basal region at GS 37–45. R. cerealis predominated in the upper 15cm above the base beyond stem extension. Brown foot rot by Microdochium spp. was favoured by cool and wet autumns/winters and dominated in English wheat. Eyespot and sharp eyespot disease index by Oculimacula spp. and R. cerealis, respectively, correlated with wet/humid springs and summers. Results suggested that stem base pathogens generally coexisted; however, their abundance in time and space was influenced by favourable weather patterns and host development, with niche differentiation after stem extension.

Published

2021

4. Canopy and Ear Traits Associated With Avoidance of Fusarium Head Blight in Wheat

Author

Jones, Stephen, Farooqi, Arifa, Foulkes, John, Sparkes, Debbie L., Linforth, Robert, and Ray, Rumiana V.

Subjects

Fusarium head blight, pathogen DNA, disease avoidance, wheat, mycotoxins, food and beverages, lcsh:SB1-1110, Plant Science, ear and canopy traits, lcsh:Plant culture, Original Research

Abstract

Doubled haploid and elite wheat genotypes were ground inoculated in three field experiments and head spray inoculated in two glasshouse experiments, using mixed Fusarium and Microdochium species, to identify crop canopy and ear traits associated with Fusarium head blight (FHB) disease. In all experiments, flag leaf length and tiller number were consistently identified as the most significant canopy traits contributing to progression of FHB caused by Fusarium graminearum, F. culmorum, and F. avenaceum. The influence of ear traits was greater for F. poae that may possess more diverse routes for transmission and spread. Consistently, spikelet density was associated with increased disease severity in the field. F. graminearum, F. culmorum, and F. langsethiae were the main mycotoxin producers and their respective toxins were significantly related to fungal biomass and number of spikelets per ear. Genotypes with lower tiller numbers, shorter flag leaves and less dense ears may be able to avoid FHB disease caused by F. graminearum, F. culmorum, F. avenaceum, or Microdochium species however selection for these canopy and ear architectural traits to enable disease avoidance in wheat is likely to result in a potential trade-off with grain yield and therefore only moderately advantageous in susceptible genotypes.

Published

2018