Habitat specialization and the role of trait lability in structuring diverse willow (genus<i>Salix</i>) communities

Savage, Jessica; Cavender‐Bares, Jeannine

doi:10.1890/11-0406.1

Cited by 74 publications

(93 citation statements)

References 78 publications

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“…Seedling physiology is critical to plant establishment and has important implications for species' distributions in their natural environments (Kitajima, 2002;Savage and Cavender-Bares, 2012) and their success in agriculture (Pujol et al, 2005). In this study, we demonstrate that phloem transport responds dynamically to changes in sink and source development and that transport velocity within a single plant can be heterogeneous.…”

Section: Resultsmentioning

confidence: 73%

“…Seedlings present a relatively simple source-sink network for studying patterns of carbon allocation, and by examining their development over time, it is possible to gain insights into how the structure of the phloem network influences its transport. Early stages of plant growth, including the transition to autotrophy and the development of true leaves, are also critical to plant survival and establishment in nature (Lovell and Moore, 1971;Kitajima, 2002;Savage and Cavender-Bares, 2012). Although several methods exist for measuring phloem transport velocity (Minchin and Thorpe, 2003;Windt et al, 2006;Froelich et al, 2011), the spatial and time resolution required for this study necessitated the use of a new dye-tracing technique .…”

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confidence: 99%

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Phloem Transport Velocity Varies over Time and among Vascular Bundles during Early Cucumber Seedling Development

2013

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We use a novel dye-tracing technique to measure in vivo phloem transport velocity in cucumber (Cucumis sativus) plants during early seedling development. We focus on seedlings because of their importance in plant establishment and because they provide a simple source and sink model of phloem transport. The dye-tracing method uses a photodiode to track the movement of a bleach front of fluorescent dye traveling in the phloem from the cotyledons (source) to the roots (sink). During early seedling development, phloem transport velocity in this direction can change 2-fold depending on vascular connectivity and the number of actively growing sinks. Prior to leaf expansion, vascular bundles attached to the first developing leaf demonstrate a decline in basipetal phloem transport that can be alleviated by the leaf's removal. At this stage, seedlings appear carbon limited and phloem transport velocity is correlated with cotyledon area, a pattern that is apparent both during cotyledon expansion and after source area manipulation. When the first leaf transitions to a carbon source, seedling growth rate increases and basipetal phloem transport velocity becomes more stable. Because bundles appear to operate autonomously, transport velocity can differ among vascular bundles. Together, these results demonstrate the dynamic and heterogeneous nature of phloem transport and underline the need for a better understanding of how changes in phloem physiology impact growth and allocation at this critical stage of development.

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Section: Resultsmentioning

confidence: 73%

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confidence: 99%

Phloem Transport Velocity Varies over Time and among Vascular Bundles during Early Cucumber Seedling Development

2013

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“…Collection populations were selected using data from previous field studies of natural populations in which water availability in the species' natural habitats was characterized (Savage and Cavender-Bares 2012). We collected from populations at Cedar Creek, as well as nearby Carlos Avery State Wildlife Management Area (Forest Lake, MN, 45°19′N, 93°05′W), that were located in habitats representative of the species' water regime affinities.…”

Section: Methodsmentioning

confidence: 99%

“…Initial leaf litter chemistry of the ground subsample was analyzed for: concentrations of carbon (C) and N (COSTECH ESC 4010 Elemental Analyzer, Valencia, CA, USA), phosphorus (P) by digestion with 10 N sulfuric acid after ashing samples at 300 °C for 30 min followed by 500 °C for 2 h (DeMott et al 1998), C fractions (soluble cell contents, SCC; cellulose, CELL; hemicellulose plus bound proteins, HBP; and lignin plus other recalcitrant compounds, LR; Ankom Fiber Analyzer, Ankom Technology, Macedon, NY, USA), and condensed Table 1 Native habitat affinity, growth form, and initial leaf litter chemistry of the 12 species (willow family, Salicaceae) studied Species are ordered based on their distribution across a water availability gradient from wet to dry habitats. Growth form and habitat affinity classifications are from field studies of natural populations in Savage and Cavender-Bares (2012). All values are expressed as mg g −1 leaf litter and n = 3 (standard error in parentheses) SCC leaf litter initial soluble cell contents, HBP leaf litter initial hemicellulose plus bound proteins, CELL leaf litter initial cellulose, LR leaf litter initial lignin plus recalcitrants, N leaf litter initial nitrogen, P leaf litter initial phosphorus, CT leaf litter initial condensed tannins tannins (CT) by acid butanol assay with quebrancho extract standard (Porter et al 1986).…”

Section: Methodsmentioning

confidence: 99%

“…We used green leaf maximum photosynthetic capacity (A max ; μmol CO 2 m −2 s −1 ), green leaf specific leaf area (SLA; cm g −1 ), green leaf turgor loss point (TLP, the leaf water potential at which a species wilts; MPa), and plant wood density (WD; g cm −3 ) measurements from field studies (Savage 2010;Savage and Cavender-Bares 2012). TLP and WD were selected in particular because previous research showed those traits to be significant indictors of drought tolerance (Savage and Cavender-Bares 2012). Furthermore, we used total plant relative growth rate (RGR; g g −1 day −1 ) measurements from a greenhouse study where the species were grown under common conditions where water was non-limiting (Savage and Cavender-Bares 2012).…”

Section: Methodsmentioning

confidence: 99%

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Contrasting effects of plant species traits and moisture on the decomposition of multiple litter fractions

et al. 2015

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Environmental variation in moisture directly influences plant litter decomposition through effects on microbial activity, and indirectly via plant species traits. Whether the effects of moisture and plant species traits are mutually reinforcing or counteracting during decomposition are unknown. To disentangle the effects of moisture from the effects of species traits that vary with moisture, we decomposed leaf litter from 12 plant species in the willow family (Salicaceae) with different native habitat moisture preferences in paired mesic and wetland plots. We fit litter mass loss data to an exponential decomposition model and estimated the decay rate of the rapidly cycling litter fraction and size of the remaining fraction that decays at a rate approaching zero. Litter traits that covaried with moisture in the species' native habitat significantly influenced the decomposition rate of the rapidly cycling litter fraction, but moisture in the decomposition environment did not. In contrast, for the slowly cycling litter fraction, litter traits that did not covary with moisture in the species' native habitat and moisture in the decomposition environment were significant. Overall, the effects of moisture and plant species traits on litter decomposition were somewhat reinforcing along a hydrologic gradient that spanned mesic upland to wetland (but not permanently surface-saturated) plots. In this system, plant trait and moisture effects may lead to greater in situ decomposition rates of wetland species compared to upland species; however, plant traits that do not covary with moisture will also influence decomposition of the slowest cycling litter fraction.

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The role of diversification in community assembly of the oaks (QuercusL.) across the continental U.S.

Cavender‐Bares

Kothari

Meireles

et al. 2018

American J of Botany

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Our results support the hypotheses that (1) interspecific interactions were important in parallel adaptive radiation of the genus into a range of habitats across the continent and (2) that the diversification process is a critical driver of community assembly. Functional convergence of complementary species from distinct clades adapted to the same local habitats is a likely mechanism that allows distantly related species to coexist. Our findings contribute to an explanation of the long-term maintenance of high oak diversity and the dominance of the oak genus in North America.

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Habitat specialization and the role of trait lability in structuring diverse willow (genusSalix) communities

Cited by 74 publications

References 78 publications

Phloem Transport Velocity Varies over Time and among Vascular Bundles during Early Cucumber Seedling Development

Phloem Transport Velocity Varies over Time and among Vascular Bundles during Early Cucumber Seedling Development

Contrasting effects of plant species traits and moisture on the decomposition of multiple litter fractions

The role of diversification in community assembly of the oaks (QuercusL.) across the continental U.S.

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