Your search keyword '"Waalwijk, Cees"' showing total 10 results

1. Living apart together: crosstalk between the core and supernumerary genomes in a fungal plant pathogen.

Author

Vanheule A, Audenaert K, Warris S, van de Geest H, Schijlen E, Höfte M, De Saeger S, Haesaert G, Waalwijk C, and van der Lee T

Subjects

Base Composition, DNA Transposable Elements, Evolution, Molecular, Gene Duplication, Genome Size, Point Mutation, Real-Time Polymerase Chain Reaction, Chromosomes, Fungal genetics, Fungi genetics, Sequence Analysis, DNA methods, Triticum microbiology

Abstract

Background: Eukaryotes display remarkable genome plasticity, which can include supernumerary chromosomes that differ markedly from the core chromosomes. Despite the widespread occurrence of supernumerary chromosomes in fungi, their origin, relation to the core genome and the reason for their divergent characteristics are still largely unknown. The complexity of genome assembly due to the presence of repetitive DNA partially accounts for this., Results: Here we use single-molecule real-time (SMRT) sequencing to assemble the genome of a prominent fungal wheat pathogen, Fusarium poae, including at least one supernumerary chromosome. The core genome contains limited transposable elements (TEs) and no gene duplications, while the supernumerary genome holds up to 25 % TEs and multiple gene duplications. The core genome shows all hallmarks of repeat-induced point mutation (RIP), a defense mechanism against TEs, specific for fungi. The absence of RIP on the supernumerary genome accounts for the differences between the two (sub)genomes, and results in a functional crosstalk between them. The supernumerary genome is a reservoir for TEs that migrate to the core genome, and even large blocks of supernumerary sequence (>200 kb) have recently translocated to the core. Vice versa, the supernumerary genome acts as a refuge for genes that are duplicated from the core genome., Conclusions: For the first time, a mechanism was determined that explains the differences that exist between the core and supernumerary genome in fungi. Different biology rather than origin was shown to be responsible. A "living apart together" crosstalk exists between the core and supernumerary genome, accelerating chromosomal and organismal evolution.

Published

2016

2. A combined amplified fragment length polymorphism and randomly amplified polymorphism DNA genetic kinkage map of Mycosphaerella graminicola, the septoria tritici leaf blotch pathogen of wheat.

Author

Kema GH, Goodwin SB, Hamza S, Verstappen EC, Cavaletto JR, Van der Lee TA, de Weerdt M, Bonants PJ, and Waalwijk C

Subjects

Electrophoresis, Gel, Pulsed-Field, Fungi pathogenicity, Genetic Markers, Triticum genetics, Triticum microbiology, Chromosome Mapping, Fungi genetics, Random Amplified Polymorphic DNA Technique

Abstract

An F(1) mapping population of the septoria tritici blotch pathogen of wheat, Mycosphaerella graminicola, was generated by crossing the two Dutch field isolates IPO323 and IPO94269. AFLP and RAPD marker data sets were combined to produce a high-density genetic linkage map. The final map contained 223 AFLP and 57 RAPD markers, plus the biological traits mating type and avirulence, in 23 linkage groups spanning 1216 cM. Many AFLPs and some RAPD markers were clustered. When markers were reduced to 1 per cluster, 229 unique positions were mapped, with an average distance of 5.3 cM between markers. Because M. graminicola probably has 17 or 18 chromosomes, at least 5 of the 23 linkage groups probably will need to be combined with others once additional markers are added to the map. This was confirmed by pulsed-field gel analysis; probes derived from 2 of the smallest linkage groups hybridized to two of the largest chromosome-sized bands, revealing a discrepancy between physical and genetic distance. The utility of the map was demonstrated by identifying molecular markers tightly linked to two genes of biological interest, mating type and avirulence. Bulked segregant analysis was used to identify additional molecular markers closely linked to these traits. This is the first genetic linkage map for any species in the genus Mycosphaerella or the family Mycosphaerellaceae.

Published

2002

3. Isolation and characterization of the mating-type idiomorphs from the wheat septoria leaf blotch fungus Mycosphaerella graminicola.

Author

Waalwijk C, Mendes O, Verstappen EC, de Waard MA, and Kema GH

Subjects

Amino Acid Sequence, Cloning, Molecular, DNA Primers, Fungal Proteins genetics, Molecular Sequence Data, Sequence Alignment, Sequence Analysis, DNA, Fungi genetics, Genes, Fungal, Genes, Mating Type, Fungal, Triticum microbiology

Abstract

Both mating-type loci from the wheat septoria leaf blotch pathogen Mycosphaerella graminicola have been cloned and sequenced. The MAT1-2 gene was identified by screening a genomic library from the MAT1-2 isolate IPO94269 with a heterologous probe from Tapesia yallundae. The MAT1-2 idiomorph is 2772 bp and contains a single gene encoding a putative high-mobility-group protein of 394 amino acids. The opposite idiomorph was obtained from isolate IPO323, which has the complementary mating type, by long-range PCR using primers derived from sequences flanking the MAT1-2 idiomorph. The MAT1-1 locus is 2839 bp in size and contains a single open reading frame encoding a putative alpha1-domain protein of 297 amino acids. Within the nonidiomorphic sequences, homology was found with palI, encoding a membrane receptor from Aspergillus nidulans, and a gene encoding a putative component of the anaphase-promoting complex from Schizosaccharomyces pombe and a DNA-(apurinic or apyrimidinic) lyase from S. pombe. For each of the MAT genes specific primers were designed and tested on an F1 mapping population that was generated from a cross between IPO323 and IPO94269. An absolute correlation was found between the amplified allele-specific fragments and the mating type as determined by backcrosses of each F1 progeny isolate to the parental isolates. The primers were also used to screen a collection of field isolates in a multiplex PCR. An equal distribution of MAT1-1 and MAT1-2 alleles was found for most geographic origins examined.

Published

2002

4. No to Neocosmospora: Phylogenomic and Practical Reasons for Continued Inclusion of the Fusarium solani Species Complex in the Genus Fusarium

Author

O’Donnell, Kerry, Al-Hatmi, Abdullah MS, Aoki, Takayuki, Brankovics, Balázs, Cano-Lira, José F, Coleman, Jeffrey J, de Hoog, G Sybren, Di Pietro, Antonio, Frandsen, Rasmus JN, Geiser, David M, Gibas, Connie FC, Guarro, Josep, Kim, Hye-Seon, Kistler, H Corby, Laraba, Imane, Leslie, John F, López-Berges, Manuel S, Lysøe, Erik, Meis, Jacques F, Monod, Michel, Proctor, Robert H, Rep, Martijn, Ruiz-Roldán, Carmen, Šišić, Adnan, Stajich, Jason E, Steenkamp, Emma T, Summerell, Brett A, van der Lee, Theo AJ, van Diepeningen, Anne D, Verweij, Paul E, Waalwijk, Cees, Ward, Todd J, Wickes, Brian L, Wiederhold, Nathan P, Wingfield, Michael J, Zhang, Ning, and Zhang, Sean X

Subjects

Microbiology, Biological Sciences, Infectious Diseases, Infection, Good Health and Well Being, Antifungal Agents, Fusarium, Phylogeny, clinical mycology, evolution, fungi, phylogenetics, taxonomy, Immunology

Abstract

This article is to alert medical mycologists and infectious disease specialists of recent name changes of medically important species of the filamentous mold FusariumFusarium species can cause localized and life-threating infections in humans. Of the 70 Fusarium species that have been reported to cause infections, close to one-third are members of the Fusarium solani species complex (FSSC), and they collectively account for approximately two-thirds of all reported Fusarium infections. Many of these species were recently given scientific names for the first time by a research group in the Netherlands, but they were misplaced in the genus Neocosmospora In this paper, we present genetic arguments that strongly support inclusion of the FSSC in Fusarium There are potentially serious consequences associated with using the name Neocosmospora for Fusarium species because clinicians need to be aware that fusaria are broadly resistant to the spectrum of antifungals that are currently available.

Published

2020

5. No to Neocosmospora: Phylogenomic and Practical Reasons for Continued Inclusion of the Fusarium solani Species Complex in the Genus Fusarium.

Author

O'Donnell, Kerry, Al-Hatmi, Abdullah MS, Aoki, Takayuki, Brankovics, Balázs, Cano-Lira, José F, Coleman, Jeffrey J, de Hoog, G Sybren, Di Pietro, Antonio, Frandsen, Rasmus JN, Geiser, David M, Gibas, Connie FC, Guarro, Josep, Kim, Hye-Seon, Kistler, H Corby, Laraba, Imane, Leslie, John F, López-Berges, Manuel S, Lysøe, Erik, Meis, Jacques F, Monod, Michel, Proctor, Robert H, Rep, Martijn, Ruiz-Roldán, Carmen, Šišić, Adnan, Stajich, Jason E, Steenkamp, Emma T, Summerell, Brett A, van der Lee, Theo AJ, van Diepeningen, Anne D, Verweij, Paul E, Waalwijk, Cees, Ward, Todd J, Wickes, Brian L, Wiederhold, Nathan P, Wingfield, Michael J, Zhang, Ning, and Zhang, Sean X

Subjects

Fusarium, Antifungal Agents, Phylogeny, clinical mycology, evolution, fungi, phylogenetics, taxonomy, Infectious Diseases, Infection

Abstract

This article is to alert medical mycologists and infectious disease specialists of recent name changes of medically important species of the filamentous mold Fusarium Fusarium species can cause localized and life-threating infections in humans. Of the 70 Fusarium species that have been reported to cause infections, close to one-third are members of the Fusarium solani species complex (FSSC), and they collectively account for approximately two-thirds of all reported Fusarium infections. Many of these species were recently given scientific names for the first time by a research group in the Netherlands, but they were misplaced in the genus Neocosmospora In this paper, we present genetic arguments that strongly support inclusion of the FSSC in Fusarium There are potentially serious consequences associated with using the name Neocosmospora for Fusarium species because clinicians need to be aware that fusaria are broadly resistant to the spectrum of antifungals that are currently available.

Published

2020

6. TAGGING PATHOGENICITY GENES IN FUSARIUM GRAMINEARUM USING THE TRANSPOSON SYSTEM MIMP/IMPALA

Author

DUFRESNE, Marie, VAN DER LEE, Theo, M’BAREK, Sarrah BEN, XU, X., ZHANG, X., LIU, Taiguo, ZHANG, Wenwei, KEMA, Gert H.J., DABOUSSI, Marie-Josée, and WAALWIJK, Cees

Published

2008

7. The Fusarium graminearum Genome Reveals a Link between Localized Polymorphism and Pathogen Specialization

Author

Cuomo, Christina A., Güldener, Ulrich, Xu, Jin-Rong, Trail, Frances, Turgeon, B. Gillian, Di Pietro, Antonio, Walton, Jonathan D., Ma, Li-Jun, Baker, Scott E., Rep, Martijn, Adam, Gerhard, Antoniw, John, Baldwin, Thomas, Calvo, Sarah, Chang, Yueh-Long, DeCaprio, David, Gale, Liane R., Gnerre, Sante, Goswami, Rubella S., Hammond-Kosack, Kim, Harris, Linda J., Hilburn, Karen, Kennell, John C., Kroken, Scott, Magnuson, Jon K., Mannhaupt, Gertrud, Mauceli, Evan, Mewes, Hans-Werner, Mitterbauer, Rudolf, Muehlbauer, Gary, Münsterkötter, Martin, Nelson, David, O'Donnell, Kerry, Ouellet, Thérèse, Qi, Weihong, Quesneville, Hadi, Roncero, M. Isabel G., Seong, Kye-Yong, Tetko, Igor V., Urban, Martin, Waalwijk, Cees, Ward, Todd J., Yao, Jiqiang, Birren, Bruce W., and Kistler, H. Corby

Published

2007

8. TOWARDS ISOLATION OF AVIRULENCE FACTORS IN FUSARIUM OXYSPORUM FROM CARNATION

Author

WAALWIJK, CEES and DE KONING, JACQ R.A.

Published

1997

9. Mitochondrial genomes reveal recombination in the presumed asexual Fusarium oxysporum species complex.

Author

Brankovics, Balázs, van Dam, Peter, Rep, Martijn, de Hoog, G. Sybren, van der Lee, Theo A. J., Waalwijk, Cees, and van Diepeningen, Anne D.

Subjects

FUSARIUM oxysporum, GENETIC recombination, MITOCHONDRIA, FUNGAL phylogeny, GENEALOGY, FUNGI

Abstract

Background: The Fusarium oxysporum species complex (FOSC) contains several phylogenetic lineages. Phylogenetic studies identified two to three major clades within the FOSC. The mitochondrial sequences are highly informative phylogenetic markers, but have been mostly neglected due to technical difficulties. Results: A total of 61 complete mitogenomes of FOSC strains were de novo assembled and annotated. Length variations and intron patterns support the separation of three phylogenetic species. The variable region of the mitogenome that is typical for the genus Fusarium shows two new variants in the FOSC. The variant typical for Fusarium is found in members of all three clades, while variant 2 is found in clades 2 and 3 and variant 3 only in clade 2. The extended set of loci analyzed using a new implementation of the genealogical concordance species recognition method support the identification of three phylogenetic species within the FOSC. Comparative analysis of the mitogenomes in the FOSC revealed ongoing mitochondrial recombination within, but not between phylogenetic species. Conclusions: The recombination indicates the presence of a parasexual cycle in F. oxysporum. The obstacles hindering the usage of the mitogenomes are resolved by using next generation sequencing and selective genome assemblers, such as GRAbB. Complete mitogenome sequences offer a stable basis and reference point for phylogenetic and population genetic studies. [ABSTRACT FROM AUTHOR]

Published

2017

10. Molecular Diagnostics for the Sigatoka Disease Complex of Banana.

Author

Arzanlou, Mahdi, Abein, Edwin C. A., Kema, Gert H. J., Waalwijk, Cees, Carlier, Jean, De Vries, Ineke, Guzmán, Mauricio, and Crous, Pedro W.

Subjects

*FUNGAL diseases of plants, *PLANT diseases, *BANANA diseases & pests, *MYCOSPHAERELLA, *FUNGI, *MOLECULAR diagnosis, *POLYMERASE chain reaction, *DNA, *DEOXYRIBOSE

Abstract

The Sigatoka disease complex of banana involves three related ascomycetous fungi, Mycosphaerella fijiensis, M. musicolci, and M. eurnusae. The exact distribution of these three species and their disease epidemiology remain unclear, because their symptoms and life cycles are rather similar. Disease diagnosis in the Mycosphaerella complex of banana is based on the presence of host symptoms and fungal fruiting structures, which hamper preventive management strategies. In the present study, we have developed rapid and robust species-specific molecular-based diagnostic tools for detection and quantification of M. fijiensis, M. musicola, and M. eumusae. Conventional species-specific polymerase chain reaction (PCR) primers were developed based on the actin gene that detected DNA at as little as 100, 1, and 10 pg/μl from M. fijiensis, M. musicola, and M. eumusae, respectively. Furthermore, TaqMan real-time quantitative PCR assays were developed based on the β-tubulin gene and detected quantities of DNA as low as I pg/μl for each Mycosphaerella sp. from pure cultures and DNA at 1.6 pg/μl per milligram of dry leaf tissue for M. fijiensis that was validated using naturally infected banana leaves. [ABSTRACT FROM AUTHOR]

Published

2007