Your search keyword '"Dutta, Bhabesh"' showing total 16 results

1. Integrating biocontrol agents with copper for center rot management in onion

Author

Koirala, Santosh, Shin, Gi Yoon, Kvitko, Brian, and Dutta, Bhabesh

Published

2024

2. Diversity, abundance, and domain architecture of plant NLR proteins in Fabaceae

Author

Negi, Vishal Singh, Srinivasan, Rajagopalbabu, and Dutta, Bhabesh

Published

2024

3. Linkage-Mapping and Genome-wide Association Study Identified Two Peanut Late Leaf Spot Resistance Loci, PLLSR-1 and PLLSR-2, Using a Nested Association Mapping

Author

Gangurde, Sunil S., primary, Thompson, Ethan, additional, Yaduru, Shasidhar, additional, Wang, Hui, additional, Fountain, Jake C., additional, Chu, Ye, additional, Ozias-Akins, Pegy, additional, Isleib, Thomas G., additional, Holbrook, C. Corley, additional, Dutta, Bhabesh, additional, Culbreath, Albert K., additional, Pandey, Manish K., additional, and Guo, Baozhu, additional

Published

2024

4. From weeds to natural enemies: implications of weed cultivation and biopesticides for organic onion production

Author

Lennon, Kylie, primary, Querejeta, Marina, additional, Dutta, Bhabesh, additional, Johnson, Caroll, additional, and Schmidt, Jason M, additional

Published

2024

5. Thiosulfinate tolerance gene clusters are common features of Burkholderia onion pathogens

Author

Paudel, Sujan, primary, Zhao, Mei, additional, Stice, Shaun P., additional, Dutta, Bhabesh, additional, and Kvitko, Brian H., additional

Published

2024

6. Onion‐pathogenic Burkholderia species: Role and regulation of characterized virulence determinants.

Author

Paudel, Sujan, Dutta, Bhabesh, and Kvitko, Brian

Subjects

*BURKHOLDERIA, *BURKHOLDERIA cepacia, *HOST plants, *SPECIES, *FACTORS of production

Abstract

Members of the bacterial genus Burkholderia are a routine threat to onion production worldwide. In addition to the common onion‐pathogenic species, Burkholderia cepacia, Burkholderia orbicola and Burkholderia gladioli, other Burkholderia species have the potential to cause onion disease. Despite their impacts and long‐known association with onion disease, the virulence mechanisms of onion‐pathogenic Burkholderia are far less well understood than Burkholderia in human and murine infection models. In this review, we will focus on genetically characterized virulence factors in species that contribute to symptom production in onion and other plant hosts. Specifically, we will focus on the variable roles of specialized protein secretion systems (T2SS, T3SS and T4SS) and secreted proteins, thiosulphinate tolerance gene (TTG) clusters and the well‐characterized phytotoxin toxoflavin in virulence. The regulation and roles of LuxI/LuxS quorum‐sensing system and IclR‐type transcriptional regulator, qsmR, as master regulators of secondary metabolite production and virulence factors will also be discussed. The TTG clusters, involved in bacterial tolerance to thiosulphinate defence compounds, exhibit onion tissue‐specific contributions to virulence. This suggests that Burkholderia onion pathogens have tissue‐specific virulence strategies for causing disease. [ABSTRACT FROM AUTHOR]

Published

2024

7. Impact of Nitrogen Fertilizer Rate and Timing on Short-day Onion Production

Author

de Jesus, Hanna Ibiapina, primary, Ribeiro da Silva, Andre Luiz Biscaia, additional, Dutta, Bhabesh, additional, and Coolong, Timothy, additional

Published

2024

8. Influence of Soil Type and Temperature on Nitrogen Mineralization from Organic Fertilizers

Author

de Jesus, Hanna Ibiapina, primary, Cassity-Duffey, Kate, additional, Dutta, Bhabesh, additional, da Silva, Andre Luiz Biscaia Ribeiro, additional, and Coolong, Timothy, additional

Published

2024

9. Assessment of prickly sida as a potential inoculum source for sida golden mosaic virus in commercial snap bean farms in Georgia, United States

Author

Codod, Clarence, primary, Severns, Paul, additional, Sparks, Alton N., additional, Srinivasan, Rajagopalbabu, additional, Kemerait, Robert, additional, and Dutta, Bhabesh, additional

Published

2024

10. Adaptability of Phytophthora capsici Resistant Bell Pepper Cultivars in Southern Georgia.

Author

Kumari, Manisha, Dutta, Bhabesh, Coolong, Timothy, Diaz-Perez, Juan Carlos, Torrance, Ty, Shealey, Justin, Dawson, Joshua, and McAvoy, Theodore

Subjects

CAPSICUM annuum, PHYTOPHTHORA capsici, FRUIT yield, FARMERS, CULTIVARS

Abstract

Phytophthora capsici (PCap), which causes Phytophthora root rot, is the most destructive soilborne pathogen for bell pepper (Capsicum annuum L.) production in Georgia, USA. Extensive host range, persistence of inoculum in the soil, and lack of effective chemical control methods make this disease particularly difficult to manage. Resistant cultivars offer a practical solution to manage PCap in affected bell pepper fields. However, most commercial cultivars resistant to PCap are predominantly grown in the northeastern United States. This research aimed to screen commercial bell pepper cultivars for resistance to PCap, marketable yield, fruit size distribution, and overall adaptability for production within the largest growing areas in southern Georgia. Field trials were conducted during Spring 2022 and 2023 in commercial growers' fields with a known history of PCap infestation to evaluate PCap-resistant bell pepper cultivars across four trials conducted in the three counties (Colquitt, Echols, and Lowndes) responsible for ~78% of bell pepper production in Georgia. Eleven cultivars were evaluated: nine that claimed PCap resistance and two widely grown PCap susceptible cultivars included for comparison. Phytophthora root rot incidence was very low in these research trials. However, there were significant differences in total yields, marketable yields, fruit size, and unmarketable yields. On the basis of marketable yields for jumbo, extra large, and large-sized fruit, we recommend the PCap-resistant cultivars PS 0994-1819, Paladin, and Mercer for fresh market bell pepper growers. Furthermore, 'Revolution' is recommended for processor growers due to higher jumbo-sized fruit yields and lower quality and higher pancaking for the spring season in southern Georgia, USA. Newer cultivars Tarpon and Nitro have a more desirable disease-resistance package; however, 'Nitro' had small-sized fruit, and 'Tarpon' tended to have lower total yields than current commercial standards. [ABSTRACT FROM AUTHOR]

Published

2024

11. Aspergillus flavus pangenome (AflaPan) uncovers novel aflatoxin and secondary metabolite associated gene clusters.

Author

Gangurde, Sunil S., Korani, Walid, Bajaj, Prasad, Wang, Hui, Fountain, Jake C., Agarwal, Gaurav, Pandey, Manish K., Abbas, Hamed K., Chang, Perng-Kuang, Holbrook, C. Corley, Kemerait, Robert C., Varshney, Rajeev K., Dutta, Bhabesh, Clevenger, Josh P., and Guo, Baozhu

Subjects

PAN-genome, ASPERGILLUS flavus, AFLATOXINS, PLANT genomes, AGRICULTURE, GENE clusters, GENETIC variation, FUNGAL metabolites, CORN diseases

Abstract

Background: Aspergillus flavus is an important agricultural and food safety threat due to its production of carcinogenic aflatoxins. It has high level of genetic diversity that is adapted to various environments. Recently, we reported two reference genomes of A. flavus isolates, AF13 (MAT1-2 and highly aflatoxigenic isolate) and NRRL3357 (MAT1-1 and moderate aflatoxin producer). Where, an insertion of 310 kb in AF13 included an aflatoxin producing gene bZIP transcription factor, named atfC. Observations of significant genomic variants between these isolates of contrasting phenotypes prompted an investigation into variation among other agricultural isolates of A. flavus with the goal of discovering novel genes potentially associated with aflatoxin production regulation. Present study was designed with three main objectives: (1) collection of large number of A. flavus isolates from diverse sources including maize plants and field soils; (2) whole genome sequencing of collected isolates and development of a pangenome; and (3) pangenome-wide association study (Pan-GWAS) to identify novel secondary metabolite cluster genes. Results: Pangenome analysis of 346 A. flavus isolates identified a total of 17,855 unique orthologous gene clusters, with mere 41% (7,315) core genes and 59% (10,540) accessory genes indicating accumulation of high genomic diversity during domestication. 5,994 orthologous gene clusters in accessory genome not annotated in either the A. flavus AF13 or NRRL3357 reference genomes. Pan-genome wide association analysis of the genomic variations identified 391 significant associated pan-genes associated with aflatoxin production. Interestingly, most of the significantly associated pan-genes (94%; 369 associations) belonged to accessory genome indicating that genome expansion has resulted in the incorporation of new genes associated with aflatoxin and other secondary metabolites. Conclusion: In summary, this study provides complete pangenome framework for the species of Aspergillus flavus along with associated genes for pathogen survival and aflatoxin production. The large accessory genome indicated large genome diversity in the species A. flavus, however AflaPan is a closed pangenome represents optimum diversity of species A. flavus. Most importantly, the newly identified aflatoxin producing gene clusters will be a new source for seeking aflatoxin mitigation strategies and needs new attention in research. [ABSTRACT FROM AUTHOR]

Published

2024

12. Impact of Nitrogen Fertilizer Rate and Timing on Short-day Onion Production.

Author

Ibiapina de Jesus, Hanna, Biscaia Ribeiro da Silva, Andre Luiz, Dutta, Bhabesh, and Coolong, Timothy

Subjects

NITROGEN fertilizers, AUTUMN, ONIONS, BURKHOLDERIA cepacia, FERTILIZER application

Abstract

Onions (Allium cepa) are typically planted late fall and harvested in spring in the Vidalia, GA, USA, region. Onions grown here are renowned for their for sweetness and are marketed to consumers as Vidalia onions. High rainfall during the relatively long growing season (4 to 5 months) may result in nitrogen (N) leaching during production. Therefore, fertilizer applications are usually aligned with stages of crop development to ensure nutrient availability for the entire season. Although the impacts of N application rate have been previously investigated for Vidalia onion production, the optimal timing for the final N application of the season has not been determined. The objectives of this study were to determine the optimal timing of the last fertilizer N application (at bulb initiation, during bulb growth, or during bulb maturation) in conjunction with the impact of three N application rates (75, 105, and 135 lb/acre N) on yield and quality in Vidalia onion. Soil N levels were affected by N rate, year, and onion growth stage. In 2020, up to 135 lb/acre N was required to maximize onion yields, and in 2021, onion yields were unchanged among N fertilizer treatments. Final N applications at bulb initiation resulted in greater yields than applications made during bulb growth or bulb maturation. In addition, as the N rate increased and the time of final application occurred later in bulb development, pungency values increased. Incidence of sour skin (Burkholderia cepacia) and center rot (Pantoea sp.) diseases were greater in 2020 compared with 2021 and seemed to be affected by environmental conditions more than N fertilization. [ABSTRACT FROM AUTHOR]

Published

2024

13. Linkage Mapping and Genome-Wide Association Study Identified Two Peanut Late Leaf Spot Resistance Loci, PLLSR-1 and PLLSR-2, Using Nested Association Mapping.

Author

Gangurde, Sunil S., Thompson, Ethan, Yaduru, Shasidhar, Hui Wang, Fountain, Jake C., Ye Chu, Ozias-Akins, Peggy, Isleib, Thomas G., Holbrook, Corley, Dutta, Bhabesh, Culbreath, Albert K., Pandey, Manish K., and Baozhu Guo

Subjects

*LOCUS (Genetics), *GENOME-wide association studies, *GENETIC recombination, *LEAF spots, *SINGLE nucleotide polymorphisms, *POLLEN

Abstract

Identification of candidate genes and molecular markers for late leaf spot (LLS) disease resistance in peanut (Arachis hypogaea) has been a focus of molecular breeding for the U.S. industry-funded peanut genome project. Efforts have been hindered by limited mapping resolution due to low levels of genetic recombination and marker density available in traditional biparental mapping populations. To address this, a multi-parental nested association mapping population has been genotyped with the peanut 58K single-nucleotide polymorphism (SNP) array and phenotyped for LLS severity in the field for 3 years. Joint linkage-based quantitative trait locus (QTL) mapping identified nine QTLs for LLS resistance with significant phenotypic variance explained up to 47.7%. A genome-wide association study identified 13 SNPs consistently associated with LLS resistance. Two genomic regions harboring the consistent QTLs and SNPs were identified from 1,336 to 1,520 kb (184 kb) on chromosome B02 and from 1,026.9 to 1,793.2 kb (767 kb) on chromosome B03, designated as peanut LLS resistance loci, PLLSR-1 and PLLSR-2, respectively. PLLSR-1 contains 10 nucleotide-binding site leucine-rich repeat disease resistance genes. A nucleotide-binding site leucine-rich repeat disease resistance gene, Arahy.VKVT6A, was also identified on homoeologous chromosome A02. PLLSR-2 contains five significant SNPs associated with five different genes encoding callose synthase, pollen defective in guidance protein, pentatricopeptide repeat, acyl-activating enzyme, and C2 GRAM domains-containing protein. This study highlights the power of multi-parent populations such as nested association mapping for genetic mapping and marker-trait association studies in peanuts. Validation of these two LLS resistance loci will be needed for marker-assisted breeding. [ABSTRACT FROM AUTHOR]

Published

2024

14. First Report of Erwinia aphidicola Causing Bulb Rot of Onion in Chile.

Author

Valenzuela M, MacLellan MP, Guajardo J, Dorta F, Seeger M, and Dutta B

Abstract

During the 2021-22 and 2022-23 seasons (December to February), onion plants (Allium cepa L.) showing decay, leaf blight, chlorosis and water soak lesions were collected in Central Chile. Five symptomatic plants were sampled from 20 different onion fields. Brown rot of the external scales was observed in bulbs from two fields: one planted with the cv. Campero (20 ha; O'Higgins Region), and another with cv. Marenge (2 ha; Metropolitan Region). The disease incidence in these fields ranged from 2% to 5%. Isolations were carried out from symptomatic leaves and bulbs from these fields on King's B medium, resulting in small white colonies with smooth margin. Three isolates were selected, two from first field (QCJ3A & QCJ2B), and one from second field (EPB1). A preliminary identification based on 16S rRNA sequences was conducted. BLAST analyses of strains QCJ3A, QCJ2B and EPB1 (GenBank Accession No. PP345601 to PP345603) against the NCBI Database resulted in a match with strains (GenBank Accession No. ON255770.1 and ON255825.1) isolated from infected bulbs in Texas, USA identified as Erwinia spp. (Khanal et al. 2023), with 100% coverage and 100% identity (707 bp out of 707). To evaluate the pathogenicity of these three strains, onion bulbs were inoculated (Guajardo et al. 2023). Toothpicks previously immersed in a bacterial suspension at ~ 108 colony forming units (CFU)/mL were pricked at a 4 cm depth into the shoulders of onion bulbs bought from commercial store and incubated at room temperature. Bulbs inoculated with sterile water served as negative control. A known onion bulb rotting bacterial strain of Dickeya sp. was used as a positive control. At the end of the incubation period (20 days), bulbs were opened longitudinally across their inoculation site, showing that the external scales had a brown color. Negative control remained asymptomatic. Strains were re-isolated from damaged tissue and identified as Erwinia sp. This assay was repeated three times with the same results. For further identification, genomic DNA extraction was carried out using the Blood & Cell Culture DNA Kit (Qiagen), and genome sequencing was performed in the Illumina HiSeq 2500 platform. The Whole Genome Shotgun project for strains QCJ3A, QCJ2B and EPB1 have been deposited at DDBJ/ENA/GenBank under the accession JBANEI010000000, JBANEJ010000000 and JBANEK010000000. The average nucleotide identity (ANI) values were 99.6% (EPB1), 98.2% (QCJ2B), and 99.6% (QCJ3A) and DNA-DNA hybridization (dDDH) values were 96.9% (EPB1), 83.7% (QCJ2B), and 97.1% (QCJ3A), when compared with the type strain Erwinia aphidicola JCM 21238 (GenBank accession No. GCF_014773485.1). The three strains were deposited in the Chilean Collection of Microbial Genetic Resources (CChRGM). Erwinia aphidicola has been previously described causing diseases in common bean ( Phaseolus vulgaris ) and pea ( Pisum sativum ), in Spain (Santos et al. 2009) and in pepper ( Capsicum annuum ) in China (Luo et al. 2018). Its close relative E. persicina has been reported causing bulb rot in onion in Korea (Cho et al. 2019) and garlic in Europe (Galvez et al. 2015). To our knowledge, this is the first report of E. aphidicola causing a bulb rot of onion in Chile. Although the distribution and prevalence of this bacterium in Chilean agroecosystems is not known, it can be a potential cause of losses in onions and other crops such as beans, peas, and peppers. Additional studies should be conducted to determine the host range of Chilean Erwinia aphidicola strains.

Published

2024

15. Characterization of Seed-to-Seedling Transmission of Alternaria brassicicola in Broccoli.

Author

Kaur N and Dutta B

Subjects

Germination, Alternaria physiology, Brassica microbiology, Seeds microbiology, Plant Diseases microbiology, Seedlings microbiology

Abstract

Alternaria brassicicola is part of a complex of Alternaria species that causes leaf blight and head rot in brassica crops such as broccoli, kale, cabbage, cauliflower, and collards. Seed can serve as a potential source of inoculum for the transmission of A. brassicicola in broccoli as demonstrated earlier; however, seed-to-seedling transmission of pathogen was never characterized empirically. So, the objectives of this study were to (i) re-evaluate the effect of artificial seed infestation on seed germination and seed-to-seedling transmission of A . brassicicola in broccoli; (ii) determine the effect of A. brassicicola- seed inoculum levels on seed-to-seedling transmission; (iii) evaluate if variations in A. brassicicola aggressiveness affect A . brassicicola seed-to-seedling transmission; and (iv) evaluate seed treatments that can reduce seed-to-seedling transmission of A. brassicicola in broccoli. Artificially infested seedlots were generated by inoculating broccoli seeds with a spore suspension of 1 × 10 5 conidia/ml of A. brassicicola using the vacuum infiltration method. Inoculated ( n = 10 seedlots; 300 seeds/seedlot) or control seedlots in three replicates were planted on two layers of sterile blotter paper saturated with sterile water in transparent plastic boxes and incubated at 20°C and >90% relative humidity (RH) under continuous fluorescent light. Percent seed germination and percent seed-to-seedling transmission were recorded every other day for 21 days. Percent seed germination was significantly affected with artificial pathogen inoculation. One hundred percent of the seedlots transmitted the pathogen to broccoli seedlings, and seed-to-seedling percentages of the seedlots varied considerably. A strong linear and significant relationship between A . brassicicola inoculum level and seed-to-seedling transmission (%) within each seedlot was observed. Interestingly, variations in aggressiveness of A. brassicicola isolates did not affect seed-to-seedling transmission, as 100% of the seedlots were able to transmit the pathogen. Seed treatment with Miravis (a.i. pydiflumetofen 18.3%) significantly increased seed germination and reduced seed-to-seedling transmission percentages in A. brassicicola- inoculated seedlots. These results indicate that artificial seed inoculation with A. brassicicola can result in consistent seed-to-seedling transmission with significant impact on seed germination. Seed inoculum density of ≥10 4 conidia/ml is necessary for reliable transmission of A . brassicicola . Further seed-to-seedling transmission is not dependent on aggressiveness of A. brassicicola isolates and seed treatment with Miravis can significantly reduce pathogen transmission in broccoli seedings. Overall, this study provides detailed characterization of seed-to-seedling transmission of A. brassicicola in broccoli that can be further used to determine inoculum threshold, which has potential applications in seed-health testing and sample size determination. Furthermore, we also provide options for effective seed treatments that can significantly reduce A. brassicicola seed-to-seedling transmission and may potentially aid in managing seedborne fungal infection., Competing Interests: The author(s) declare no conflict of interest.

Published

2024

16. Aggressive Alternaria brassicicola with Reduced Fungicide Sensitivity Can Be Associated with Naturally Infested Broccoli Seeds.

Author

Kaur N and Dutta B

Subjects

Pyrimidines pharmacology, Methacrylates pharmacology, Phylogeny, Alternaria drug effects, Alternaria genetics, Alternaria physiology, Brassica microbiology, Fungicides, Industrial pharmacology, Seeds microbiology, Plant Diseases microbiology, Strobilurins pharmacology

Abstract

Alternaria brassicicola is a part of the Alternaria complex that causes leaf blight and head rot (ABHR) in brassica crops. Infested broccoli seeds can play an important role in introducing A. brassicicola in transplant houses and production fields. However, characterization of natural seed infestation and seed-to-seedling transmission of A. brassicicola in broccoli is yet to be demonstrated. In this research, we characterized Alternaria spp. isolates from commercial broccoli seedlots for their species identity, pathogenicity, and aggressiveness on broccoli and their sensitivity to a quinone-outside inhibitor (QoI) fungicide (azoxystrobin). Two hundred commercial seedlots from two broccoli cultivars, Cultivar 1 (EC; n = 100 seedlots) and Cultivar 2 (ED; n = 100 seedlots) were, evaluated for the presence of A. brassicicola under in vitro conditions using a seedling grow-out assay. Alternaria spp. was detected in 31 and 28% of the commercial seedlots of Cultivar 1 and Cultivar 2, respectively. The seed-to-seedling transmission (%) varied considerably within each positive-infested seedlot, which ranged from 1.3 to 17.3%. Subsequent molecular identification of single-spore cultures ( n = 138) was made by sequencing four housekeeping genes: actin, the major allergen (Alta1), plasma membrane ATPase, and glyceraldehyde-3-phosphate dehydrogenase (GPD), and the sequences were concatenated and compared for the phylogenetic distance with diverse Alternaria species. Ninety-six percent ( n = 133) of the isolates formed a cluster with a known A . brassicicola based on a multigene phylogeny, which were later confirmed as A. brassicicola using a species-specific PCR assay. One hundred percent of the A. brassicicola seed isolates ( n = 133) were either highly or moderately aggressive on broccoli (cultivar Emerald Crown) based on a detached leaf assay. Sensitivity of representative A. brassicicola isolates ( n = 58) to azoxystrobin was evaluated using a spore germination assay, and the EC 50 values (effective fungicide concentration [ppm] at which germination of conidia of isolates were reduced by 50% compared to control) for each isolate was determined. A. brassicicola isolates from naturally infested commercial broccoli seeds were sensitive to azoxystrobin with considerably low EC 50 values in the range of <0.0001 to 0.33 ppm; however, there were a few isolates (14%) that showed 100-fold reduced sensitivity from the most sensitive isolate (EC 50 = 0.0001 ppm). Our results confirm that commercial broccoli seedlots can be naturally contaminated with pathogenic and aggressive A. brassicicola . We also provide evidence for the potential presence of A. brassicicola isolates with reduced azoxystrobin-sensitivity in naturally infested commercial broccoli seedlots, which has never been reported before. Together, these findings may have implications in considerations for seed-health testing, seed treatments, and greenhouse scouting to limit introduction of infested seedlots in commercial broccoli fields., Competing Interests: The author(s) declare no conflict of interest.

Published

2024