Your search keyword '"Griffin, Kevin L."' showing total 109 results

1. Importance of Timing of Dark Acclimation for Estimating Light Inhibition of Leaf Respiratory CO2 Efflux.

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Author

Bruhn, Dan, Griffin, Kevin L., and Møller, Ian M.

Subjects

*BOTANY, *PHYSIOLOGY, *PYRUVATE dehydrogenase complex, *BIOLOGICAL evolution, *LIFE sciences, *RESPIRATION in plants

Published

2024

2. Measured leaf dark respiratory CO2-release is not controlled by stomatal conductance.

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Author

Bruhn, Dan, Faber, Andreas H., Sloth Cristophersen, Kaare, Svanekær Nielsen, Jakob, and Griffin, Kevin L.

Subjects

STOMATA, ABSCISIC acid, VAPOR pressure

Abstract

Leaf dark respiratory CO2-release (RD) is, according to some literature, dependent on the rate of leaf transpiration. If this is true, then at a given vapor pressure deficit, the leaf stomatal conductance (gs) will be expected to be a controlling factor of measured RD at any given time. We artificially lowered leaf gs by applying abscisic acid (ABA). Although leaf RD generally covaried temporally with gs, artificially lowering gs by applying ABA does not affect the measured leaf RD. These results indicate that observed diel fluctuations in gs are not directly influencing the measured leaf RD, thereby simplifying both future studies and the interpretation of past studies of the underlying environmental- and physiological drivers of temporal variation in leaf RD. [ABSTRACT FROM AUTHOR] more...

Published

2024

3. Differential nighttime decreases in leaf respiratory CO2‐efflux and O2‐uptake.

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Author

Bruhn, Dan, Noguchi, Ko, Griffin, Kevin L., and Tjoelker, Mark G.

Subjects

RESPIRATION in plants, PLANT ecophysiology, BOTANY, PLANT physiology, RESPIRATORY quotient

Abstract

This article examines the changes in leaf respiration during the night, specifically focusing on the decrease in leaf respiratory O2-uptake and CO2-efflux. The authors analyze data from various studies and find that these decreases indicate a decrease in leaf mitochondrial electron transport and ATP demand. The article emphasizes the need for further research to understand the underlying mechanisms and species-specific differences in nocturnal changes in leaf respiration. The authors also discuss the implications of changes in the respiratory quotient (RQ), suggesting that the relative composition of respiratory substrates may shift during the early hours of the dark period. They highlight the importance of studying factors that affect RQ, such as substrate composition and demand for respiratory intermediates. Overall, this information is valuable for understanding the relationship between environmental and metabolic regulation of respiration and its impact on carbon uptake. [Extracted from the article] more...

Published

2024

4. Ecosystem feedbacks constrain the effect of day‐to‐day weather variability on land–atmosphere carbon exchange.

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Author

Rastetter, Edward B., Griffin, Kevin L., Kwiatkowski, Bonnie L., and Kling, George W.

Subjects

*WEATHER & climate change, *EXTREME weather, *TUNDRAS, *PHOSPHORUS cycle (Biogeochemistry), *CLIMATE extremes, *WEATHER, *CARBON sequestration

Abstract

Whole‐ecosystem interactions and feedbacks constrain ecosystem responses to environmental change. The effects of these constraints on responses to climate trends and extreme weather events have been well studied. Here we examine how these constraints respond to changes in day‐to‐day weather variability without changing the long‐term mean weather. Although environmental variability is recognized as a critical factor affecting ecological function, the effects of climate change on day‐to‐day weather variability and the resultant impacts on ecosystem function are still poorly understood. Changes in weather variability can alter the mean rates of individual ecological processes because many processes respond non‐linearly to environmental drivers. We assessed how these individual‐process responses to changes in day‐to‐day weather variability interact with one another at an ecosystem level. We examine responses of arctic tundra to changes in weather variability using stochastic simulations of daily temperature, precipitation, and light to drive a biogeochemical model. Changes in weather variability altered ecosystem carbon, nitrogen, and phosphorus stocks and cycling rates in our model. However, responses of some processes (e.g., respiration) were inconsistent with expectations because ecosystem feedbacks can moderate, or even reverse, direct process responses to weather variability. More weather variability led to greater carbon losses from land to atmosphere; less variability led to higher carbon sequestration on land. The magnitude of modeled ecosystem response to weather variability was comparable to that predicted for the effects of climate mean trends by the end of the century. [ABSTRACT FROM AUTHOR] more...

Published

2023

5. Planting design influences green infrastructure performance: Plant species identity and complementarity in rain gardens.

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Author

Bruner, Sarah G., Palmer, Matthew I., Griffin, Kevin L., and Naeem, Shahid

Subjects

GREEN infrastructure, RAIN gardens, SUSTAINABLE design, PLANT performance, PLANT species, LEAF temperature, SHRUBS, ORNAMENTAL plants

Abstract

Green infrastructure's capacity to mitigate urban environmental problems, like heat island effects and excessive stormwater runoff, is partially governed by its plant community. Traditionally, green infrastructure design has focused on engineered aspects, such as substrate and drainage, rather than on the properties of its living components. Since the functioning of these plant assemblages is controlled by ecophysiological processes that differ by species, the identity and relative abundance of the species used will influence green infrastructure performance. We used trait‐based modeling to derive principles for the effective composition of green infrastructure plant assemblages, parameterizing our model using the vegetation and ecophysiological traits of the species within New York City rain gardens. Focusing on two plant traits that influence rain garden performance, leaf surface temperature and stomatal conductance, we simulated the cumulative temperature and transpiration for plant communities of differing species composition and diversity. The outcomes of the model demonstrate that plant species composition, species identity, selection effects, and interspecific complementarity increase green infrastructure performance in much the way biodiversity affects ecosystem functioning in natural systems. More diverse assemblages resulted in more consistent transpiration and surface temperatures, with the former showing a positive, saturating curve as diversity increased. While the dominant factors governing individual species leaf temperature were abiotic, transpiration was more influential at the community level, suggesting that plants within diverse communities may be cooler in aggregate than any individual species on its own. This implies green infrastructure should employ a variety of vegetation; particularly plants with different statures and physical attributes, such as low‐growing ground covers, erect herbaceous perennials, and shrubs. [ABSTRACT FROM AUTHOR] more...

Published

2023

6. Leaf temperatures and environmental conditions predict daily stem radial variations in a temperate coniferous forest.

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Author

Weygint, William A., Eitel, Jan U. H., Maguire, Andrew J., Vierling, Lee A., Johnson, Daniel M., Campbell, Colin S., and Griffin, Kevin L.

Subjects

LEAF temperature, CONIFEROUS forests, TEMPERATE forests, REMOTE sensing, TREE growth, PLANT-water relationships

Abstract

Hourly‐resolved measurements of stem radial variations (SRVs) provide valuable insights into how climate‐induced changes in hydrological regimes affect tree water status and tree stem radial growth. However, while SRVs are easily measured at the individual tree level, currently no methods are available to monitor this phenomenon across broad regions at intra‐annual (daily to weekly) scales. Near‐surface (in situ) thermal remote sensing—with its sensitivity to plant water status—may provide an approach for monitoring intra‐annual SRVs, with the potential for scaling these approaches to the landscape level. Thus, we explored the suitability of in situ thermal remote sensing, in combination with other environmental data, to monitor SRVs in a coniferous forest of the North American Intermountain West. Specifically, we were interested in answering two main questions: Can we use in situ thermal remote sensing by itself and in combination with environmental variables (i.e., photoperiod, photosynthetically active radiation, and soil moisture) to predict (1) daily tree water status and (2) daily tree stem radial growth derived from SRVs? We used data collected by an environmental monitoring network in central Idaho over three growing seasons (2019–2021) to address these questions. Results showed that leaf temperature (TL) in combination with environmental variables explained up to three‐quarters of the SRV‐based variability in daily tree water status (in the form of tree water deficit [TWD]) and approximately one‐half of the variability in daily stem radial growth. The time of day when TL was acquired also appeared to change the strength, shape, and predictive power of the models, with acquisition times in the morning and evening showing stronger relationships with daily SRVs than other times of the day. Overall, these results highlight the promise of utilizing thermal remote sensing data to derive tree hydrological and growth status, and reveal key considerations (e.g., the time of data acquisition) for future observational and modeling efforts. This study also provides a benchmark against which to compare future efforts to test these observed relationships at coarser spatial scales. [ABSTRACT FROM AUTHOR] more...

Published

2023

7. Vertical gradients in photosynthetic physiology diverge at the latitudinal range extremes of white spruce.

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Author

Schmiege, Stephanie C., Griffin, Kevin L., Boelman, Natalie T., Vierling, Lee A., Bruner, Sarah G., Min, Elizabeth, Maguire, Andrew J., Jensen, Johanna, and Eitel, Jan U. H.

Subjects

*WHITE spruce, *LEAF physiology, *PHOTOSYNTHETIC rates, *HAWTHORNS, *LIGHT curves, *TROPICAL forests, *PRIMARY productivity (Biology)

Abstract

Light availability drives vertical canopy gradients in photosynthetic functioning and carbon (C) balance, yet patterns of variability in these gradients remain unclear. We measured light availability, photosynthetic CO2 and light response curves, foliar C, nitrogen (N) and pigment concentrations, and the photochemical reflectance index (PRI) on upper and lower canopy needles of white spruce trees (Picea glauca) at the species' northern and southern range extremes. We combined our photosynthetic data with previously published respiratory data to compare and contrast canopy C balance between latitudinal extremes. We found steep canopy gradients in irradiance, photosynthesis and leaf traits at the southern range limit, but a lack of variation across canopy positions at the northern range limit. Thus, unlike many tree species from tropical to mid‐latitude forests, high latitude trees may not require vertical gradients of metabolic activity to optimize photosynthetic C gain. Consequently, accounting for self‐shading is less critical for predicting gross primary productivity at northern relative to southern latitudes. Northern trees also had a significantly smaller net positive leaf C balance than southern trees suggesting that, regardless of canopy position, low photosynthetic rates coupled with high respiratory costs may ultimately constrain the northern range limit of this widely distributed boreal species. Summary statement: Canopy gradients in photosynthetic capacity of white spruce diminish at high compared to low latitudes. Low carbon balance in high latitude trees may determine the extent of northern treeline. [ABSTRACT FROM AUTHOR] more...

Published

2023

8. Consistent diurnal pattern of leaf respiration in the light among contrasting species and climates.

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Author

Faber, Andreas H., Griffin, Kevin L., Tjoelker, Mark G., Pagter, Majken, Yang, Jinyan, and Bruhn, Dan

Subjects

*RESPIRATION, *RESPIRATION in plants, *SPECIES, *CIRCADIAN rhythms, *SOIL respiration

Abstract

Summary: Leaf daytime respiration (leaf respiration in the light, RL) is often assumed to constitute a fixed fraction of leaf dark respiration (RD) (i.e. a fixed light inhibition of respiration (RD)) and vary diurnally due to temperature fluctuations.These assumptions were tested by measuring RL, RD and the light inhibition of RD in the field at a constant temperature using the Kok method. Measurements were conducted diurnally on 21 different species: 13 deciduous, four evergreen and four herbaceous from humid continental and humid subtropical climates.RL and RD showed significant diurnal variations and the diurnal pattern differed in trajectory and magnitude between climates, but not between plant functional types (PFTs). The light inhibition of RD varied diurnally and differed between climates and in trajectory between PFTs.The results highlight the entrainment of leaf daytime respiration to the diurnal cycle and that time of day should be accounted for in studies seeking to examine the environmental and biological drivers of leaf daytime respiration. [ABSTRACT FROM AUTHOR] more...

Published

2022

9. Small but mighty: Impacts of rodent‐herbivore structures on carbon and nutrient cycling in arctic tundra.

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Author

Roy, Austin, Gough, Laura, Boelman, Natalie T., Rowe, Rebecca J., Griffin, Kevin L., and McLaren, Jennie R.

Subjects

TUNDRAS, NUTRIENT cycles, CARBON cycle, MAMMAL populations, BIOGEOCHEMICAL cycles, PLANT-soil relationships

Abstract

Understanding arctic ecosystem function is key to understanding future global carbon (C) and nutrient cycling processes. However, small mammal herbivores can have effects on ecosystems as structure builders and these effects have been underrepresented in the understanding of arctic systems.We examined the impact of small mammal structures (hay piles, runways, latrines) on soils and plants in three arctic tundra regions near Utqiaġvik, Toolik Lake, and Nome, Alaska. Our aims were to (1) examine how vole and lemming structures influence plant and soil nutrient pools and microbial processes, (2) determine if structure effects were similar across tundra system types, and (3) understand how changes in the abundance and cover of these structures during different phases of small mammal multi‐annual population cycles might influence biogeochemical cycling.In general, small mammal structures increased nitrogen (N) availability in soils, although effects varied by study region. Across study regions, hay piles were relatively uncommon (lowest % cover) but increased multiple soil N and P pools, C‐ and N‐acquiring enzyme activities, and leaf phosphorus (P) concentrations, with the specific nutrient variables and size of the effects varying by study region. Latrines had the second highest cover and influenced multiple C, N and P pools, but their effects were mainly observed within a single region. Lastly, runways had the highest % cover of all activity types but increased the fewest number of soil nutrient variables.We conclude that by influencing soil nutrient availability and biogeochemical cycling, small mammal structures can influence bottom‐up regulation of ecosystem function, particularly during the high phase of the small mammal population cycle. Future changes in these population cycles might alter the role of small mammals in the Arctic and have lasting effects on system processes. Read the free Plain Language Summary for this article on the Journal blog [ABSTRACT FROM AUTHOR] more...

Published

2022

10. Variation in White spruce needle respiration at the species range limits: A potential impediment to Northern expansion.

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Author

Griffin, Kevin L., Griffin, Zoe M., Schmiege, Stephanie C., Bruner, Sarah G., Boelman, Natalie T., Vierling, Lee A., and Eitel, Jan U. H.

Subjects

*WHITE spruce, *SPECIES, *RESPIRATION in plants, *TIMBERLINE, *RESPIRATION, *CURVE fitting, *ACCLIMATIZATION

Abstract

White spruce (Picea glauca) spans a massive range, yet the variability in respiratory physiology and related implications for tree carbon balance at the extremes of this distribution remain as enigmas. Working at both the most northern and southern extents of the distribution range more than 5000 km apart, we measured the short‐term temperature response of dark respiration (R/T) at upper and lower canopy positions. R/T curves were fit to both polynomial and thermodynamic models so that model parameters could be compared among locations, canopy positions, and with previously published data. Respiration measured at 25°C (R25) was 68% lower at the southern location than at the northern location, resulting in a significantly lower intercept in R/T response in temperate trees. Only at the southern location did upper canopy leaves have a steeper temperature response than lower canopy leaves, likely reflecting canopy gradients in light. At the northern range limit respiration is nearly twice that of the average R25 reported in a global leaf respiration database. We predict that without significant thermal acclimation, respiration will increase with projected end‐of‐the‐century warming and will likely constrain the future range limits of this important boreal species. Summary Statement: White spruce (Picea glauca) needle respiration at the northern limit of the species range is three times higher than at the southern range limit (when measured at 25°C). This high carbon cost likely challenges tree survival and contributes to the location of the northern treeline. [ABSTRACT FROM AUTHOR] more...

Published

2022

11. Small herbivores with big impacts: Tundra voles (Microtus oeconomus) alter post‐fire ecosystem dynamics.

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Author

Steketee, Jess K., Rocha, Adrian V., Gough, Laura, Griffin, Kevin L., Klupar, Ian, An, Ruby, Williamson, Nicole, and Rowe, Rebecca J.

Subjects

ECOSYSTEM dynamics, ECOLOGICAL disturbances, MICROTUS, HERBIVORES, VOLES, ANIMAL-plant relationships, PLANT productivity, ECOSYSTEMS

Abstract

Fire is an important ecological disturbance that can reset ecosystems and initiate changes in plant community composition, ecosystem biogeochemistry, and primary productivity. As herbivores rely on primary producers for food, changes in vegetation may alter plant–herbivore interactions with important—but often unexplored—feedbacks to ecosystems. Here we examined the impact of post‐fire changes in plant community composition and structure on habitat suitability and rodent herbivore activity in response to a large, severe, and unprecedented fire in northern Alaskan tundra. In moist acidic tundra where the fire occurred, tundra voles (Microtus oeconomus) are the dominant herbivore and rely on the tussock forming sedge Eriophorum vaginatum for both food and nesting material. Tundra voles were 10 times more abundant at the burned site compared with nearby unburned tundra 7‐12 years after the fire. Fire increased the habitat suitability for voles by increasing plant productivity and biomass, food quality, and cover through both taller vegetation and increased microtopography. As a result of elevated vole abundance, Eriophorum mortality caused by vole herbivory was two orders of magnitude higher than natural mortality and approached the magnitude of the mortality rate resulting directly from the fire. These findings suggest that post‐fire increases in herbivore pressure on Eriophorum could, in turn, disrupt graminoid recovery and enhance shrub encroachment. Tundra state transitions from graminoid to shrub dominated are also evident following other disturbances and fertilization experiments, suggesting that as Arctic temperatures rise, greater available nutrients and increased frequencies of large‐scale disturbances may also alter plant–animal interactions with cascading impacts on plant communities and ecosystem function. [ABSTRACT FROM AUTHOR] more...

Published

2022

12. Model responses to CO2 and warming are underestimated without explicit representation of Arctic small‐mammal grazing.

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Author

Rastetter, Edward B., Griffin, Kevin L., Rowe, Rebecca J., Gough, Laura, McLaren, Jennie R., and Boelman, Natalie T.

Subjects

NITROGEN cycle, CARBON cycle, TUNDRAS, GRAZING, CLIMATE change, CARBON dioxide, BIOGEOCHEMISTRY, ECOSYSTEMS

Abstract

We use a simple model of coupled carbon and nitrogen cycles in terrestrial ecosystems to examine how "explicitly representing grazers" vs. "having grazer effects implicitly aggregated in with other biogeochemical processes in the model" alters predicted responses to elevated carbon dioxide and warming. The aggregated approach can affect model predictions because grazer‐mediated processes can respond differently to changes in climate compared with the processes with which they are typically aggregated. We use small‐mammal grazers in a tundra as an example and find that the typical three‐to‐four‐year cycling frequency is too fast for the effects of cycle peaks and troughs to be fully manifested in the ecosystem biogeochemistry. We conclude that implicitly aggregating the effects of small‐mammal grazers with other processes results in an underestimation of ecosystem response to climate change, relative to estimations in which the grazer effects are explicitly represented. The magnitude of this underestimation increases with grazer density. We therefore recommend that grazing effects be incorporated explicitly when applying models of ecosystem response to global change. [ABSTRACT FROM AUTHOR] more...

Published

2022

13. Photosynthesis, fluorescence, and biomass responses of white oak seedlings to urban soil and air temperature effects.

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Author

Sonti, Nancy Falxa, Griffin, Kevin L., Hallett, Richard A., and Sullivan, Joe H.

Subjects

*WHITE oak, *URBAN soils, *SOIL temperature, *SOIL air, *ATMOSPHERIC temperature, *TEMPERATURE effect, *SOIL testing

Abstract

Urban forest patches can provide critical ecosystem services and their ability to regenerate native tree species is critical to their sustainability. Little is known about native tree seedling establishment and physiological function in urban ecosystems. This growth chamber study examined the effects of urban soil and air temperatures on white oak (Quercus alba L.) germination, seedling growth, and leaf‐level physiology. A split‐plot design tested effects of field collected soils from urban and reference forest sites in Baltimore, Maryland, and warm (urban) versus cool (rural) growth chamber temperature regimes. Seedlings were harvested at the end of the 23‐week experiment to assess foliar chemistry and biomass allocation. Seed germination was unaffected by treatments and was high in both soil types and temperature regimes. Urban soils supported significantly higher total seedling biomass and had a significant effect on leaf‐level physiological parameters, with seedlings grown in urban soils having greater Anet, Vcmax, ETRmax, Jmax, PNUE, gs, Anet/Rd, and PIabs (an integrated chlorophyll fluorescence parameter). PIabs measurements taken throughout the experiment revealed a significant time × temperature interaction effect. Baltimore urban forest patch soils were higher in nutrients than reference soils, but also higher in heavy metals. Despite higher levels of heavy metals, these results demonstrate that urban forest patch soils are able to support robust white oak seedling growth and enhanced seedling physiological parameters. However, interactions with temperature suggest that warming air temperatures may cause seedling stress and reduced growth. [ABSTRACT FROM AUTHOR] more...

Published

2021

14. Respiratory temperature responses of tropical conifers differ with leaf morphology.

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Author

Schmiege, Stephanie C., Buckley, Brendan M., Stevenson, Dennis W., Heskel, Mary A., Cuong, Truong Quang, Nam, Le Canh, and Griffin, Kevin L.

Subjects

LEAF morphology, CONIFEROUS forests, PINACEAE, TROPICAL forests, MOUNTAIN forests, CONIFERS, TEMPERATURE

Abstract

Photosynthetic traits suggest that shade tolerance may explain the contrasting success of two conifer taxa, Podocarpaceae and Pinaceae, in tropical forests. Needle‐leaved species from Pinus (Pinaceae) are generally absent from tropical forests, whereas Pinus krempfii, a flat‐leaved pine, and numerous flat‐leaved Podocarpaceae are abundant. Respiration (R) traits may provide additional insight into the drivers of the contrasting success of needle‐ and flat‐leaved conifers in tropical forests.We measured the short‐term respiratory temperature (RT) response between 10 and 50°C and foliar morphological traits of three needle‐ and seven flat‐leaved conifer species coexisting in a tropical montane forest in the Central Highlands of Vietnam containing notable conifer diversity. We fit a lognormal polynomial model to each RT curve and extracted the following three parameters: a (basal R), and b and c (together describing the shape of the response).Needle‐leaved species (Pinus kesiya, Pinus dalatensis and Dacrydium elatum) had higher rates of area‐based R at 25°C (R25‐area) as well as higher area‐based modelled basal respiration (a) than flat‐leaved species (P. krempfii, Podocarpus neriifolius, Dacrycarpus imbricatus, Nageia nana, Taxus wallichiana, Keteeleria evelyniana and Fokienia hodginsii). No significant differences were found between needle‐ and flat‐leaved species in mass‐based R25 (R25‐mass) or in the shape of the RT response (b and c); however, interspecific differences in R25‐mass, R at nighttime temperature extremes (R4.1 and R20.6) and leaf traits were apparent.Differences in R25‐area and a suggest that needle‐leaved foliage may be more energetically costly to maintain than flat‐leaved foliage, providing new insight and additional support for the hypothesis that shade tolerance is an important driver of Podocarpaceae success and Pinaceae absence in the majority of tropical forests.Interspecific differences in R25‐mass and leaf traits highlight that varying ecological strategies are employed by conifers to coexist and survive in the Central Highlands of Vietnam. Ultimately, these data further our understanding of current conifer biogeographical distributions and underscore the need for additional studies to elucidate the effects of extreme temperature events on the continued survival of conifers in this unique forest. A free Plain Language Summary can be found within the Supporting Information of this article. [ABSTRACT FROM AUTHOR] more...

Published

2021

15. Acclimation of leaf respiration temperature responses across thermally contrasting biomes.

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Author

Zhu, Lingling, Bloomfield, Keith J., Asao, Shinichi, Tjoelker, Mark G., Egerton, John J.G., Hayes, Lucy, Weerasinghe, Lasantha K., Creek, Danielle, Griffin, Kevin L., Hurry, Vaughan, Liddell, Michael, Meir, Patrick, Turnbull, Matthew H., and Atkin, Owen K. more...

Subjects

LEAF temperature, ACCLIMATIZATION, BIOMES, BODY temperature, RAIN forests, RESPIRATION

Abstract

Summary: Short‐term temperature response curves of leaf dark respiration (R–T) provide insights into a critical process that influences plant net carbon exchange. This includes how respiratory traits acclimate to sustained changes in the environment.Our study analysed 860 high‐resolution R–T (10–70°C range) curves for: (a) 62 evergreen species measured in two contrasting seasons across several field sites/biomes; and (b) 21 species (subset of those sampled in the field) grown in glasshouses at 20°C : 15°C, 25°C : 20°C and 30°C : 25°C, day : night.In the field, across all sites/seasons, variations in R25 (measured at 25°C) and the leaf T where R reached its maximum (Tmax) were explained by growth T (mean air‐T of 30‐d before measurement), solar irradiance and vapour pressure deficit, with growth T having the strongest influence. R25 decreased and Tmax increased with rising growth T across all sites and seasons with the single exception of winter at the cool‐temperate rainforest site where irradiance was low. The glasshouse study confirmed that R25 and Tmax thermally acclimated.Collectively, the results suggest: (1) thermal acclimation of leaf R is common in most biomes; and (2) the high T threshold of respiration dynamically adjusts upward when plants are challenged with warmer and hotter climates. [ABSTRACT FROM AUTHOR] more...

Published

2021

16. Is the Kok effect a respiratory phenomenon? Metabolic insight using 13C labeling in Helianthus annuus leaves.

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Author

Gauthier, Paul P. G., Saenz, Natalie, Griffin, Kevin L., Way, Danielle, and Tcherkez, Guillaume

Subjects

COMMON sunflower, LABELS, PHOTOSYNTHESIS, RESPIRATION, DECARBOXYLATION

Abstract

Summary: The Kok effect is a well‐known phenomenon in which the quantum yield of photosynthesis changes abruptly at low light. This effect has often been interpreted as a shift in leaf respiratory metabolism and thus used widely to measure day respiration. However, there is still no formal evidence that the Kok effect has a respiratory origin.Here, both gas exchange and isotopic labeling were carried out on sunflower leaves, using glucose that was 13C‐enriched at specific C‐atom positions. Position‐specific decarboxylation measurements and NMR analysis of metabolites were used to trace the fate of C‐atoms in metabolism.Decarboxylation rates were significant at low light (including above the Kok break point) and increased with decreasing irradiance below 100 µmol photons m−2 s−1. The variation in several metabolite pools such as malate, fumarate or citrate, and flux calculations suggest the involvement of several decarboxylating pathways in the Kok effect, including the malic enzyme.Our results show that day respiratory CO2 evolution plays an important role in the Kok effect. However, the increase in the apparent quantum yield of photosynthesis below the Kok break point is also probably related to malate metabolism, which participates in maintaining photosynthetic linear electron flow. [ABSTRACT FROM AUTHOR] more...

Published

2020

17. Remote sensing tracks daily radial wood growth of evergreen needleleaf trees.

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Author

Eitel, Jan U. H., Griffin, Kevin L., Boelman, Natalie T., Maguire, Andrew J., Meddens, Arjan J. H., Jensen, Johanna, Vierling, Lee A., Schmiege, Stephanie C., and Jennewein, Jyoti S.

Subjects

*REMOTE sensing, *TIME series analysis, *TAIGAS, *CARBON cycle, *VEGETATION dynamics, *TREE growth, *FORESTS & forestry

Abstract

Relationships between gross primary productivity (GPP) and the remotely sensed photochemical reflectance index (PRI) suggest that time series of foliar PRI may provide insight into climate change effects on carbon cycling. However, because a large fraction of carbon assimilated via GPP is quickly returned to the atmosphere via respiration, we ask a critical question—can PRI time series provide information about longer term gains in aboveground carbon stocks? Here we study the suitability of PRI time series to understand intra‐annual stem‐growth dynamics at one of the world's largest terrestrial carbon pools—the boreal forest. We hypothesized that PRI time series can be used to determine the onset (hypothesis 1) and cessation (hypothesis 2) of radial growth and enable tracking of intra‐annual tree growth dynamics (hypothesis 3). Tree‐level measurements were collected in 2018 and 2019 to link highly temporally resolved PRI observations unambiguously with information on daily radial tree growth collected via point dendrometers. We show that the seasonal onset of photosynthetic activity as determined by PRI time series was significantly earlier (p <.05) than the onset of radial tree growth determined from the point dendrometer time series which does not support our first hypothesis. In contrast, seasonal decline of photosynthetic activity and cessation of radial tree growth was not significantly different (p >.05) when derived from PRI and dendrometer time series, respectively, supporting our second hypothesis. Mixed‐effects modeling results supported our third hypothesis by showing that the PRI was a statistically significant (p <.0001) predictor of intra‐annual radial tree growth dynamics, and tracked these daily radial tree‐growth dynamics in remarkable detail with conditional and marginal coefficients of determination of 0.48 and 0.96 (for 2018) and 0.43 and 0.98 (for 2019), respectively. Our findings suggest that PRI could provide novel insights into nuances of carbon cycling dynamics by alleviating important uncertainties associated with intra‐annual vegetation response to climate change. [ABSTRACT FROM AUTHOR] more...

Published

2020

18. On the Functional Relationship Between Fluorescence and Photochemical Yields in Complex Evergreen Needleleaf Canopies.

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Author

Maguire, Andrew J., Eitel, Jan U. H., Griffin, Kevin L., Magney, Troy S., Long, Ryan A., Vierling, Lee A., Schmiege, Stephanie C., Jennewein, Jyoti S., Weygint, William A., Boelman, Natalie T., and Bruner, Sarah G. more...

Subjects

FLUORESCENCE yield, PINE needles, CHLOROPHYLL spectra, PHOTOSYSTEMS, CLIMATE change

Abstract

Recent advancements in understanding remotely sensed solar‐induced chlorophyll fluorescence often suggest a linear relationship with gross primary productivity at large spatial scales. However, the quantum yields of fluorescence and photochemistry are not linearly related, and this relationship is largely driven by irradiance. This raises questions about the mechanistic basis of observed linearity from complex canopies that experience heterogeneous irradiance regimes at subcanopy scales. We present empirical data from two evergreen forest sites that demonstrate a nonlinear relationship between needle‐scale observations of steady‐state fluorescence yield and photochemical yield under ambient irradiance. We show that accounting for subcanopy and diurnal patterns of irradiance can help identify the physiological constraints on needle‐scale fluorescence at 70–80% accuracy. Our findings are placed in the context of how solar‐induced chlorophyll fluorescence observations from spaceborne sensors relate to diurnal variation in canopy‐scale physiology. Plain Language Summary: Chlorophyll fluorescence is a faint signal emitted by plants that can provide information about photosynthesis and other processes important for plant growth. However, fluorescence is governed by complex chemical reactions that depend on light, and it is not linearly related to photosynthetic carbon uptake. Ecosystems with complex canopy structure, such as evergreen needleleaf forests, experience dynamic sunlit and shaded conditions, which make fluorescence observations challenging to interpret. However, by accounting for incoming light at fine spatial scales in studies using fluorescence, we can track the conditions under which canopies are partitioned by light‐saturated and light‐limited physiological constraints at 70–80% accuracy. Findings from our field‐based study are relevant for interpreting satellite‐based measurements of fluorescence as a proxy of photosynthetic carbon uptake. Furthermore, our study underscores the need for further research on how data from leaf‐scale studies can be scaled up to shed light on ecosystem responses to changing climatic conditions. Key Points: Needle‐scale observations from forests show a nonlinear, irradiance‐dependent relationship between fluorescence and photosystem II yieldsWe use the breakpoint in this relationship to distinguish physiological constraints on photosystem II operating efficiencyWe use this relationship to contextualize the apparent linear relationship between fluorescence and carbon uptake at the canopy scale [ABSTRACT FROM AUTHOR] more...

Published

2020

19. Repeatable, continuous and real‐time estimates of coupled nitrogenase activity and carbon exchange at the whole‐plant scale.

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Author

Bytnerowicz, Thomas A., Min, Elizabeth, Griffin, Kevin L., Menge, Duncan N. L., and Freckleton, Robert

Subjects

PLANT capacity, CARBON cycle, NITROGEN fixation, PHOTOSYNTHETIC rates, LASER spectroscopy, DETECTION limit

Abstract

Symbiotic nitrogen fixation (SNF) by higher plants and their bacterial symbionts is a globally important input of nitrogen. Our understanding of the mechanisms that control SNF and the time‐scales over which they operate has been constrained by the limitations of the existing methods for measuring SNF. One method, Acetylene Reduction Assays by Cavity ring‐down laser Absorption Spectroscopy (ARACAS), seems promising, as it is highly sensitive and gives rapid, continuous, repeatable and real‐time measurements of nitrogenase activity. ARACAS has been used to study nitrogen fixation in lichens, mosses and asymbiotic bacteria, but adapting it to higher plants poses challenges because acetylene and ethylene can influence plant function.Here, we report modifications to ARACAS that allow it to be used on higher plants in an environmentally controlled incubation chamber. The modifications include lower concentrations of acetylene (2%) and ethylene and concurrent measurements of whole‐chamber CO2 exchange, H2O exchange and nitrogenase activity, linking nitrogenase activity to whole‐plant rates of photosynthesis and respiration.After propagating the error terms from all sources, we establish the following parameters of the method: (a) The detection limit of our method was 2–3 ppbv C2H4 per hour, although it rose substantially when we used tank‐derived acetylene, which has much higher ethylene contamination; (b) Repeated measures at a frequency of 3 days or longer did not diminish nitrogenase activity or photosynthesis, although daily measurements diminished nitrogenase activity; (c) This method can detect changes at time‐scales as short as seconds; (d) Continuous measurement of nitrogenase activity is maintained above 90% of the maximum rate for 7.0 ± 1.3 (M ± SD) hours.This method has the potential to improve our understanding of the controls over SNF, and therefore, how SNF and global nitrogen and carbon cycling are likely to be affected by global change. [ABSTRACT FROM AUTHOR] more...

Published

2019

20. Interannual variations in needle and sapwood traits of <italic>Pinus edulis</italic> branches under an experimental drought.

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Author

Guérin, Marceau, Martin‐Benito, Dario, von Arx, Georg, Andreu‐Hayles, Laia, Griffin, Kevin L., Hamdan, Rayann, McDowell, Nate G., Muscarella, Robert, Pockman, William, and Gentine, Pierre

Subjects

SAPWOOD, CONIFERS, PINACEAE, PLANT variation, EFFECT of drought on plants, SOIL moisture

Abstract

Abstract: In the southwestern USA, recent large‐scale die‐offs of conifers raise the question of their resilience and mortality under droughts. To date, little is known about the interannual structural response to droughts. We hypothesized that piñon pines (Pinus edulis) respond to drought by reducing the drop of leaf water potential in branches from year to year through needle morphological adjustments. We tested our hypothesis using a 7‐year experiment in central New Mexico with three watering treatments (irrigated, normal, and rain exclusion). We analyzed how variation in “evaporative structure” (needle length, stomatal diameter, stomatal density, stomatal conductance) responded to watering treatment and interannual climate variability. We further analyzed annual functional adjustments by comparing yearly addition of needle area (LA) with yearly addition of sapwood area (SA) and distance to tip (d), defining the yearly ratios SA:LA and SA:LA/d. Needle length (l) increased with increasing winter and monsoon water supply, and showed more interannual variability when the soil was drier. Stomatal density increased with dryness, while stomatal diameter was reduced. As a result, anatomical maximal stomatal conductance was relatively invariant across treatments. SA:LA and SA:LA/d showed significant differences across treatments and contrary to our expectation were lower with reduced water input. Within average precipitation ranges, the response of these ratios to soil moisture was similar across treatments. However, when extreme soil drought was combined with high VPD, needle length, SA:LA and SA:LA/d became highly nonlinear, emphasizing the existence of a response threshold of combined high VPD and dry soil conditions. In new branch tissues, the response of annual functional ratios to water stress was immediate (same year) and does not attempt to reduce the drop of water potential. We suggest that unfavorable evaporative structural response to drought is compensated by dynamic stomatal control to maximize photosynthesis rates. [ABSTRACT FROM AUTHOR] more...

Published

2018

21. Nitrogen and phosphorus availabilities interact to modulate leaf trait scaling relationships across six plant functional types in a controlled-environment study.

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Author

Crous, Kristine Y., O'Sullivan, Odhran S., Zaragoza‐Castells, Joana, Bloomfield, Keith J., Negrini, A. Clarissa A., Meir, Patrick, Turnbull, Matthew H., Griffin, Kevin L., and Atkin, Owen K.

Subjects

PLANT metabolism, PHOTOSYNTHESIS, RESPIRATION in plants, PLANT physiology, HERBACEOUS plants

Abstract

Nitrogen (N) and phosphorus (P) have key roles in leaf metabolism, resulting in a strong coupling of chemical composition traits to metabolic rates in field-based studies. However, in such studies, it is difficult to disentangle the effects of nutrient supply per se on trait-trait relationships., Our study assessed how high and low N (5 mM and 0.4 mM, respectively) and P (1 mM and 2 μM, respectively) supply in 37 species from six plant functional types (PTFs) affected photosynthesis ( A) and respiration ( R) (in darkness and light) in a controlled environment., Low P supply increased scaling exponents (slopes) of area-based log-log A-N or R-N relationships when N supply was not limiting, whereas there was no P effect under low N supply. By contrast, scaling exponents of A-P and R-P relationships were altered by P and N supply. Neither R : A nor light inhibition of leaf R was affected by nutrient supply. Light inhibition was 26% across nutrient treatments; herbaceous species exhibited a lower degree of light inhibition than woody species., Because N and P supply modulates leaf trait−trait relationships, the next generation of terrestrial biosphere models may need to consider how limitations in N and P availability affect trait−trait relationships when predicting carbon exchange. [ABSTRACT FROM AUTHOR] more...

Published

2017

22. Tracking the origins of the Kok effect, 70 years after its discovery.

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Author

Tcherkez, Guillaume, Gauthier, Paul, Buckley, Thomas N., Busch, Florian A., Barbour, Margaret M., Bruhn, Dan, Heskel, Mary A., Gong, Xiao Ying, Crous, Kristine, Griffin, Kevin L., Way, Danielle A., Turnbull, Matthew H., Adams, Mark A., Atkin, Owen K., Bender, Michael, Farquhar, Graham D., and Cornic, Gabriel more...

Subjects

PHOTOSYNTHESIS, PLANT photorespiration, RESPIRATION in plants, CARBON dioxide, GAS exchange in plants

Abstract

The article discusses 18th phytologist workshop "The Kok effect: beyond the artefact, emerging leaf mechanisms (KOALA)" held at Angers, France, on July, 2016, on change in quantum yield of net photosynthesis. Topics include photosynthetic organs of plants accompanied by concurrent efflux of carbon dioxide by photorespiration and day respiration; difference between inlet and outlet air in open gas exchange systems; and leaf respiration in the light for ecosystem. more...

Published

2017

23. A gradient of nutrient enrichment reveals nonlinear impacts of fertilization on Arctic plant diversity and ecosystem function.

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Author

Prager, Case M., Naeem, Shahid, Boelman, Natalie T., Eitel, Jan U. H., Greaves, Heather E., Heskel, Mary A., Magney, Troy S., Menge, Duncan N.L., Vierling, Lee A., and Griffin, Kevin L.

Subjects

PLANT fertilization, PLANT communities, PLANT nutrients, PRIMARY productivity (Biology), VEGETATION & climate, PLANT diversity

Abstract

Rapid environmental change at high latitudes is predicted to greatly alter the diversity, structure, and function of plant communities, resulting in changes in the pools and fluxes of nutrients. In Arctic tundra, increased nitrogen (N) and phosphorus (P) availability accompanying warming is known to impact plant diversity and ecosystem function; however, to date, most studies examining Arctic nutrient enrichment focus on the impact of relatively large (>25x estimated naturally occurring N enrichment) doses of nutrients on plant community composition and net primary productivity. To understand the impacts of Arctic nutrient enrichment, we examined plant community composition and the capacity for ecosystem function (net ecosystem exchange, ecosystem respiration, and gross primary production) across a gradient of experimental N and P addition expected to more closely approximate warming-induced fertilization. In addition, we compared our measured ecosystem CO2 flux data to a widely used Arctic ecosystem exchange model to investigate the ability to predict the capacity for CO2 exchange with nutrient addition. We observed declines in abundance-weighted plant diversity at low levels of nutrient enrichment, but species richness and the capacity for ecosystem carbon uptake did not change until the highest level of fertilization. When we compared our measured data to the model, we found that the model explained roughly 30%-50% of the variance in the observed data, depending on the flux variable, and the relationship weakened at high levels of enrichment. Our results suggest that while a relatively small amount of nutrient enrichment impacts plant diversity, only relatively large levels of fertilization-over an order of magnitude or more than warming-induced rates-significantly alter the capacity for tundra CO2 exchange. Overall, our findings highlight the value of measuring and modeling the impacts of a nutrient enrichment gradient, as warming-related nutrient availability may impact ecosystems differently than single-level fertilization experiments. [ABSTRACT FROM AUTHOR] more...

Published

2017

24. Thermal limits of leaf metabolism across biomes.

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Author

O'sullivan, Odhran S., Heskel, Mary A., Reich, Peter B., Tjoelker, Mark G., Weerasinghe, Lasantha K., Penillard, Aurore, Zhu, Lingling, Egerton, John J. G., Bloomfield, Keith J., Creek, Danielle, Bahar, Nur H. A., Griffin, Kevin L., Hurry, Vaughan, Meir, Patrick, Turnbull, Matthew H., and Atkin, Owen K. more...

Subjects

EFFECT of global warming on plants, EFFECT of temperature on plants, BIOMES, LEAF temperature, PHOTOSYSTEMS, HEAT waves (Meteorology)

Abstract

High-temperature tolerance in plants is important in a warming world, with extreme heat waves predicted to increase in frequency and duration, potentially leading to lethal heating of leaves. Global patterns of high-temperature tolerance are documented in animals, but generally not in plants, limiting our ability to assess risks associated with climate warming. To assess whether there are global patterns in high-temperature tolerance of leaf metabolism, we quantified Tcrit (high temperature where minimal chlorophyll a fluorescence rises rapidly and thus photosystem II is disrupted) and Tmax (temperature where leaf respiration in darkness is maximal, beyond which respiratory function rapidly declines) in upper canopy leaves of 218 plant species spanning seven biomes. Mean site-based Tcrit values ranged from 41.5 °C in the Alaskan arctic to 50.8 °C in lowland tropical rainforests of Peruvian Amazon. For Tmax, the equivalent values were 51.0 and 60.6 °C in the Arctic and Amazon, respectively. Tcrit and Tmax followed similar biogeographic patterns, increasing linearly ( ˜8 °C) from polar to equatorial regions. Such increases in high-temperature tolerance are much less than expected based on the 20 °C span in high-temperature extremes across the globe. Moreover, with only modest high-temperature tolerance despite high summer temperature extremes, species in mid-latitude (~20-50°) regions have the narrowest thermal safety margins in upper canopy leaves; these regions are at the greatest risk of damage due to extreme heat-wave events, especially under conditions when leaf temperatures are further elevated by a lack of transpirational cooling. Using predicted heat-wave events for 2050 and accounting for possible thermal acclimation of Tcrit and Tmax, we also found that these safety margins could shrink in a warmer world, as rising temperatures are likely to exceed thermal tolerance limits. Thus, increasing numbers of species in many biomes may be at risk as heat-wave events become more severe with climate change. [ABSTRACT FROM AUTHOR] more...

Published

2017

25. Greater deciduous shrub abundance extends tundra peak season and increases modeled net CO2 uptake.

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Author

Sweet, Shannan K., Griffin, Kevin L., Steltzer, Heidi, Gough, Laura, and Boelman, Natalie T.

Subjects

*DECIDUOUS plants, *PLANT diversity, *TUNDRA plants, *CARBON dioxide, *SNOW cover

Abstract

Satellite studies of the terrestrial Arctic report increased summer greening and longer overall growing and peak seasons since the 1980s, which increases productivity and the period of carbon uptake. These trends are attributed to increasing air temperatures and reduced snow cover duration in spring and fall. Concurrently, deciduous shrubs are becoming increasingly abundant in tundra landscapes, which may also impact canopy phenology and productivity. Our aim was to determine the influence of greater deciduous shrub abundance on tundra canopy phenology and subsequent impacts on net ecosystem carbon exchange ( NEE) during the growing and peak seasons in the arctic foothills region of Alaska. We compared deciduous shrub-dominated and evergreen/graminoid-dominated community-level canopy phenology throughout the growing season using the normalized difference vegetation index ( NDVI). We used a tundra plant-community-specific leaf area index ( LAI) model to estimate LAI throughout the green season and a tundra-specific NEE model to estimate the impact of greater deciduous shrub abundance and associated shifts in both leaf area and canopy phenology on tundra carbon flux. We found that deciduous shrub canopies reached the onset of peak greenness 13 days earlier and the onset of senescence 3 days earlier compared to evergreen/graminoid canopies, resulting in a 10-day extension of the peak season. The combined effect of the longer peak season and greater leaf area of deciduous shrub canopies almost tripled the modeled net carbon uptake of deciduous shrub communities compared to evergreen/graminoid communities, while the longer peak season alone resulted in 84% greater carbon uptake in deciduous shrub communities. These results suggest that greater deciduous shrub abundance increases carbon uptake not only due to greater leaf area, but also due to an extension of the period of peak greenness, which extends the period of maximum carbon uptake. [ABSTRACT FROM AUTHOR] more...

Published

2015

26. Thermal acclimation of shoot respiration in an Arctic woody plant species subjected to 22 years of warming and altered nutrient supply.

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Author

Heskel, Mary A., Greaves, Heather E., Turnbull, Matthew H., O'Sullivan, Odhran S., Shaver, Gaius R., Griffin, Kevin L., and Atkin, Owen K.

Subjects

ACCLIMATIZATION (Plants), WOODY plants, GLOBAL warming & the environment, PLANT shoots, PLANT nutrients, RESPIRATION in plants, PHYSIOLOGY

Abstract

Despite concern about the status of carbon (C) in the Arctic tundra, there is currently little information on how plant respiration varies in response to environmental change in this region. We quantified the impact of long-term nitrogen (N) and phosphorus (P) treatments and greenhouse warming on the short-term temperature ( T) response and sensitivity of leaf respiration ( R), the high- T threshold of R, and associated traits in shoots of the Arctic shrub Betula nana in experimental plots at Toolik Lake, Alaska. Respiration only acclimated to greenhouse warming in plots provided with both N and P (resulting in a ~30% reduction in carbon efflux in shoots measured at 10 and 20 °C), suggesting a nutrient dependence of metabolic adjustment. Neither greenhouse nor N+P treatments impacted on the respiratory sensitivity to T ( Q10); overall, Q10 values decreased with increasing measuring T, from ~3.0 at 5 °C to ~1.5 at 35 °C. New high-resolution measurements of R across a range of measuring Ts (25-70 °C) yielded insights into the T at which maximal rates of R occurred ( Tmax). Although growth temperature did not affect Tmax, N+P fertilization increased Tmax values ~5 °C, from 53 to 58 °C. N+P fertilized shoots exhibited greater rates of R than nonfertilized shoots, with this effect diminishing under greenhouse warming. Collectively, our results highlight the nutrient dependence of thermal acclimation of leaf R in B. nana, suggesting that the metabolic efficiency allowed via thermal acclimation may be impaired at current levels of soil nutrient availability. This finding has important implications for predicting carbon fluxes in Arctic ecosystems, particularly if soil N and P become more abundant in the future as the tundra warms. [ABSTRACT FROM AUTHOR] more...

Published

2014

27. Predicting ecosystem carbon balance in a warming Arctic: the importance of long-term thermal acclimation potential and inhibitory effects of light on respiration.

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Author

McLaughlin, Blair C., Xu, Cheng‐Yuan, Rastetter, Edward B., and Griffin, Kevin L.

Subjects

ACCLIMATIZATION, BIOLOGICAL adaptation, ECOSYSTEM management, CLIMATE change, ENVIRONMENTAL sciences

Abstract

The carbon balance of Arctic ecosystems is particularly sensitive to global environmental change. Leaf respiration ( R), a temperature-dependent key process in determining the carbon balance, is not well-understood in Arctic plants. The potential for plants to acclimate to warmer conditions could strongly impact future global carbon balance. Two key unanswered questions are (1) whether short-term temperature responses can predict long-term respiratory responses to growth in elevated temperatures and (2) to what extent the constant daylight conditions of the Arctic growing season inhibit leaf respiration. In two dominant Arctic species E riophorum vaginatum (tussock grass) and B etula nana (woody shrub), we assessed the extent of respiratory inhibition in the light ( RL/ RD), respiratory response to short-term temperature change, and respiratory acclimation to long-term warming treatments. We found that R of both species is strongly inhibited by light (averaging 35% across all measurement temperatures). In E . vaginatum both RL and RD acclimated to the long-term warming treatment, reducing the magnitude of respiratory response relative to the short-term response to temperature increase. In B . nana, both RL and RD responded to short-term temperature increase but showed no acclimation to the long-term warming. The ability to predict plant respiratory response to global warming with short-term temperature responses will depend on species-specific acclimation potential and the differential response of RL and RD to temperature. With projected woody shrub encroachment in Arctic tundra and continued warming, changing species dominance between these two functional groups, may impact ecosystem respiratory response and carbon balance. [ABSTRACT FROM AUTHOR] more...

Published

2014

28. Modulation of respiratory metabolism in response to nutrient changes along a soil chronosequence.

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Author

KORNFELD, ARI, ATKIN, OWEN K., GRIFFIN, KEVIN L., HORTON, TRAVIS W., YAKIR, DAN, and TURNBULL, MATTHEW H.

Subjects

SOIL chronosequences, RESPIRATION in plants, PLANT nutrients, CYTOCHROME oxidase, TEMPERATE rain forests, PHOTOSYNTHETIC oxygen evolution

Abstract

Laboratory studies indicate that plant respiratory efficiency may decrease in response to low nutrient availability due to increased partitioning of electrons to the energy-wasteful alternative oxidase ( AOX); however, field confirmation of this hypothesis is lacking. We therefore investigated plant respiratory changes associated with succession and retrogression in soils aged from 10 to 120 000 years along the Franz Josef soil chronosequence, New Zealand. Respiration rates and electron partitioning were determined based on oxygen isotopic fractionation. Leaf structural traits, foliar nutrient status, carbohydrates and species composition were measured as explanatory variables. Although soil nutrient levels and species composition varied by site along the chronosequence, foliar respiration across all sites and species corresponded strongly with leaf nitrogen concentration ( r2 = 0.8). In contrast, electron partitioning declined with increasing nitrogen/phosphorus ( r2 = 0.23) and AOX activity correlated with phosphorus ( r2 = 0.64). Independently, total respiration was further associated with foliar Cu, possibly linked to its effect on AOX. Independent control of AOX and cytochrome pathway activities is also discussed. These responses of plant terminal respiratory oxidases - and therefore respiratory carbon efficiency - to multiple nutrient deficiencies demonstrate that modulation of respiratory metabolism may play an important role in plant responses to nutrient gradients. [ABSTRACT FROM AUTHOR] more...

Published

2013

29. Differential physiological responses to environmental change promote woody shrub expansion.

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Author

Heskel, Mary, Greaves, Heather, Kornfeld, Ari, Gough, Laura, Atkin, Owen K., Turnbull, Matthew H., Shaver, Gaius, and Griffin, Kevin L.

Published

2013

30. Respiratory flexibility and efficiency are affected by simulated global change in Arctic plants.

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Author

Kornfeld, Ari, Heskel, Mary, Atkin, Owen K., Gough, Laura, Griffin, Kevin L., Horton, Travis W., and Turnbull, Matthew H.

Subjects

RESPIRATION in plants, CLOUDBERRY, CYTOCHROME oxidase, ACCLIMATIZATION (Plants)

Abstract

Laboratory studies indicate that, in response to environmental conditions, plants modulate respiratory electron partitioning between the 'energy-wasteful' alternative pathway ( AP) and the 'energy-conserving' cytochrome pathway ( CP). Field data, however, are scarce. Here we investigate how 20-yr field manipulations simulating global change affected electron partitioning in Alaskan Arctic tundra species., We sampled leaves from three dominant tundra species - Betula nana, Eriophorum vaginatum and Rubus chamaemorus - that had been strongly affected by manipulations of soil nutrients, light availability, and warming. We measured foliar dark respiration, in-vivo electron partitioning and alternative oxidase/cytochrome c oxidase concentrations in addition to leaf traits and mitochondrial ultrastructure., Changes in leaf traits and ultrastructure were similar across species. Respiration at 20°C ( R20) was reduced 15% in all three species grown at elevated temperature, suggesting thermal acclimation of respiration. In Betula, the species with the largest growth response to added nutrients, CP activity increased from 9.4 ± 0.8 to 16.6 ± 1.6 nmol O2 g−1 DM s−1 whereas AP activity was unchanged., The ability of Betula to selectively increase CP activity in response to the environment may contribute to its overall ecological success by increasing respiratory energy efficiency, and thus retaining more carbon for growth. [ABSTRACT FROM AUTHOR] more...

Published

2013

31. LEAF- AND CELL-LEVEL CARBON CYCLING RESPONSES TO A NITROGEN AND PHOSPHORUS GRADIENT IN TWO ARCTIC TUNDRA SPECIES.

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Author

Heskel, Mary A., Anderson, O. Roger, Atkin, Owen K., Turnbull, Matthew H., and Griffin, Kevin L.

Subjects

CARBON cycle, TUNDRA plants, PHOSPHORUS, MITOCHONDRIA, CHLOROPLASTS

Abstract

* Premise of the study: Consequences of global climate change are detectable in the historically nitrogen- and phosphorus-limited Arctic tundra landscape and have implications for the terrestrial carbon cycle. Warmer temperatures and elevated soil nutrient availability associated with increased microbial activity may influence rates of photosynthesis and respiration. * Methods: This study examined leaf-level gas exchange, cellular ultrastructure, and related leaf traits in two dominant tundra species, Betula nana, a woody shrub, and Eriophorum vaginatum, a tussock sedge, under a 3-yr-old treatment gradient of nitrogen (N) and phosphorus (P) fertilization in the North Slope of Alaska. * Key results: Respiration increased with N and P addition--the highest rates corresponding to the highest concentrations of leaf N in both species. The inhibition of respiration by light ("Kok effect") significantly reduced respiration rates in both species (P < 0.001), ranged from 12-63% (mean 34%), and generally decreased with fertilization for both species. However, in both species, observed rates of photosynthesis did not increase, and photosynthetic nitrogen use efficiency generally decreased under increasing fertilization. Chloroplast and mitochondrial size and density were highly sensitive to N and P fertilization (P < 0.001), though species interactions indicated divergent cellular organizational strategies. * Conclusions: Results from this study demonstrate a species-specific decoupling of respiration and photosynthesis under N and P fertilization, implying an alteration of the carbon balance of the tundra ecosystem under future conditions. [ABSTRACT FROM AUTHOR] more...

Published

2012

32. A field-compatible method for measuring alternative respiratory pathway activities in vivo using stable O2 isotopes.

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Author

KORNFELD, ARI, HORTON, TRAVIS W., YAKIR, DAN, SEARLE, STEPHANIE Y., GRIFFIN, KEVIN L., ATKIN, OWEN K., SUBKE, JENS-ARNE, and TURNBULL, MATTHEW H.

Subjects

OXYGEN isotopes, RESPIRATION in plants, OXIDASES, MASS spectrometry, CYTOCHROME oxidase, STABLE isotopes, MATHEMATICAL analysis

Abstract

ABSTRACT Plants can alter rates of electron transport through the alternative oxidase (AOX) pathway in response to environmental cues, thus modulating respiratory efficiency, but the 18O discrimination method necessary for measuring electron partitioning in vivo has been restricted to laboratory settings. To overcome this limitation, we developed a field-compatible analytical method. Series of plant tissue subsamples were incubated in 12 mL septum-capped vials for 0.5-4 h before aliquots of incubation air were injected into 3.7 mL evacuated storage vials. Vials were stored for up to 10 months before analysis by mass spectrometry. Measurements were corrected for unavoidable contamination. Additional mathematical tools were developed for detecting and addressing non-linearity (whether intrinsic or due to contamination) in the data used to estimate discrimination values. Initial contamination in the storage vials was 0.03 ± 0.01 atm; storing the gas samples at −17 °C eliminated further contamination effects over 10 months. Discrimination values obtained using our offline incubation and computation method replicated previously reported results over a range of 10-31‰, with precision generally better than ±0.5‰. Our method enables large-scale investigations of plant alternative respiration along natural environmental gradients under field conditions. [ABSTRACT FROM AUTHOR] more...

Published

2012

33. Age-related decline of stand biomass accumulation is primarily due to mortality and not to reduction in NPP associated with individual tree physiology, tree growth or stand structure in a Quercus-dominated forest.

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Author

Xu, Cheng-Yuan, Turnbull, Matthew H., Tissue, David T., Lewis, James D., Carson, Rob, Schuster, William S. F., Whitehead, David, Walcroft, Adrian S., Li, Jinbao, and Griffin, Kevin L.

Subjects

OAK, TREE growth, CARBON sequestration, BIOMASS & the environment, ECOLOGICAL disturbances, PLANT ecophysiology, PHOTOSYNTHESIS

Abstract

Summary 1. Age-related reductions in stand biomass accumulation are frequently observed in old-growth forests. The phenomenon may be caused by reduced production, increased mortality or both. The relative importance of production and mortality is not well studied, so the mechanisms controlling age-related decline of stand biomass accumulation remain unclear. 2. In this study, conducted in a Quercus-dominated deciduous forest in the Northeastern USA, we examined whether age-related decline in stand above-ground biomass (AGB) accumulation could be explained by reduction of above-ground net primary production (NPP) (growth of surviving trees) that may be associated with (i) physiological constraints within individual trees or (ii) changes in stand structure, or by (iii) age-related, increasing tree mortality in stands up to 135 years old. Few previous studies have tested these hypotheses simultaneously within the same forest. 3. We did not find evidence for a reduction in individual tree growth associated with age-related physiological constraints, in terms of foliar carbon assimilation capacity, photosynthesis/respiration balance, nitrogen availability or hydraulic constraints on carbon gain. Over the period of 1937-2006, we did not observe alterations in stand structure, and the above-ground NPP of the Quercus forest was generally stable. 4. However, we did find that the primary mechanism driving age-related decline of stand AGB accumulation was biomass loss due to the death of large, dominant trees. Our results indicate that shifts in mortality from the loss of small trees to the loss of large trees, rather than changes in above-ground NPP, drives age-related decline in stand AGB accumulation in this forest. 5. Synthesis. We found that within the range of stand development stages analysed, the age-related decline of stand AGB accumulation in a Quercus-dominated forest was primarily due to mortality of large, dominant trees and not due to changes in above-ground NPP associated with tree physiology, individual tree growth or stand structure. This result indicates that tree demography and the influence of climate change on disturbances may need to be integrated into models to predict the change of above-ground carbon stock of some old-growth forests. [ABSTRACT FROM AUTHOR] more...

Published

2012

34. Respiratory alternative oxidase responds to both low- and high-temperature stress in Quercus rubra leaves along an urban-rural gradient in New York.

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Author

Searle, Stephanie Y., Bitterman, Danielle S., Thomas, Samuel, Griffin, Kevin L., Atkin, Owen K., and Turnbull, Matthew H.

Subjects

RED oak, EFFECT of stress on plants, RESPIRATION in plants, PHYSIOLOGICAL effects of heat, OXIDASES, PLANT ecology

Abstract

Summary 1. Urban-rural transects can be utilized as natural gradients of temperature and also as a tool to predict how plant ecology and physiology might respond to expected global change variables such as elevated temperatures, CO2 and inorganic nitrogen deposition. 2. We investigated differences in respiration ( R) and the balance of electron partitioning through the cytochrome (CP) and alternative (AP) pathways in leaves of mature Quercus rubra L. trees along a transect from New York City to the Catskill Mountains over the course of one growing season. In addition, we investigated the effects of elevated temperature on Q. rubra seedlings in a controlled environment study. 3. In the field study, we found that urban-grown leaves often respired at greater rates than leaves grown at other sites and that this was likely due to higher leaf nitrogen. At each site, R at the prevailing growth temperature declined steadily throughout the growing season despite higher temperatures at the end of the summer. Differences in R were associated with changes in the relative abundances of cytochrome and alternative oxidase proteins. Oxygen isotope discrimination ( D), which reflects relative changes in AP and CP partitioning, was negatively correlated with daily minimum temperature in trees grown at the colder rural sites, but not at the warmer urban sites. 4. In the growth cabinet study, we found that R acclimated to elevated temperatures and that this was accompanied by a steady increase in D. 5. These findings that AP partitioning increases with both high and low temperatures show that the AP may play an important role in plant responses to environmental conditions that elicit stress, and not simply to specific conditions such as low temperature. [ABSTRACT FROM AUTHOR] more...

Published

2011

35. Processing arctic eddy-flux data using a simple carbon-exchange model embedded in the ensemble Kalman filter.

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Author

Rastetter, Edward B., Williams, Mathew, Griffin, Kevin L., Kwiatkowski, Bonnie L., Tomasky, Gabrielle, Potosnak, Mark J., Stoy, Paul C., Shaver, Gaius R., Stieglitz, Marc, Hobbie, John E., and Kling, George W. more...

Subjects

TIME series analysis, EDDY flux, PLANT phenology, KALMAN filtering, ANALYSIS of covariance

Abstract

The article presents the study of time-series estimates using the net ecosystem carbon exchange (NEE) model with the application of eddy covariance techniques and embedded in an ensemble Kalman filter (EnKF). Researchers employ a model testing in estimating the dynamic variables on the changes of leaf phenology in Alaska and uses two modifications of EnKF. It presents that there is a deficiency on the model due to the vapor pressure which affects the canopy conductance. more...

Published

2010

36. Thermal acclimation of leaf respiration but not photosynthesis in Populus deltoides× nigra.

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Author

Lai Fern Ow, Griffin, Kevin L., Whitehead, David, Walcroft, Adrian S., and Turnbull, Matthew H.

Subjects

*ACCLIMATIZATION, *RESPIRATION in plants, *LEAVES, *PHOTOSYNTHESIS, *COTTONWOOD, *BLACK poplar

Abstract

• Dark respiration and photosynthesis were measured in leaves of poplar Populus deltoides × nigra (‘Veronese’) saplings to investigate the extent of respiratory and photosynthetic acclimation in pre-existing and newly emerged leaves to abrupt changes in air temperature. • The saplings were grown at three temperature regimes and at high and low nitrogen availabilities. Rates of photosynthesis and dark respiration ( Rd) were measured at the initial temperature and the saplings were then transferred to a different temperature regime, where the plants remained for a second and third round of measurements on pre-existing and newly emerged leaves. • Acclimation of photosynthesis was limited following transfer to warmer or cooler growing conditions. There was strong evidence of cold and warm acclimation of Rd to growth temperature, but this was limited in pre-existing leaves. Full acclimation of Rd was restricted to newly emerged leaves grown at the new growth temperature. • These findings indicate that the extent of thermal acclimation differs significantly between photosynthesis and respiration. Importantly, pre-existing leaves in poplar were capable of some respiratory acclimation, but full acclimation was observed only in newly emerged leaves. The Rd/ Amax ratio declined at higher growth temperatures, and nitrogen status of leaves had little impact on the degree of acclimation. [ABSTRACT FROM AUTHOR] more...

Published

2008

37. Spatial and temporal scaling of intercellular CO2 concentration in a temperate rain forest dominated by Dacrydium cupressinum in New Zealand.

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Author

TISSUE, DAVID T., BARBOUR, MARGARET M., HUNT, JOHN E., TURNBULL, MATTHEW H., GRIFFIN, KEVIN L., WALCROFT, ADRIAN S., and WHITEHEAD, DAVID

Subjects

DACRYDIUM (Plants), RAIN forest ecology, RAIN forests, PODOCARPACEAE, PHOTOSYNTHESIS, STOMATA, PLANT canopies, PLANT communities, FOREST canopies

Abstract

Seven methods, including measurements of photosynthesis ( A) and stomatal conductance ( gs), carbon isotope discrimination, ecosystem CO2 and water vapour exchange using eddy covariance and the use of a multilayer canopy model and ecosystem Keeling plots, were employed to derive estimates of intercellular CO2 concentration ( Ci) across a range of spatial and temporal scales in a low productivity rain forest ecosystem dominated by the conifer Dacrydium cupressinum Lamb. in New Zealand. Estimates of shoot and canopy Ci across temporal scales ranging from minutes to years were remarkably similar (range of 274–294 µmol mol−1). The gradual increase in shoot Ci with depth in the canopy was more likely attributable to decreases in A resulting from lower irradiance ( Q) than to increases in gs due to changes in air saturation deficit ( D). The lack of marked vertical gradients in A and gs at saturating Q through the canopy and the low seasonal variability in environmental conditions contributed to the efficacy of scaling Ci. However, the canopy Ci estimate calculated from the carbon isotope composition of respired ecosystem CO2 ( δ 13CR; 236 µmol mol−1) was much lower than other estimates of canopy Ci. Partitioning δ 13CR into four components (soil, roots, litter and foliage) indicated root respiration as the dominant (> 50%) contributor to δ 13CR. Variable time lags and differences in isotopic composition during photosynthesis and respiration make the direct estimation of canopy Ci from δ 13CR problematic. [ABSTRACT FROM AUTHOR] more...

Published

2006

38. Sap flow rates and sapwood density are critical factors in within- and between-tree variation in CO2 efflux from stems of mature Dacrydium cupressinum trees.

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Author

Bowman, William P., Barbour, Margaret M., Turnbull, Matthew H., Tissue, David T., Whitehead, David, and Griffin, Kevin L.

Subjects

DACRYDIUM (Plants), XYLEM, PLANT cells & tissues, PLANT stems, CARBON dioxide

Abstract

• Measurements of CO2 efflux from stems and branches, sap velocity, and respiratory activity of excised wood cores were conducted in Dacrydium cupressinum trees that differed in diameter, age, and canopy emergence. The objective of this study was to determine if consistent linkages exist among respiratory production of CO2 within stems, xylem transport of CO2, and the rate of CO2 diffusing from stem surfaces. • Stem CO2 efflux was depressed during periods of sap flow compared with the efflux rate expected for a given stem temperature and was positively correlated with sapwood density. By contrast, no significant relationships were observed between CO2 efflux and the respiratory activity of wood tissues. • Between 86 and 91% of woody tissue respiration diffused to the atmosphere over a 24-h period. However, at certain times of the day, xylem transport and internal storage of CO2 may account for up to 13–38% and 12–18%, respectively, of woody tissue respiration. • These results demonstrate that differences in sap flow rates and xylem anatomy are critically important for explaining within- and between-tree variation in CO2 efflux from stems. New Phytologist (2005) doi: 10.1111/j.1469-8137.2005.01478.x © New Phytologist (2005) [ABSTRACT FROM AUTHOR] more...

Published

2005

39. Atmospheric CO2 enrichment alters energy assimilation, investment and allocation in Xanthium strumarium.

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Author

Nagel, Jennifer M., Xianzhong Wang, Lewis, James D., Fung, Howard A., Tissue, David T., and Griffin, Kevin L.

Subjects

CARBON dioxide enrichment of greenhouses, XANTHIUM, PHOTOBIOLOGY, PHOTOSYNTHESIS, ASTERACEAE, BIOMASS

Abstract

• Energy-use efficiency and energy assimilation, investment and allocation patterns are likely to influence plant growth responses to increasing atmospheric CO2 concentration ([CO2]). Here, we describe the influence of elevated[CO2] on energetic properties as a mechanism of growth responses inXanthium strumarium.• Individuals ofX. strumariumwere grown at ambient or elevated[CO2] and harvested. Total biomass and energetic construction costs (CC) of leaves, stems, roots and fruits and percentage of total biomass and energy allocated to these components were determined. Photosynthetic energy-use efficiency (PEUE) was calculated as the ratio of total energy gained via photosynthetic activity (Atotal) to leaf CC.• Elevated[CO2] increased leafAtotal, but decreased CC per unit mass of leaves and roots. Consequently,X. strumariumindividuals produced more leaf and root biomass at elevated[CO2] without increasing total energy investment in these structures (CCtotal). Whole-plant biomass was associated positively with PEUE. Whole-plant construction required 16.1% less energy than modeled whole-plant energy investment had CC not responded to increased[CO2].• As a physiological mechanism affecting growth, altered energetic properties could positively influence productivity ofX. strumarium, and potentially other species, at elevated[CO2].New Phytologist(2005)doi: 10.1111/j.1469-8137.2005.01341.x© New Phytologist(2005) [ABSTRACT FROM AUTHOR] more...

Published

2005

40. Leaf respiratory CO2 is 13C-enriched relative to leaf organic components in five species of C3 plants.

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Author

Cheng-yuan Xu, Guang-hui Lin, Griffin, Kevin L., and Sambrotto, Raymond N.

Subjects

CARBON dioxide, COTTONWOOD, LEAVES, PLANTS, ISOTOPES

Abstract

• Here, we compared the carbon isotope ratios of leaf respiratory CO2 (δ13CR) and leaf organic components (soluble sugar, water soluble fraction, starch, protein and bulk organic matter) in five C3 plants grown in a glasshouse and inside Biosphere 2. One species, Populus deltoides, was grown under three different CO2 concentrations. • The Keeling plot approach was applied to the leaf scale to measure leaf δ13CR and these results were compared with the δ13C of leaf organic components. • In all cases, leaf respiratory CO2 was more 13C-enriched than leaf organic components. The amount of 13C enrichment displayed a significant species-specific pattern, but the effect of CO2 treatment was not significant on P. deltoides. • In C3 plant leaves, 13C-enriched respiratory CO2 appears widespread. Among currently hypothesized mechanisms contributing to this phenomenon, non-statistical carbon isotope distribution within the sugar substrates seems most likely. However, caution should be taken when attempting to predict the δ13C of leaf respiratory CO2 at the ecosystem scale by upscaling the relationship between leaf δ13CR and δ13C of leaf organic components. New Phytologist (2004) 163: 499–505 © New Phytologist (2004) doi: 10.1111/j.1469-8137.2004.01153.x [ABSTRACT FROM AUTHOR] more...

Published

2004

41. Response of total night-time respiration to differences in total daily photosynthesis for leaves in a Quercus rubra L. canopy: implications for modelling canopy CO2 exchange.

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Author

Whitehead, David, Griffin, Kevin L., Turnbull, Matthew H., Tissue, David T., Engel, Victor C., Brown, Kim J., Schuster, William S.F., and Walcroft, Adrian S.

Subjects

*PHOTOSYNTHESIS, *RED oak, *PLANT canopies, *FOREST canopies, *LEAVES, *CARBON dioxide

Abstract

Measurements of photosynthesis and respiration were made on leaves in summer in a Quercus rubra L. canopy at approximately hourly intervals throughout 5 days and nights. Leaves were selected in the upper canopy in fully sunlit conditions (upper) and in the lower canopy (lower). In addition, leaves in the upper canopy were shaded (upper shaded) to decrease photosynthesis rates. The data were used to test the hypothesis that total night-time respiration is dependent on total photosynthesis during the previous day and that the response is mediated through changes in storage in carbohydrate pools. Measurements were made on clear sunny days with similar solar irradiance and air temperature, except for the last day when temperature, especially at night, was lower than that for the previous days. Maximum rates of photosynthesis in the upper leaves (18.7 μmol m−2 s−1) were approximately four times higher than those in the lower leaves (4.3 μmol m−2 s−1) and maximum photosynthesis rates in the upper shaded leaves (8.0 μmol m−2 s−1) were about half those in the upper leaves. There was a strong linear relationship between total night-time respiration and total photosynthesis during the previous day when rates of respiration were normalized to a fixed temperature of 20°C, removing the effects of temperature from this relationship. Measurements of specific leaf area, nitrogen and chlorophyll concentration and calculations of the maximum rate of carboxylation activity, Vcmax, were not significantly different between upper and upper shaded leaves 5 days after the shading treatment was started. There were small, but significant decreases in the rate of apparent maximum electron transport at saturating irradiance, Jmax ( P>0.05), and light use efficiency, ℇ ( P<0.05), for upper shaded leaves compared with those for upper leaves. This suggests that the duration of shading in the experiment was sufficient to initiate changes in the electron transport, but not the carboxylation processes of photosynthesis. Support for the hypothesis was provided from analysis of soluble sugar and starch concentrations in leaves. Respiration rates in the upper shaded leaves were lower than those expected from a relationship between respiration and soluble sugar concentration for fully exposed upper and lower leaves. However, there was no similar difference in starch concentrations. This suggests that shading for the duration of several days did not affect sugar concentrations but reduced starch concentrations in leaves, leading to lower rates of respiration at night. A model was used to quantify the significance of the findings on estimated canopy CO2 exchange for the full growing season. Introducing respiration as a function of total photosynthesis on the previous day resulted in a decrease in growing season night-time respiration by 23% compared with the value when respiration was held constant. This highlights the need for a process-based approach linking respiration to photosynthesis when modelling long-term carbon exchange in forest ecosystems. [ABSTRACT FROM AUTHOR] more...

Published

2004

42. Nocturnal warming increases photosynthesis at elevated CO2 partial pressure in Populus deltoides.

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Author

Turnbull, Matthew H., Tissue, David T., Murthy, Ramesh, Xianzhong Wang, Sparrow, Ashley D., and Griffin, Kevin L.

Subjects

COTTONWOOD, PHOTOSYNTHESIS, CARBON dioxide, LEAVES, CARBOHYDRATES, GLOBAL warming, RESPIRATION in plants

Abstract

© New Phytologist (2004) doi: 10.1111/j.1469-8137.2004.00994.x [ABSTRACT FROM AUTHOR]

Published

2004

43. CO[sub2] ENRICHMENT REDUCES THE ENERGETIC COST OF BIOMASS CONSTRUCTION IN AN INVASIVE DESERT GRASS.

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Author

Nagel, Jennifer M., Huxman, Travis E., Griffin, Kevin L., and Smith, Stanley D.

Subjects

CARBON dioxide & the environment, ATMOSPHERIC carbon dioxide, BROMEGRASSES, ECOLOGY, BIOMASS

Abstract

To examine how global change could influence species invasions, we compared the responses of energetic processes and growth of invasive and native grass species to atmospheric CO2ipt> enrichment in an intact Mojave Desert ecosystem. Combined with its modest influence on photosynthetic activity, elevated atmospheric CO2 was associated with a significant reduction in the energetic cost of aboveground biomass construction in invasive Bromus madritensis spp. rubens (red brome) without a concurrent cost reduction in native Vulpia octoflora (six-weeks fescue). Consequently, the invasive grass species grew faster, grew bigger, and produced more seeds with atmospheric CO2 enrichment than the native grass species. As a physiological mechanism of invasive species success driven by CO2 enrichment, such alterations in biomass construction costs combined with increased photosynthetic activity could trigger a shift in the species composition of this ecosystem, and potentially that of other invaded ecosystems, toward increased invasive species dominance. [ABSTRACT FROM AUTHOR] more...

Published

2004

44. The contribution of bryophytes to the carbon exchange for a temperate rainforest.

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Author

DeLucia, Evan H., Turnbull, Matthew H., Walcroft, Adrian S., Griffin, Kevin L., Tissue, David T., Glenny, David, McSeveny, Tony M., and Whitehead, David

Subjects

BRYOPHYTES, CARBON cycle

Abstract

Abstract Bryophytes blanket the floor of temperate rainforests in New Zealand and may influence a number of important ecosystem processes, including carbon cycling. Their contribution to forest floor carbon exchange was determined in a mature, undisturbed podocarp-broadleaved forest in New Zealand, dominated by 100–400-year-old rimu (Dacrydium cupressimum ) trees. Eight species of mosses and 13 species of liverworts contributed to the 62% cover of the diverse forest floor community. The bryophyte community developed a relatively thin (depth <30 mm), but dense, canopy that experienced elevated CO2 partial pressures (median 46.6 Pa immediately below the bryophyte canopy) relative to the surrounding air (median 37.6 Pa at 100 mm above the canopy). Light-saturated rates of net CO2 exchange from 14 microcosms collected from the forest floor were highly variable; the maximum rate of net uptake (bryophyte photosynthesis – whole-plant respiration) per unit ground area at saturating irradiance was 1.9 μmol m-2 s-1 and in one microcosm, the net rate of CO2 exchange was negative (respiration). CO2 exchange for all microcosms was strongly dependent on water content. The average water content in the microcosms ranged from 1375% when fully saturated to 250% when air-dried. Reduction in water content across this range resulted in an average decrease of 85% in net CO2 uptake per unit ground area. The results from the microcosms were used in a model to estimate annual carbon exchange for the forest floor. This model incorporated hourly variability in average irradiance reaching the forest floor, water content of the bryophyte layer, and air and soil temperature. The annual net carbon uptake by forest floor bryophytes was 103 g m-2 , compared to annual carbon efflux from the forest floor (bryophyte and soil respiration) of -1010 g m-2 . To put this in perspective... [ABSTRACT FROM AUTHOR] more...

Published

2003

45. Sex-specific physiological and growth responses to elevated atmospheric CO2 in Silene latifolia Poiret.

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Author

WANG, XIANZHONG and GRIFFIN, KEVIN L.

Subjects

*SILENE (Genus), *ATMOSPHERIC carbon dioxide

Abstract

Abstract Dioecy is found in nearly half of the angiosperm families, but little is known about how rising atmospheric CO2 concentration will affect male and female individuals of dioecious species. We examined gender-specific physiological and growth responses of Silene latifolia Poiret, a widespread dioecious species, to a doubled atmospheric CO2 concentration in environmentally controlled growth chambers. Elevated CO2 significantly increased photosynthesis in both male and female plants and by a similar magnitude. Males and females did not differ in net photosynthetic rate, but females had significantly greater biomass production than males, regardless of CO2 concentrations. Vegetative mass increased by 39% in males and in females, whereas reproductive mass increased by 82% in males and 97% in females at elevated CO2 . As a result, proportionately more carbon was allocated to reproduction in male and female plants at elevated CO2 . Higher CO2 increased individual seed mass significantly, but had no effect on the number or mass of seeds per female plant. Our results demonstrated that rising atmospheric CO2 will alter the allocation patterns in both male and female S. latifolia Poiret plants by shifting proportionally more photosynthate to reproduction. [ABSTRACT FROM AUTHOR] more...

Published

2003

46. Canopy position affects the temperature response of leaf respiration in Populus deltoides.

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Author

Griffin, Kevin L., Turnbull, Matthew, and Murthy, Ramesh

Subjects

*COTTONWOOD, *PLANT canopies

Abstract

Summary • Leaf respiration and its temperature response were measured in 4-m-tall, 1-yr-old Populus deltoides trees to assess the effect of within-canopy distribution of respiratory physiology on total foliar C exchange of a model ecosystem at Biosphere 2. • Over the course of five nights, air temperature was varied over a 10°C range and the steady-state rate of leaf respiration was measured. These data were then modeled to calculate the temperature response of leaf and canopy respiration. • Results indicate that there is considerable within-canopy variation in both the rate of respiration and its temperature response and that these variables are most strongly related to leaf carbohydrate and leaf N. Scaling these results to the ecosystem level demonstrates the importance of quantifying the vertical distribution of respiratory physiology, particularly at lower temperatures. • Simplifying assumptions regarding the variation in respiration and its temperature response with canopy height tend to result in an underestimation of the actual C loss if the assumptions are based on lower- or mid-canopy leaf physiology, but overestimate C loss if the model assumptions are based on upper-canopy physiology. [ABSTRACT FROM AUTHOR] more...

Published

2002

47. CONSTRUCTION COST AND INVASIVE POTENTIAL: COMPARING LYTHRUM SALICARIA (LYTHRACEAE) WITH CO-OCCURRING NATIVE SPECIES ALONG POND BANKS.

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Author

Nagel, Jennifer M. and Griffin, Kevin L.

Subjects

*PURPLE loosestrife, *LYTHRUM

Abstract

Compares the construction cost and invasive potential of Lythrum salicaria plants with co-occurring native species along pond banks. Description of the leaf material; Discussion on leaf energy and resource investment; Indication of the negative correlation between species abundance and area-based leaf. more...

Published

2001

48. The onset of photosynthetic acclimation to elevated CO2 partial pressure in field-grown Pinus radiata D. Don. after 4 years.

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Author

Griffin., Kevin L., Griffin, K. L., Tissue, D. T., Turnbull, M. H., and Whitehead, D.

Subjects

*PINUS radiata, *ACCLIMATIZATION (Plants), *PHOTOSYNTHESIS

Abstract

ABSTRACT The effects of CO2 enrichment on photosynthesis and ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco) were studied in current year and 1-year-old needles of the same branch of field-grown Pinus radiata D. Don trees. All measurements were made in the fourth year of growth in large, open-top chambers continuously maintained at ambient (36 Pa) or elevated (65 Pa) CO2 partial pressures. Photosynthetic rates of the 1-year-old needles made at the growth CO2 partial pressure averaged 10·5 ± 0·5 μmol m-2 s-1 in the 36 Pa grown trees and 11·8 ± 0·4 μmol m-2 s-1 in the 65 Pa grown trees, and were not significantly different from each other. The photosynthetic capacity of 1-year-old needles was reduced by 25% from 23·0 ± 1·8 μmol m-2 s-1 in the 36 Pa CO2 grown trees to 17·3 ± 0·7 μmol m-2 s-1 in the 65 Pa grown trees. Growth in elevated CO2 also resulted in a 25% reduction in Vcmax (maximum carboxylation rate), a 23% reduction in Jmax (RuBP regeneration capacity mediated by maximum electron transport rate) and a 30% reduction in Rubisco activity and content. Total non-structural carbohydrates (TNC) as a fraction of total dry mass increased from 12·8 ± 0·4% in 1-year-old needles from the 36 Pa grown trees to 14·2 ± 0·7% in 1-year-old needles from the 65 Pa grown trees and leaf nitrogen content decreased from 1·30 ± 0·02 to 1·09 ± 0·10 g m-2. The current-year needles were not of sufficient size for gas exchange measurements, but none of the biochemical parameters measured (Rubisco, leaf chlorophyll, TNC and N), were effected by growth in elevated CO2. These results demonstrate that photosynthetic acclimation, which was not found in the first 2 years of this experiment, can develop over time in field-grown trees and may be regulated by source-sink balance, sugar feedback mechanisms and nitrogen allocation. [ABSTRACT FROM AUTHOR] more...

Published

2000

49. Growth and dry matter partitioning in loblolly and ponderosa pine seedlings in response to carbon and nitrogen availability.

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Author

Griffin, Kevin L., Winner, William E., and Strain, Boyd R.

Subjects

*PLANT growth, *LOBLOLLY pine, *PONDEROSA pine, *SEEDLINGS, *EFFECT of carbon on plants, *EFFECT of nitrogen on plants

Abstract

We grew lobolly pine (Prnus taeda L.) and ponderosa pine (Pinus ponderosa Dougal. ex Laws.) seedling in a factorial experiment with two CO2 partial pressures (35 and 70 Pa) and two nitrogen treatments (1.0 and 3.5 mM NH4+) for one growing season in a 'common garden' experiment designed to examine the extent that dry matter and nitrogen accumulation and partitioning are environmentally controlled. Ponderosa pine seedlings grown in 35 Pa CO2 and 3.5 mM NH4+ showed symptoms of nitrogen toxicity, characterized by greatly reduced growth, and moderately reduced total plant N. With the exception of this treatment combination, there were no significant differences between species in total plant dry matter or total plant nitrogen, suggesting that responses go growth to environmental conditions were stronger than heritable responses. There were however large differences in dry matter and N partitioning between the two species. Increases in leaf mass were largest in loblolly pine, whilst ponderosa pine tended to have higher root: shoot (R:S) ratios. R:S ratio of loblolly increased in response to C availability and decreased in response to N availability, whilst R:S ratio of ponderosa pine was much less responsive resource availability. Total plant N varied with N supply, and N partitioning was related to plant growth and carbon partitioning. Carbon and N were interactive, such that an increase in the accumulation of either resource was alway6s accompanied by an increase in the other. Over several-seasons the different patterns of resource acquisition and biomass allocation that we observed in a uniform environment could potentially result in different growth rates at most resource levels. In the first season, contrary to out expectations, heritable differences in growth rate did not appear. [ABSTRACT FROM AUTHOR] more...

Published

1995

50. Altered night-time CO[sub 2] concentration affects the growth, physiology and biochemistry of soybean.

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Author

GRIFFIN, SIMS, SEEMANN, and Griffin, Kevin L.

Subjects

SOYBEAN, PHOTOSYNTHESIS, PLANT physiology

Abstract

Soybean plants (Glycine max (L.) Merr. c.v. Williams) were grown in CO2 controlled, natural-light growth chambers under one of four atmospheric CO2 concentrations ([CO2]): (1) 250 μmol mol–1 24 h d–1 [250/250]; (2) 1000 μmol mol–1 24 h d–1 [1000/1000]; (3) 250 μmol mol–1 during daylight hours and 1000 μmol mol–1 during night-time hours [250/1000] or (4) 1000 μmol mol–1 during daylight hours and 250 μmol mol–1 during night-time hours [1000/250]. During the vegetative growth phase few physiological differences were observed between plants exposed to a constant 24 h [CO2] (250/250 and 1000/1000) and those that were switched to a higher or lower [CO2] at night (250/1000 and 1000/250), suggesting that the primary physiological responses of plants to growth in elevated [CO2] is apparently a response to daytime [CO2] only. However, by the end of the reproductive growth phase, major differences were observed. Plants grown in the 1000/250 regime, when compared with those in the 1000/1000 regime, had significantly more leaf area and leaf mass, 27% more total plant dry mass, but only 18% of the fruit mass. After 12 weeks of growth these plants also had 19% higher respiration rates and 32% lower photosynthetic rates than the 1000/1000 plants. As a result the ratio of carbon gain to carbon loss was reduced significantly in the plants exposed to the reduced night-time [CO2]. Plants grown in the opposite switching environment, 250/1000 versus 250/250, showed no major differences in biomass accumulation or allocation with the exception of a significant increase in the amount of leaf mass per unit area. Physiologically, those plants exposed to elevated night-time [CO2] had 21% lower respiration rates, 14% lower... [ABSTRACT FROM AUTHOR] more...

Published

1999