Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4?

Gowik U, Bräutigam A, Weber KL, Weber APM, Westhoff P (2011)
Plant Cell 23(6): 2087-2105.

Zeitschriftenaufsatz | Veröffentlicht | Englisch
 
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DOI
URN
urn:nbn:de:0070-pub-29151597
Autor*in
Gowik, Udo; Bräutigam, AndreaUniBi ; Weber, Katrin L.; Weber, Andreas P. M.; Westhoff, Peter
Einrichtung
Fakultät für Biologie > Computational Biology
Abstract / Bemerkung
Selective pressure exerted by a massive decline in atmospheric CO2 levels 55 to 40 million years ago promoted the evolution of a novel, highly efficient mode of photosynthetic carbon assimilation known as C-4 photosynthesis. C-4 species have concurrently evolved multiple times in a broad range of plant families, and this multiple and parallel evolution of the complex C-4 trait indicates a common underlying evolutionary mechanism that might be elucidated by comparative analyses of related C-3 and C-4 species. Here, we use mRNA-Seq analysis of five species within the genus Flaveria, ranging from C-3 to C-3-C-4 intermediate to C-4 species, to quantify the differences in the transcriptomes of closely related plant species with varying degrees of C-4-associated characteristics. Single gene analysis defines the C-4 cycle enzymes and transporters more precisely and provides new candidates for yet unknown functions as well as identifies C-4 associated pathways. Molecular evidence for a photorespiratory CO2 pump prior to the establishment of the C-4 cycle-based CO2 pump is provided. Cluster analysis defines the upper limit of C-4-related gene expression changes in mature leaves of Flaveria as 3582 alterations.
Erscheinungsjahr
2011
Zeitschriftentitel
Plant Cell
Band
23
Ausgabe
6
Seite(n)
2087-2105
ISSN
1040-4651
Page URI
https://pub.uni-bielefeld.de/record/2915159

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Gowik U, Bräutigam A, Weber KL, Weber APM, Westhoff P. Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4? Plant Cell. 2011;23(6):2087-2105.
Gowik, U., Bräutigam, A., Weber, K. L., Weber, A. P. M., & Westhoff, P. (2011). Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4? Plant Cell, 23(6), 2087-2105. doi:10.1105/tpc.111.086264
Gowik, Udo, Bräutigam, Andrea, Weber, Katrin L., Weber, Andreas P. M., and Westhoff, Peter. 2011. “Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4?”. Plant Cell 23 (6): 2087-2105.
Gowik, U., Bräutigam, A., Weber, K. L., Weber, A. P. M., and Westhoff, P. (2011). Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4? Plant Cell 23, 2087-2105.
Gowik, U., et al., 2011. Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4? Plant Cell, 23(6), p 2087-2105.
U. Gowik, et al., “Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4?”, Plant Cell, vol. 23, 2011, pp. 2087-2105.
Gowik, U., Bräutigam, A., Weber, K.L., Weber, A.P.M., Westhoff, P.: Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4? Plant Cell. 23, 2087-2105 (2011).
Gowik, Udo, Bräutigam, Andrea, Weber, Katrin L., Weber, Andreas P. M., and Westhoff, Peter. “Evolution of C-4 Photosynthesis in the Genus Flaveria: How Many and Which Genes Does It Take to Make C-4?”. Plant Cell 23.6 (2011): 2087-2105.
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91 Zitationen in Europe PMC

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Majeran W, van Wijk KJ., Trends Plant Sci. 14(2), 2009
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Subunits of the plastid ClpPR protease complex have differential contributions to embryogenesis, plastid biogenesis, and plant development in Arabidopsis.
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The variegated mutants lacking chloroplastic FtsHs are defective in D1 degradation and accumulate reactive oxygen species.
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Increased leaf size: different means to an end.
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Evolution of C4 photosynthesis--looking for the master switch.
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Plant receptor-like kinase gene family: diversity, function, and signaling.
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C(4) photosynthesis: principles of CO(2) concentration and prospects for its introduction into C(3) plants.
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Unravelling angiosperm genome evolution by phylogenetic analysis of chromosomal duplication events.
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