Your search keyword '"Waalwijk, Cees"' showing total 6 results

1. RNA-Seq analysis reveals new gene models and alternative splicing in the fungal pathogen Fusarium graminearum

Author

Zhao Chunzhao, Waalwijk Cees, de Wit Pierre J G M, Tang Dingzhong, and van der Lee Theo

Subjects

Fusarium graminearum, RNA-Seq, Alternative splicing, Gene annotation, Novel transcriptionally active regions, Biotechnology, TP248.13-248.65, Genetics, QH426-470

Abstract

Abstract Background The genome of Fusarium graminearum has been sequenced and annotated previously, but correct gene annotation remains a challenge. In addition, posttranscriptional regulations, such as alternative splicing and RNA editing, are poorly understood in F. graminearum. Here we took advantage of RNA-Seq to improve gene annotations and to identify alternative splicing and RNA editing in F. graminearum. Results We identified and revised 655 incorrectly predicted gene models, including revisions of intron predictions, intron splice sites and prediction of novel introns. 231 genes were identified with two or more alternative splice variants, mostly due to intron retention. Interestingly, the expression ratios between different transcript isoforms appeared to be developmentally regulated. Surprisingly, no RNA editing was identified in F. graminearum. Moreover, 2459 novel transcriptionally active regions (nTARs) were identified and our analysis indicates that many of these could be missed genes. Finally, we identified the 5′ UTR and/or 3′ UTR sequences of 7666 genes. A number of representative novel gene models and alternatively spliced genes were validated by reverse transcription polymerase chain reaction and sequencing of the generated amplicons. Conclusions We have developed novel and efficient strategies to identify alternatively spliced genes and incorrect gene models based on RNA-Seq data. Our study identified hundreds of alternatively spliced genes in F. graminearum and for the first time indicated that alternative splicing is developmentally regulated in filamentous fungi. In addition, hundreds of incorrect predicted gene models were identified and revised and thousands of nTARs were discovered in our study, which will be helpful for the future genomic and transcriptomic studies in F. graminearum.

Published

2013

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

Author

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

Published

2017

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

Author

Vanheule, Adriaan, primary, Audenaert, Kris, additional, Warris, Sven, additional, van de Geest, Henri, additional, Schijlen, Elio, additional, Höfte, Monica, additional, De Saeger, Sarah, additional, Haesaert, Geert, additional, Waalwijk, Cees, additional, and van der Lee, Theo, additional

Published

2016

4. Relocation of genes generates non-conserved chromosomal segments in Fusarium graminearumthat show distinct and co-regulated gene expression patterns

Author

Zhao, Chunzhao, primary, Waalwijk, Cees, additional, de Wit, Pierre JGM, additional, Tang, Dingzhong, additional, and van der Lee, Theo, additional

Published

2014

5. Relocation of genes generates non-conserved chromosomal segments in Fusarium graminearum that show distinct and co-regulated gene expression patterns.

Author

Chunzhao Zhao, Waalwijk, Cees, de Wit, Pierre J. G. M., Dingzhong Tang, and van der Lee, Theo

Subjects

*FUSARIUM, *CHROMOSOMES, *DEVELOPMENTAL stability (Genetics), *GENE expression, *SECONDARY metabolism, *CONIDIA, *MYCELIUM

Abstract

Background: Genome comparisons between closely related species often show non-conserved regions across chromosomes. Some of them are located in specific regions of chromosomes and some are even confined to one or more entire chromosomes. The origin and biological relevance of these non-conserved regions are still largely unknown. Here we used the genome of Fusarium graminearum to elucidate the significance of non-conserved regions. Results: The genome of F. graminearum harbours thirteen non-conserved regions dispersed over all of the four chromosomes. Using RNA-Seq data from the mycelium of F. graminearum, we found weakly expressed regions on all of the four chromosomes that exactly matched with non-conserved regions. Comparison of gene expression between two different developmental stages (conidia and mycelium) showed that the expression of genes in conserved regions is stable, while gene expression in non-conserved regions is much more influenced by developmental stage. In addition, genes involved in the production of secondary metabolites and secreted proteins are enriched in non-conserved regions, suggesting that these regions could also be important for adaptations to new environments, including adaptation to new hosts. Finally, we found evidence that non-conserved regions are generated by sequestration of genes from multiple locations. Gene relocations may lead to clustering of genes with similar expression patterns or similar biological functions, which was clearly exemplified by the PKS2 gene cluster. Conclusions: Our results showed that chromosomes can be functionally divided into conserved and non-conserved regions, and both could have specific and distinct roles in genome evolution and regulation of gene expression. [ABSTRACT FROM AUTHOR]

Published

2014

6. Relocation of genes generates non-conserved chromosomal segments in Fusarium graminearum that show distinct and co-regulated gene expression patterns.

Author

Zhao C, Waalwijk C, de Wit PJ, Tang D, and van der Lee T

Subjects

Evolution, Molecular, Fusarium metabolism, Gene Expression Profiling, Gene Expression Regulation, Developmental, Multigene Family, Sequence Analysis, RNA, Synteny, Chromosomes, Fungal, Fusarium genetics, Gene Expression Regulation, Fungal, Genes, Fungal

Abstract

Background: Genome comparisons between closely related species often show non-conserved regions across chromosomes. Some of them are located in specific regions of chromosomes and some are even confined to one or more entire chromosomes. The origin and biological relevance of these non-conserved regions are still largely unknown. Here we used the genome of Fusarium graminearum to elucidate the significance of non-conserved regions., Results: The genome of F. graminearum harbours thirteen non-conserved regions dispersed over all of the four chromosomes. Using RNA-Seq data from the mycelium of F. graminearum, we found weakly expressed regions on all of the four chromosomes that exactly matched with non-conserved regions. Comparison of gene expression between two different developmental stages (conidia and mycelium) showed that the expression of genes in conserved regions is stable, while gene expression in non-conserved regions is much more influenced by developmental stage. In addition, genes involved in the production of secondary metabolites and secreted proteins are enriched in non-conserved regions, suggesting that these regions could also be important for adaptations to new environments, including adaptation to new hosts. Finally, we found evidence that non-conserved regions are generated by sequestration of genes from multiple locations. Gene relocations may lead to clustering of genes with similar expression patterns or similar biological functions, which was clearly exemplified by the PKS2 gene cluster., Conclusions: Our results showed that chromosomes can be functionally divided into conserved and non-conserved regions, and both could have specific and distinct roles in genome evolution and regulation of gene expression.

Published

2014