Your search keyword '"Xiaohan Yang"' showing total 6 results

1. Expanding the application of anti-CRISPR proteins in plants for tunable genome editing

Author

Yang Liu, Guoliang Yuan, Brennan Hyden, Gerald A Tuskan, Paul E Abraham, and Xiaohan Yang

Subjects

Physiology, Genetics, Plant Science

Abstract

Anti-CRISPR proteins are very efficient for inhibiting CRISPR/Cas9-based genome editing tools in both herbaceous and woody plant species.

Published

2023

2. Agave REVEILLE1 regulates the onset and release of seasonal dormancy in Populus

Author

Degao Liu, Dan Tang, Meng Xie, Jin Zhang, Longmei Zhai, Jiangping Mao, Chao Luo, Anna Lipzen, Yu Zhang, Emily Savage, Guoliang Yuan, Hao-Bo Guo, Dimiru Tadesse, Rongbin Hu, Sara Jawdy, Hua Cheng, Linling Li, Huseyin Yer, Miranda M Clark, Huayu Sun, Jiyuan Shi, Roshani Budhathoki, Rahul Kumar, Troy Kamuda, Yanjun Li, Christa Pennacchio, Kerrie Barry, Jeremy Schmutz, Rajiv Berry, Wellington Muchero, Jin-Gui Chen, Yi Li, Gerald A Tuskan, and Xiaohan Yang

Subjects

Physiology, Genetics, Plant Science

Abstract

Deciduous woody plants like poplar (Populus spp.) have seasonal bud dormancy. It has been challenging to simultaneously delay the onset of bud dormancy in the fall and advance bud break in the spring, as bud dormancy, and bud break were thought to be controlled by different genetic factors. Here, we demonstrate that heterologous expression of the REVEILLE1 gene (named AaRVE1) from Agave (Agave americana) not only delays the onset of bud dormancy but also accelerates bud break in poplar in field trials. AaRVE1 heterologous expression increases poplar biomass yield by 166% in the greenhouse. Furthermore, we reveal that heterologous expression of AaRVE1 increases cytokinin contents, represses multiple dormancy-related genes, and up-regulates bud break-related genes, and that AaRVE1 functions as a transcriptional repressor and regulates the activity of the DORMANCY-ASSOCIATED PROTEIN 1 (DRM1) promoter. Our findings demonstrate that AaRVE1 appears to function as a regulator of bud dormancy and bud break, which has important implications for extending the growing season of deciduous trees in frost-free temperate and subtropical regions to increase crop yield.

Published

2022

3. The F-Box Gene Family Is Expanded in Herbaceous Annual Plants Relative to Woody Perennial Plants

Author

Timothy J. Tschaplinski, Priya Ranjan, Tongming Yin, Xiaohan Yang, Gerald A. Tuskan, Sara S. Jawdy, David J. Weston, Udaya C. Kalluri, and Lee E. Gunter

Subjects

Populus trichocarpa, Perennial plant, Physiology, fungi, food and beverages, Plant Science, Biology, Herbaceous plant, Oryza, biology.organism_classification, Arabidopsis, Botany, Genetics, Gene family, Arabidopsis thaliana, Woody plant

Abstract

F-box proteins are generally responsible for substrate recognition in the Skp1-Cullin-F-box complexes that are involved in protein degradation via the ubiquitin-26S proteasome pathway. In plants, F-box genes influence a variety of biological processes, such as leaf senescence, branching, self-incompatibility, and responses to biotic and abiotic stresses. The number of F-box genes in Populus (Populus trichocarpa; approximately 320) is less than half that found in Arabidopsis (Arabidopsis thaliana; approximately 660) or Oryza (Oryza sativa; approximately 680), even though the total number of genes in Populus is equivalent to that in Oryza and 1.5 times that in Arabidopsis. We performed comparative genomics analysis between the woody perennial plant Populus and the herbaceous annual plants Arabidopsis and Oryza in order to explicate the functional implications of this large gene family. Our analyses reveal interspecific differences in genomic distribution, orthologous relationship, intron evolution, protein domain structure, and gene expression. The set of F-box genes shared by these species appear to be involved in core biological processes essential for plant growth and development; lineage-specific differences primarily occurred because of an expansion of the F-box genes via tandem duplications in Arabidopsis and Oryza. The number of F-box genes in the newly sequenced woody species Vitis (Vitis vinifera; 156) and Carica (Carica papaya; 139) is similar to that in Populus, supporting the hypothesis that the F-box gene family is expanded in herbaceous annual plants relative to woody perennial plants. This study provides insights into the relationship between the structure and composition of the F-box gene family in herbaceous and woody species and their associated developmental and physiological features.

Published

2008

4. Divergence of the Dof Gene Families in Poplar, Arabidopsis, and Rice Suggests Multiple Modes of Gene Evolution after Duplication

Author

Gerald A. Tuskan, Xiaohan Yang, and Zong-Ming Cheng

Subjects

Genetics, Phylogenetic tree, Physiology, fungi, Plant Science, Biology, Massively parallel signature sequencing, Gene duplication, Subfunctionalization, Gene family, Neofunctionalization, Synonymous substitution, Functional divergence

Abstract

It is widely accepted that gene duplication is a primary source of genetic novelty. However, the evolutionary fate of duplicated genes remains largely unresolved. The classical Ohno's Duplication-Retention-Non/Neofunctionalization theory, and the recently proposed alternatives such as subfunctionalization or duplication-degeneration-complementation, and subneofunctionalization, each can explain one or more aspects of gene fate after duplication. Duplicated genes are also affected by epigenetic changes. We constructed a phylogenetic tree using Dof (DNA binding with one finger) protein sequences from poplar (Populus trichocarpa) Torr. & Gray ex Brayshaw, Arabidopsis (Arabidopsis thaliana), and rice (Oryza sativa). From the phylogenetic tree, we identified 27 pairs of paralogous Dof genes in the terminal nodes. Analysis of protein motif structure of the Dof paralogs and their ancestors revealed six different gene fates after gene duplication. Differential protein methylation was revealed between a pair of duplicated poplar Dof genes, which have identical motif structure and similar expression pattern, indicating that epigenetics is involved in evolution. Analysis of reverse transcription-PCR, massively parallel signature sequencing, and microarray data revealed that the paralogs differ in expression pattern. Furthermore, analysis of nonsynonymous and synonymous substitution rates indicated that divergence of the duplicated genes was driven by positive selection. About one-half of the motifs in Dof proteins were shared by non-Dof proteins in the three plants species, indicating that motif co-option may be one of the forces driving gene diversification. We provided evidence that the Ohno's Duplication-Retention-Non/Neofunctionalization, subfunctionalization/duplication-degeneration-complementation, and subneofunctionalization hypotheses are complementary with, not alternative to, each other.

Published

2006

5. The F-Box Gene Family Is Expanded in Herbaceous Annual Plants Relative to Woody Perennial Plants.

Author

Xiaohan Yang, Kalluri, Udaya C., Jawdy, Sara, Gunter, Lee E., Tongming Yin, Tschaplinski, Timothy J., Weston, David J., Ranjan, Priya, and Tuskan, Gerald A.

Subjects

*PLANT proteins, *BLACK cottonwood, *ARABIDOPSIS thaliana, *BRANCHING (Botany), *PLANT self-incompatibility, *PLANT physiology

Abstract

F-box proteins are generally responsible for substrate recognition in the Skp1-Cullin-F-box complexes that are involved in protein degradation via the ubiquitin-26S proteasome pathway. In plants, F-box genes influence a variety of biological processes, such as leaf senescence, branching, self-incompatibility, and responses to biotic and abiotic stresses. The number of F-box genes in Populus (Populus trichocarpa; approximately 320) is less than half that found in Arabidopsis (Arabidopsis thaliana; approximately 660) or Oryza (Oryza sativa; approximately 680), even though the total number of genes in Populus is equivalent to that in Oryza and 1.5 times that in Arabidopsis. We performed comparative genomics analysis between the woody perennial plant Populus and the herbaceous annual plants Arabidopsis and Oryza in order to explicate the functional implications of this large gene family. Our analyses reveal interspecific differences in genomic distribution, orthologous relationship, intron evolution, protein domain structure, and gene expression. The set of F-box genes shared by these species appear to be involved in core biological processes essential for plant growth and development; lineage-specific differences primarily occurred because of an expansion of the F-box genes via tandem duplications in Arabidopsis and Oryza. The number of F-box genes in the newly sequenced woody species Vitis (Vitis vinifera; 156) and Carica (Carica papaya; 139) is similar to that in Populus, supporting the hypothesis that the F-box gene family is expanded in herbaceous annual plants relative to woody perennial plants. This study provides insights into the relationship between the structure and composition of the F-box gene family in herbaceous and woody species and their associated developmental and physiological features. [ABSTRACT FROM AUTHOR]

Published

2008

6. Divergence of the Dof Gene Families in Poplar, Arabidopsis, and Rice Suggests Multiple Modes of Gene Evolution after Duplication.

Author

Xiaohan Yang, Tuskan, Gerald A., and Zong-Ming Cheng

Subjects

*PLANT genetics, *POPLARS, *ARABIDOPSIS, *RICE, *GENETICS, *BOTANY

Abstract

It is widely accepted that gene duplication is a primary source of genetic novelty. However, the evolutionary fate of duplicated genes remains largely unresolved. The classical Ohno's Duplication-Retention-Non/Neofunctionalization theory, and the recently proposed alternatives such as subfunctionalization or duplication-degeneration-complementation, and subneofunctionalization, each can explain one or more aspects of gene fate after duplication. Duplicated genes are also affected by epigenetic changes. We constructed a phylogenetic tree using Dof (DNA binding with one finger) protein sequences from poplar (Populus trichocarpa) Torr. & Gray ex Brayshaw, Arabidopsis (Arabidopsis thaliana), and rice (Oryza sativa). From the phylogenetic tree, we identified 27 pairs of paralogous Dof genes in the terminal nodes. Analysis of protein motif structure of the Dof paralogs and their ancestors revealed six different gene fates after gene duplication. Differential protein methylation was revealed between a pair of duplicated poplar Dof genes, which have identical motif structure and similar expression pattern, indicating that epigenetics is involved in evolution. Analysis of reverse transcription-PCR, massively parallel signature sequencing, and microarray data revealed that the paralogs differ in expression pattern. Furthermore, analysis of non- synonymous and synonymous substitution rates indicated that divergence of the duplicated genes was driven by positive selection. About one-half of the motifs in Dof proteins were shared by non-Dof proteins in the three plants species, indicating that motif co-option may be one of the forces driving gene diversification. We provided evidence that the Ohno's Duplication- Retention-Non/Neofunctionalization, subfunctionalization/duplication-degeneration-complementation, and subneofunctionalization hypotheses are complementary with, not alternative to, each other. [ABSTRACT FROM AUTHOR]

Published

2006