Independent and Parallel Recruitment of Preexisting Mechanisms Underlying C
            <sub>4</sub>
            Photosynthesis

Brown, Naomi J.; Newell, C. A.; Stanley, Susan E.; Chen, Jit Ern; Perrin, Abigail J.; Kajala, Kaisa; Hibberd, Julian M.

doi:10.1126/science.1201248

Cited by 136 publications

(143 citation statements)

References 26 publications

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“…Once a photorespiratory pump is fixed by natural selection, the biochemical components of the C 4 pathway can be gradually acquired and optimized until a highly efficient C 4 trait emerges. All enzymes of the C 4 pathway already exist in C 3 plants, and C 4 compatible promoter sequences are widespread in angiosperms (6,7). The evolution of the C 4 trait can consequently require relatively few mutations in plants with a suitable leaf anatomy, which, in grasses, largely includes members of the PACMAD clade (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Despite this complexity, it evolved more than 62 times independently in distantly related groups of flowering plants (5). These recurrent C 4 origins were probably facilitated by the existence in most C 3 plants of metabolic modules that are suitable for the C 4 pathway and can be recruited for this function through relatively few mutations (6,7). In addition, the photorespiratory pump based on glycine decarboxylase is a likely evolutionary stable intermediate phenotype on the road from C 3 to C 4 (3,8).…”

mentioning

confidence: 99%

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Anatomical enablers and the evolution of C ₄ photosynthesis in grasses

Christin

Osborne

Chatelet

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

240

254

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C 4 photosynthesis is a series of anatomical and biochemical modifications to the typical C 3 pathway that increases the productivity of plants in warm, sunny, and dry conditions. Despite its complexity, it evolved more than 62 times independently in flowering plants. However, C 4 origins are absent from most plant lineages and clustered in others, suggesting that some characteristics increase C 4 evolvability in certain phylogenetic groups. The C 4 trait has evolved 22-24 times in grasses, and all origins occurred within the PACMAD clade, whereas the similarly sized BEP clade contains only C 3 taxa. Here, multiple foliar anatomy traits of 157 species from both BEP and PACMAD clades are quantified and analyzed in a phylogenetic framework. Statistical modeling indicates that C 4 evolvability strongly increases when the proportion of vascular bundle sheath (BS) tissue is higher than 15%, which results from a combination of short distance between BS and large BS cells. A reduction in the distance between BS occurred before the split of the BEP and PACMAD clades, but a decrease in BS cell size later occurred in BEP taxa. Therefore, when environmental changes promoted C 4 evolution, suitable anatomy was present only in members of the PACMAD clade, explaining the clustering of C 4 origins in this lineage. These results show that key alterations of foliar anatomy occurring in a C 3 context and preceding the emergence of the C 4 syndrome by millions of years facilitated the repeated evolution of one of the most successful physiological innovations in angiosperm history.precursor | preadaptation | phylogeny | Poaceae

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Anatomical enablers and the evolution of C ₄ photosynthesis in grasses

Christin

Osborne

Chatelet

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

240

254

View full text Add to dashboard Cite

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“…The fact that C 4 photosynthesis has independently evolved in many genetic backgrounds on different occasions increases the likelihood that successful engineering can be achieved [107]. Specific evidence for this assertion includes that: (i) independent lineages of C 4 species share common mechanisms controlling the localization of key enzymes for C 4 photosynthesis in bundle sheath cells; and (ii) specific localization of enzymes in C 4 leaves to bundle sheath versus mesophyll cells can be achieved by modification of trans-factors without a change in existing cis-regulation of C 3 species [124].…”

Section: Question 5: How Does Evolutionary History Impact and Informmentioning

confidence: 99%

Evolutionary context for understanding and manipulating plant responses to past, present and future atmospheric [CO ₂ ]

Leakey

Lau

2012

Phil. Trans. R. Soc. B

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Variation in atmospheric [CO 2 ] is a prominent feature of the environmental history over which vascular plants have evolved. Periods of falling and low [CO 2 ] in the palaeo-record appear to have created selective pressure for important adaptations in modern plants. Today, rising [CO 2 ] is a key component of anthropogenic global environmental change that will impact plants and the ecosystem goods and services they deliver. Currently, there is limited evidence that natural plant populations have evolved in response to contemporary increases in [CO 2 ] in ways that increase plant productivity or fitness, and no evidence for incidental breeding of crop varieties to achieve greater yield enhancement from rising [CO 2 ]. Evolutionary responses to elevated [CO 2 ] have been studied by applying selection in controlled environments, quantitative genetics and traitbased approaches. Findings to date suggest that adaptive changes in plant traits in response to future [CO 2 ] will not be consistently observed across species or environments and will not be large in magnitude compared with physiological and ecological responses to future [CO 2 ]. This lack of evidence for strong evolutionary effects of elevated [CO 2 ] is surprising, given the large effects of elevated [CO 2 ] on plant phenotypes. New studies under more stressful, complex environmental conditions associated with climate change may revise this view. Efforts are underway to engineer plants to: (i) overcome the limitations to photosynthesis from today's [CO 2 ] and (ii) benefit maximally from future, greater [CO 2 ]. Targets range in scale from manipulating the function of a single enzyme (e.g. Rubisco) to adding metabolic pathways from bacteria as well as engineering the structural and functional components necessary for C 4 photosynthesis into C 3 leaves. Successfully improving plant performance will depend on combining the knowledge of the evolutionary context, cellular basis and physiological integration of plant responses to varying [CO 2 ].

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“…However, it is now clear that multiple genes are expressed preferentially in M or BS cells of C 4 G. gynandra because of pre-existing cis-elements located in orthologous genes from A. thaliana. For example, both genes encoding the heterodimeric NAD-ME in G. gynandra contain elements in the coding sequence that determine BS expression, and these elements are found in the orthologues from A. thaliana [73,74]. The genes from A. thaliana are not preferentially expressed in the BS in the ancestral C 3 state, but they are when placed into leaves of C 4 G. gynandra.…”

Section: Recruitment Of Pre-existing Gene Regulatory Networkmentioning

confidence: 99%

Recruitment of pre-existing networks during the evolution of C ₄ photosynthesis

Reyna-Llorens¹,

Hibberd²

2017

Phil. Trans. R. Soc. B

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During C 4 photosynthesis, CO 2 is concentrated around the enzyme RuBisCO. The net effect is to reduce photorespiration while increasing water and nitrogen use efficiencies. Species that use C 4 photosynthesis have evolved independently from their C 3 ancestors on more than 60 occasions. Along with mimicry and the camera-like eye, the C 4 pathway therefore represents a remarkable example of the repeated evolution of a highly complex trait. In this review, we provide evidence that the polyphyletic evolution of C 4 photosynthesis is built upon pre-existing metabolic and genetic networks. For example, cells around veins of C 3 species show similarities to those of the C 4 bundle sheath in terms of C 4 acid decarboxylase activity and also the photosynthetic electron transport chain. Enzymes of C 4 photosynthesis function together in gluconeogenesis during early seedling growth of C 3 Arabidopsis thaliana. Furthermore, multiple C 4 genes appear to be under control of both light and chloroplast signals in the ancestral C 3 state. We, therefore, hypothesize that relatively minor rewiring of pre-existing genetic and metabolic networks has facilitated the recurrent evolution of this trait. Understanding how these changes are likely to have occurred could inform attempts to install C 4 traits into C 3 crops.This article is part of the themed issue 'Enhancing photosynthesis in crop plants: targets for improvement'.

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Independent and Parallel Recruitment of Preexisting Mechanisms Underlying C ₄ Photosynthesis

Cited by 136 publications

References 26 publications

Anatomical enablers and the evolution of C ₄ photosynthesis in grasses

Anatomical enablers and the evolution of C ₄ photosynthesis in grasses

Evolutionary context for understanding and manipulating plant responses to past, present and future atmospheric [CO ₂ ]

Recruitment of pre-existing networks during the evolution of C ₄ photosynthesis

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Independent and Parallel Recruitment of Preexisting Mechanisms Underlying C 4 Photosynthesis

Cited by 136 publications

References 26 publications

Anatomical enablers and the evolution of C 4 photosynthesis in grasses

Anatomical enablers and the evolution of C 4 photosynthesis in grasses

Evolutionary context for understanding and manipulating plant responses to past, present and future atmospheric [CO 2 ]

Recruitment of pre-existing networks during the evolution of C 4 photosynthesis

Contact Info

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Resources

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Independent and Parallel Recruitment of Preexisting Mechanisms Underlying C ₄ Photosynthesis

Anatomical enablers and the evolution of C ₄ photosynthesis in grasses

Anatomical enablers and the evolution of C ₄ photosynthesis in grasses

Evolutionary context for understanding and manipulating plant responses to past, present and future atmospheric [CO ₂ ]

Recruitment of pre-existing networks during the evolution of C ₄ photosynthesis