Biophysical constraints on the origin of leaves inferred from the fossil record

Osborne, Colin P.; Beerling, David J.; Lomax, Barry H.; Chaloner, W. G.

doi:10.1073/pnas.0402787101

Cited by 63 publications

(65 citation statements)

References 22 publications

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“…The developmental algorithm and scaling relationships we have shown makes this possible for dicotyledons, providing a strong ecological advantage. Dicotyledons can produce large leaves with both large major veins for mechanical support and high vein densities that enable transpirational cooling and high photosynthetic rates 1,[47][48][49] . Large simple leaves with high vein density are an angiosperm innovation, because the ongoing production of minor veins in expanding leaves depends on the plate meristem that is typically found only in angiosperms 18 .…”

Section: Discussionmentioning

confidence: 99%

Developmentally based scaling of leaf venation architecture explains global ecological patterns

et al. 2012

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Leaf size and venation show remarkable diversity across dicotyledons, and are key determinants of plant adaptation in ecosystems past and present. Here we present global scaling relationships of venation traits with leaf size. Across a new database for 485 globally distributed species, larger leaves had major veins of larger diameter, but lower length per leaf area, whereas minor vein traits were independent of leaf size. These scaling relationships allow estimation of intact leaf size from fragments, to improve hindcasting of past climate and biodiversity from fossil remains. The vein scaling relationships can be explained by a uniquely synthetic model for leaf anatomy and development derived from published data for numerous species. Vein scaling relationships can explain the global biogeographical trend for smaller leaves in drier areas, the greater construction cost of larger leaves and the ability of angiosperms to develop larger and more densely vascularised lamina to outcompete earlier-evolved plant lineages.

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Section: Discussionmentioning

confidence: 99%

Developmentally based scaling of leaf venation architecture explains global ecological patterns

et al. 2012

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“…Previously hypothesized modifications of the water transport system and associated plant features driven by low CO 2 include the evolution of xylem vessels and stomata [108], and the planate leaf [109,110] with high vein density [78]. These innovations permitted more rapid growth and diversification, leading to the succession of dominance from pteridophytes to gymnosperms to angiosperms [78,80,111,112].…”

Section: Discussionmentioning

confidence: 99%

Evolution of C ₄ plants: a new hypothesis for an interaction of CO ₂ and water relations mediated by plant hydraulics

Osborne

Sack²

2012

Phil. Trans. R. Soc. B

176

193

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C 4 photosynthesis has evolved more than 60 times as a carbon-concentrating mechanism to augment the ancestral C 3 photosynthetic pathway. The rate and the efficiency of photosynthesis are greater in the C 4 than C 3 type under atmospheric CO 2 depletion, high light and temperature, suggesting these factors as important selective agents. This hypothesis is consistent with comparative analyses of grasses, which indicate repeated evolutionary transitions from shaded forest to open habitats. However, such environmental transitions also impact strongly on plant -water relations. We hypothesize that excessive demand for water transport associated with low CO 2 , high light and temperature would have selected for C 4 photosynthesis not only to increase the efficiency and rate of photosynthesis, but also as a water-conserving mechanism. Our proposal is supported by evidence from the literature and physiological models. The C 4 pathway allows high rates of photosynthesis at low stomatal conductance, even given low atmospheric CO 2 . The resultant decrease in transpiration protects the hydraulic system, allowing stomata to remain open and photosynthesis to be sustained for longer under drying atmospheric and soil conditions. The evolution of C 4 photosynthesis therefore simultaneously improved plant carbon and water relations, conferring strong benefits as atmospheric CO 2 declined and ecological demand for water rose.

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“…The development of megaphyll leaves in multiple independent lineages was coincident with the transition from high to low [CO 2 ] during the Devonian and Carboniferous 400 -350 Ma [25,28]. As [CO 2 ] dropped, rates of A would have become increasingly limited by the resistance to diffusion of CO 2 from the atmosphere to the site of fixation by Rubisco.…”

Section: Question 1: Have Plants Evolved In Response To Varying [Co 2mentioning

confidence: 98%

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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Biophysical constraints on the origin of leaves inferred from the fossil record

Cited by 63 publications

References 22 publications

Developmentally based scaling of leaf venation architecture explains global ecological patterns

Developmentally based scaling of leaf venation architecture explains global ecological patterns

Evolution of C ₄ plants: a new hypothesis for an interaction of CO ₂ and water relations mediated by plant hydraulics

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

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Biophysical constraints on the origin of leaves inferred from the fossil record

Cited by 63 publications

References 22 publications

Developmentally based scaling of leaf venation architecture explains global ecological patterns

Developmentally based scaling of leaf venation architecture explains global ecological patterns

Evolution of C 4 plants: a new hypothesis for an interaction of CO 2 and water relations mediated by plant hydraulics

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

Contact Info

Product

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Evolution of C ₄ plants: a new hypothesis for an interaction of CO ₂ and water relations mediated by plant hydraulics

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