Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species

Külahoglu C, Denton AK, Sommer M, Mass J, Schliesky S, Wrobel TJ, Berckmans B, Gongora-Castillo E, Buell CR, Simon R, De Veylder L, et al. (2014)
Plant Cell 26(8): 3243-3260.

Zeitschriftenaufsatz | Veröffentlicht | Englisch
 
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urn:nbn:de:0070-pub-29151340
Autor*in
Külahoglu, Canan; Denton, Alisandra K.; Sommer, Manuel; Mass, Janina; Schliesky, Simon; Wrobel, Thomas J.; Berckmans, Barbara; Gongora-Castillo, Elsa; Buell, C. Robin; Simon, Ruediger; De Veylder, Lieven; Bräutigam, AndreaUniBi
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Fakultät für Biologie > Computational Biology
Abstract / Bemerkung
C-4 photosynthesis outperforms the ancestral C-3 state in a wide range of natural and agro-ecosystems by affording higher water-use and nitrogen-use efficiencies. It therefore represents a prime target for engineering novel, high-yielding crops by introducing the trait into C-3 backgrounds. However, the genetic architecture of C-4 photosynthesis remains largely unknown. To define the divergence in gene expression modules between C-3 and C-4 photosynthesis during leaf ontogeny, we generated comprehensive transcriptome atlases of two Cleomaceae species, Gynandropsis gynandra (C-4) and Tarenaya hassleriana (C-3), by RNA sequencing. Overall, the gene expression profiles appear remarkably similar between the C-3 and C-4 species. We found that known C-4 genes were recruited to photosynthesis from different expression domains in C-3, including typical housekeeping gene expression patterns in various tissues as well as individual heterotrophic tissues. Furthermore, we identified a structure-related module recruited from the C-3 root. Comparison of gene expression patterns with anatomy during leaf ontogeny provided insight into genetic features of Kranz anatomy. Altered expression of developmental factors and cell cycle genes is associated with a higher degree of endoreduplication in enlarged C-4 bundle sheath cells. A delay in mesophyll differentiation apparent both in the leaf anatomy and the transcriptome allows for extended vein formation in the C-4 leaf.
Erscheinungsjahr
2014
Zeitschriftentitel
Plant Cell
Band
26
Ausgabe
8
Seite(n)
3243-3260
ISSN
1040-4651
eISSN
1532-298X
Page URI
https://pub.uni-bielefeld.de/record/2915134

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Külahoglu C, Denton AK, Sommer M, et al. Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species. Plant Cell. 2014;26(8):3243-3260.
Külahoglu, C., Denton, A. K., Sommer, M., Mass, J., Schliesky, S., Wrobel, T. J., Berckmans, B., et al. (2014). Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species. Plant Cell, 26(8), 3243-3260. doi:10.1105/tpc.114.123752
Külahoglu, Canan, Denton, Alisandra K., Sommer, Manuel, Mass, Janina, Schliesky, Simon, Wrobel, Thomas J., Berckmans, Barbara, et al. 2014. “Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species”. Plant Cell 26 (8): 3243-3260.
Külahoglu, C., Denton, A. K., Sommer, M., Mass, J., Schliesky, S., Wrobel, T. J., Berckmans, B., Gongora-Castillo, E., Buell, C. R., Simon, R., et al. (2014). Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species. Plant Cell 26, 3243-3260.
Külahoglu, C., et al., 2014. Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species. Plant Cell, 26(8), p 3243-3260.
C. Külahoglu, et al., “Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species”, Plant Cell, vol. 26, 2014, pp. 3243-3260.
Külahoglu, C., Denton, A.K., Sommer, M., Mass, J., Schliesky, S., Wrobel, T.J., Berckmans, B., Gongora-Castillo, E., Buell, C.R., Simon, R., De Veylder, L., Bräutigam, A., Weber, A.P.M.: Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species. Plant Cell. 26, 3243-3260 (2014).
Külahoglu, Canan, Denton, Alisandra K., Sommer, Manuel, Mass, Janina, Schliesky, Simon, Wrobel, Thomas J., Berckmans, Barbara, Gongora-Castillo, Elsa, Buell, C. Robin, Simon, Ruediger, De Veylder, Lieven, Bräutigam, Andrea, and Weber, Andreas P. M. “Comparative Transcriptome Atlases Reveal Altered Gene Expression Modules between Two Cleomaceae C-3 and C-4 Plant Species”. Plant Cell 26.8 (2014): 3243-3260.
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Systems analysis of a maize leaf developmental gradient redefines the current C4 model and provides candidates for regulation.
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Scarecrow plays a role in establishing Kranz anatomy in maize leaves.
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GTL1 keeps cell growth and nuclear ploidy under control.
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