Robert W. Pearcy scite author profile

Abstract. The comparative phenotypic plasticity of 16 species of tropical rainforest shrubs (genus Psychotria, Rubiaceae) was investigated by growing plants in three light environments on Barro Colorado Island (BCI, Panama). The three light environments gave daily photon flux densities (PPFD) similar to the natural light gradient from shaded forest understory to small and large canopy gaps. Six of the species are principally found in gaps or forest edge environments, whereas the other ten species are principally found in shaded understories. Interactions between light treatment and species resulted in unpredictable mean phenotypic expression across light treatments. Shoot relative growth rates (RGR) were similar for understory and gap species in the low light treatment. Gap species had significantly greater shoot RGR in the intermediate light treatment than in the high light treatment. Mean plasticity was significantly lower for morphological variables when compared to physiological variables, while variation in plasticity was significantly greater for structural variables. Significant differences between gap and understory species were found in the plasticity of six out of the seven variables. The mean phenotypic plasticity of the seven variables was significantly greater for gap than for understory species. The high plasticity of gap species was consistent with the hypothesis that specialization in a more favorable environment increases plasticity. The species exhibited a wide range of leaf longevities, from four to 29 months, with gap species having, on average, shorter leaf lifespan than understory species. Mean phenotypic plasticity decreased with increasing leaf longevity. Selection for greater plasticity may be stronger in the gap species because gaps exhibit a relatively predictable decrease in PPFD for which plasticity could be adaptive. While we have found a significant correlation between phenotypic plasticity and habitat affiliation, phylogeny (subgenus ascription) was not correlated with plasticity or with plant performance in any given PPFD treatment, reinforcing the hypothesis that phenotypic plasticity has evolved through natural selection in this diverse genus.

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Sunflecks and Photosynthesis in Plant Canopies

Pearcy

1990

Annu. Rev. Plant. Physiol. Plant. Mol. Biol.

570

362

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The Importance of Sunflecks for Forest Understory Plants

Chazdon¹,

Pearcy²

1991

BioScience

458

314

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Plastic Phenotypic Response to Light of 16 Congeneric Shrubs From a Panamanian Rainforest

Valladares

Wright

Lasso

et al. 2000

Ecology

598

295

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The comparative phenotypic plasticity of 16 species of tropical rainforest shrubs (genus Psychotria, Rubiaceae) was investigated by growing plants in three light environments on Barro Colorado Island (BCI, Panama). The three light environments gave daily photon flux densities (PPFD) similar to the natural light gradient from shaded forest understory to small and large canopy gaps. Six of the species are principally found in gaps or forest edge environments, whereas the other ten species are principally found in shaded understories. Interactions between light treatment and species resulted in unpredictable mean phenotypic expression across light treatments. Shoot relative growth rates (RGR) were similar for understory and gap species in the low light treatment. Gap species had significantly greater shoot RGR in the intermediate light treatment than in the high light treatment. Mean plasticity was significantly lower for morphological variables when compared to physiological variables, while variation in plasticity was significantly greater for structural variables. Significant differences between gap and understory species were found in the plasticity of six out of the seven variables. The mean phenotypic plasticity of the seven variables was significantly greater for gap than for understory species. The high plasticity of gap species was consistent with the hypothesis that specialization in a more favorable environment increases plasticity. The species exhibited a wide range of leaf longevities, from four to 29 months, with gap species having, on average, shorter leaf life‐span than understory species. Mean phenotypic plasticity decreased with increasing leaf longevity. Selection for greater plasticity may be stronger in the gap species because gaps exhibit a relatively predictable decrease in PPFD for which plasticity could be adaptive. While we have found a significant correlation between phenotypic plasticity and habitat affiliation, phylogeny (subgenus ascription) was not correlated with plasticity or with plant performance in any given PPFD treatment, reinforcing the hypothesis that phenotypic plasticity has evolved through natural selection in this diverse genus.

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Photosynthetic Responses of Tropical Forest Plants to Contrasting Light Environments

Chazdon¹,

Pearcy²,

Lee³

et al. 1996

259

270

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Comparative ecophysiology of C₃ and C₄ plants

Pearcy

Ehleringer

1984

Plant Cell & Environment

524

281

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In this review we relate the physiological significance of C4 photosynthesis to plant performance in nature. We begin with an examination of the physiological consequences of the C4 pathway on photosynthesis, then discuss the ecophysiological performance of C4 plants in contrasting environments. We then compare the performance of C3 and C4 plants when they occur together in similar habitats, and finally discuss the distribution of C4 photosynthesis with respect to the physical environment, phylogeny, and life form.

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Interactions between water stress, sun‐shade acclimation, heat tolerance and photoinhibition in the sclerophyll Heteromeles arbutifolia

Valladares¹,

Pearcy²

1997

Plant Cell & Environment

359

261

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Gas exchange and chlorophyll fluorescence techniques were used to evaluate the acclimation capacity of the schlerophyll shrub Heteromeles arbutifolia M. Roem. to the multiple co-occurring summer stresses of the California chaparral. We examined the influence of water, heat and high light stresses on the carhon gain and survival of sun and shade seedlings via a factorial experiment involving a slow drying cycle applied to plants grown outdoors during the summer. The photochemical efficiency of PSII exhibited a diurnal, transient decrease (AF/F^') and a chronic decrease or photoinhibition (FJFj^) in plants exposed to full sunlight. Water stress enhanced both transient decreases of AFIF^' and photoinhibition. Effects of decreased AF/F^^' and F,^/F^ on carbon gain were observed only in well-watered plants since in waterstressed plants they were overidden by stomatal closure. Reductions in photochemical efficiency and stomatal conductance were observed in all plants exposed to full sunlight, even in those that were well-watered. This suggested that H. arbutifolia sacrificed carbon gain for water conservation and photoprotection (both structurally via sboot architecture and physiologically via down-regulation) and that this response was triggered by a hot and dry atmosphere together with high PFD, before severe water, heat or high PFD stresses occur. We found fast adaptive adjustments of the thermal stability of PSII (diurnal changes) and a superimposed long-term acclimation (days to weeks) to high leaf temperatures. Water stress enhanced resistance of PSII to high temperatures both in the dark and over a wide range of PFD. Low PFD protected photochemical activity against inactivation by heat while high PFD exacerbated damage of PSII by heat. The greater interception of radiation by horizontally restrained leaves relative to the steep leaves of sun-acclimated plants caused photoinhibition and increased leaf temperature. When transpirational cooling was decreased by water stress, leaf temperature surpassed the limits of chloroplast thermostability. The remarkable acclimation of water-stressed Key-words: Heteromeles arbutifolia., heat stress; interaction between stresses; leaf angle; photoinhibition; photosynthesis; sclerophyll; sun-shade acclimation; thermal stability of photosystem II; transpiration cooling; water stress.Abbreviations: A, net CO2 assimilation rate; FJF^, photochemical efficiency of PSII (dark adapted leaves); AF/F^', photochemical efficiency of PSII in the light; g^, stomatal conductance to water vapour; PFD, photosynthetic photon flux density; PSII, photosystem II; T^., critical temperature for heat-induced fluorescence rise; Tp, temperature of heatinduced peak fluorescence; % water potential.

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Climate change and the evolution of C4 photosynthesis

Ehleringer

Sage

Flanagan

et al. 1991

Trends in Ecology & Evolution

500

270

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Robert W. Pearcy

Plastic Phenotypic Response to Light of 16 Congeneric Shrubs from a Panamanian Rainforest

Sunflecks and Photosynthesis in Plant Canopies

The Importance of Sunflecks for Forest Understory Plants

Plastic Phenotypic Response to Light of 16 Congeneric Shrubs From a Panamanian Rainforest

Photosynthetic Responses of Tropical Forest Plants to Contrasting Light Environments

Comparative ecophysiology of C₃ and C₄ plants

Interactions between water stress, sun‐shade acclimation, heat tolerance and photoinhibition in the sclerophyll Heteromeles arbutifolia

Climate change and the evolution of C4 photosynthesis

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Resources

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Robert W. Pearcy

Plastic Phenotypic Response to Light of 16 Congeneric Shrubs from a Panamanian Rainforest

Sunflecks and Photosynthesis in Plant Canopies

The Importance of Sunflecks for Forest Understory Plants

Plastic Phenotypic Response to Light of 16 Congeneric Shrubs From a Panamanian Rainforest

Photosynthetic Responses of Tropical Forest Plants to Contrasting Light Environments

Comparative ecophysiology of C3 and C4 plants

Interactions between water stress, sun‐shade acclimation, heat tolerance and photoinhibition in the sclerophyll Heteromeles arbutifolia

Climate change and the evolution of C4 photosynthesis

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Product

Resources

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Comparative ecophysiology of C₃ and C₄ plants