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1. Comparative Transcriptomics of Fusarium graminearum and Magnaporthe oryzae Spore Germination Leading up To Infection

   https://doi.org/10.1128/mbio.02442-22  

   Miguel-Rojas, Cristina; Cavinder, Brad; Townsend, Jeffrey P; Trail, Frances (February 2023, mBio)

   Pietro, Antonio Di (Ed.)

   Fusarium graminearumandMagnaporthe oryzaeare two of the most important pathogens of cereal grains worldwide. Despite years of research, strong host resistance has not been identified forF. graminearum, so other methods of control are essential. 

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2. Inoculation of Maize Ears with Fusarium graminearum to Study Gibberella Ear Rot

   https://doi.org/10.1101/pdb.prot108641  

   Lipps, Sarah; Sorensen, Peyton; Krone, Mara; Mideros, Santiago; Jamann, Tiffany (June 2025, Cold Spring Harbor Protocols)

   Maize is an important food and fuel crop globally. Ear rots, caused by fungal pathogens, are some of the most detrimental maize diseases, due to reduced grain yield and the production of harmful mycotoxins. Mycotoxins are naturally occurring toxins produced by certain fungal species that can cause acute and chronic health issues in humans and animals that consume mycotoxin-contaminated grain. Pathogens can infect the developing ear through silks, or through wounds in the ears produced by pests. Plants naturally develop genetic resistance to pathogens. The maize genes involved in resistance to the pathogen may be different, depending on whether the ear was infected via silks or wounds. To differentiate between these two forms of resistance, natural infections can be reproduced by injecting inoculum through the silk channel, or by producing wounds using a needle, and introducing inoculum directly onto developing ears. Our protocol describes a technique used to inoculate developing maize ears withFusarium graminearum, one of the fungal species that causes ear rot. We describe both silk channel and side needle inoculation techniques. Our protocol uses a backpack inoculator for both methods of infection, allowing for high-throughput inoculations, which are necessary for large field experiments. After harvest, the ears are visually rated on a percentage of disease scale. The protocol results in quantitative data that can be used for research on elucidating genetic resistance to fungal pathogens to assist breeding selections, and to understand plant–pathogen interactions of ear rots in maize. 

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3. Type IV Pilus-Mediated Inhibition of Acinetobacter baumannii Biofilm Formation by Phenothiazine Compounds

   https://doi.org/10.1128/spectrum.01023-23  

   Vo, Nam; Sidner, Benjamin S.; Yu, Yafan; Piepenbrink, Kurt H. (August 2023, Microbiology Spectrum)

   Atack, John M. (Ed.)

   Acinetobacterinfections are a growing burden on health care systems worldwide due to increasing antimicrobial resistance through multiple mechanisms. Biofilm formation is an established mechanism of antimicrobial resistance, and its inhibition has the potential to potentiate the use of existing drugs against pathogenicAcinetobacter. 

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4. Stable Positions of Epigenetically Inherited Centromeres in the Emerging Fungal Pathogen Candida auris and Its Relatives

   https://doi.org/10.1128/mBio.01036-21  

   Rusche, Laura N (August 2021, mBio)

   Candida aurisis an emerging fungal pathogen that is thermotolerant and often resistant to standard antifungal treatments. To trace its evolutionary history, the Sanyal lab conducted a comparative genomic study focusing on the positions of centromeres inC. aurisand eight other species from theClavispora/Candidaclade of yeasts (A. 

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5. Phylogenomic analysis of a 55.1 kb 19-gene dataset resolves a monophyletic Fusarium that includes the Fusarium solani Species Complex

   https://doi.org/10.1094/PHYTO-08-20-0330-LE  

   Geiser, David M; Al-Hatmi, Abdullah; Aoki, Takayuki; Arie, Tsutomu; Balmas, Virgilio; Barnes, Irene; Bergstrom, Gary C; Bhattacharyya, M.K. K.; Blomquist, Cheryl L.; Bowden, Robert; et al (November 2020, Phytopathology®)

   null (Ed.)

   Scientific communication is facilitated by a data-driven, scientifically sound taxonomy that considers the end-user's needs and established successful practice. Previously (Geiser et al. 2013; Phytopathology 103:400-408. 2013), the Fusarium community voiced near unanimous support for a concept of Fusarium that represented a clade comprising all agriculturally and clinically important Fusarium species, including the F. solani Species Complex (FSSC). Subsequently, this concept was challenged by one research group (Lombard et al. 2015 Studies in Mycology 80: 189-245) who proposed dividing Fusarium into seven genera, including the FSSC as the genus Neocosmospora, with subsequent justification based on claims that the Geiser et al. (2013) concept of Fusarium is polyphyletic (Sandoval-Denis et al. 2018; Persoonia 41:109-129). Here we test this claim, and provide a phylogeny based on exonic nucleotide sequences of 19 orthologous protein-coding genes that strongly support the monophyly of Fusarium including the FSSC. We reassert the practical and scientific argument in support of a Fusarium that includes the FSSC and several other basal lineages, consistent with the longstanding use of this name among plant pathologists, medical mycologists, quarantine officials, regulatory agencies, students and researchers with a stake in its taxonomy. In recognition of this monophyly, 40 species recently described as Neocosmospora were recombined in Fusarium, and nine others were renamed Fusarium. Here the global Fusarium community voices strong support for the inclusion of the FSSC in Fusarium, as it remains the best scientific, nomenclatural and practical taxonomic option available. 

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