Stipe Anatomy, Water Potentials, and Xylem Conductances in Seven Species of Ferns (Filicopsida)

Woodhouse, Robert M.; Nobel, Park S.

doi:10.1002/j.1537-2197.1982.tb13242.x

Cited by 40 publications

(6 citation statements)

References 20 publications

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“…This is likely explained by the well‐ known relationship between topography and soil moisture (Huggett and Cheeseman 2002, Petter et al 2015), which can influence plant communities (Dearborn and Danby 2017, Muscarella et al 2020). Further, resprouting ferns are typically shade‐tolerant and occupy mesic environments with high soil moisture due to their poor control of water conduction and loss (Woodhouse and Nobel 1982, Hunt et al 2002, Page 2002). Therefore, these species can be sensitive to water stress (Hunt et al 2002, Volkova et al 2010, Riaño and Briones 2013) and the harsh solar radiation associated with north‐facing slopes (Petter et al 2015).…”

Section: Discussionmentioning

confidence: 99%

Prior disturbance legacy effects on plant recovery post‐high‐severity wildfire

2021

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Large, high-severity wildfires are an important component of disturbance regimes around the world and can influence the structure and function of forest ecosystems. Climatic changes and anthropogenic disturbances have altered global disturbance patterns and increased the frequency of high-severity wildfires worldwide. While the recovery of plant communities at different successional stages after fire is well known, the influence of prior disturbances and stand age is poorly understood. Despite this, high-intensity wildfires can produce long-lasting legacy effects, which can influence the resistance and resilience of ecosystems. Here, we quantified the influence of prior stand age and disturbance history on the recovery of plant communities in the Mountain Ash and Alpine Ash forests of south-eastern Australia after highseverity wildfire. Specifically, controlling for stand age, we compared the abundance (percent cover) of different plant life forms and reproductive strategies in forests that were, at the time of high-severity wildfire in 2009, "young" (28-35 yr old and previously logged), "mixed" age (26, 70-83, >150 yr old), "mature" (70-83 yr old), and "old-growth" (>150 yr old). We uncovered evidence that the legacy of prior disturbance and stand age at the time of high-severity wildfire can influence the recovery of plant communities in early successional forests. Specifically, we found that "young" forests burnt in 2009 had a higher abundance of ruderal and graminoid species, but had a lower abundance of persistent, onsite seeders, including Acacia and eucalypt species, relative to "old-growth" forests burnt in 2009. "Mature" aged forests burnt in 2009 also had a lower abundance of Acacia, eucalypt, and shrub species, relative to "old-growth forests" burnt in 2009. Our findings provide evidence of advanced recovery in forests that were older when burnt by high-severity wildfire, relative to younger forests burnt by the same wildfire. Further, we also demonstrate the influence of different environmental conditions on plant communities. In a period of rapid, global, environmental change, our study provides insights into the recovery of plant communities postwildfire with implications for forest management. Further, our findings suggest that predicted increases in the frequency of high-severity wildfires may have consequences for forest regeneration.

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Section: Discussionmentioning

confidence: 99%

Prior disturbance legacy effects on plant recovery post‐high‐severity wildfire

2021

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“…For example, passive stomatal control has been reported several times in ferns (Brodribb & McAdam, 2011; Cardoso, Randall, & McAdam, 2019; McAdam & Brodribb, 2012; Ruszala et al, 2011), suggesting that they possess a diminished capacity to optimize water‐use efficiency (Brodribb, McAdam, Jordan, & Feild, 2009). A suite of studies also reveals how anatomical traits directly influence fern water relations and gas exchange in a manner that is functionally different from seed plants (Baer, Wheeler, & Pittermann, 2016; Brodersen, Roark, & Pittermann, 2012; Brodribb, Holbrook, Zwieniecki, & Palma, 2005; Pittermann, Limm, Rico, & Christman, 2011; Woodhouse & Nobel, 1982; Zhang, Chen, Li, & Cao, 2009). Taken together, the weight of the evidence suggests that fern ecophysiology is inherently constrained, leaving means by which a third of all tropical fern species adapted and diversified into canopy habitats an open question (Schuettpelz & Pryer, 2009; Zotz, 2013a).…”

Section: Introductionmentioning

confidence: 99%

Leaf water relations in epiphytic ferns are driven by drought avoidance rather than tolerance mechanisms

Campany

Pittermann

Baer

et al. 2021

Plant Cell & Environment

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Opportunistic diversification has allowed ferns to radiate into epiphytic niches in angiosperm dominated landscapes. However, our understanding of how ecophysiological function allowed establishment in the canopy and the potential transitionary role of the hemi-epiphytic life form remain unclear. Here, we surveyed 39 fern species in Costa Rican tropical forests to explore epiphytic trait divergence in a phylogenetic context. We examined leaf responses to water deficits in terrestrial, hemi-epiphytic and epiphytic ferns and related these findings to functional traits that regulate leaf water status. Epiphytic ferns had reduced xylem area (−63%), shorter stipe lengths (−56%), thicker laminae (+41%) and reduced stomatal density (−46%) compared to terrestrial ferns. Epiphytic ferns exhibited similar turgor loss points, higher osmotic potential at saturation and lower tissue capacitance after turgor loss than terrestrial ferns. Overall, hemi-epiphytic ferns exhibited traits that share characteristics of both terrestrial and epiphytic species. Our findings clearly demonstrate the prevalence of water conservatism in both epiphytic and hemi-epiphytic ferns, via selection for anatomical and structural traits that avoid leaf water stress. Even with likely evolutionarily constrained physiological function, adaptations for drought avoidance have allowed epiphytic ferns to successfully endure the stresses of the canopy habitat.

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“…Studies have indicated that the hydraulic conductivity of fern stipes range from the low end of angiosperms to several orders of magnitude lower (Woodhouse & Nobel, 1982; Veres, 1990), resulting in large pressure gradients during transpiration (Nobel, 1978). These observations have been used to explain the low photosynthetic and growth rates typically exhibited by pteridophytes, suggesting inefficient delivery of water to the mesophyll as a limiting factor to photosynthesis (Woodhouse & Nobel, 1982). By contrast, a recent study demonstrated high photosynthetic rates (implying high hydraulic conductivity) and low stomatal sensitivity to changes in vapour pressure deficit (VPD) (implying the opposite) in two vessel bearing fern species (Franks & Farquhar, 1999).…”

Section: Introductionmentioning

confidence: 99%

Stomatal protection against hydraulic failure: a comparison of coexisting ferns and angiosperms

2004

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Summary• Hydraulic characteristics of pteridophyte (fern and Selaginella ) foliage were investigated to determine whether the processes of water conduction and water loss are coordinated in these early vascular plants similarly to angiosperms.• Eight species of pteridophytes and associated woody angiosperms were examined from the sun and shade in a seasonally dry tropical forest.• Maximum leaf hydraulic conductivity ( K leaf ) in the four pteridophytes was within the range of the sampled shade angiosperms but much lower than that of the sundwelling angiosperms. Hydraulic conductivity of both angiosperm and pteridophyte leaves showed a similar response to desiccation, with K leaf becoming rapidly depressed once leaf water potential fell below a threshold. Stomatal closure in angiosperms corresponded closely with the water potential responsible for 50% loss of K leaf while pteridophytes were found to close stomata before K leaf depression.• The contrasting behaviour of stomata in this sample of pteridophytes suggest that this may be an intrinsic difference between pteridophytes and angiosperms, with lower safety margins in angiosperms possibly enhancing both optimization of gas exchange and xylem investment.

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Stipe Anatomy, Water Potentials, and Xylem Conductances in Seven Species of Ferns (Filicopsida)

Cited by 40 publications

References 20 publications

Prior disturbance legacy effects on plant recovery post‐high‐severity wildfire

Prior disturbance legacy effects on plant recovery post‐high‐severity wildfire

Leaf water relations in epiphytic ferns are driven by drought avoidance rather than tolerance mechanisms

Stomatal protection against hydraulic failure: a comparison of coexisting ferns and angiosperms

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