Photosynthetic adaptation to temperature in four species from the Colorado shortgrass steppe: a physiological model for coexistence

Monson, Russell K.; Littlejohn, Robert O.; Williams, George

doi:10.1007/bf00384540

Cited by 106 publications

(50 citation statements)

References 25 publications

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“…Numerous studies from grasslands throughout the world, including the Great Plains, have con®rmed the C 3 /C 4 transition in grassland composition correlated with temperature along a geographic gradient (Table 2) or on an interseasonal basis (Ode et al 1980;Barnes et al 1983;Monson et al 1983;Boryslawski and Bentley 1985) as predicted by the quantum yield model. It is unlikely that the strong agreements between predictions of C 3 /C 4 monocot transition based on quantum yield modeling analysis and ®eld observations are fortuitous.…”

Section: Phylogenetic Distribution Of C 4 Photosynthesismentioning

confidence: 98%

“…However, where grasslands exhibit two distinct growing seasons (winter±spring and summer), strong seasonal dierences exist for the dominance of one pathway versus the other. Primary productivity in the central and northern portions of the Great Plains of North America is dominated by C 3 grasses in the spring growing season, while C 4 grasses predominate during the summer growing season (Ode et al 1980;Barnes et al 1983;Monson et al 1983;Boryslawski and Bentley 1985;Paruelo and Lauenroth 1996;Tieszen et al 1997). A similar pattern occurs in the Sonoran Desert, where the winter±spring vegetation is exclusively C 3 , whereas C 4 grasses dominate in the summer monsoon season (Shreve and Wiggins 1964;Mulroy and Rundel 1977).…”

Section: Phylogenetic Distribution Of C 4 Photosynthesismentioning

confidence: 99%

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C 4 photosynthesis, atmospheric CO 2 , and climate

1997

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The objectives of this synthesis are (1) to review the factors that influence the ecological, geographical, and palaeoecological distributions of plants possessing C photosynthesis and (2) to propose a hypothesis/model to explain both the distribution of C plants with respect to temperature and CO and why C photosynthesis is relatively uncommon in dicotyledonous plants (hereafter dicots), especially in comparison with its widespread distribution in monocotyledonous species (hereafter monocots). Our goal is to stimulate discussion of the factors controlling distributions of C plants today, historically, and under future elevated CO environments. Understanding the distributions of C/C plants impacts not only primary productivity, but also the distribution, evolution, and migration of both invertebrates and vertebrates that graze on these plants. Sixteen separate studies all indicate that the current distributions of C monocots are tightly correlated with temperature: elevated temperatures during the growing season favor C monocots. In contrast, the seven studies on C dicot distributions suggest that a different environmental parameter, such as aridity (combination of temperature and evaporative potential), more closely describes their distributions. Differences in the temperature dependence of the quantum yield for CO uptake (light-use efficiency) of C and C species relate well to observed plant distributions and light-use efficiency is the only mechanism that has been proposed to explain distributional differences in C/C monocots. Modeling of C and C light-use efficiencies under different combinations of atmospheric CO and temperature predicts that C-dominated ecosystems should not have expanded until atmospheric CO concentrations reached the lower levels that are thought to have existed beginning near the end of the Miocene. At that time, palaeocarbonate and fossil data indicate a simultaneous, global expansion of C-dominated grasslands. The C monocots generally have a higher quantum yield than C dicots and it is proposed that leaf venation patterns play a role in increasing the light-use efficiency of most C monocots. The reduced quantum yield of most C dicots is consistent with their rarity, and it is suggested that C dicots may not have been selected until CO concentrations reached their lowest levels during glacial maxima in the Quaternary. Given the intrinsic light-use efficiency advantage of C monocots, C dicots may have been limited in their distributions to the warmest ecosystems, saline ecosystems, and/or to highly disturbed ecosystems. All C plants have a significant advantage over C plants under low atmospheric CO conditions and are predicted to have expanded significantly on a global scale during full-glacial periods, especially in tropical regions. Bog and lake sediment cores as well as pedogenic carbonates support the hypothesis that C ecosystems were more extensive during the last glacial maximum and then decreased in abundance following deglaciation as atmospheric CO levels increased.

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Section: Phylogenetic Distribution Of C 4 Photosynthesismentioning

confidence: 98%

Section: Phylogenetic Distribution Of C 4 Photosynthesismentioning

confidence: 99%

C 4 photosynthesis, atmospheric CO 2 , and climate

1997

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“…Photorespiration scavenges some of the lost carbon from this process, but net losses of carbon and energy still occur. Evaporative water loss increases with photorespiration rates because greater stomatal conductance is necessary to make up for carbon losses (Monson et al, 1983).…”

Section: Miocene Climate Change and Innovations In Photosynthesismentioning

confidence: 99%

Examining plant physiological responses to climate change through an evolutionary lens

et al. 2016

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“…C 3 grasses are more competitive during years with moist, mild springs and dry summers; on the other hand, in years with dry springs and wet summers, C 4 species are favored (Monson et al 1983). In 2000, a dry spring was associated with lower C 3 /C 4 live biomass ratios compared to 2001, when more moisture allowed for superior growth of C 3 species.…”

Section: Discussionmentioning

confidence: 96%

Wetting and drying cycles drive variations in the stable carbon isotope ratio of respired carbon dioxide in semi-arid grassland

et al. 2009

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In semi-arid regions, where plants using both C(3) and C(4) photosynthetic pathways are common, the stable C isotope ratio (delta(13)C) of ecosystem respiration (delta(13)C(R)) is strongly variable seasonally and inter-annually. Improved understanding of physiological and environmental controls over these variations will improve C cycle models that rely on the isotopic composition of atmospheric CO(2). We hypothesized that timing of precipitation events and antecedent moisture interact with activity of C(3) and C(4) grasses to determine net ecosystem CO(2) exchange (NEE) and delta(13)C(R). Field measurements included CO(2) and delta(13)C fluxes from the whole ecosystem and from patches of different plant communities, biomass and delta(13)C of plants and soils over the 2000 and 2001 growing seasons. NEE shifted from C source to sink in response to rainfall events, but this shift occurred after a time lag of up to 2 weeks if a dry period preceded the rainfall. The seasonal average of delta(13)C(R) was higher in 2000 (-16 per thousand) than 2001 (20 per thousand), probably due to drier conditions during the 2000 growing season (79.7 mm of precipitation from April up to and including July) than in 2001 (189 mm). During moist conditions, delta(13)C averaged -22 per thousand from C(3) patches, -16 per thousand from C(4) patches, and -19 per thousand from mixed C(3) and C(4) patches. However, during dry conditions the apparent spatial differences were not obvious, suggesting reduced autotrophic activity in C(4) grasses with shallow rooting depth, soon after the onset of dry conditions. Air and soil temperatures were negatively correlated with delta(13)C(R); vapor pressure deficit was a poor predictor of delta(13)C(R), in contrast to more mesic ecosystems. Responses of respiration components to precipitation pulses were explained by differences in soil moisture thresholds between C(3) and C(4) species. Stable isotopic composition of respiration in semi-arid ecosystems is more temporally and spatially variable than in mesic ecosystems owing to dynamic aspects of pulse precipitation episodes and biological drivers.

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Photosynthetic adaptation to temperature in four species from the Colorado shortgrass steppe: a physiological model for coexistence

Cited by 106 publications

References 25 publications

C 4 photosynthesis, atmospheric CO 2 , and climate

C 4 photosynthesis, atmospheric CO 2 , and climate

Examining plant physiological responses to climate change through an evolutionary lens

Wetting and drying cycles drive variations in the stable carbon isotope ratio of respired carbon dioxide in semi-arid grassland

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