Protein storage and root:shoot reallocation provide tolerance to damage in a hybrid willow system

Hochwender, Cris G.; Dong, Hao; Czesak, Mary Ellen; Fritz, Robert S.; Smyth, Rebecca R.; Kaufman, Arlen D.; Warren, Brandi; Neuman, A

doi:10.1007/s00442-011-2176-9

Cited by 19 publications

(21 citation statements)

References 84 publications

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“…Leaf damage can also increase the photosynthetic efficiency of plant tissue (Thomson et al, 2003;Stevens et al, 2008) suggesting that the loss of photosynthetic tissue in damaged portions of the plant may be additively beneficial to the undamaged portions as these plant parts will benefit from increases in both photosynthetic capacity and light radiation. Further, storage of proteins and carbohydrates may also function as tolerance mechanisms (Myers and Kitajima, 2007;Babst et al, 2008;Hochwender et al, 2011). For example, damaging insects may induce transport responses of carbon within woody plants (Babst et al, 2008) which potentially could induce rapid growth in remaining plant tissue.…”

Section: Morphological Growth Responsesmentioning

confidence: 99%

“…Mechanisms mediating tolerance may be many; e.g. patterns in resource allocation (Canham et al, 1999;Eyles et al, 2009) and storage (Myers and Kitajima, 2007;Babst et al, 2008;Hochwender et al, 2011), photosynthetic activity (Thomson et al, 2003), phenology and plant architecture (Fornoni, 2011) and the mechanism through which tolerance is expressed may also vary with the type of damage received (the identity of the damaging herbivore). For example, removal of photosynthetic tissue may be compensated through increased photosynthetic ability of remaining tissue whereas when subjected to loss of woody biomass the plant may depend more on a resource storage mechanism (Marquis, 1996).…”

Section: Introductionmentioning

confidence: 99%

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Tolerance and growth responses of populus hybrids and their genetically modified varieties to simulated leaf damage and harvest

Axelsson

Hjältén

2012

Forest Ecology and Management

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Section: Morphological Growth Responsesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tolerance and growth responses of populus hybrids and their genetically modified varieties to simulated leaf damage and harvest

Axelsson

Hjältén

2012

Forest Ecology and Management

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“…This may also indicate that both growth and reserves suffer from resource limitation. In parallel, earlier studies similarly reported that defoliation can influence the mobilization and storage of NSC between sinks and sources depending on resource availability (Babst et al, 2008; Schwachtje et al, 2005; Hochwender et al, 2012). However, our results contradict the results of Rivera-Solís et al (2012) who found higher carbon accumulation in roots of defoliated Ruellia nudiflora –a perennial herb–relative to non-defoliated plants.…”

Section: Discussionmentioning

confidence: 54%

“…We interpreted the large differences in root biomass between control and defoliated seedlings in a resource limited environment as a result of two main co-occurring processes: (a) after defoliation, translocation of photoassimilates from foliage to roots is severely reduced, which in turn reduces root growth, and (b) as new stem buds are activated to produce new leaves, roots translocate reserves to promote active growth in these carbohydrate sinks, which further compromises root growth. These predictions are based on the assumption that defoliation alters resource allocation in woody plants (Babst et al, 2008; Stevens, Kruger & Lindroth, 2008; Najar et al, 2014) and resources are utilized for growth of remaining plant tissues, particularly leaves (Landhäusser & Lieffers, 2002; Babst et al, 2008; Hochwender et al, 2012). Furthermore, substantial allocation of resources to roots may not be advantageous to early successional tree species–like aspen, because increasing above ground biomass, such as leaves and stems, may improve aspen’s competitive ability to capture lights.…”

Section: Discussionmentioning

confidence: 99%

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Resource availability and repeated defoliation mediate compensatory growth in trembling aspen (Populus tremuloides) seedlings

Erbilgin

Gálvez

Zhang

et al. 2014

PeerJ

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Plant ecologists have debated the mechanisms used by plants to cope with the impact of herbivore damage. While plant resistance mechanisms have received much attention, plant compensatory growth as a type of plant tolerance mechanisms has been less studied. We conducted a greenhouse experiment to evaluate compensatory growth for trembling aspen (Populus tremuloides) seedlings under varying intensities and frequencies of simulated defoliation, with or without nutrient enriched media. For the purpose of this study, changes in biomass production and non-structural carbohydrate concentrations (NSC) of roots and leaves were considered compensatory responses. All defoliated seedlings showed biomass accumulation under low defoliation intensity and frequency, regardless of resource availability; however, as defoliation intensity and frequency increased, compensatory growth of seedlings was altered depending on resource availability. Seedlings in a resource-rich environment showed complete compensation, in contrast responses ranged from undercompensation to complete compensation in a resource-limited environment. Furthermore, at the highest defoliation intensity and frequency, NSC concentrations in leaves and roots were similar between defoliated and non-defoliated seedlings in a resource-rich environment; in contrast, defoliated seedlings with limited resources sustained the most biomass loss, had lower amounts of stored NSC. Using these results, we developed a new predictive framework incorporating the interactions between frequency and intensity of defoliation and resource availability as modulators of plant compensatory responses.

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Solidago gigantea plants from nonnative ranges compensate more in response to damage than plants from the native range

Liao

Gurgel

Pál

et al. 2016

Ecology

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Resistance and tolerance are two ways that plants cope with herbivory. Tolerance, the ability of a plant to regrow or reproduce after being consumed, has been studied less than resistance, but this trait varies widely among species and has considerable potential to affect the ecology of plant species. One particular aspect of tolerance, compensatory responses, can evolve rapidly in plant species; providing insight into interactions between consumers and plants. However, compensation by invasive species has rarely been explored. We compared compensatory responses to the effects of simulated herbivory expressed by plants from seven Solidago gigantea populations from the native North American range to that expressed by plants from nine populations from the nonnative European range. Populations were also collected along elevational gradients to compare ecotypic variation within and between ranges. Solidago plants from the nonnative range of Europe were more tolerant to herbivory than plants from the native range of North America. Furthermore, plants from European populations increased in total biomass and growth rate with elevation, but decreased in compensatory response. There were no relationships between elevation and growth or compensation for North American populations. Our results suggest that Solidago gigantea may have evolved to better compensate for herbivory damage in Europe, perhaps in response to a shift to greater proportion of attack from generalists. Our results also suggest a possible trade-off between rapid growth and compensation to damage in European populations but not in North American populations.

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Protein storage and root:shoot reallocation provide tolerance to damage in a hybrid willow system

Cited by 19 publications

References 84 publications

Tolerance and growth responses of populus hybrids and their genetically modified varieties to simulated leaf damage and harvest

Tolerance and growth responses of populus hybrids and their genetically modified varieties to simulated leaf damage and harvest

Resource availability and repeated defoliation mediate compensatory growth in trembling aspen (Populus tremuloides) seedlings

Solidago gigantea plants from nonnative ranges compensate more in response to damage than plants from the native range

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