Your search keyword '"Grant Nickles"' showing total 5 results

1. Copper starvation induces antimicrobial isocyanide integrated into two distinct biosynthetic pathways in fungi

Author

Tae Hyung Won, Jin Woo Bok, Nischala Nadig, Nandhitha Venkatesh, Grant Nickles, Claudio Greco, Fang Yun Lim, Jennifer B. González, B. Gillian Turgeon, Nancy P. Keller, and Frank C. Schroeder

Subjects

Science

Abstract

The genomes of filamentous fungi, such as Aspergillus, include many biosynthetic gene clusters of unknown function. Here, the authors show that copper starvation induces expression of an enzyme that generates a valine-derived isocyanide participating in two different pathways, for biosynthesis of acylated sugar alcohols and modified ergot alkaloids.

Published

2022

2. Secreted Secondary Metabolites Reduce Bacterial Wilt Severity of Tomato in Bacterial–Fungal Co-Infections

Author

Nandhitha Venkatesh, Max J. Koss, Claudio Greco, Grant Nickles, Philipp Wiemann, and Nancy P. Keller

Subjects

secondary metabolites, plant–microbe interactions, coinfection, wilt disease, bacterial–fungal interactions, Fusarium oxysporum, Biology (General), QH301-705.5

Abstract

In order to gain a comprehensive understanding of plant disease in natural and agricultural ecosystems, it is essential to examine plant disease in multi-pathogen–host systems. Ralstonia solanacearum and Fusarium oxysporum f. sp. lycopersici are vascular wilt pathogens that can result in heavy yield losses in susceptible hosts such as tomato. Although both pathogens occupy the xylem, the costs of mixed infections on wilt disease are unknown. Here, we characterize the consequences of co-infection with R. solanacearum and F. oxysporum using tomato as the model host. Our results demonstrate that bacterial wilt severity is reduced in co-infections, that bikaverin synthesis by Fusarium contributes to bacterial wilt reduction, and that the arrival time of each microbe at the infection court is important in driving the severity of wilt disease. Further, analysis of the co-infection root secretome identified previously uncharacterized secreted metabolites that reduce R. solanacearum growth in vitro and provide protection to tomato seedlings against bacterial wilt disease. Taken together, these results highlight the need to understand the consequences of mixed infections in plant disease.

Published

2021

3. Correlative metabologenomics of 110 fungi reveals metabolite–gene cluster pairs

Author

Lindsay K. Caesar, Fatma A. Butun, Matthew T. Robey, Navid J. Ayon, Raveena Gupta, David Dainko, Jin Woo Bok, Grant Nickles, Robert J. Stankey, Don Johnson, David Mead, Kristof B. Cank, Cody E. Earp, Huzefa A. Raja, Nicholas H. Oberlies, Nancy P. Keller, and Neil L. Kelleher

Subjects

Cell Biology, Molecular Biology, Article

Abstract

Natural products research increasingly applies -omics technologies to guide molecular discovery. While the combined analysis of genomic and metabolomic datasets has proved valuable for identifying natural products and their biosynthetic gene clusters (BGCs) in bacteria, this integrated approach lacks application to fungi. Because fungi are hyper-diverse and underexplored for new chemistry and bioactivities, we created a linked genomics–metabolomics dataset for 110 Ascomycetes, and optimized both gene cluster family (GCF) networking parameters and correlation-based scoring for pairing fungal natural products with their BGCs. Using a network of 3,007 GCFs (organized from 7,020 BGCs), we examined 25 known natural products originating from 16 known BGCs and observed statistically significant associations between 21 of these compounds and their validated BGCs. Furthermore, the scalable platform identified the BGC for the pestalamides, demystifying its biogenesis, and revealed more than 200 high-scoring natural product–GCF linkages to direct future discovery.

Published

2023

4. Comprehensive Guide to Extracting and Expressing Fungal Secondary Metabolites with Aspergillus fumigatus as a Case Study

Author

Grant Nickles, Isabelle Ludwikoski, Jin Woo Bok, and Nancy P. Keller

Subjects

Medical Laboratory Technology, Aspergillus, Bacteria, General Immunology and Microbiology, Aspergillus fumigatus, Multigene Family, General Neuroscience, Fungi, Health Informatics, General Pharmacology, Toxicology and Pharmaceutics, Article, General Biochemistry, Genetics and Molecular Biology

Abstract

Fungal secondary metabolites (SMs) have captured the interest of natural products researchers in academia and industry for decades. In recent years, the high rediscovery rate of previously characterized metabolites is making it increasingly difficult to uncover novel compounds. Additionally, the vast majority of fungal SMs reside in genetically intractable fungi or are silent under normal laboratory conditions in genetically tractable fungi. The fungal natural products community has broadly overcome these barriers by altering the physical growth conditions of the fungus and heterologous/homologous expression of biosynthetic gene cluster regulators or proteins. The protocols described here summarize vital methodologies needed when researching SM production in fungi. We also summarize the growth conditions, genetic backgrounds, and extraction protocols for every published SM in Aspergillus fumigatus, enabling readers to easily replicate the production of previously characterized SMs. Readers will also be equipped with the tools for developing their own strategy for expressing and extracting SMs from their given fungus or a suitable heterologous model system. © 2021 Wiley Periodicals LLC. Basic Protocol 1: Making glycerol stocks from spore suspensions Alternate Protocol 1: Creating glycerol stocks from non-sporulating filamentous fungi Basic Protocol 2: Activating spore-suspension glycerol stocks Basic Protocol 3: Extracting secondary metabolites from Aspergillus spp grown on solid medium Alternate Protocol 2: Extracting secondary metabolites from Aspergillus spp using ethyl acetate Alternate Protocol 3: High-volume metabolite extraction using ethyl acetate Alternate Protocol 4: Extracting secondary metabolites from Aspergillus spp in liquid medium Support Protocol: Creating an overlay culture Basic Protocol 4: Extracting DNA from filamentous fungi Basic Protocol 5: Creating a DNA construct with double-joint PCR Alternate Protocol 5: Creating a DNA construct with yeast recombineering Basic Protocol 6: Transformation of Aspergillus spp Basic Protocol 7: Co-culturing fungi and bacteria for extraction of secondary metabolites.

Published

2021

5. Secreted Secondary Metabolites Reduce Bacterial Wilt Severity of Tomato in Bacterial-Fungal Co-Infections

Author

Claudio Greco, Philipp Wiemann, Nancy P. Keller, Max J Koss, Nandhitha Venkatesh, and Grant Nickles

Subjects

Microbiology (medical), Fusarium, plant–microbe interactions, Ralstonia solanacearum, QH301-705.5, wilt disease, Microbiology, Article, Virology, Fusarium oxysporum, Biology (General), Wilt disease, biology, Host (biology), secondary metabolites, Bacterial wilt, fungi, Xylem, food and beverages, biology.organism_classification, Plant disease, coinfection, bacterial–fungal interactions

Abstract

In order to gain a comprehensive understanding of plant disease in natural and agricultural ecosystems, it is essential to examine plant disease in multi-pathogen–host systems. Ralstonia&nbsp, solanacearum and Fusarium oxysporum f. sp. lycopersici are vascular wilt pathogens that can result in heavy yield losses in susceptible hosts such as tomato. Although both pathogens occupy the xylem, the costs of mixed infections on wilt disease are unknown. Here, we characterize the consequences of co-infection with R. solanacearum and F. oxysporum using tomato as the model host. Our results demonstrate that bacterial wilt severity is reduced in co-infections, that bikaverin synthesis by Fusarium contributes to bacterial wilt reduction, and that the arrival time of each microbe at the infection court is important in driving the severity of wilt disease. Further, analysis of the co-infection root secretome identified previously uncharacterized secreted metabolites that reduce R. solanacearum growth in vitro and provide protection to tomato seedlings against bacterial wilt disease. Taken together, these results highlight the need to understand the consequences of mixed infections in plant disease.

Published

2021