Your search keyword '"Ware, Sarah B."' showing total 12 results

1. Realizing Present and Future Promise of DIY Biology and Medicine through a Trust Architecture

Author

Rasmussen, Lisa M., Guerrini, Christi J., Kuiken, Todd, Nebeker, Camille, Pearlman, Alex, Ware, Sarah B., Wexler, Anna, and Zettler, Patricia J.

Published

2020

2. Finished genome of the fungal wheat pathogen Mycosphaerella graminicola reveals dispensome structure, chromosome plasticity, and stealth pathogenesis.

Author

Goodwin, Stephen B, M'barek, Sarrah Ben, Dhillon, Braham, Wittenberg, Alexander HJ, Crane, Charles F, Hane, James K, Foster, Andrew J, Van der Lee, Theo AJ, Grimwood, Jane, Aerts, Andrea, Antoniw, John, Bailey, Andy, Bluhm, Burt, Bowler, Judith, Bristow, Jim, van der Burgt, Ate, Canto-Canché, Blondy, Churchill, Alice CL, Conde-Ferràez, Laura, Cools, Hans J, Coutinho, Pedro M, Csukai, Michael, Dehal, Paramvir, De Wit, Pierre, Donzelli, Bruno, van de Geest, Henri C, van Ham, Roeland CHJ, Hammond-Kosack, Kim E, Henrissat, Bernard, Kilian, Andrzej, Kobayashi, Adilson K, Koopmann, Edda, Kourmpetis, Yiannis, Kuzniar, Arnold, Lindquist, Erika, Lombard, Vincent, Maliepaard, Chris, Martins, Natalia, Mehrabi, Rahim, Nap, Jan PH, Ponomarenko, Alisa, Rudd, Jason J, Salamov, Asaf, Schmutz, Jeremy, Schouten, Henk J, Shapiro, Harris, Stergiopoulos, Ioannis, Torriani, Stefano FF, Tu, Hank, de Vries, Ronald P, Waalwijk, Cees, Ware, Sarah B, Wiebenga, Ad, Zwiers, Lute-Harm, Oliver, Richard P, Grigoriev, Igor V, and Kema, Gert HJ

Subjects

Chromosomes, Fungal, Ascomycota, Triticum, Plant Diseases, Gene Rearrangement, Synteny, Genome, Fungal, Genetics, Infectious Diseases, Biotechnology, 2.2 Factors relating to the physical environment, Infection, Developmental Biology

Abstract

The plant-pathogenic fungus Mycosphaerella graminicola (asexual stage: Septoria tritici) causes septoria tritici blotch, a disease that greatly reduces the yield and quality of wheat. This disease is economically important in most wheat-growing areas worldwide and threatens global food production. Control of the disease has been hampered by a limited understanding of the genetic and biochemical bases of pathogenicity, including mechanisms of infection and of resistance in the host. Unlike most other plant pathogens, M. graminicola has a long latent period during which it evades host defenses. Although this type of stealth pathogenicity occurs commonly in Mycosphaerella and other Dothideomycetes, the largest class of plant-pathogenic fungi, its genetic basis is not known. To address this problem, the genome of M. graminicola was sequenced completely. The finished genome contains 21 chromosomes, eight of which could be lost with no visible effect on the fungus and thus are dispensable. This eight-chromosome dispensome is dynamic in field and progeny isolates, is different from the core genome in gene and repeat content, and appears to have originated by ancient horizontal transfer from an unknown donor. Synteny plots of the M. graminicola chromosomes versus those of the only other sequenced Dothideomycete, Stagonospora nodorum, revealed conservation of gene content but not order or orientation, suggesting a high rate of intra-chromosomal rearrangement in one or both species. This observed "mesosynteny" is very different from synteny seen between other organisms. A surprising feature of the M. graminicola genome compared to other sequenced plant pathogens was that it contained very few genes for enzymes that break down plant cell walls, which was more similar to endophytes than to pathogens. The stealth pathogenesis of M. graminicola probably involves degradation of proteins rather than carbohydrates to evade host defenses during the biotrophic stage of infection and may have evolved from endophytic ancestors.

Published

2011

3. Stress and sexual reproduction affect the dynamics of the wheat pathogen effector AvrStb6 and strobilurin resistance

Author

Kema, Gerrit H. J., Mirzadi Gohari, Amir, Aouini, Lamia, Gibriel, Hesham A. Y., Ware, Sarah B., van den Bosch, Frank, Manning-Smith, Robbie, Alonso-Chavez, Vasthi, Helps, Joe, Ben M’Barek, Sarrah, Mehrabi, Rahim, Diaz-Trujillo, Caucasella, Zamani, Elham, Schouten, Henk J., van der Lee, Theo A. J., Waalwijk, Cees, de Waard, Maarten A., de Wit, Pierre J. G. M., Verstappen, Els C. P., Thomma, Bart P. H. J., Meijer, Harold J. G., and Seidl, Michael F.

Published

2018

4. Loop-Mediated Isothermal Amplification Detection of SARS-CoV-2 and Myriad Other Applications

Author

Moore, Keith J. M., primary, Cahill, Jeremy, additional, Aidelberg, Guy, additional, Aronoff, Rachel, additional, Bektaş, Ali, additional, Bezdan, Daniela, additional, Butler, Daniel J., additional, Chittur, Sridar V., additional, Codyre, Martin, additional, Federici, Fernan, additional, Tanner, Nathan A., additional, Tighe, Scott W., additional, True, Randy, additional, Ware, Sarah B., additional, Wyllie, Anne L., additional, Afshin, Evan E., additional, Bendesky, Andres, additional, Chang, Connie B., additional, Dela Rosa, Richard, additional, Elhaik, Eran, additional, Erickson, David, additional, Goldsborough, Andrew S., additional, Grills, George, additional, Hadasch, Kathrin, additional, Hayden, Andrew, additional, Her, Seong-Young, additional, Karl, Julie A., additional, Kim, Chang Hee, additional, Kriegel, Alison J., additional, Kunstman, Thomas, additional, Landau, Zeph, additional, Land, Kevin, additional, Langhorst, Bradley W., additional, Lindner, Ariel B., additional, Mayer, Benjamin E., additional, McLaughlin, Lee A., additional, McLaughlin, Matthew T., additional, Molloy, Jenny, additional, Mozsary, Christopher, additional, Nadler, Jerry L., additional, D'Silva, Melinee, additional, Ng, David, additional, O'Connor, David H., additional, Ongerth, Jerry E., additional, Osuolale, Olayinka, additional, Pinharanda, Ana, additional, Plenker, Dennis, additional, Ranjan, Ravi, additional, Rosbash, Michael, additional, Rotem, Assaf, additional, Segarra, Jacob, additional, Schürer, Stephan, additional, Sherrill-Mix, Scott, additional, Solo-Gabriele, Helena, additional, To, Shaina, additional, Vogt, Merly C., additional, Yu, Albert D., additional, and Mason, Christopher E., additional

Published

2021

5. Discovery of a functional Mycosphaerella teleomorph in the presumed asexual barley pathogen Septoria passerinii

Author

Ware, Sarah B., Verstappen, Els C.P., Breeden, Jill, Cavaletto, Jessica R., Goodwin, Stephen B., Waalwijk, Cees, Crous, Pedro W., and Kema, Gert H.J.

Published

2007

6. Loop-Mediated Isothermal Amplification (LAMP) Detection of SARS-CoV-2 and Myriad Other Applications.

Author

Moore, Keith J. M., Cahill, Jeremy, Aidelberg, Guy, Aronoff, Rachel, Bektaş, Ali, Bezdan, Daniela, Butler, Daniel J., Chittur, Sridar V., Codyre, Martin, Federici, Fernan, Tanner, Nathan A., Tighe, Scott W., True, Randy, Ware, Sarah B., Wyllie, Anne L., Afshin, Evan E., Bendesky, Andres, Chang, Connie B., Rosa, Richard II Dela, and Elhaik, Eran

Published

2021

7. Stress and sexual reproduction affect the dynamics of the wheat pathogen effector AvrStb6 and strobilurin resistance

Author

Kema, Gerrit H J, Mirzadi Gohari, Amir, Aouini, Lamia, Gibriel, Hesham A Y, Ware, Sarah B, van den Bosch, Frank, Manning-Smith, Robbie, Alonso-Chavez, Vasthi, Helps, Joe, Ben M'Barek, Sarrah, Mehrabi, Rahim, Diaz-Trujillo, Caucasella, Zamani, Elham, Schouten, Henk J, van der Lee, Theo A J, Waalwijk, Cees, de Waard, Maarten A, de Wit, Pierre J G M, Verstappen, Els C P, Thomma, Bart P H J, Meijer, Harold J G, Seidl, Michael F, Kema, Gerrit H J, Mirzadi Gohari, Amir, Aouini, Lamia, Gibriel, Hesham A Y, Ware, Sarah B, van den Bosch, Frank, Manning-Smith, Robbie, Alonso-Chavez, Vasthi, Helps, Joe, Ben M'Barek, Sarrah, Mehrabi, Rahim, Diaz-Trujillo, Caucasella, Zamani, Elham, Schouten, Henk J, van der Lee, Theo A J, Waalwijk, Cees, de Waard, Maarten A, de Wit, Pierre J G M, Verstappen, Els C P, Thomma, Bart P H J, Meijer, Harold J G, and Seidl, Michael F

Published

2018

8. Effector discovery in the fungal wheat pathogen Zymoseptoria tritici

Author

Mirzadi Gohari, Amir, Ware, Sarah B., Wittenberg, Alexander H. J., Mehrabi, Rahim, Ben M'Barek, Sarrah, Verstappen, Els C. P., van der Lee, Theo A. J., Robert, Olivier, Schouten, Henk J., de Wit, Pierre P. J. G. M., and Kema, Gert H. J.

Subjects

Fungal Proteins, Ascomycota, Virulence Factors, Gene Expression Profiling, Genes, Fungal, Quantitative Trait Loci, food and beverages, Original Articles, Triticum

Abstract

Fungal plant pathogens, such as Zymoseptoria tritici (formerly known as Mycosphaerella graminicola), secrete repertoires of effectors to facilitate infection or trigger host defence mechanisms. The discovery and functional characterization of effectors provides valuable knowledge that can contribute to the design of new and effective disease management strategies. Here, we combined bioinformatics approaches with expression profiling during pathogenesis to identify candidate effectors of Z. tritici. In addition, a genetic approach was conducted to map quantitative trait loci (QTLs) carrying putative effectors, enabling the validation of both complementary strategies for effector discovery. In planta expression profiling revealed that candidate effectors were up-regulated in successive waves corresponding to consecutive stages of pathogenesis, contrary to candidates identified by QTL mapping that were, overall, expressed at low levels. Functional analyses of two top candidate effectors (SSP15 and SSP18) showed their dispensability for Z. tritici pathogenesis. These analyses reveal that generally adopted criteria, such as protein size, cysteine residues and expression during pathogenesis, may preclude an unbiased effector discovery. Indeed, genetic mapping of genomic regions involved in specificity render alternative effector candidates that do not match the aforementioned criteria, but should nevertheless be considered as promising new leads for effectors that are crucial for the Z. tritici-wheat pathosystem.

Published

2015

9. Effector discovery in the fungal wheat pathogenZymoseptoria tritici

Author

Mirzadi Gohari, Amir, primary, Ware, Sarah B., additional, Wittenberg, Alexander H. J., additional, Mehrabi, Rahim, additional, Ben M'Barek, Sarrah, additional, Verstappen, Els C. P., additional, van der Lee, Theo A. J., additional, Robert, Olivier, additional, Schouten, Henk J., additional, de Wit, Pierre P. J. G. M., additional, and Kema, Gert H. J., additional

Published

2015

10. Finished Genome of the Fungal Wheat Pathogen Mycosphaerella graminicola Reveals Dispensome Structure, Chromosome Plasticity, and Stealth Pathogenesis

Author

Goodwin, Stephen B., M’Barek, Sarrah Ben, Dhillon, Braham, Wittenberg, Alexander H. J., Crane, Charles F., Hane, James K., Foster, Andrew J., Van der Lee, Theo A. J., Grimwood, Jane, Aerts, Andrea, Antoniw, John, Bailey, Andy, Bluhm, Burt, Bowler, Judith, Bristow, Jim, van der Burgt, Ate, Canto-Canche, Blondy, Churchill, Alice C. L., Conde-Ferraez, Laura, Cools, Hans J., Coutinho, Pedro M., Csukai, Michael, Dehal, Paramvir, De Wit, Pierre, Donzelli, Bruno, van de Geest, Henri C., van Ham, Roel C. H. J., Hammond-Kosack, Kim E., Henrissat, Bernard, Kilian, Andrzej, Kobayashi, Adilson K., Koopmann, Edda, Kourmpetis, Yiannis, Kuzniar, Arnold, Lindquist, Erika, Lombard, Vincent, Maliepaard, Chris, Martins, Natalia, Mehrabi, Rahim, Nap, Jan P. H., Ponomarenko, Alisa, Rudd, Jason J., Salamov, Asaf, Schmutz, Jeremy, Schouten, Henk J., Shapiro, Harris, Stergiopoulos, Ioannis, Torriani, Stefano F.F., Tu, Hank, de Vries, Ronald P., Waalwijk, Cees, Ware, Sarah B., Wiebenga, Ad, Zwiers, Lute-Harm, Oliver, Richard P., Grigoriev, Igor V., Kema, Gert. H. J., Goodwin, Stephen B., M’Barek, Sarrah Ben, Dhillon, Braham, Wittenberg, Alexander H. J., Crane, Charles F., Hane, James K., Foster, Andrew J., Van der Lee, Theo A. J., Grimwood, Jane, Aerts, Andrea, Antoniw, John, Bailey, Andy, Bluhm, Burt, Bowler, Judith, Bristow, Jim, van der Burgt, Ate, Canto-Canche, Blondy, Churchill, Alice C. L., Conde-Ferraez, Laura, Cools, Hans J., Coutinho, Pedro M., Csukai, Michael, Dehal, Paramvir, De Wit, Pierre, Donzelli, Bruno, van de Geest, Henri C., van Ham, Roel C. H. J., Hammond-Kosack, Kim E., Henrissat, Bernard, Kilian, Andrzej, Kobayashi, Adilson K., Koopmann, Edda, Kourmpetis, Yiannis, Kuzniar, Arnold, Lindquist, Erika, Lombard, Vincent, Maliepaard, Chris, Martins, Natalia, Mehrabi, Rahim, Nap, Jan P. H., Ponomarenko, Alisa, Rudd, Jason J., Salamov, Asaf, Schmutz, Jeremy, Schouten, Henk J., Shapiro, Harris, Stergiopoulos, Ioannis, Torriani, Stefano F.F., Tu, Hank, de Vries, Ronald P., Waalwijk, Cees, Ware, Sarah B., Wiebenga, Ad, Zwiers, Lute-Harm, Oliver, Richard P., Grigoriev, Igor V., and Kema, Gert. H. J.

Abstract

The plant-pathogenic fungus Mycosphaerella graminicola (asexual stage: Septoria tritici) causes septoria tritici blotch, a disease that greatly reduces the yield and quality of wheat. This disease is economically important in most wheat-growing areas worldwide and threatens global food production. Control of the disease has been hampered by a limited understanding of the genetic and biochemical bases of pathogenicity, including mechanisms of infection and of resistance in the host. Unlike most other plant pathogens, M. graminicola has a long latent period during which it evades host defenses. Although this type of stealth pathogenicity occurs commonly in Mycosphaerella and other Dothideomycetes, the largest class of plant-pathogenic fungi, its genetic basis is not known. To address this problem, the genome of M. graminicola was sequenced completely. The finished genome contains 21 chromosomes, eight of which could be lost with no visible effect on the fungus and thus are dispensable. This eight-chromosome dispensome is dynamic in field and progeny isolates, is different from the core genome in gene and repeat content, and appears to have originated by ancient horizontal transfer from an unknown donor. Synteny plots of the M. graminicola chromosomes versus those of the only other sequenced Dothideomycete, Stagonospora nodorum, revealed conservation of gene content but not order or orientation, suggesting a high rate of intra-chromosomal rearrangement in one or both species.This observed “mesosynteny” is very different from synteny seen between other organisms. A surprising feature of the M. graminicola genome compared to other sequenced plant pathogens was that it contained very few genes for enzymes that break down plant cell walls, which was more similar to endophytes than to pathogens. The stealth pathogenesis of M. graminicola probably involves degradation of proteins rather than carbohydrates to evade host defenses during the biotrophic stage of infection and ma

Published

2011

11. Meiosis Drives Extraordinary Genome Plasticity in the Haploid Fungal Plant Pathogen Mycosphaerella graminicola

Author

Wittenberg, Alexander H.J., Van Der Lee, Theo A. J., M'Barek, Sarrah Ben, Ware, Sarah B, Goodwin, Stephen B, Kilian, Andrzej, Visser, Richard G.F., Kema, Gert H.J., Schouten, Henk J, Wittenberg, Alexander H.J., Van Der Lee, Theo A. J., M'Barek, Sarrah Ben, Ware, Sarah B, Goodwin, Stephen B, Kilian, Andrzej, Visser, Richard G.F., Kema, Gert H.J., and Schouten, Henk J

Abstract

Meiosis in the haploid plant-pathogenic fungus Mycosphaerella graminicola results in eight ascospores due to a mitotic division following the two meiotic divisions. The transient diploid phase allows for recombination among homologous chromosomes. However, some chromosomes of M. graminicola lack homologs and do not pair during meiosis. Because these chromosomes are not present universally in the genome of the organism they can be considered to be dispensable. To analyze the meiotic transmission of unequal chromosome numbers, two segregating populations were generated by crossing genetically unrelated parent isolates originating from Algeria and The Netherlands that had pathogenicity towards durum or bread wheat, respectively. Detailed genetic analyses of these progenies using high-density mapping (1793 DArT, 258 AFLP and 25 SSR markers) and graphical genotyping revealed that M. graminicola has up to eight dispensable chromosomes, the highest number reported in filamentous fungi. These chromosomes vary from 0.39 to 0.77 Mb in size, and represent up to 38% of the chromosomal complement. Chromosome numbers among progeny isolates varied widely, with some progeny missing up to three chromosomes, while other strains were disomic for one or more chromosomes. Between 15–20% of the progeny isolates lacked one or more chromosomes that were present in both parents. The two high-density maps showed no recombination of dispensable chromosomes and hence, their meiotic processing may require distributive disjunction, a phenomenon that is rarely observed in fungi. The maps also enabled the identification of individual twin isolates from a single ascus that shared the same missing or doubled chromosomes indicating that the chromosomal polymorphisms were mitotically stable and originated from nondisjunction during the second division and, less frequently, during the first division of fungal meiosis. High genome plasticity could be among the strategies enabling this versatile pathogen

Published

2009

12. Meiosis Drives Extraordinary Genome Plasticity in the Haploid Fungal Plant Pathogen Mycosphaerella graminicola

Author

Wittenberg, Alexander H. J., primary, van der Lee, Theo A. J., additional, Ben M'Barek, Sarrah, additional, Ware, Sarah B., additional, Goodwin, Stephen B., additional, Kilian, Andrzej, additional, Visser, Richard G. F., additional, Kema, Gert H. J., additional, and Schouten, Henk J., additional

Published

2009