Photosynthesis Optimized across Land Plant Phylogeny

Gago, Jorge; Carriquí, Marc; Nadal, Miquel; Clemente‐Moreno, María José; Coopman, Rafael E.; Fernie, Alisdair R.; Flexas, Jaume

doi:10.1016/j.tplants.2019.07.002

Cited by 107 publications

(124 citation statements)

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“…In fact, using the photosynthetic relative limitation model by Grassi and Magnani () we have recently shown that the relative photosynthetic limitations also change along the phylogeny, from predominant mesophyll conductance limitations in bryophytes and lycophytes, to co‐limitation by stomatal and mesophyll conductance limitations in pteridophytes and gymnosperms and a very well balanced co‐limitation by the three factors– stomata, mesophyll and photochemical/biochemical limitations – in angiosperms (Gago et al ., ). We have also shown that this transition is associated with another progressive phylogenetic trend in some key anatomical parameters: from very low S c and very large CWT in bryophytes to very large S c and low CWT in angiosperms (Gago et al ., ).…”

Section: Key Role Of Mesophyll Conductance and Other Physiological Trmentioning

confidence: 97%

“…This observation has sometimes been attributed to a partial compensation of their low g s and g m by a high carboxylation capacity ( V c,max ), but nevertheless may deserve better attention in future studies (Veromann‐Jürgenson et al ., ; Yiotis and McElwain, ). Increasing LMA (Figure ), A mass and PNUE levels along the phylogeny were expected because the typical leaf economics spectrum (LES) relationships – such as those between A mass and LMA on the one hand, and between A mass and leaf N content on the other hand – present identical slopes but very different intercepts among phylogenetic groups, so that the more basal the group the less A mass achieved per either LMA or N (Gago et al ., ; Carriquí et al ., ). However, and in addition, the gymnosperm deviation from the rule, the overall positive scaling of all these parameters also with WUE, was somewhat unexpected and the results were quite interesting.…”

Section: Photosynthetic Capacity and Photosynthetic Efficiencies Alonmentioning

confidence: 99%

“…what it is called mesophyll conductance); and (iii) the velocity of RuBisCO reactions with CO 2 to produce organic molecules, the latter being strongly interconnected with the operation of thylakoid reactions and the Calvin cycle (Foyer et al ., ). While it has been demonstrated that all these three limitations have a similar quantitative importance in limiting photosynthesis in C3 plants (Flexas et al ., ; Gago et al ., ), each of these is very complex and could be further dissected into different factors. For instance, the photosynthetic limitation imposed by stomata depends on stomatal size and density, and both active and hydro‐passive regulation of their aperture (Drake et al ., ; Franks et al ., ).…”

Section: Introductionmentioning

confidence: 99%

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Photosynthesis and photosynthetic efficiencies along the terrestrial plant’s phylogeny: lessons for improving crop photosynthesis

Flexas

Carriquí

2020

The Plant Journal

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Summary Photosynthesis is the basis of all life on Earth. Surprisingly, until very recently, data on photosynthesis, photosynthetic efficiencies, and photosynthesis limitations in terrestrial land plants other than spermatophytes were very scarce. Here we provide an updated data compilation showing that maximum photosynthesis rates (expressed either on an area or dry mass basis) progressively scale along the land plant’s phylogeny, from lowest values in bryophytes to largest in angiosperms. Unexpectedly, both photosynthetic water (WUE) and nitrogen (PNUE) use efficiencies also scale positively through the phylogeny, for which it has been commonly reported that these two efficiencies tend to trade‐off between them when comparing different genotypes or a single species subject to different environmental conditions. After providing experimental evidence that these observed trends are mostly due to an increased mesophyll conductance to CO2 – associated with specific anatomical changes – along the phylogeny, we discuss how these findings on a large phylogenetic scale can provide useful information to address potential photosynthetic improvements in crops in the near future.

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Section: Key Role Of Mesophyll Conductance and Other Physiological Trmentioning

confidence: 97%

Section: Photosynthetic Capacity and Photosynthetic Efficiencies Alonmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Photosynthesis and photosynthetic efficiencies along the terrestrial plant’s phylogeny: lessons for improving crop photosynthesis

Flexas

Carriquí

2020

The Plant Journal

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“…This diffusive pathway is facilitated by several specific enzymes, such as carbonic anhydrases and aquaporins (AQP) (Flexas et al , and references therein). Another important anatomical trait related to g m is the degree of chloroplast surface that is directly exposed to the mesophyll airspaces ( S c / S ) (Gago et al , ).…”

Section: Photosynthesis In Extreme Environments: Taking Advantage Of mentioning

confidence: 99%

How do vascular plants perform photosynthesis in extreme environments? An integrative ecophysiological and biochemical story

et al. 2020

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Summary In this work, we review the physiological and molecular mechanisms that allow vascular plants to perform photosynthesis in extreme environments, such as deserts, polar and alpine ecosystems. Specifically, we discuss the morpho/anatomical, photochemical and metabolic adaptive processes that enable a positive carbon balance in photosynthetic tissues under extreme temperatures and/or severe water‐limiting conditions in C3 species. Nevertheless, only a few studies have described the in situ functioning of photoprotection in plants from extreme environments, given the intrinsic difficulties of fieldwork in remote places. However, they cover a substantial geographical and functional range, which allowed us to describe some general trends. In general, photoprotection relies on the same mechanisms as those operating in the remaining plant species, ranging from enhanced morphological photoprotection to increased scavenging of oxidative products such as reactive oxygen species. Much less information is available about the main physiological and biochemical drivers of photosynthesis: stomatal conductance (gs), mesophyll conductance (gm) and carbon fixation, mostly driven by RuBisCO carboxylation. Extreme environments shape adaptations in structures, such as cell wall and membrane composition, the concentration and activation state of Calvin–Benson cycle enzymes, and RuBisCO evolution, optimizing kinetic traits to ensure functionality. Altogether, these species display a combination of rearrangements, from the whole‐plant level to the molecular scale, to sustain a positive carbon balance in some of the most hostile environments on Earth.

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“…While this seems to be the case for well studied PFTs, more measurements are needed for deciduous needle‐leaf trees, tropical trees (both deciduous and evergreen), as well as C4 plants. The magnitude of g m in other plant groups such as bryophytes and ferns is relatively well constrained and lower compared with those shown in Figure [bryophytes: 0.005 ± 0.004 mol m −2 sec −1 (median ± standard error of the median), ferns: 0.05 ± 0.013 mol m −2 sec −1 (Gago et al , )]. These plant groups are usually not considered in LSMs, despite their potentially significant contributions to terrestrial carbon uptake, especially at higher latitudes (Sjögersten et al , ; Turetsky et al , ).…”

Section: Challenges and Pathways For Model Improvementmentioning

confidence: 99%

Mesophyll conductance in land surface models: effects on photosynthesis and transpiration

et al. 2019

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Summary The CO2 transfer conductance within plant leaves (mesophyll conductance, gm) is currently not considered explicitly in most land surface models (LSMs), but instead treated implicitly as an intrinsic property of the photosynthetic machinery. Here, we review approaches to overcome this model deficiency by explicitly accounting for gm, which comprises the re‐adjustment of photosynthetic parameters and a model describing the variation of gm in dependence of environmental conditions. An explicit representation of gm causes changes in the response of photosynthesis to environmental factors, foremost leaf temperature, and ambient CO2 concentration, which are most pronounced when gm is small. These changes in leaf‐level photosynthesis translate into a stronger climate and CO2 response of gross primary productivity (GPP) and transpiration at the global scale. The results from two independent studies show consistent latitudinal patterns of these effects with biggest differences in GPP in the boreal zone (up to ~15%). Transpiration and evapotranspiration show spatially similar, but attenuated, changes compared with GPP. These changes are indirect effects of gm caused by the assumed strong coupling between stomatal conductance and photosynthesis in current LSMs. Key uncertainties in these simulations are the variation of gm with light and the robustness of its temperature response across plant types and growth conditions. Future research activities focusing on the response of gm to environmental factors and its relation to other plant traits have the potential to improve the representation of photosynthesis in LSMs and to better understand its present and future role in the Earth system.

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Photosynthesis Optimized across Land Plant Phylogeny

Cited by 107 publications

References 96 publications

Photosynthesis and photosynthetic efficiencies along the terrestrial plant’s phylogeny: lessons for improving crop photosynthesis

Photosynthesis and photosynthetic efficiencies along the terrestrial plant’s phylogeny: lessons for improving crop photosynthesis

How do vascular plants perform photosynthesis in extreme environments? An integrative ecophysiological and biochemical story

Mesophyll conductance in land surface models: effects on photosynthesis and transpiration

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