Flooding constraints on tree (Taxodium distichum) and herb growth responses to elevated CO2

Megonigal, J. Patrick; Vann, Cheryl D.; Wolf, Amelia A.

doi:10.1672/17

Cited by 15 publications

(10 citation statements)

References 44 publications

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“…Ethylene synthesis is increased in the seeds of Helianthus annuus in higher CO 2 levels (Corbineau et al, 1990). Our findings showed some effect on seed germination, but generally support the broader pattern that CO 2 primarily influences seedling growth, rather than germination, similar to findings of other freshwater wetlands studies (e.g., Megonigal et al, 2005).…”

Section: Discussionsupporting

confidence: 91%

“…In other studies, C 4 species did not increase growth in enhanced CO 2 in any water regime or salinity level (Rozema et al, 1991;Lenssen et al, 1993). In elevated CO 2 , the seedlings of Taxodium distichum (C 3 ), a freshwater swamp species, did not have a higher biomass in flooded conditions, but seedlings of Orontium aquaticum (C 3 ) had higher biomass when exposed to elevated CO 2 in both flooded and unflooded conditions (Megonigal et al, 2005).…”

Section: Introductionmentioning

confidence: 74%

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Can elevated CO2 modify regeneration from seed banks of floating freshwater marshes subjected to rising sea-level?

Middleton

McKee

2011

Hydrobiologia

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Higher atmospheric concentrations of CO 2 can offset the negative effects of flooding or salinity on plant species, but previous studies have focused on mature, rather than regenerating vegetation. This study examined how interacting environments of CO 2 , water regime, and salinity affect seed germination and seedling biomass of floating freshwater marshes in the Mississippi River Delta, which are dominated by C 3 grasses, sedges, and forbs. Germination density and seedling growth of the dominant species depended on multifactor interactions of CO 2 (385 and 720 ll l -1 ) with flooding (drained, ?8-cm depth, ?8-cm depthgradual) and salinity (0, 6% seawater) levels. Of the three factors tested, salinity was the most important determinant of seedling response patterns. Species richness (total = 19) was insensitive to CO 2 . Our findings suggest that for freshwater marsh communities, seedling response to CO 2 is species-specific and secondary to salinity and flooding effects. Elevated CO 2 did not ameliorate flooding or salinity stress. Consequently, climate-related changes in sea level or human-caused alterations in hydrology may override atmospheric CO 2 concentrations in driving shifts in this plant community. The results of this study suggest caution in making extrapolations from species-specific responses to community-level predictions without detailed attention to the nuances of multifactor responses.

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Section: Discussionsupporting

confidence: 91%

Section: Introductionmentioning

confidence: 74%

Can elevated CO2 modify regeneration from seed banks of floating freshwater marshes subjected to rising sea-level?

Middleton

McKee

2011

Hydrobiologia

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“…Data were analyzed for statistical differences between the main effects (planting and CO 2 treatment) by two-way ANOVA using the SAS generalized linear model (GLM) procedure (e.g. Megonigal et al, 2005). Data with heterogeneous variance were log transformed and outliers were removed using Grubbs' outlier test.…”

Section: Discussionmentioning

confidence: 99%

An oxygen‐mediated positive feedback between elevated carbon dioxide and soil organic matter decomposition in a simulated anaerobic wetland

Wolf

Drake

Erickson

et al. 2007

Global Change Biology

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We examined the effects of elevated atmospheric CO 2 on soil carbon decomposition in an experimental anaerobic wetland system. Pots containing either bare C 4 -derived soil or the C 3 sedge Scirpus olneyi planted in C 4 -derived soil were incubated in greenhouse chambers at either ambient or twice-ambient atmospheric CO 2 . We measured CO 2 flux from each pot, quantified soil organic matter (SOM) mineralization using d 13 C, and determined root and shoot biomass. SOM mineralization increased in response to elevated CO 2 by 83-218% (Po0.0001). In addition, soil redox potential was significantly and positively correlated with root biomass (P 5 0.003). Our results (1) show that there is a positive feedback between elevated atmospheric CO 2 concentrations and wetland SOM decomposition and (2) suggest that this process is mediated by the release of oxygen from the roots of wetland plants. Because this feedback may occur in any wetland system, including peatlands, these results suggest a limitation on the size of the carbon sink presented by anaerobic wetland soils in a future elevated-CO 2 atmosphere.

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“…All of the tests were conducted between 9:00 am-11:00 am at a temperature of 25°C, with 400 µmol L −1 CO 2 and 1,000 µmol photons m −2 s −1 Megonigal 2002, 2003). Leaf area was determined according to Megonigal et al (2005), by tracing the portion of the leaf enclosed by the Li-Cor LI-6400 cuvette onto paper, then passing it through a Li-Cor 3100 leaf area meter. The paper area was divided by two to correct for spaces between the individual needles on the leaf.…”

Section: Measurement Of Physiological Responsesmentioning

confidence: 99%

Comparative studies on physiological and biochemical adaptation of Taxodium distichum and Taxodium ascendens seedlings to different soil water regimes

Zhong

Geng

et al. 2009

Plant Soil

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Flooding constraints on tree (Taxodium distichum) and herb growth responses to elevated CO2

Cited by 15 publications

References 44 publications

Can elevated CO2 modify regeneration from seed banks of floating freshwater marshes subjected to rising sea-level?

Can elevated CO2 modify regeneration from seed banks of floating freshwater marshes subjected to rising sea-level?

An oxygen‐mediated positive feedback between elevated carbon dioxide and soil organic matter decomposition in a simulated anaerobic wetland

Comparative studies on physiological and biochemical adaptation of Taxodium distichum and Taxodium ascendens seedlings to different soil water regimes

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