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2. Biased Retention of Environment-Responsive Genes Following Genome Fractionation.

Author

Beringer, Marc, Choudhury, Rimjhim Roy, Mandáková, Terezie, Grünig, Sandra, Poretti, Manuel, Leitch, Ilia J, Lysak, Martin A, and Parisod, Christian

Subjects
GENE expression, GENES, GENOMES, BRASSICACEAE, MUSTARD
Abstract

The molecular underpinnings and consequences of cycles of whole-genome duplication (WGD) and subsequent gene loss through subgenome fractionation remain largely elusive. Endogenous drivers, such as transposable elements (TEs), have been postulated to shape genome-wide dominance and biased fractionation, leading to a conserved least-fractionated (LF) subgenome and a degenerated most-fractionated (MF) subgenome. In contrast, the role of exogenous factors, such as those induced by environmental stresses, has been overlooked. In this study, a chromosome-scale assembly of the alpine buckler mustard (Biscutella laevigata ; Brassicaceae) that underwent a WGD event about 11 million years ago is coupled with transcriptional responses to heat, cold, drought, and herbivory to assess how gene expression is associated with differential gene retention across the MF and LF subgenomes. Counteracting the impact of TEs in reducing the expression and retention of nearby genes across the MF subgenome, dosage balance is highlighted as a main endogenous promoter of the retention of duplicated gene products under purifying selection. Consistent with the "turn a hobby into a job" model, about one-third of environment-responsive duplicates exhibit novel expression patterns, with one copy typically remaining conditionally expressed, whereas the other copy has evolved constitutive expression, highlighting exogenous factors as a major driver of gene retention. Showing uneven patterns of fractionation, with regions remaining unbiased, but with others showing high bias and significant enrichment in environment-responsive genes, this mesopolyploid genome presents evolutionary signatures consistent with an interplay of endogenous and exogenous factors having driven gene content following WGD-fractionation cycles. [ABSTRACT FROM AUTHOR]

Published
2024
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4. A survey of lineage-specific genes in Triticeae reveals de novo gene evolution from genomic raw material

Author

Swiss National Science Foundation, University of Zurich, Poretti, Manuel [0000-0001-6915-2238], Praz, Coraline R. [0000-0002-9133-4406], Sotiropoulos, Alexandros G. [0000-0002-3591-0851], Wicker, Thomas [0000-0002-6777-7135], Poretti, Manuel, Praz, Coraline R., Sotiropoulos, Alexandros G., Wicker, Thomas, Swiss National Science Foundation, University of Zurich, Poretti, Manuel [0000-0001-6915-2238], Praz, Coraline R. [0000-0002-9133-4406], Sotiropoulos, Alexandros G. [0000-0002-3591-0851], Wicker, Thomas [0000-0002-6777-7135], Poretti, Manuel, Praz, Coraline R., Sotiropoulos, Alexandros G., and Wicker, Thomas

Abstract

Diploid plant genomes typically contain ~35,000 genes, almost all belonging to highly conserved gene families. Only a small fraction are lineage-specific, which are found in only one or few closely related species. Little is known about how genes arise de novo in plant genomes and how often this occurs; however, they are believed to be important for plants diversification and adaptation. We developed a pipeline to identify lineage-specific genes in Triticeae, using newly available genome assemblies of wheat, barley, and rye. Applying a set of stringent criteria, we identified 5942 candidate Triticeae-specific genes (TSGs), of which 2337 were validated as protein-coding genes in wheat. Differential gene expression analyses revealed that stress-induced wheat TSGs are strongly enriched in putative secreted proteins. Some were previously described to be involved in Triticeae non-host resistance and cold response. Additionally, we show that 1079 TSGs have sequence homology to transposable elements (TEs), ~68% of them deriving from regulatory non-coding regions of Gypsy retrotransposons. Most importantly, we demonstrate that these TSGs are enriched in transmembrane domains and are among the most highly expressed wheat genes overall. To summarize, we conclude that de novo gene formation is relatively rare and that Triticeae probably possess ~779 lineage-specific genes per haploid genome. TSGs, which respond to pathogen and environmental stresses, may be interesting candidates for future targeted resistance breeding in Triticeae. Finally, we propose that non-coding regions of TEs might provide important genetic raw material for the functional innovation of TM domains and the evolution of novel secreted proteins.

Published
2023

5. A survey of lineage-specific genes in Triticeae reveals de novo gene evolution from genomic raw material

Author

Poretti, Manuel, Praz, Coraline R, Sotiropoulos, Alexandros G, Wicker, Thomas, University of Zurich, Wicker, Thomas, Swiss National Science Foundation, Poretti, Manuel, Praz, Coraline R., and Sotiropoulos, Alexandros G.

Subjects
Ecology, Plant Science, 580 Plants (Botany), Biochemistry, Genetics and Molecular Biology (miscellaneous), 1301 Biochemistry, Genetics and Molecular Biology (miscellaneous), UFSP13-7 Evolution in Action: From Genomes to Ecosystems, 1105 Ecology, Evolution, Behavior and Systematics, 10126 Department of Plant and Microbial Biology, 1110 Plant Science, Triticeae‐specific genes, De novo gene evolution, 10211 Zurich-Basel Plant Science Center, Stress adaptation, Transposable elements, 2303 Ecology, Ecology, Evolution, Behavior and Systematics
Abstract

16 Pág., Diploid plant genomes typically contain ~35,000 genes, almost all belonging to highly conserved gene families. Only a small fraction are lineage-specific, which are found in only one or few closely related species. Little is known about how genes arise de novo in plant genomes and how often this occurs; however, they are believed to be important for plants diversification and adaptation. We developed a pipeline to identify lineage-specific genes in Triticeae, using newly available genome assemblies of wheat, barley, and rye. Applying a set of stringent criteria, we identified 5942 candidate Triticeae-specific genes (TSGs), of which 2337 were validated as protein-coding genes in wheat. Differential gene expression analyses revealed that stress-induced wheat TSGs are strongly enriched in putative secreted proteins. Some were previously described to be involved in Triticeae non-host resistance and cold response. Additionally, we show that 1079 TSGs have sequence homology to transposable elements (TEs), ~68% of them deriving from regulatory non-coding regions of Gypsy retrotransposons. Most importantly, we demonstrate that these TSGs are enriched in transmembrane domains and are among the most highly expressed wheat genes overall. To summarize, we conclude that de novo gene formation is relatively rare and that Triticeae probably possess ~779 lineage-specific genes per haploid genome. TSGs, which respond to pathogen and environmental stresses, may be interesting candidates for future targeted resistance breeding in Triticeae. Finally, we propose that non-coding regions of TEs might provide important genetic raw material for the functional innovation of TM domains and the evolution of novel secreted proteins., This work was supported by the Swiss National Foundation grant 31003A_163325.University of Zurich Research Priority Program, Grant/Award Number: U-702-21-01; Swiss National Foundation, Grant/Award Number: 31003A_163325

Published
2023

7. A survey of lineage-specific genes in Triticeae reveals de novo gene evolution from genomic raw material

Author

Poretti, Manuel; https://orcid.org/0000-0001-6915-2238, Praz, Coraline R; https://orcid.org/0000-0002-9133-4406, Sotiropoulos, Alexandros G; https://orcid.org/0000-0002-3591-0851, Wicker, Thomas; https://orcid.org/0000-0002-6777-7135, Poretti, Manuel; https://orcid.org/0000-0001-6915-2238, Praz, Coraline R; https://orcid.org/0000-0002-9133-4406, Sotiropoulos, Alexandros G; https://orcid.org/0000-0002-3591-0851, and Wicker, Thomas; https://orcid.org/0000-0002-6777-7135

Abstract

Diploid plant genomes typically contain ~35,000 genes, almost all belonging to highly conserved gene families. Only a small fraction are lineage-specific, which are found in only one or few closely related species. Little is known about how genes arise de novo in plant genomes and how often this occurs; however, they are believed to be important for plants diversification and adaptation. We developed a pipeline to identify lineage-specific genes in Triticeae, using newly available genome assemblies of wheat, barley, and rye. Applying a set of stringent criteria, we identified 5942 candidate Triticeae-specific genes (TSGs), of which 2337 were validated as protein-coding genes in wheat. Differential gene expression analyses revealed that stress-induced wheat TSGs are strongly enriched in putative secreted proteins. Some were previously described to be involved in Triticeae non-host resistance and cold response. Additionally, we show that 1079 TSGs have sequence homology to transposable elements (TEs), ~68% of them deriving from regulatory non-coding regions of Gypsy retrotransposons. Most importantly, we demonstrate that these TSGs are enriched in transmembrane domains and are among the most highly expressed wheat genes overall. To summarize, we conclude that de novo gene formation is relatively rare and that Triticeae probably possess ~779 lineage-specific genes per haploid genome. TSGs, which respond to pathogen and environmental stresses, may be interesting candidates for future targeted resistance breeding in Triticeae. Finally, we propose that non-coding regions of TEs might provide important genetic raw material for the functional innovation of TM domains and the evolution of novel secreted proteins.

Published
2023

8. Transposable Element Populations Shed Light on the Evolutionary History of Wheat and the Complex Co-Evolution of Autonomous and Non-Autonomous Retrotransposons

Author

Wicker, Thomas; https://orcid.org/0000-0002-6777-7135, Stritt, Christoph; https://orcid.org/0000-0002-3167-6658, Sotiropoulos, Alexandros G; https://orcid.org/0000-0002-3591-0851, Poretti, Manuel; https://orcid.org/0000-0001-6915-2238, Pozniak, Curtis J; https://orcid.org/0000-0002-7536-3856, Walkowiak, Sean, Gundlach, Heidrun; https://orcid.org/0000-0002-6757-0943, Stein, Nils; https://orcid.org/0000-0003-3011-8731, Wicker, Thomas; https://orcid.org/0000-0002-6777-7135, Stritt, Christoph; https://orcid.org/0000-0002-3167-6658, Sotiropoulos, Alexandros G; https://orcid.org/0000-0002-3591-0851, Poretti, Manuel; https://orcid.org/0000-0001-6915-2238, Pozniak, Curtis J; https://orcid.org/0000-0002-7536-3856, Walkowiak, Sean, Gundlach, Heidrun; https://orcid.org/0000-0002-6757-0943, and Stein, Nils; https://orcid.org/0000-0003-3011-8731

Abstract

Wheat has one of the largest and most repetitive genomes among major crop plants, containing over 85% transposable elements (TEs). TEs populate genomes much in the way that individuals populate ecosystems, diversifying into different lineages, sub-families and sub-populations. The recent availability of high-quality, chromosome-scale genome sequences from ten wheat lines enables a detailed analysis how TEs evolved in allohexaploid wheat, its diploids progenitors, and in various chromosomal haplotype segments. LTR retrotransposon families evolved into distinct sub-populations and sub-families that were active in waves lasting several hundred thousand years. Furthermore, It is shown that different retrotransposon sub-families were active in the three wheat sub-genomes, making them useful markers to study and date polyploidization events and chromosomal rearrangements. Additionally, haplotype-specific TE sub-families are used to characterize chromosomal introgressions in different wheat lines. Additionally, populations of non-autonomous TEs co-evolved over millions of years with their autonomous partners, leading to complex systems with multiple types of autonomous, semi-autonomous and non-autonomous elements. Phylogenetic and TE population analyses revealed the relationships between non-autonomous elements and their mobilizing autonomous partners. TE population analysis provided insights into genome evolution of allohexaploid wheat and genetic diversity of species, and may have implication for future crop breeding.

Published
2022

10. Transposable element populations shed light on the evolutionary history of wheat and the complex co-evolution of autonomous and non-autonomous retrotransposons

Author

Wicker, Thomas, Stritt, Christoph, Sotiropoulos, Alexandros G, Poretti, Manuel, Pozniak, Curtis J, Walkowiak, Sean, Gundlach, Heidrun, Stein, Nils, and University of Zurich

Subjects
UFSP13-7 Evolution in Action: From Genomes to Ecosystems, 10126 Department of Plant and Microbial Biology, LTR-retrotransposon, chromosomal introgression, non-autonomous element, TE population, Genetics, food and beverages, 580 Plants (Botany), 10211 Zurich-Basel Plant Science Center, Molecular Biology, Biochemistry
Abstract

Wheat has one of the largest and most repetitive genomes among major crop plants, containing over 85% transposable elements (TEs). TEs populate genomes much in the way that individuals populate ecosystems, diversifying into different lineages, sub-families and sub-populations. The recent availability of high-quality, chromosome-scale genome sequences from ten wheat lines enables a detailed analysis how TEs evolved in allohexaploid wheat, its diploids progenitors, and in various chromosomal haplotype segments. LTR retrotransposon families evolved into distinct sub-populations and sub-families that were active in waves lasting several hundred thousand years. Furthermore, It is shown that different retrotransposon sub-families were active in the three wheat sub-genomes, making them useful markers to study and date polyploidization events and chromosomal rearrangements. Additionally, haplotype-specific TE sub-families are used to characterize chromosomal introgressions in different wheat lines. Additionally, populations of non-autonomous TEs co-evolved over millions of years with their autonomous partners, leading to complex systems with multiple types of autonomous, semi-autonomous and non-autonomous elements. Phylogenetic and TE population analyses revealed the relationships between non-autonomous elements and their mobilizing autonomous partners. TE population analysis provided insights into genome evolution of allohexaploid wheat and genetic diversity of species, and may have implication for future crop breeding.

Published
2022

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