Your search keyword '"Lindroth RL"' showing total 106 results

1. Herbivory in global climate change research: direct effects of rising temperature on insect herbivores

Author

Bale, Js, Masters, Gj, Hodkinson, Id, Awmack, C., Bezemer, Tm, Brown, Vk, Butterfield, J., Buse, A., Coulson, Jc, Farrar, J., Good, Jeg, Harrington, R., Hartley, S., Jones, Th, Lindroth, Rl, Press, Mc, Symrnioudis, I., Allan Watt, Whittaker, Jb, and Multitrophic Interactions (MTI)

Subjects

Ecology, biodiversity conservation, Environmental Sciences

Abstract

This review examines the direct effects of climate change on insect herbivores. Temperature is identified as the dominant abiotic factor directly affecting herbivorous insects. There is little evidence of any direct effects Of CO2 or UVB. Direct impacts of precipitation have been largely neglected in current research on climate change. Temperature directly affects development, survival, range and abundance. Species with a large geographical range will tend to be less affected. The main effect of temperature in temperate regions is to influence winter survival; at more northerly latitudes, higher temperatures extend the summer season, increasing the available thermal budget for growth and reproduction. Photoperiod is the dominant cue for the seasonal synchrony of temperate insects, but their thermal requirements may differ at different times of year. Interactions between photoperiod and temperature determine phenology; the two factors do not necessarily operate in tandem. Insect herbivores show a number of distinct life-history strategies to exploit plants with different growth forms and strategies, which will be differentially affected by climate warming. There are still many challenges facing biologists in predicting and monitoring the impacts of climate change. Future research needs to consider insect herbivore phenotypic and genotypic flexibility, their responses to global change parameters operating in concert, and awareness that some patterns may only become apparent in the longer term. [KEYWORDS: global warming; insect-plant interactions; multitrophic interactions; phenology]

2. Plant size, latitude, and phylogeny explain within-population variability in herbivory

Author

Robinson, ML, Hahn, PG, Inouye, BD, Underwood, N, Whitehead, SR, Abbott, KC, Bruna, EM, Cacho, NI, Dyer, LA, Abdala-Roberts, L, Allen, WJ, Andrade, JF, Angulo, DF, Anjos, D, Anstett, DN, Bagchi, R, Bagchi, S, Barbosa, M, Barrett, S, Baskett, CA, Ben-Simchon, E, Bloodworth, KJ, Bronstein, JL, Buckley, YM, Burghardt, KT, Bustos-Segura, C, Calixto, ES, Carvalho, RL, Castagneyrol, B, Chiuffo, MC, Cinolu, D, Cinto Mejía, E, Cock, MC, Cogni, R, Cope, OL, Cornelissen, T, Cortez, DR, Crowder, DW, Dallstream, C, Dáttilo, W, Davis, JK, Dimarco, RD, Dole, HE, Egbon, IN, Eisenring, M, Ejomah, A, Elderd, BD, Endara, MJ, Eubanks, MD, Everingham, SE, Farah, KN, Farias, RP, Fernandes, AP, Fernandes, GW, Ferrante, M, Finn, A, Florjancic, GA, Forister, ML, Fox, QN, Frago, E, França, FM, Getman-Pickering, AS, Getman-Pickering, Z, Gianoli, E, Gooden, B, Gossner, MM, Greig, KA, Gripenberg, S, Groenteman, R, Grof-Tisza, P, Haack, N, Hahn, L, Haq, SM, Helms, AM, Hennecke, J, Hermann, SL, Holeski, LM, Holm, S, Hutchinson, MC, Jackson, EE, Kagiya, S, Kalske, A, Kalwajtys, M, Karban, R, Kariyat, R, Keasar, T, Kersch-Becker, MF, Kharouba, HM, Kim, TN, Kimuyu, DM, Kluse, J, Koerner, SE, Komatsu, KJ, Krishnan, S, Laihonen, M, Lamelas-López, L, LaScaleia, MC, Lecomte, N, Lehn, CR, Li, X, Lindroth, RL, LoPresti, EF, Losada, M, Louthan, AM, Luizzi, VJ, Lynch, SC, Lynn, JS, Lyon, NJ, Maia, RA, Mannall, TL, Martin, BS, Massad, TJ, McCall, AC, McGurrin, K, Merwin, AC, Mijango-Ramos, Z, Mills, CH, Moles, AT, Moore, CM, Moreira, X, Morrison, CR, Moshobane, MC, Muola, A, Nakajima, K, Novais, S, Ogbebor, CO, Ohsaki, H, Pan, VS, Pardikes, NA, Pareja, M, Parthasarathy, N, Pawar, RR, Paynter, Q, Pearse, IS, Penczykowski, RM, Pepi, AA, Pereira, CC, Phartyal, SS, Piper, FI, Poveda, K, Pringle, EG, Puy, J, Quijano, T, Quintero, C, Rasmann, S, Rosche, C, Rosenheim, LY, Runyon, JB, Sadeh, A, Sakata, Y, Salcido, DM, Salgado-Luarte, C, Santos, BA, Sapir, Y, Sasal, Y, Sato, Y, Sawant, M, Schoeder, H, Schumann, I, Segoli, M, Segre, H, Shelef, O, Shinohara, N, Singh, RP, Smith, DS, Sobral, M, Stotz, GC, Tack, AJM, Tayal, M, Tooker, JF, Vaca-Uribe, JL, Valtonen, A, van Dik, LJA, Vandvik, V, Villellas, J, Waller, Lauren, Weber, MG, Yamawo, A, Yim, S, Zarnetske, PL, Zehr, LN, Zhong, Z, and Wetzel, WC

Published

2023

3. Forest defoliation by an invasive outbreak insect: Catastrophic consequences for a charismatic mega moth.

Author

Lindroth RL, Zierden MR, Morrow CJ, and Fernandez PC

Abstract

Earth is now experiencing declines in insect abundance and diversity unparalleled in human history. The drivers underlying those declines are many, complex, and incompletely known. Here, using a natural experiment, we report the first test of the hypothesis that forest defoliation by an invasive outbreak insect compromises the fitness of a native insect via damage-induced increases in toxicity of the forest canopy. We demonstrate that defoliation by the invasive spongy moth ( Lymantria dispar ) elicits an average 8.4-fold increase in foliar defense expression among aspen ( Populus tremuloides ) genotypes. In turn, elevated defense dramatically reduces survivorship, feeding, and growth of a charismatic mega moth ( Anthereae polyphemus ). This work suggests that changes to the phytochemical landscape of forests, mediated by invasive outbreak insects, are likely to negatively impact native insects, with potential repercussions for community diversity and ecosystem function across expansive scales., Competing Interests: None of the authors has any competing interest, financial or otherwise, with the research reported in this paper., (© 2024 The Author(s). Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2024

4. Plant size, latitude, and phylogeny explain within-population variability in herbivory.

Author

Robinson ML, Hahn PG, Inouye BD, Underwood N, Whitehead SR, Abbott KC, Bruna EM, Cacho NI, Dyer LA, Abdala-Roberts L, Allen WJ, Andrade JF, Angulo DF, Anjos D, Anstett DN, Bagchi R, Bagchi S, Barbosa M, Barrett S, Baskett CA, Ben-Simchon E, Bloodworth KJ, Bronstein JL, Buckley YM, Burghardt KT, Bustos-Segura C, Calixto ES, Carvalho RL, Castagneyrol B, Chiuffo MC, Cinoğlu D, Cinto Mejía E, Cock MC, Cogni R, Cope OL, Cornelissen T, Cortez DR, Crowder DW, Dallstream C, Dáttilo W, Davis JK, Dimarco RD, Dole HE, Egbon IN, Eisenring M, Ejomah A, Elderd BD, Endara MJ, Eubanks MD, Everingham SE, Farah KN, Farias RP, Fernandes AP, Fernandes GW, Ferrante M, Finn A, Florjancic GA, Forister ML, Fox QN, Frago E, França FM, Getman-Pickering AS, Getman-Pickering Z, Gianoli E, Gooden B, Gossner MM, Greig KA, Gripenberg S, Groenteman R, Grof-Tisza P, Haack N, Hahn L, Haq SM, Helms AM, Hennecke J, Hermann SL, Holeski LM, Holm S, Hutchinson MC, Jackson EE, Kagiya S, Kalske A, Kalwajtys M, Karban R, Kariyat R, Keasar T, Kersch-Becker MF, Kharouba HM, Kim TN, Kimuyu DM, Kluse J, Koerner SE, Komatsu KJ, Krishnan S, Laihonen M, Lamelas-López L, LaScaleia MC, Lecomte N, Lehn CR, Li X, Lindroth RL, LoPresti EF, Losada M, Louthan AM, Luizzi VJ, Lynch SC, Lynn JS, Lyon NJ, Maia LF, Maia RA, Mannall TL, Martin BS, Massad TJ, McCall AC, McGurrin K, Merwin AC, Mijango-Ramos Z, Mills CH, Moles AT, Moore CM, Moreira X, Morrison CR, Moshobane MC, Muola A, Nakadai R, Nakajima K, Novais S, Ogbebor CO, Ohsaki H, Pan VS, Pardikes NA, Pareja M, Parthasarathy N, Pawar RR, Paynter Q, Pearse IS, Penczykowski RM, Pepi AA, Pereira CC, Phartyal SS, Piper FI, Poveda K, Pringle EG, Puy J, Quijano T, Quintero C, Rasmann S, Rosche C, Rosenheim LY, Rosenheim JA, Runyon JB, Sadeh A, Sakata Y, Salcido DM, Salgado-Luarte C, Santos BA, Sapir Y, Sasal Y, Sato Y, Sawant M, Schroeder H, Schumann I, Segoli M, Segre H, Shelef O, Shinohara N, Singh RP, Smith DS, Sobral M, Stotz GC, Tack AJM, Tayal M, Tooker JF, Torrico-Bazoberry D, Tougeron K, Trowbridge AM, Utsumi S, Uyi O, Vaca-Uribe JL, Valtonen A, van Dijk LJA, Vandvik V, Villellas J, Waller LP, Weber MG, Yamawo A, Yim S, Zarnetske PL, Zehr LN, Zhong Z, and Wetzel WC

Subjects

Ecosystem, Phylogeny, Animals, Biological Evolution, Herbivory, Plants, Plant Defense Against Herbivory, Biological Variation, Population

Abstract

Interactions between plants and herbivores are central in most ecosystems, but their strength is highly variable. The amount of variability within a system is thought to influence most aspects of plant-herbivore biology, from ecological stability to plant defense evolution. Our understanding of what influences variability, however, is limited by sparse data. We collected standardized surveys of herbivory for 503 plant species at 790 sites across 116° of latitude. With these data, we show that within-population variability in herbivory increases with latitude, decreases with plant size, and is phylogenetically structured. Differences in the magnitude of variability are thus central to how plant-herbivore biology varies across macroscale gradients. We argue that increased focus on interaction variability will advance understanding of patterns of life on Earth.

Published

2023

5. Resistance against Leucoptera sinuella (Lepidoptera: Lyonetiidae) among hybrid clones of Populus spp. in central Chile.

Author

Yánez-Segovia S, Ramírez CC, Lindroth RL, and Fuentes-Contreras E

Abstract

Leucoptera sinuella (Reutti) (Lepidoptera: Lyonetiidae) is a leaf miner specialist on Salicaceae recently introduced to Chile and Argentina, where it is causing economic damage to poplar plantations. We report a field survey in a poplar nursery naturally infested showing that regardless of the poplar hybrid taxon, high variability in resistance was observed among clones within families for oviposition and leaf-mining damage. A group of susceptible and resistant hybrid poplar clones was then selected for a laboratory evaluation of oviposition (antixenosis) and leaf-mining damage (antibiosis) on potted, rooted shoot cuttings. The concentration of condensed tannins (CTs) and salicinoid phenolic glucosides (SPGs) of the leaves of the selected clones from the laboratory study was also measured. Total oviposited eggs were positively correlated with leaf area, with the lowest oviposition on TMxT 11372 clone. The lowest percentage of mined leaf area was obtained for clones TMxT 11372, TMxT 11463, and TDxD 17574, but surprisingly no correlation between the percentage of mined leaf area and concentration of CTs and SPGs was found. Resistant poplar hybrids of our study could be suitable for breeding programs aimed for L. sinuella integrated pest management., (© The Author(s) 2023. Published by Oxford University Press on behalf of Entomological Society of America. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2023

6. Genomic and transcriptomic analyses reveal polygenic architecture for ecologically important traits in aspen ( Populus tremuloides Michx.).

Author

Riehl JFL, Cole CT, Morrow CJ, Barker HL, Bernhardsson C, Rubert-Nason K, Ingvarsson PK, and Lindroth RL

Abstract

Intraspecific genetic variation in foundation species such as aspen ( Populus tremuloides Michx.) shapes their impact on forest structure and function. Identifying genes underlying ecologically important traits is key to understanding that impact. Previous studies, using single-locus genome-wide association (GWA) analyses to identify candidate genes, have identified fewer genes than anticipated for highly heritable quantitative traits. Mounting evidence suggests that polygenic control of quantitative traits is largely responsible for this "missing heritability" phenomenon. Our research characterized the genetic architecture of 30 ecologically important traits using a common garden of aspen through genomic and transcriptomic analyses. A multilocus association model revealed that most traits displayed a highly polygenic architecture, with most variation explained by loci with small effects (likely below the detection levels of single-locus GWA methods). Consistent with a polygenic architecture, our single-locus GWA analyses found only 38 significant SNPs in 22 genes across 15 traits. Next, we used differential expression analysis on a subset of aspen genets with divergent concentrations of salicinoid phenolic glycosides (key defense traits). This complementary method to traditional GWA discovered 1243 differentially expressed genes for a polygenic trait. Soft clustering analysis revealed three gene clusters (241 candidate genes) involved in secondary metabolite biosynthesis and regulation. Our work reveals that ecologically important traits governing higher-order community- and ecosystem-level attributes of a foundation forest tree species have complex underlying genetic structures and will require methods beyond traditional GWA analyses to unravel., (© 2023 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2023

7. Environment and Genotype Influence Quantitative and Qualitative Variation in Condensed Tannins in Aspen.

Author

Rubert-Nason KF, Yang P, Morrow CJ, and Lindroth RL

Subjects

Principal Component Analysis, Plant Leaves chemistry, Herbivory, Mammals, Animals, Insecta, Temperature, Soil chemistry, Climate, Tannins analysis, Populus chemistry, Populus genetics

Abstract

Condensed tannins (CTs) are abundant, ecologically-relevant secondary metabolites in many plants, which respond to variables associated with anthropogenic environmental change. While many studies have reported how genetic and environmental factors affect CT concentrations, few have explored how they influence CT molecular structure. Here, using trembling aspen (Populus tremuloides) as a model organism, we report how foliar CT concentrations, polymer sizes, representation of procyanidins and prodelphinidins, and stereochemistry vary in response to changes in air temperature (warming and freeze damage), air composition (elevated CO 2 and O 3 ), soil quality (nutrients and microbiome), and herbivory (mammal and lepidopteran). Use of multiple aspen genotypes enabled assessment of genetic influences on aspen CTs. CT concentration and composition were analyzed by thiolysis-ultra high performance liquid chromatography/mass spectrometry in archived leaf samples from prior experiments. All environmental variables explored except for soil microbiome influenced both CT quantity and quality, with climate factors appearing to have larger effect magnitudes than herbivory. Climate, soil, and herbivory effects varied among genotypes, while air composition effects were consistent across genotypes. Considering that CT properties (concentrations and molecular structures) mediate functions at the organismal through ecosystem scales, intraspecific variation in responses of CT properties to environmental factors could provide a pathway through which environmental change exerts selective pressure on Populus populations. Future studies are needed to identify the molecular-level mechanisms by which environmental factors influence CT concentrations and structures, and to establish their ecological and evolutionary significance., (© 2023. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

8. Phenotypic Variation in Phytochemical Defense of Trembling Aspen in Western North America: Genetics, Development, and Geography.

Author

Lindroth RL, Wooley SC, Donaldson JR, Rubert-Nason KF, Morrow CJ, and Mock KE

Subjects

Animals, Plant Leaves metabolism, Phytochemicals metabolism, Glycosides metabolism, North America, Trees metabolism, Nitrogen metabolism, Phenols metabolism, Biological Variation, Population, Geography, Mammals, Ecosystem, Populus metabolism

Abstract

Trembling aspen (Populus tremuloides) is arguably the most important deciduous tree species in the Intermountain West of North America. There, as elsewhere in its range, aspen exhibits remarkable genetic variation in observable traits such as morphology and phenology. In contrast to Great Lakes populations, however, relatively little is known about phytochemical variation in western aspen. This survey of phytochemistry in western aspen was undertaken to assess how chemical expression varies among genotypes, cytotypes (diploid vs. triploid), and populations, and in response to development and mammalian browsing. We measured levels of foliar nitrogen, salicinoid phenolic glycosides (SPGs) and condensed tannins (CTs), as those constituents influence organismal interactions and ecosystem processes. Results revealed striking genotypic variation and considerable population variation, but minimal cytotype variation, in phytochemistry of western aspen. Levels of SPGs and nitrogen declined, whereas levels of CTs increased, with tree age. Browsed ramets had much higher levels of SPGs, and lower levels of CTs, than unbrowsed ramets of the same genotype. We then evaluated how composite chemical profiles of western aspen differ from those of Great Lakes aspen (assessed in earlier research). Interestingly, mature western aspen trees maintain much higher levels of SPGs, and lower levels of CTs, than Great Lakes aspen. Phenotypic variation in chemical composition of aspen - a foundation species - in the Intermountain West likely has important consequences for organismal interactions and forest ecosystem dynamics. Moreover, those consequences likely play out over spatial and temporal scales somewhat differently than have been documented for Great Lakes aspen., (© 2023. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2023

9. Genotypic variation rather than ploidy level determines functional trait expression in a foundation tree species in the presence and absence of environmental stress.

Author

Eisenring M, Lindroth RL, Flansburg A, Giezendanner N, Mock KE, and Kruger EL

Subjects

Triploidy, Ploidies, Phenotype, Genotype, Trees physiology, Populus genetics

Abstract

Background and Aims: At the population level, genetic diversity is a key determinant of a tree species' capacity to cope with stress. However, little is known about the relative importance of the different components of genetic diversity for tree stress responses. We compared how two sources of genetic diversity, genotype and cytotype (i.e. differences in ploidy levels), influence growth, phytochemical and physiological traits of Populus tremuloides in the presence and absence of environmental stress., Methods: In a series of field studies, we first assessed variation in traits across diploid and triploid aspen genotypes from Utah and Wisconsin under non-stressed conditions. In two follow-up experiments, we exposed diploid and triploid aspen genotypes from Wisconsin to individual and interactive drought stress and defoliation treatments and quantified trait variations under stress., Key Results: We found that (1) tree growth and associated traits did not differ significantly between ploidy levels under non-stressed conditions. Instead, variation in tree growth and most other traits was driven by genotypic and population differences. (2) Genotypic differences were critical for explaining variation of most functional traits and their responses to stress. (3) Ploidy level played a subtle role in shaping traits and trait stress responses, as its influence was typically obscured by genotypic differences. (4) As an exception to the third conclusion, we showed that triploid trees expressed 17 % higher foliar defence (tremulacin) levels, 11 % higher photosynthesis levels and 23 % higher rubisco activity under well-watered conditions. Moreover, triploid trees displayed greater drought resilience than diploids as they produced 35 % more new tissue than diploids when recovering from drought stress., Conclusion: Although ploidy level can strongly influence the ecology of tree species, those effects may be relatively small in contrast to the effects of genotypic variation in highly diverse species., (© The Author(s) 2022. Published by Oxford University Press on behalf of the Annals of Botany Company. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2023

10. Genetic divergence along a climate gradient shapes chemical plasticity of a foundation tree species to both changing climate and herbivore damage.

Author

Eisenring M, Best RJ, Zierden MR, Cooper HF, Norstrem MA, Whitham TG, Grady K, Allan GJ, and Lindroth RL

Subjects

Animals, Climate Change, Ecosystem, Herbivory, Insecta, Populus genetics, Trees genetics

Abstract

Climate change is threatening the persistence of many tree species via independent and interactive effects on abiotic and biotic conditions. In addition, changes in temperature, precipitation, and insect attacks can alter the traits of these trees, disrupting communities and ecosystems. For foundation species such as Populus, phytochemical traits are key mechanisms linking trees with their environment and are likely jointly determined by interactive effects of genetic divergence and variable environments throughout their geographic range. Using reciprocal Fremont cottonwood (Populus fremontii) common gardens along a steep climatic gradient, we explored how environment (garden climate and simulated herbivore damage) and genetics (tree provenance and genotype) affect both foliar chemical traits and the plasticity of these traits. We found that (1) Constitutive and plastic chemical responses to changes in garden climate and damage varied among defense compounds, structural compounds, and leaf nitrogen. (2) For both defense and structural compounds, plastic responses to different garden climates depended on the climate in which a population or genotype originated. Specifically, trees originating from cool provenances showed higher defense plasticity in response to climate changes than trees from warmer provenances. (3) Trees from cool provenances growing in cool garden conditions expressed the lowest constitutive defense levels but the strongest induced (plastic) defenses in response to damage. (4) The combination of hot garden conditions and simulated herbivory switched the strategy used by these genotypes, increasing constitutive defenses but erasing the capacity for induction after damage. Because Fremont cottonwood chemistry plays a major role in shaping riparian communities and ecosystems, the effects of changes in phytochemical traits can be wide reaching. As the southwestern US is confronted with warming temperatures and insect outbreaks, these results improve our capacity to predict ecosystem consequences of climate change and inform selection of tree genotypes for conservation and restoration purposes., (© 2022 The Authors. Global Change Biology published by John Wiley & Sons Ltd.)

Published

2022

11. Intraspecific variation in plant economic traits predicts trembling aspen resistance to a generalist insect herbivore.

Author

Morrow CJ, Jaeger SJ, and Lindroth RL

Subjects

Animals, Insecta, Phenotype, Plant Leaves genetics, Plants, Herbivory, Populus genetics

Abstract

Patterns of trait expression within some plant species have recently been shown to align with the leaf economics spectrum paradigm. Resistance to herbivores is also expected to covary with leaf economics traits. We selected 36 mature Populus tremuloides genotypes in a common garden to assess whether aspen leaf economics patterns follow those observed among species globally. We also evaluated leaf economics strategies in the context of insect resistance by conducting bioassays to determine the effects of plant traits on preference and performance of Lymantria dispar. We found that: (1) intraspecific trait patterns of P. tremuloides parallel those exhibited by the interspecific leaf economics spectrum, (2) herbivores preferred leaves from genotypes with resource-acquisitive strategies, and (3) herbivores also performed best on genotypes with resource-acquisitive strategies. We conclude that a leaf economics spectrum that incorporates defense traits is a useful tool for explaining intraspecific patterns of variation in plant strategies, including resistance to herbivores., (© 2022. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2022

12. Polyploidy and growth-defense tradeoffs in natural populations of western quaking Aspen.

Author

DeRose RJ, Gardner RS, Lindroth RL, and Mock KE

Subjects

Genotype, Glycosides metabolism, Plant Leaves chemistry, Triploidy, Populus genetics, Populus metabolism, Proanthocyanidins metabolism

Abstract

Polyploidy, the expression of more than two sets of chromosomes, is common in plants, and is thought to influence plant trait expression and drive plant species evolution. The degree to which polyploidy influences interactions among physiological processes such as growth and defense in natural populations through its effect on phenotypic variability is poorly understood. We link broad plant genotypic features (including polyploidy) to phenotypic expression of growth and chemical defense in natural populations of quaking aspen (Populus tremuloides) to examine patterns in resource allocation that might drive growth-defense tradeoffs. Quaking aspen are capable of rapid growth, and are also a primary food plant for a large range of herbivores, including insects and ungulates. While often diploid, aspen can exhibit polyploidy as triploid clones. We tested for the effect of genotype, cytotype (ploidy level, divided between diploids and triploids), and ramet age on relationships between growth and leaf chemistry across natural aspen clones in northern Utah. Substantial genotype variability in growth and leaf chemistry occurred across both cytotypes. Phenolic glycosides, but not condensed tannins, were negatively related to growth. Ramet age was also negatively related to growth. Phenolic glycosides were negatively related to condensed tannins, but only for the diploid clones. Triploid clones exhibited ~ 20% higher levels of phenolic glycosides than diploids. Growth in quaking aspen was likely sacrificed for the production of phenolic glycosides. Our study underscores the importance of considering polyploidy, genetic variability, and ramet age in understanding growth-defense tradeoffs in natural populations of clonal organisms, such as quaking aspen., (© 2022. The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.)

Published

2022

13. Coordinated resource allocation to plant growth-defense tradeoffs.

Author

Monson RK, Trowbridge AM, Lindroth RL, and Lerdau MT

Subjects

Resource Allocation, Plants genetics, Proteomics

Abstract

Plant resource allocation patterns often reveal tradeoffs that favor growth (G) over defense (D), or vice versa. Ecologists most often explain G-D tradeoffs through principles of economic optimality, in which negative trait correlations are attributed to the reconciliation of fitness costs. Recently, researchers in molecular biology have developed 'big data' resources including multi-omic (e.g. transcriptomic, proteomic and metabolomic) studies that describe the cellular processes controlling gene expression in model species. In this synthesis, we bridge ecological theory with discoveries in multi-omics biology to better understand how selection has shaped the mechanisms of G-D tradeoffs. Multi-omic studies reveal strategically coordinated patterns in resource allocation that are enabled by phytohormone crosstalk and transcriptional signal cascades. Coordinated resource allocation justifies the framework of optimality theory, while providing mechanistic insight into the feedbacks and control hubs that calibrate G-D tradeoff commitments. We use the existing literature to describe the coordinated resource allocation hypothesis (CoRAH) that accounts for balanced cellular controls during the expression of G-D tradeoffs, while sustaining stored resource pools to buffer the impacts of future stresses. The integrative mechanisms of the CoRAH unify the supply- and demand-side perspectives of previous G-D tradeoff theories., (© 2021 The Authors. New Phytologist © 2021 New Phytologist Foundation.)

Published

2022

14. Plastic responses to hot temperatures homogenize riparian leaf litter, speed decomposition, and reduce detritivores.

Author

Jeplawy JR, Cooper HF, Marks J, Lindroth RL, Andrews MI, Compson ZG, Gehring C, Hultine KR, Grady K, Whitham TG, Allan GJ, and Best RJ

Subjects

Hot Temperature, Plant Leaves, Trees, Ecosystem, Populus genetics

Abstract

Efforts to maintain the function of critical ecosystems under climate change often begin with foundation species. In the southwestern United States, cottonwood trees support diverse communities in riparian ecosystems that are threatened by rising temperatures. Genetic variation within cottonwoods shapes communities and ecosystems, but these effects may be modified by phenotypic plasticity, where genotype traits change in response to environmental conditions. Here, we investigated plasticity in Fremont cottonwood (Populus fremontii) leaf litter traits as well as the consequences of plasticity for riparian ecosystems. We used three common gardens each planted with genotypes from six genetically divergent populations spanning a 12°C temperature gradient, and a decomposition experiment in a common stream environment. We found that leaf litter area, specific leaf area, and carbon to nitrogen ratio (C:N) were determined by interactions between genetics and growing environment, as was the subsequent rate of litter decomposition. Most of the genetic variation in leaf litter traits appeared among rather than within source populations with distinct climate histories. Source populations from hotter climates generally produced litter that decomposed more quickly, but plasticity varied the magnitude of this effect. We also found that hotter growing conditions reduced the variation in litter traits produced across genotypes, homogenizing the litter inputs to riparian ecosystems. All genotypes in the hottest garden produced comparatively small leaves that decomposed quickly and supported lower abundances of aquatic invertebrates, whereas the same genotypes in the coldest garden produced litter with distinct morphologies and decomposition rates. Our results suggest that plastic responses to climate stress may constrict the expression of genetic variation in predictable ways that impact communities and ecosystems. Understanding these interactions between genetic and environmental variation is critical to our ability to plan for the role of foundation species when managing and restoring riparian ecosystems in a warming world., (© 2021 by the Ecological Society of America.)

Published

2021

15. Growth-defense trade-offs shape population genetic composition in an iconic forest tree species.

Author

Cope OL, Keefover-Ring K, Kruger EL, and Lindroth RL

Subjects

Biological Evolution, Ecosystem, Forests, Genetics, Population methods, Genotype, Phenotype, Plant Leaves, Plants, Trees, Populus genetics, Populus growth & development, Selection, Genetic physiology

Abstract

All organisms experience fundamental conflicts between divergent metabolic processes. In plants, a pivotal conflict occurs between allocation to growth, which accelerates resource acquisition, and to defense, which protects existing tissue against herbivory. Trade-offs between growth and defense traits are not universally observed, and a central prediction of plant evolutionary ecology is that context-dependence of these trade-offs contributes to the maintenance of intraspecific variation in defense [Züst and Agrawal, Annu. Rev. Plant Biol. , 68, 513-534 (2017)]. This prediction has rarely been tested, however, and the evolutionary consequences of growth-defense trade-offs in different environments are poorly understood, especially in long-lived species [Cipollini et al. , Annual Plant Reviews (Wiley, 2014), pp. 263-307]. Here we show that intraspecific trait trade-offs, even when fixed across divergent environments, interact with competition to drive natural selection of tree genotypes corresponding to their growth-defense phenotypes. Our results show that a functional trait trade-off, when coupled with environmental variation, causes real-time divergence in the genetic architecture of tree populations in an experimental setting. Specifically, competitive selection for faster growth resulted in dominance by fast-growing tree genotypes that were poorly defended against natural enemies. This outcome is a signature example of eco-evolutionary dynamics: Competitive interactions affected microevolutionary trajectories on a timescale relevant to subsequent ecological interactions [Brunner et al. , Funct. Ecol. 33, 7-12 (2019)]. Eco-evolutionary drivers of tree growth and defense are thus critical to stand-level trait variation, which structures communities and ecosystems over expansive spatiotemporal scales., Competing Interests: The authors declare no competing interest.

Published

2021

16. Trait plasticity and trade-offs shape intra-specific variation in competitive response in a foundation tree species.

Author

Cope OL, Lindroth RL, Helm A, Keefover-Ring K, and Kruger EL

Subjects

Genotype, Phenotype, Plant Leaves, Populus genetics, Trees genetics

Abstract

The ability to tolerate neighboring plants (i.e. degree of competitive response) is a key determinant of plant success in high-competition environments. Plant genotypes adjust their functional trait expression under high levels of competition, which may help explain intra-specific variation in competitive response. However, the relationships between traits and competitive response are not well understood, especially in trees. In this study, we investigated among-genotype associations between tree trait plasticity and competitive response. We manipulated competition intensity in experimental stands of trembling aspen (Populus tremuloides) to address the covariance between competition-induced changes in functional trait expression and aspects of competitive ability at the genotype level. Genotypic variation in the direction and magnitude of functional trait responses, especially those of crown foliar mass, phytochemistry, and leaf physiology, was associated with genotypic variation in competitive response. Traits exhibited distinct plastic responses to competition, with varying degrees of genotypic variation and covariance with other trait responses. The combination of genotypic diversity and covariance among functional traits led to tree responses to competition that were coordinated among traits yet variable among genotypes. Such relationships between tree traits and competitive success have the potential to shape stand-level trait distributions over space and time., (© 2020 The Authors. New Phytologist © 2020 New Phytologist Foundation.)

Published

2021

17. Growing up aspen: ontogeny and trade-offs shape growth, defence and reproduction in a foundation species.

Author

Cole CT, Morrow CJ, Barker HL, Rubert-Nason KF, Riehl JFL, Köllner TG, Lackus ND, and Lindroth RL

Subjects

Ecosystem, Genotype, Plant Leaves, Reproduction, Trees, Populus genetics

Abstract

Background and Aims: Intraspecific variation in foundation species of forest ecosystems can shape community and ecosystem properties, particularly when that variation has a genetic basis. Traits mediating interactions with other species are predicted by simple allocation models to follow ontogenetic patterns that are rarely studied in trees. The aim of this research was to identify the roles of genotype, ontogeny and genotypic trade-offs shaping growth, defence and reproduction in aspen., Methods: We established a common garden replicating >500 aspen genets in Wisconsin, USA. Trees were measured through the juvenile period into the onset of reproduction, for growth, defence chemistry (phenolic glycosides and condensed tannins), nitrogen, extrafloral nectaries, leaf morphology (specific leaf area), flower production and foliar herbivory and disease. We also assayed the TOZ19 sex marker and heterozygosity at ten microsatellite loci., Key Results: We found high levels of genotypic variation for all traits, and high heritabilities for both the traits and their ontogenetic trajectories. Ontogeny strongly shaped intraspecific variation, and trade-offs among growth, defence and reproduction supported some predictions while contradicting others. Both direct resistance (chemical defence) and indirect defence (extrafloral nectaries) declined during the juvenile stage, prior to the onset of reproduction. Reproduction was higher in trees that were larger, male and had higher individual heterozygosity. Growth was diminished by genotypic allocation to both direct and indirect defence as well as to reproduction, but we found no evidence of trade-offs between defence and reproduction., Conclusions: Key traits affecting the ecological communities of aspen have high levels of genotypic variation and heritability, strong patterns of ontogeny and clear trade-offs among growth, defence and reproduction. The architecture of aspen's community genetics - its ontogeny, trade-offs and especially its great variability - is shaped by both its broad range and the diverse community of associates, and in turn further fosters that diversity., (© The Author(s) 2020. Published by Oxford University Press on behalf of the Annals of Botany Company. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2021

18. Root Secondary Metabolites in Populus tremuloides: Effects of Simulated Climate Warming, Defoliation, and Genotype.

Author

Li Z, Rubert-Nason KF, Jamieson MA, Raffa KF, and Lindroth RL

Subjects

Animals, Biomass, Climate Change, Defoliants, Chemical metabolism, Genotype, Glycosides chemistry, Glycosides metabolism, Herbivory, Larva drug effects, Moths, Phenols chemistry, Phenols metabolism, Plant Leaves metabolism, Proanthocyanidins chemistry, Proanthocyanidins metabolism, Secondary Metabolism, Soil, Temperature, Defoliants, Chemical chemistry, Plant Extracts analysis, Plant Leaves chemistry, Plant Roots chemistry, Plant Roots metabolism, Populus chemistry, Populus metabolism

Abstract

Climate warming can influence interactions between plants and associated organisms by altering levels of plant secondary metabolites. In contrast to studies of elevated temperature on aboveground phytochemistry, the consequences of warming on root chemistry have received little attention. Herein, we investigated the effects of elevated temperature, defoliation, and genotype on root biomass and phenolic compounds in trembling aspen (Populus tremuloides). We grew saplings of three aspen genotypes under ambient or elevated temperatures (+4-6 °C), and defoliated (by 75%) half of the trees in each treatment. After 4 months, we harvested roots and determined their condensed tannin and salicinoid (phenolic glycoside) concentrations. Defoliation reduced root biomass, with a slightly larger impact under elevated, relative to ambient, temperature. Elevated temperature decreased condensed tannin concentrations by 21-43% across the various treatment combinations. Warming alone did not alter salicinoid concentrations but eliminated a small negative impact of defoliation on those compounds. Graphical vector analysis suggests that effects of warming and defoliation on condensed tannins and salicinoids were predominantly due to reduced biosynthesis of these metabolites in roots, rather than to changes in root biomass. In general, genotypes did not differ in their responses to temperature or temperature by defoliation interactions. Collectively, our results suggest that future climate warming will alter root phytochemistry, and that effects will vary among different classes of secondary metabolites and be influenced by concurrent ecological interactions such as herbivory. Temperature- and herbivory-mediated changes in root chemistry have the potential to influence belowground trophic interactions and soil nutrient dynamics.

Published

2021

19. Local adaptation and rapid evolution of aphids in response to genetic interactions with their cottonwood hosts.

Author

Wooley SC, Smith DS, Lonsdorf EV, Brown SC, Whitham TG, Shuster SM, and Lindroth RL

Abstract

Several studies have demonstrated the ecological consequences of genetic variation within a single plant species. For example, these studies show that individual plant genotypes support unique composition of the plants' associated arthropod community. By contrast, fewer studies have explored how plant genetic variation may influence evolutionary dynamics in the plant's associated species. Here, we examine how aphids respond evolutionarily to genetic variation in their host plant. We conducted two experiments to examine local adaptation and rapid evolution of the free-feeding aphid Chaitophorus populicola across genetic variants of its host plant, Populus angustifolia . To test for local adaptation, we collected tree cuttings and aphid colonies from three sites along an elevation/climate gradient and conducted a reciprocal transplant experiment. In general, home aphids (aphids transplanted onto trees from the same site) produced 1.7-3.4 times as many offspring as foreign aphids (aphids transplanted onto trees from different sites). To test for rapid evolution, we used 4 clonally replicated aphid genotypes and transplanted each onto 5 clonally replicated P. angustifolia genotypes. Each tree genotype started with the same aphid genotype composition. After 21 days (~two aphid generations), aphid genotype composition changed (i.e., aphids evolved) and some tree genotypes supported unique evolutionary trajectories of aphids. These results suggest that plant evolution in response to human perturbation, such as climate change and invasive species, will also result in evolutionary responses in strongly interacting species that could cascade to affect whole communities., Competing Interests: Authors do not have any conflicts of interests., (© 2020 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2020

20. The Occurrence of Sulfated Salicinoids in Poplar and Their Formation by Sulfotransferase1.

Author

Lackus ND, Müller A, Kröber TDU, Reichelt M, Schmidt A, Nakamura Y, Paetz C, Luck K, Lindroth RL, Constabel CP, Unsicker SB, Gershenzon J, and Köllner TG

Subjects

Benzyl Alcohols metabolism, Glucosides metabolism, Hydroquinones metabolism, Plant Proteins genetics, Populus genetics, RNA Interference, Sulfotransferases genetics, Plant Proteins metabolism, Populus metabolism, Sulfotransferases metabolism

Abstract

Salicinoids form a specific class of phenolic glycosides characteristic of the Salicaceae. Although salicinoids accumulate in large amounts and have been shown to be involved in plant defense, their biosynthesis is unclear. We identified two sulfated salicinoids, salicin-7-sulfate and salirepin-7-sulfate, in black cottonwood ( Populus trichocarpa ). Both compounds accumulated in high amounts in above-ground tissues including leaves, petioles, and stems, but were also found at lower concentrations in roots. A survey of salicin-7-sulfate and salirepin-7-sulfate in a subset of poplar ( Populus sp.) and willow ( Salix sp.) species revealed a broader distribution within the Salicaceae. To elucidate the formation of these compounds, we studied the sulfotransferase ( SOT ) gene family in P trichocarpa ( PtSOT ). One of the identified genes, PtSOT1 , was shown to encode an enzyme able to convert salicin and salirepin into salicin-7-sulfate and salirepin-7-sulfate, respectively. The expression of PtSOT1 in different organs of P trichocarpa matched the accumulation of sulfated salicinoids in planta. Moreover, RNA interference-mediated knockdown of SOT1 in gray poplar ( Populus × canescens ) resulted in decreased levels of sulfated salicinoids in comparison to wild-type plants, indicating that SOT1 is responsible for their formation in planta. The presence of a nonfunctional SOT1 allele in black poplar ( Populus nigra ) was shown to correlate with the absence of salicin-7-sulfate and salirepin-7-sulfate in this species. Food choice experiments with leaves from wild-type and SOT1 knockdown trees suggest that sulfated salicinoids do not affect the feeding preference of the generalist caterpillar Lymantria dispar A potential role of the sulfated salicinoids in sulfur storage and homeostasis is discussed., (© 2020 American Society of Plant Biologists. All Rights Reserved.)

Published

2020

21. To compete or defend: linking functional trait variation with life-history tradeoffs in a foundation tree species.

Author

Kruger EL, Keefover-Ring K, Holeski LM, and Lindroth RL

Subjects

Phenotype, Photosynthesis, Plant Leaves, Populus, Trees

Abstract

Although chemical deterrents to herbivory often exact costs in terms of plant growth, the manner in which those costs arise, and their physiological relationship to other functional traits, remain unclear. In the absence of appreciable herbivory, we examined interrelationships among chemical defense levels and other foliar functional traits (e.g., light-saturated photosynthesis, specific leaf area, nitrogen concentration) as co-determinants of tree growth and, by extension, competitive ability in high-density populations comprising 16 genotypes of Populus tremuloides. Across genotypes, concentrations of chemical defenses were not significantly related to other leaf functional traits, but levels of the salicinoid phenolic glycosides (SPGs) salicin, salicortin and tremulacin were each negatively correlated with relative mass growth (RMG) of aboveground woody tissue (P ≤ 0.001). RMG, in turn, underpinned 77% of the genotypic variation in relative height growth (our index of competitive ability). RMG was also positively related to light-saturated photosynthesis (P ≤ 0.001), which, together with the three SPGs, explained 86% of genotypic RMG variation (P ≤ 0.001). Moreover, results of a carbon balance simulation indicated that costs of resource allocation to SPGs, reaching nearly a third of annual crown photosynthesis, were likely mediated by substantial metabolic turnover, particularly for salicin. The lack of discernible links between foliar defense allocation and other (measured) functional traits, and the illustrated potential of metabolic turnover to reconcile influences of SPG allocation on RMG, shed additional light on fundamental physiological mechanisms underlying evolutionary tradeoffs between chemical defense investment and competitive ability in a foundation tree species.

Published

2020

22. Divergent host plant utilization by adults and offspring is related to intra-plant variation in chemical defences.

Author

Mason CJ, Long DC, Lindroth RL, and Hoover K

Subjects

Animals, Female, Herbivory, Introduced Species, Larva, Coleoptera, Ovum

Abstract

Adult and juvenile herbivores of the same species can use divergent feeding strategies, and thus may inhabit and consume different parts of the plant. Because the expression of chemical defences often differs between host plant tissues, this variation may result in disparate performance outcomes for adult and juvenile conspecifics that feed on distinct dietary substrates. The goal of this study was to evaluate how host range may differ between adults and juveniles in a generalist herbivore. We addressed the impacts of among- and within-plant defence variation using the wood-feeding Asian longhorned beetle (Anoplophora glabripennis) and three host plants having a range of putative resistance. Impacts of host plants on adult and offspring performance were assessed using a series of controlled bioassays. We evaluated adult-feeding and egg-laying behaviours in choice and no-choice experiments using the different hosts, and subsequent offspring establishment. We then evaluated host plant chemical composition related to nutrition and defence. Different plants had strong impacts on adult performance, but these patterns did not extend to effects on offspring. Females were capable of developing eggs when provided Acer rubrum, but not Populus deltoides or Populus tomentosa. Females that produced eggs by feeding on A. rubrum, however, deposited eggs into all three plant species. Larvae hatched and consumed tissues in all three hosts. The differences between adult and juvenile utilization of Populus spp. were reflected in markedly higher salicinoid phenolic concentrations in bark (>2% dw), while wood had trace quantities. Our results demonstrate that plant resistance mechanisms can differentially act upon adult and juvenile life stages of a polyphagous herbivore when there is differential expression of chemical defences among plant tissue types. Anoplophora glabripennis has been a globally successful invader due in part to its broad host range, and our results suggest a mechanism that permits the beetle to exploit marginally resistant plants. This study has implications for how host range differs between insect feeding stages, which is particularly important for invasive, polyphagous species encountering novel food sources., (© 2019 The Authors. Journal of Animal Ecology © 2019 British Ecological Society.)

Published

2019

23. Linking plant genes to insect communities: Identifying the genetic bases of plant traits and community composition.

Author

Barker HL, Riehl JF, Bernhardsson C, Rubert-Nason KF, Holeski LM, Ingvarsson PK, and Lindroth RL

Subjects

Animals, Biological Evolution, Ecology, Genes, Plant genetics, Genotype, Phenotype, Biota, Genome-Wide Association Study, Host-Parasite Interactions, Insecta physiology, Molecular Biology, Polymorphism, Single Nucleotide genetics, Populus genetics

Abstract

Community genetics aims to understand the effects of intraspecific genetic variation on community composition and diversity, thereby connecting community ecology with evolutionary biology. Thus far, research has shown that plant genetics can underlie variation in the composition of associated communities (e.g., insects, lichen and endophytes), and those communities can therefore be considered as extended phenotypes. This work, however, has been conducted primarily at the plant genotype level and has not identified the key underlying genes. To address this gap, we used genome-wide association mapping with a population of 445 aspen (Populus tremuloides) genets to identify the genes governing variation in plant traits (defence chemistry, bud phenology, leaf morphology, growth) and insect community composition. We found 49 significant SNP associations in 13 Populus genes that are correlated with chemical defence compounds and insect community traits. Most notably, we identified an early nodulin-like protein that was associated with insect community diversity and the abundance of interacting foundation species (ants and aphids). These findings support the concept that particular plant traits are the mechanistic link between plant genes and the composition of associated insect communities. In putting the "genes" into "genes to ecosystems ecology", this work enhances understanding of the molecular genetic mechanisms that underlie plant-insect associations and the consequences thereof for the structure of ecological communities., (© 2019 John Wiley & Sons Ltd.)

Published

2019

24. Analysis of condensed tannins in Populus spp. using reversed phase UPLC-PDA-(-)esi-MS following thiolytic depolymerisation.

Author

Rubert-Nason KF and Lindroth RL

Subjects

Calibration, Genes, Plant, Genotype, Hydroxylation, Limit of Detection, Plant Leaves chemistry, Polymerization, Populus genetics, Reference Standards, Spectrophotometry, Ultraviolet methods, Stereoisomerism, Tannins standards, Chromatography, High Pressure Liquid methods, Populus chemistry, Spectrometry, Mass, Electrospray Ionization methods, Sulfhydryl Compounds chemistry, Tannins analysis

Abstract

Introduction: Condensed tannins (CTs) are proanthocyanidin heteropolymers that are widely distributed among plants. Their biochemical properties are determined by molecular structure (e.g. polymer size, hydroxylation, stereochemistry). In Populus, genetically and environmentally-determined CT concentrations have been related to ecological effects, while the potential role of CT molecular structure has received little attention., Objective: Evaluate CT polymerisation, major constituent monomers, stereochemistry and overall content in Populus tremuloides foliage using ultra-high-performance liquid chromatography with photodiode array and mass spectrometry (UPLC-PDA-(-)esi-MS) detection following thiolytic depolymerisation of the CTs., Methodology: CTs were extracted from dried foliage of six P. tremuloides genotypes into methanol and thiolytically depolymerised into constituent monomers. Calibration standards were prepared by thiolysis of CT mixtures isolated from P. tremuloides foliage on Sephadex LH-20, followed by preparative high-performance liquid chromatography (HPLC)., Results: Populus tremuloides CTs contained predominantly repeating subunits of three putative stereoisomers each of catechin and gallocatechin. Linear calibrations for standards of these subunits and their thioethers (purities 44-87%, UPLC-(-)esi-MS) were generally stable over the course of 10 months. CT polymer size, hydroxylation, stereochemistry and concentrations differed among genotypes., Conclusion: This thiolysis-UPLC-PDA-(-)esiMS method was optimised for analysis of CT polymer size, hydroxylation, stereochemistry, and total concentration in Populus foliage. It revealed significant variation in each of these properties among P. tremuloides genotypes, and will facilitate evaluation of how environmental factors affect CT molecular structures., (© 2018 John Wiley & Sons, Ltd.)

Published

2019

25. Clonal Saplings of Trembling Aspen Do Not Coordinate Defense Induction.

Author

Cope OL and Lindroth RL

Subjects

Animals, Chromatography, High Pressure Liquid, Genotype, Glycosides analysis, Herbivory, Mass Spectrometry, Moths growth & development, Moths physiology, Phenols chemistry, Plant Leaves chemistry, Plant Leaves genetics, Plant Leaves parasitology, Populus genetics, Populus parasitology, Tannins analysis, Glycosides metabolism, Populus chemistry, Tannins metabolism

Abstract

Induction of plant chemical defenses in response to insect feeding may be localized to the site of damage or expressed systemically, mediated by signal transduction throughout the plant. Such systemic induction processes have been widely investigated in plants with single stems, but rarely in clonal plants comprised of multiple ramets with vascular connections. For a clonal tree species such as trembling aspen (Populus tremuloides Michx), integration of induced defense within clones could be adaptive, as clones are spatially extensive and susceptible to outbreak herbivores. We used pairs of aspen saplings with shared roots, replicated from three genotypes, to determine whether defense-induction signals are communicated within clones. One ramet in each pair was subjected to a damage treatment (feeding by Lymantria dispar, followed by mechanical damage), and subsequent changes in leaf defensive chemistry were measured in both ramets. Responses to damage varied by defense type: condensed tannins (CTs) increased in damaged ramets but not in connected undamaged ramets, whereas salicinoid phenolic glycosides (SPGs) were not induced in any ramets. Genotypes varied in their levels of CTs, but not in their levels of SPGs, and responded similarly to damage treatment. These results suggest that, even with both vascular and volatile information available, young aspen ramets do not induce defenses based on signals or metabolites from other ramets. Thus, unlike other clonal plant species, aspen do not appear to coordinate defense induction within clones. Lack of coordinated early induction in aspen may be related to the function of CTs in tolerance, rather than resistance.

Published

2018

26. Genotypic variation in plant traits shapes herbivorous insect and ant communities on a foundation tree species.

Author

Barker HL, Holeski LM, and Lindroth RL

Subjects

Animals, Eating, Phenotype, Ants physiology, Genetic Variation, Genotype, Herbivory, Populus physiology, Trees physiology

Abstract

Community genetics aims to understand the effects of intraspecific genetic variation on community composition and diversity, thereby connecting community ecology with evolutionary biology. Multiple studies have shown that different plant genotypes harbor different communities of associated organisms, such as insects. Yet, the mechanistic links that tie insect community composition to plant genetics are still not well understood. To shed light on these relationships, we explored variation in both plant traits (e.g., growth, phenology, defense) and herbivorous insect and ant communities on 328 replicated aspen (Populus tremuloides) genets grown in a common garden. We measured traits and visually surveyed insect communities annually in 2014 and 2015. We found that insect communities overall exhibited low heritability and were shaped primarily by relationships among key insects (i.e., aphids, ants, and free-feeders). Several tree traits affected insect communities and the presence/absence of species and functional groups. Of these traits, tree size and foliar phenology were the most important. Larger trees had denser (i.e., number of insects per unit tree size) and more diverse insect communities, while timing of bud break and bud set differentially influenced particular species and insect groups, especially leaf modifying insects. These findings will inform future research directed toward identification of plant genes and genetic regions that underlie the structure of associated insect communities., Competing Interests: The authors have declared that no competing interests exist.

Published

2018

27. Genetic variation in aspen phytochemical patterns structures windows of opportunity for gypsy moth larvae.

Author

Falk MA, Lindroth RL, Keefover-Ring K, and Raffa KF

Subjects

Animals, Genetic Variation, Larva, Phytochemicals, Plant Leaves, Moths, Populus

Abstract

Empirical studies indicate that host-tree bud break will likely advance faster than spring-folivore egg hatch in response to predicted increases in temperature. How these phenological shifts will affect herbivory will depend on temporal patterns of foliar traits that occur during leaf expansion, and their effects on folivore performance. Through fine-scale time series sampling of newly flushed trembling aspen (Populus tremuloides) foliage, we observed a previously unknown peak in phenolic glycoside concentrations that coincides with the emergence of sensitive neonates of gypsy moths and rapidly declines soon after bud break. The magnitude and duration of the initial post-bud break peak in phenolic glycosides varied substantially among genotypes. In contrast, foliar nitrogen concentrations declined at a more uniform rate among genotypes throughout leaf expansion. In addition, leaf toughness remained uniformly low throughout these periods of phytochemical change, and did not rise or vary substantially among genotypes until after anticipated windows of climate change-induced shifts between bud break and egg hatch had elapsed. Controlled manipulation of intervals between gypsy moth egg hatch and aspen bud break generated differences in larval performance among hatch cohorts and host genotypes that corresponded with changes in foliar phenolic glycoside and nitrogen concentrations. These findings indicate that the effects of climate change-induced phenological shifts on herbivory will differ among host plant genotypes, and that genetic variation in foliar chemical patterns will strongly influence this heterogeneity.

Published

2018

28. Large effect quantitative trait loci for salicinoid phenolic glycosides in Populus : Implications for gene discovery.

Author

Woolbright SA, Rehill BJ, Lindroth RL, DiFazio SP, Martinsen GD, Zinkgraf MS, Allan GJ, Keim P, and Whitham TG

Abstract

Genomic studies have been used to identify genes underlying many important plant secondary metabolic pathways. However, genes for salicinoid phenolic glycosides (SPGs)-ecologically important compounds with significant commercial, cultural, and medicinal applications-remain largely undescribed. We used a linkage map derived from a full-sib population of hybrid cottonwoods ( Populus spp.) to search for quantitative trait loci (QTL) for the SPGs salicortin and HCH-salicortin. SSR markers and primer sequences were used to anchor the map to the V3.0 P. trichocarpa genome. We discovered 21 QTL for the two traits, including a major QTL for HCH-salicortin ( R 2  = .52) that colocated with a QTL for salicortin on chr12. Using the V3.0 Populus genome sequence, we identified 2,983 annotated genes and 1,480 genes of unknown function within our QTL intervals. We note ten candidate genes of interest, including a BAHD-type acyltransferase that has been potentially linked to Populus SPGs. Our results complement other recent studies in Populus with implications for gene discovery and the evolution of defensive chemistry in a model genus. To our knowledge, this is the first study to use a full-sib mapping population to identify QTL intervals and gene lists associated with SPGs.

Published

2018

29. Vernal freeze damage and genetic variation alter tree growth, chemistry, and insect interactions.

Author

Rubert-Nason KF, Couture JJ, Gryzmala EA, Townsend PA, and Lindroth RL

Subjects

Analysis of Variance, Animals, Biomass, Genotype, Least-Squares Analysis, Populus parasitology, Trees parasitology, Aphids physiology, Freezing, Genetic Variation, Populus genetics, Populus growth & development, Trees genetics, Trees growth & development

Abstract

Anticipated consequences of climate change in temperate regions include early spring warmup punctuated by intermittent hard freezes. Warm weather accelerates leaf flush in perennial woody species, potentially exposing vulnerable young tissues to damaging frosts. We employed a 2 × 6 randomized factorial design to examine how the interplay of vernal (springtime) freeze damage and genetic variation in a hardwood species (Populus tremuloides) influences tree growth, phytochemistry, and interactions with an insect herbivore (Chaitophorus stevensis). Acute effects of freezing included defoliation and mortality. Surviving trees exhibited reduced growth and altered biomass distribution. Reflushed leaves on these trees had lower mass per area, lower lignin concentrations, and higher nitrogen concentrations, altered chemical defence profiles, and supported faster aphid population growth. Many effects varied among plant genotypes and were related with herbivore performance. This study suggests that a single damaging vernal freeze event can alter tree-insect interactions through effects on plant growth and chemistry. Differential responses of various genotypes to freeze damage suggest that more frequent vernal freeze events could also influence natural selection, favouring trees with greater freeze hardiness, and more resistance or tolerance to herbivores following damage., (© 2017 John Wiley & Sons Ltd.)

Published

2017

30. Genetic Modification of Lignin in Hybrid Poplar (Populus alba × Populus tremula) Does Not Substantially Alter Plant Defense or Arthropod Communities.

Author

Buhl C, Meilan R, and Lindroth RL

Subjects

Animals, Arthropods, Biodiversity, Herbivory, Lignin genetics, Populus genetics

Abstract

Lignin impedes access to cellulose during biofuel production and pulping but trees can be genetically modified to improve processing efficiency. Modification of lignin may have nontarget effects on mechanical and chemical resistance and subsequent arthropod community responses with respect to pest susceptibility and arthropod biodiversity. We quantified foliar mechanical and chemical resistance traits in lignin-modified and wild-type (WT) poplar (Populus alba × Populus tremula) grown in a plantation and censused arthropods present on these trees to determine total abundance, as well as species richness, diversity and community composition. Our results indicate that mechanical resistance was not affected by lignin modification and only one genetic construct resulted in a (modest) change in chemical resistance. Arthropod abundance and community composition were consistent across modified and WT trees, but transgenics produced using one construct exhibited higher species richness and diversity relative to the WT. Our findings indicate that modification of lignin in poplar does not negatively affect herbivore resistance traits or arthropod community response, and may even result in a source of increased genetic diversity in trees and arthropod communities., (© The Authors 2017. Published by Oxford University Press on behalf of Entomological Society of America.)

Published

2017

31. Effects of Elevated Atmospheric Carbon Dioxide and Tropospheric Ozone on Phytochemical Composition of Trembling Aspen ( Populus tremuloides ) and Paper Birch ( Betula papyrifera ).

Author

Couture JJ, Meehan TD, Rubert-Nason KF, and Lindroth RL

Subjects

Betula metabolism, Carbohydrate Metabolism drug effects, Lignin metabolism, Nitrogen metabolism, Phenols metabolism, Plant Leaves drug effects, Plant Leaves metabolism, Populus metabolism, Tannins metabolism, Betula drug effects, Carbon Dioxide pharmacology, Ozone pharmacology, Phytochemicals metabolism, Populus drug effects

Abstract

Anthropogenic activities are altering levels of atmospheric carbon dioxide (CO 2 ) and tropospheric ozone (O 3 ). These changes can alter phytochemistry, and in turn, influence ecosystem processes. We assessed the individual and combined effects of elevated CO 2 and O 3 on the phytochemical composition of two tree species common to early successional, northern temperate forests. Trembling aspen (Populus tremuloides) and paper birch (Betula papyrifera) were grown at the Aspen FACE (Free-Air Carbon dioxide and ozone Enrichment) facility under four combinations of ambient and elevated CO 2 and O 3 . We measured, over three years (2006-08), the effects of CO 2 and O 3 on a suite of foliar traits known to influence forest functioning. Elevated CO 2 had minimal effect on foliar nitrogen and carbohydrate levels in either tree species, and increased synthesis of condensed tannins and fiber in aspen, but not birch. Elevated O 3 decreased nitrogen levels in both tree species and increased production of sugar, condensed tannins, fiber, and lignin in aspen, but not birch. The magnitude of responses to elevated CO 2 and O 3 varied seasonally for both tree species. When co-occurring, CO 2 offset most of the changes in foliar chemistry expressed under elevated O 3 alone. Our results suggest that levels of CO 2 and O 3 predicted for the mid-twenty-first century will alter the foliar chemistry of northern temperate forests with likely consequences for forest community and ecosystem dynamics.

Published

2017

32. Heterozygosity, gender, and the growth-defense trade-off in quaking aspen.

Author

Cole CT, Stevens MT, Anderson JE, and Lindroth RL

Subjects

Environment, Heterozygote, Trees, Plant Leaves, Populus genetics

Abstract

Although plant growth is generally recognized to be influenced by allocation to defense, genetic background (e.g., inbreeding), and gender, rarely have those factors been addressed collectively. In quaking aspen (Populus tremuloides Michx.), phenolic glycosides (PGs) and condensed tannins (CTs) constitute up to 30 % of leaf dry weight. To quantify the allocation cost of this chemical defense, we measured growth, defense chemistry, and individual heterozygosity (H obs at 16 microsatellite loci) for male and female trees in both controlled and natural environments. The controlled environment consisted of 12 juvenile genets grown for 3 years in a common garden, with replication. The natural environment consisted of 51 mature genets in wild populations, from which we sampled multiple ramets (trees) per genet. Concentrations of PGs and CTs were negatively correlated. PGs were uncorrelated with growth, but CT production represented a major cost. Across the range of CT levels found in wild-grown trees, growth rates varied by 2.6-fold, such that a 10 % increase in CT concentration occurred with a 38.5 % decrease in growth. H obs had a marked effect on aspen growth: for wild trees, a 10 % increase in H obs corresponded to a 12.5 % increase in growth. In wild trees, this CT effect was significant only in females, in which reproduction seems to exacerbate the cost of defense, while the H obs effect was significant only in males. Despite the lower growth rate of low-H obs trees, their higher CT levels may improve survival, which could account for the deficit of heterozygotes repeatedly found in natural aspen populations.

Published

2016

33. Interactions between Bacteria And Aspen Defense Chemicals at the Phyllosphere - Herbivore Interface.

Author

Mason CJ, Lowe-Power TM, Rubert-Nason KF, Lindroth RL, and Raffa KF

Subjects

Animals, Trees microbiology, Acinetobacter physiology, Herbivory, Moths microbiology, Phytochemicals metabolism, Trees physiology

Abstract

Plant- and insect-associated microorganisms encounter a diversity of allelochemicals, and require mechanisms for contending with these often deleterious and broadly-acting compounds. Trembling aspen, Populus tremuloides, contains two principal groups of defenses, phenolic glycosides (salicinoids) and condensed tannins, which differentially affect the folivorous gypsy moth, Lymantria dispar, and its gut symbionts. The bacteria genus Acinetobacter is frequently associated with both aspen foliage and gypsy moth consuming that tissue, and one isolate, Acinetobacter sp. R7-1, previously has been shown to metabolize phenolic glycosides. In this study, we aimed to characterize further interactions between this Acinetobacter isolate and aspen secondary metabolites. We assessed bacterial carbon utilization and growth in response to different concentrations of phenolic glycosides and condensed tannins. We also tested if enzyme inhibitors reduce bacterial growth and catabolism of phenolic glycosides. Acinetobacter sp. R7-1 utilized condensed tannins but not phenolic glycosides or glucose as carbon sources. Growth in nutrient-rich medium was increased by condensed tannins, but reduced by phenolic glycosides. Addition of the P450 enzyme inhibitor piperonyl butoxide increased the effects of phenolic glycosides on Acinetobacter sp. R7-1. In contrast, the esterase inhibitor S,S,S,-tributyl-phosphorotrithioate did not affect phenolic glycoside inhibition of bacterial growth. Degradation of phenolic glycosides by Acinetobacter sp. R7-1 appears to alleviate the cytotoxicity of these compounds, rather than provide an energy source. Our results further suggest this bacterium utilizes additional, complementary mechanisms to degrade antimicrobial phytochemicals. Collectively, these results provide insight into mechanisms by which microorganisms contend with their environment within the context of plant-herbivore interactions.

Published

2016

34. Rapid modulation of ultraviolet shielding in plants is influenced by solar ultraviolet radiation and linked to alterations in flavonoids.

Author

Barnes PW, Tobler MA, Keefover-Ring K, Flint SD, Barkley AE, Ryel RJ, and Lindroth RL

Subjects

Abelmoschus physiology, Acclimatization, Circadian Rhythm, Flavonoids physiology, Hibiscus physiology, Solanum lycopersicum physiology, Plant Epidermis physiology, Plant Epidermis radiation effects, Plant Leaves physiology, Plant Leaves radiation effects, Sunlight, Ultraviolet Rays, Vicia faba physiology, Zea mays physiology, Abelmoschus radiation effects, Flavonoids radiation effects, Hibiscus radiation effects, Solanum lycopersicum radiation effects, Vicia faba radiation effects, Zea mays radiation effects

Abstract

The accumulation of ultraviolet (UV)-absorbing compounds (flavonoids and related phenylpropanoids) and the resultant decrease in epidermal UV transmittance (TUV ) are primary protective mechanisms employed by plants against potentially damaging solar UV radiation and are critical components of the overall acclimation response of plants to changing solar UV environments. Whether plants can adjust this UV sunscreen protection in response to rapid changes in UV, as occurs on a diurnal basis, is largely unexplored. Here, we use a combination of approaches to demonstrate that plants can modulate their UV-screening properties within minutes to hours, and these changes are driven, in part, by UV radiation. For the cultivated species Abelmoschus esculentus, large (30-50%) and reversible changes in TUV occurred on a diurnal basis, and these adjustments were associated with changes in the concentrations of whole-leaf UV-absorbing compounds and several quercetin glycosides. Similar results were found for two other species (Vicia faba and Solanum lycopersicum), but no such changes were detected in Zea mays. These findings reveal a much more dynamic UV-protection mechanism than previously recognized, raise important questions concerning the costs and benefits of UV-protection strategies in plants and have practical implications for employing UV to enhance crop vigor and quality in controlled environments., (© 2015 John Wiley & Sons Ltd.)

Published

2016

35. Condensed tannins increase nitrogen recovery by trees following insect defoliation.

Author

Madritch MD and Lindroth RL

Subjects

Analysis of Variance, Animals, Genotype, Herbivory, Isotope Labeling, Nitrogen Isotopes, Populus genetics, Moths physiology, Nitrogen metabolism, Plant Leaves physiology, Populus physiology, Proanthocyanidins metabolism, Trees physiology

Abstract

While the importance of plant secondary metabolites to belowground functioning is gaining recognition, the perception remains that secondary metabolites are produced for herbivore defense, whereas their belowground impacts are ecological by-products, or 'afterlife' effects. However, plants invest a significant amount of resources into production of secondary metabolites that have minimal effects on herbivore resistance (e.g. condensed tannins and insect herbivores). We show that genetically mediated variation in condensed tannin concentration is correlated with plant nitrogen recovery following a severe defoliation event. We used single-tree mesocosms labeled with (15) N to track nitrogen through both the frass and litter cycling pathways. High concentrations of leaf tannins in Populus tremuloides were correlated with (15) N recovery from frass within the same growing season and in the following growing season. Likewise, leaf tannin concentrations were also correlated with (15) N recovery from the litter of defoliated trees in the growing season following the defoliation event. Conversely, tannins were not well correlated with nitrogen uptake under conditions of nominal herbivory. Our results suggest that tannins may confer benefits in response to herbivore pressure through conserved belowground nitrogen cycling, rather than via defensive properties. Consequently, tannins may be considered as chemical mediators of tolerance rather than resistance., (© 2015 The Authors. New Phytologist © 2015 New Phytologist Trust.)

Published

2015

36. Influence of Genotype, Environment, and Gypsy Moth Herbivory on Local and Systemic Chemical Defenses in Trembling Aspen (Populus tremuloides).

Author

Rubert-Nason KF, Couture JJ, Major IT, Constabel CP, and Lindroth RL

Subjects

Animals, Genome, Plant, Moths growth & development, Nitrogen analysis, Nitrogen metabolism, Phytochemicals analysis, Phytochemicals genetics, Phytochemicals metabolism, Plant Leaves chemistry, Plant Leaves genetics, Plant Leaves physiology, Populus chemistry, Populus genetics, Soil chemistry, Tannins analysis, Tannins genetics, Tannins metabolism, Herbivory, Moths physiology, Populus physiology

Abstract

Numerous studies have explored the impacts of intraspecific genetic variation and environment on the induction of plant chemical defenses by herbivory. Relatively few, however, have considered how those factors affect within-plant distribution of induced defenses. This work examined the impacts of plant genotype and soil nutrients on the local and systemic phytochemical responses of trembling aspen (Populus tremuloides) to defoliation by gypsy moth (Lymantria dispar). We deployed larvae onto foliage on individual tree branches for 15 days and then measured chemistry in leaves from: 1) branches receiving damage, 2) undamaged branches of insect-damaged trees, and 3) branches of undamaged control trees. The relationship between post-herbivory phytochemical variation and insect performance also was examined. Plant genotype, soil nutrients, and damage all influenced phytochemistry, with genotype and soil nutrients being stronger determinants than damage. Generally, insect damage decreased foliar nitrogen, increased levels of salicinoids and condensed tannins, but had little effect on levels of a Kunitz trypsin inhibitor, TI3. The largest damage-mediated tannin increases occurred in leaves on branches receiving damage, whereas the largest salicinoid increases occurred in leaves of adjacent, undamaged branches. Foliar nitrogen and the salicinoid tremulacin had the strongest positive and negative relationships, respectively, with insect growth. Overall, plant genetics and environment concomitantly influenced both local and systemic phytochemical responses to herbivory. These findings suggest that herbivory can contribute to phytochemical heterogeneity in aspen foliage, which may in turn influence future patterns of herbivory and nutrient cycling over larger spatial scales.

Published

2015

37. Experimental climate warming alters aspen and birch phytochemistry and performance traits for an outbreak insect herbivore.

Author

Jamieson MA, Schwartzberg EG, Raffa KF, Reich PB, and Lindroth RL

Abstract

Climate change and insect outbreaks are key factors contributing to regional and global patterns of increased tree mortality. While links between these environmental stressors have been established, our understanding of the mechanisms by which elevated temperature may affect tree-insect interactions is limited. Using a forest warming mesocosm, we investigated the influence of elevated temperature on phytochemistry, tree resistance traits, and insect performance. Specifically, we examined warming effects on forest tent caterpillar (Malacosoma disstria) and host trees aspen (Populus tremuloides) and birch (Betula papyrifera). Trees were grown under one of three temperature treatments (ambient, +1.7 °C, +3.4 °C) in a multiyear open-air warming experiment. In the third and fourth years of warming (2011, 2012), we assessed foliar nutrients and defense chemistry. Elevated temperatures altered foliar nitrogen, carbohydrates, lignin, and condensed tannins, with differences in responses between species and years. In 2012, we performed bioassays using a common environment approach to evaluate plant-mediated indirect warming effects on larval performance. Warming resulted in decreased food conversion efficiency and increased consumption, ultimately with minimal effect on larval development and biomass. These changes suggest that insects exhibited compensatory feeding due to reduced host quality. Within the context of observed phytochemical variation, primary metabolites were stronger predictors of insect performance than secondary metabolites. Between-year differences in phytochemical shifts corresponded with substantially different weather conditions during these two years. By sampling across years within an ecologically realistic and environmentally open setting, our study demonstrates that plant and insect responses to warming can be temporally variable and context dependent. Results indicate that elevated temperatures can alter phytochemistry, tree resistance traits, and herbivore feeding, but that annual weather variability may modulate warming effects leading to uncertain consequences for plant-insect interactions with projected climate change., (© 2015 John Wiley & Sons Ltd.)

Published

2015

38. Insect herbivory alters impact of atmospheric change on northern temperate forests.

Author

Couture JJ, Meehan TD, Kruger EL, and Lindroth RL

Abstract

Stimulation of forest productivity by elevated concentrations of CO2 is expected to partially offset continued increases in anthropogenic CO2 emissions. However, multiple factors can impair the capacity of forests to act as carbon sinks; prominent among these are tropospheric O3 and nutrient limitations(1,2). Herbivorous insects also influence carbon and nutrient dynamics in forest ecosystems, yet are often ignored in ecosystem models of forest productivity. Here we assess the effects of elevated levels of CO2 and O3 on insect-mediated canopy damage and organic matter deposition in aspen and birch stands at the Aspen FACE facility in northern Wisconsin, United States. Canopy damage was markedly higher in the elevated CO2 stands, as was the deposition of organic substrates and nitrogen. The opposite trends were apparent in the elevated O3 stands. Using a light-use efficiency model, we show that the negative impacts of herbivorous insects on net primary production more than doubled under elevated concentrations of CO2, but decreased under elevated concentrations of O3. We conclude that herbivorous insects may limit the capacity of forests to function as sinks for anthropogenic carbon emissions in a high CO2 world.

Published

2015

39. Aspen defense chemicals influence midgut bacterial community composition of gypsy moth.

Author

Mason CJ, Rubert-Nason KF, Lindroth RL, and Raffa KF

Subjects

Acinetobacter genetics, Animals, Genotype, Glucosides analysis, Herbivory physiology, Larva microbiology, Phenols analysis, Plant Leaves chemistry, Plant Leaves microbiology, Populus genetics, RNA, Ribosomal, 16S, Ralstonia genetics, Tannins analysis, Digestive System microbiology, Moths microbiology, Populus chemistry, Populus physiology

Abstract

Microbial symbionts are becoming increasingly recognized as mediators of many aspects of plant - herbivore interactions. However, the influence of plant chemical defenses on gut associates of insect herbivores is less well understood. We used gypsy moth (Lymantria dispar L.), and differing trembling aspen (Populus tremuloides Michx.) genotypes that vary in chemical defenses, to assess the influence of foliar chemistry on bacterial communities of larval midguts. We evaluated the bacterial community composition of foliage, and of midguts of larvae feeding on those leaves, using next-generation high-throughput sequencing. Plant defense chemicals did not influence the composition of foliar communities. In contrast, both phenolic glycosides and condensed tannins affected the bacterial consortia of gypsy moth midguts. The two most abundant operational taxonomic units were classified as Ralstonia and Acinetobacter. The relative abundance of Ralstonia was higher in midguts than in foliage when phenolic glycoside concentrations were low, but lower in midguts when phenolic glycosides were high. In contrast, the relative abundance of Ralstonia was lower in midguts than in foliage when condensed tannin concentrations were low, but higher in midguts when condensed tannins were high. Acinetobacter showed a different relationship with host chemistry, being relatively more abundant in midguts than with foliage when condensed tannin concentrations were low, but lower in midguts when condensed tannins were high. Acinetobacter tended to have a greater relative abundance in midguts of insects feeding on genotypes with high phenolic glycoside concentrations. These results show that plant defense chemicals influence herbivore midgut communities, which may in turn influence host utilization.

Published

2015

40. Condensed tannin biosynthesis and polymerization synergistically condition carbon use, defense, sink strength and growth in Populus.

Author

Harding SA, Xue LJ, Du L, Nyamdari B, Lindroth RL, Sykes R, Davis MF, and Tsai CJ

Subjects

Carbon Sequestration, Chimera, Genotype, Glucosides metabolism, Glycosides metabolism, Metabolome, Nitrogen metabolism, Oligonucleotide Array Sequence Analysis, Phenethylamines metabolism, Phenols metabolism, Plant Leaves chemistry, Plant Leaves growth & development, Plant Leaves immunology, Plant Leaves metabolism, Polymerization, Populus chemistry, Populus growth & development, Populus immunology, Propanols metabolism, Carbon metabolism, Gene Expression Regulation, Plant, Populus metabolism, Proanthocyanidins metabolism

Abstract

The partitioning of carbon for growth, storage and constitutive chemical defenses is widely framed in terms of a hypothetical sink-source differential that varies with nutrient supply. According to this framework, phenolics accrual is passive and occurs in source leaves when normal sink growth is not sustainable due to a nutrient limitation. In assessing this framework, we present gene and metabolite evidence that condensed tannin (CT) accrual is strongest in sink leaves and sequesters carbon in a way that impinges upon foliar sink strength and upon phenolic glycoside (PG) accrual in Populus. The work was based on two Populus fremontii × angustifolia backcross lines with contrasting rates of CT accrual and growth, and equally large foliar PG reserves. However, foliar PG accrual was developmentally delayed in the high-CT, slow-growth line (SG), and nitrogen-limitation led to increased foliar PG accrual only in the low-CT, fast-growth line (FG). Metabolite profiling of developing leaves indicated comparatively carbon-limited amino acid metabolism, depletion of several Krebs cycle intermediates and reduced organ sink strength in SG. Gene profiling indicated that CT synthesis decreased as leaves expanded and PGs increased. A most striking finding was that the nitrogenous monoamine phenylethylamine accumulated only in leaves of SG plants. The potential negative impact of CT hyper-accumulation on foliar sink strength, as well as a mechanism for phenylethylamine involvement in CT polymerization in Populus are discussed. Starch accrual in source leaves and CT accrual in sink leaves of SG may both contribute to the maintenance of a slow-growth phenotype suited to survival in nutrient-poor habitats., (© The Author 2013. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2014

41. Herbivore-mediated material fluxes in a northern deciduous forest under elevated carbon dioxide and ozone concentrations.

Author

Meehan TD, Couture JJ, Bennett AE, and Lindroth RL

Subjects

Animals, Betula drug effects, Betula growth & development, Biomass, Carbon metabolism, Ecosystem, Environment, Forests, Herbivory, Host-Parasite Interactions, Nitrogen metabolism, Plant Leaves drug effects, Plant Leaves growth & development, Plant Leaves physiology, Plant Roots drug effects, Plant Roots growth & development, Plant Roots physiology, Populus drug effects, Populus growth & development, Soil, Trees, Betula physiology, Carbon Dioxide pharmacology, Insecta physiology, Ozone pharmacology, Photosynthesis, Populus physiology

Abstract

Anthropogenic changes in atmospheric carbon dioxide (CO2 ) and ozone (O3 ) are known to alter tree physiology and growth, but the cascading effects on herbivore communities and herbivore-mediated nutrient cycling are poorly understood. We sampled herbivore frass, herbivore-mediated greenfall, and leaf-litter deposition in temperate forest stands under elevated CO2 (c. 560 ppm) and O3 (c. 1.5× ambient), analyzed substrate chemical composition, and compared the quality and quantity of fluxes under multiple atmospheric treatments. Leaf-chewing herbivores fluxed 6.2 g m(-2)  yr(-1) of frass and greenfall from the canopy to the forest floor, with a carbon : nitrogen (C : N) ratio 32% lower than that of leaf litter. Herbivore fluxes of dry matter, C, condensed tannins, and N increased under elevated CO2 (35, 32, 63 and 39%, respectively), while fluxes of N decreased (18%) under elevated O3 . Herbivore-mediated dry matter inputs scaled across atmospheric treatments as a constant proportion of leaf-litter inputs. Increased fluxes under elevated CO2 were consistent with increased herbivore consumption and abundance, and with increased plant growth and soil respiration, previously reported for this experimental site. Results suggest that insect herbivory will reinforce other factors, such as photosynthetic rate and fine-root production, impacting C sequestration by forests in future environments., (© 2014 The Authors New Phytologist © 2014 New Phytologist Trust.)

Published

2014

42. Simulated climate warming alters phenological synchrony between an outbreak insect herbivore and host trees.

Author

Schwartzberg EG, Jamieson MA, Raffa KF, Reich PB, Montgomery RA, and Lindroth RL

Subjects

Animals, Larva physiology, Models, Statistical, Moths growth & development, Seasons, Temperature, Trees, Betula parasitology, Global Warming, Herbivory, Moths physiology, Populus parasitology

Abstract

As the world's climate warms, the phenologies of interacting organisms in seasonally cold environments may advance at differing rates, leading to alterations in phenological synchrony that can have important ecological consequences. For temperate and boreal species, the timing of early spring development plays a key role in plant-herbivore interactions and can influence insect performance, outbreak dynamics, and plant damage. We used a field-based, meso-scale free-air forest warming experiment (B4WarmED) to examine the effects of elevated temperature on the phenology and performance of forest tent caterpillar (Malacosoma disstria) in relation to the phenology of two host trees, aspen (Populus tremuloides) and birch (Betula papyrifera). Results of our 2-year study demonstrated that spring phenology advanced for both insects and trees, with experimentally manipulated increases in temperature of 1.7 and 3.4 °C. However, tree phenology advanced more than insect phenology, resulting in altered phenological synchrony. Specifically, we observed a decrease in the time interval between herbivore egg hatch and budbreak of aspen in both years and birch in one year. Moreover, warming decreased larval development time from egg hatch to pupation, but did not affect pupal mass. Larvae developed more quickly on aspen than birch, but pupal mass was not affected by host species. Our study reveals that warming-induced phenological shifts can alter the timing of ecological interactions across trophic levels. These findings illustrate one mechanism by which climate warming could mediate insect herbivore outbreaks, and also highlights the importance of climate change effects on trophic interactions.

Published

2014

43. Determination of salicinoids by micro-high-performance liquid chromatography and photodiode array detection.

Author

Rubert-Nason KF, Hedman CJ, Holeski LM, and Lindroth RL

Subjects

Benzyl Alcohols isolation & purification, Calibration, Glucosides analysis, Glucosides isolation & purification, Plant Extracts isolation & purification, Plant Leaves chemistry, Quality Control, Reproducibility of Results, Benzyl Alcohols chemistry, Chromatography, High Pressure Liquid methods, Glucosides chemistry, Plant Extracts chemistry, Populus chemistry

Abstract

Introduction: Plant-derived salicinoids (conjugates of glucose and salicylate phenolic moieties) are potent modulators of plant-herbivore interactions. We demonstrate the use of micro-high-performance liquid chromatography (μHPLC) with photodiode-array detection (DAD) for quantification of four salicinoids (salicin, salicortin, hydroxycyclohexen-on-oyl salicortin and tremulacin) in methanolic extracts of Populus., Objective: To develop and implement a solvent-conserving μHPLC method to quantify salicinoids in methanolic extracts of Populus tissue., Methods: Salicinoids were extracted from Populus tissue into methanol, filtered, and introduced to μHPLC. Extracted analytes were separated on a Zorbax SB C18-column with a binary gradient of methanol and water (with 2% tetrahydrofuran; 20 μL/min), and quantified by DAD (274 nm). We confirmed measurement reliability through standard addition, comparison with an accepted method, and assessment of chromatographic peak purity by ultraviolet absorbance spectra., Results: Method detection and quantification limits for the salicinoids as a percentage of dry leaf weight were as follows: salicin (0.1%, 0.2%), salicortin (0.001%, 0.02%), hydroxycyclohexen-on-oyl salicortin (0.02%, 0.06%) and tremulacin (0.0006%, 0.002%). Calibrations by external standardisation were linear over 1.5 orders of magnitude with acceptable accuracy and reproducibility., Conclusion: Micro-HPLC can serve as a solvent-conserving alternative to conventional HPLC for quantification of salicinoids in Populus tissue

Published

2014

44. Imaging spectroscopy links aspen genotype with below-ground processes at landscape scales.

Author

Madritch MD, Kingdon CC, Singh A, Mock KE, Lindroth RL, and Townsend PA

Subjects

DNA, Plant chemistry, DNA, Plant genetics, Discriminant Analysis, Genotype, Lignin analysis, Microsatellite Repeats genetics, North America, Plant Leaves chemistry, Populus chemistry, Soil Microbiology, Ecosystem, Genetic Variation genetics, Plant Leaves genetics, Populus genetics, Satellite Imagery methods, Soil chemistry

Abstract

Fine-scale biodiversity is increasingly recognized as important to ecosystem-level processes. Remote sensing technologies have great potential to estimate both biodiversity and ecosystem function over large spatial scales. Here, we demonstrate the capacity of imaging spectroscopy to discriminate among genotypes of Populus tremuloides (trembling aspen), one of the most genetically diverse and widespread forest species in North America. We combine imaging spectroscopy (AVIRIS) data with genetic, phytochemical, microbial and biogeochemical data to determine how intraspecific plant genetic variation influences below-ground processes at landscape scales. We demonstrate that both canopy chemistry and below-ground processes vary over large spatial scales (continental) according to aspen genotype. Imaging spectrometer data distinguish aspen genotypes through variation in canopy spectral signature. In addition, foliar spectral variation correlates well with variation in canopy chemistry, especially condensed tannins. Variation in aspen canopy chemistry, in turn, is correlated with variation in below-ground processes. Variation in spectra also correlates well with variation in soil traits. These findings indicate that forest tree species can create spatial mosaics of ecosystem functioning across large spatial scales and that these patterns can be quantified via remote sensing techniques. Moreover, they demonstrate the utility of using optical properties as proxies for fine-scale measurements of biodiversity over large spatial scales.

Published

2014

45. A high-resolution genetic map of yellow monkeyflower identifies chemical defense QTLs and recombination rate variation.

Author

Holeski LM, Monnahan P, Koseva B, McCool N, Lindroth RL, and Kelly JK

Subjects

Chromosomes, Plant, Genetic Linkage, Genotype, Inbreeding, Phenotype, Chromosome Mapping, Mimulus genetics, Quantitative Trait Loci, Quantitative Trait, Heritable, Recombination, Genetic

Abstract

Genotyping-by-sequencing methods have vastly improved the resolution and accuracy of genetic linkage maps by increasing both the number of marker loci as well as the number of individuals genotyped at these loci. Using restriction-associated DNA sequencing, we construct a dense linkage map for a panel of recombinant inbred lines derived from a cross between divergent ecotypes of Mimulus guttatus. We used this map to estimate recombination rate across the genome and to identify quantitative trait loci for the production of several secondary compounds (PPGs) of the phenylpropanoid pathway implicated in defense against herbivores. Levels of different PPGs are correlated across recombinant inbred lines suggesting joint regulation of the phenylpropanoid pathway. However, the three quantitative trait loci identified in this study each act on a distinct PPG. Finally, we map three putative genomic inversions differentiating the two parental populations, including a previously characterized inversion that contributes to life-history differences between the annual/perennial ecotypes., (Copyright © 2014 Holeski et al.)

Published

2014

46. Long-term exposure to elevated CO2 and O3 alters aspen foliar chemistry across developmental stages.

Author

Couture JJ, Holeski LM, and Lindroth RL

Subjects

Glycosides metabolism, Nitrogen metabolism, Proanthocyanidins metabolism, Time Factors, Carbon Dioxide pharmacology, Ozone pharmacology, Plant Leaves drug effects, Plant Leaves growth & development, Populus drug effects, Populus growth & development

Abstract

Anthropogenic activities are altering levels of greenhouse gases to the extent that multiple and diverse ecosystem processes are being affected. Two gases that substantially influence forest health are atmospheric carbon dioxide (CO2 ) and tropospheric ozone (O3 ). Plant chemistry will play an important role in regulating ecosystem processes in future environments, but little information exists about the longitudinal effects of elevated CO2 and O3 on phytochemistry, especially for long-lived species such as trees. To address this need, we analysed foliar chemical data from two genotypes of trembling aspen, Populus tremuloides, collected over 10 years of exposure to levels of CO2 and O3 predicted for the year 2050. Elevated CO2 and O3 altered both primary and secondary chemistry, and the magnitude and direction of the responses varied across developmental stages and between aspen genotypes. Our findings suggest that the effects of CO2 and O3 on phytochemical traits that influence forest processes will vary over tree developmental stages, highlighting the need to continue long-term, experimental atmospheric change research., (© 2013 John Wiley & Sons Ltd.)

Published

2014

47. Root chemistry in Populus tremuloides: effects of soil nutrients, defoliation, and genotype.

Author

Stevens MT, Gusse AC, and Lindroth RL

Subjects

Plant Leaves drug effects, Plant Leaves metabolism, Plant Roots drug effects, Populus drug effects, Genotype, Phytochemicals metabolism, Plant Leaves growth & development, Plant Roots metabolism, Populus genetics, Populus metabolism, Soil chemistry

Abstract

Although genetic, environmental, and G x E effects on aboveground phytochemistry have been well documented in trembling aspen (Populus tremuloides), little work has focused on the same factors affecting tissues underground. Belowground plant defenses are likely important mediators of root-feeding herbivores that can strongly influence plant fitness. We used a common garden of potted aspen trees to explore the individual and interactive effects of soil nutrient availability, foliar damage, genotype, and their interactions, on concentrations of phytochemicals in aspen roots. Our common garden experiment employed 12 aspen genotypes that were planted into either low- or high-nutrient soil environments. Half of the trees were subjected to defoliation for two successive years, while the others were protected from damage. At the end of the growing season after the second defoliation, we harvested the trees to obtain root samples for which we assessed levels of phenolic glycosides, condensed tannins, nitrogen, and starch. Phenolic glycosides were most affected by genotype, while the other root phytochemicals were most responsive to soil nutrient conditions. The effects of defoliation were observed in interaction with soil nutrient environment and/or genotype. Interestingly, the effect of defoliation on phenolic glycosides was mediated by soil nutrients, whereas the effect of defoliation on condensed tannins was observed in concert with effects of both soil nutrients and genotype. Comparison of data from this study with an earlier, related study revealed that concentrations of phenolic glycosides and condensed tannins are lower in roots than leaves, and less responsive to defoliation. That soil nutrient environment affects root phytochemical concentrations is not unexpected given the intimate association of roots and soil, but the complex interactions between soil nutrients, aboveground damage, and genotype, and their effects on root phytochemistry, are intriguing. Variation in root chemistry could have wide-reaching effects on soil microbial communities, nutrient cycling, and herbivores. Additionally, the response of phytochemicals to damage across organs can link different, spatially separated herbivores as they use different parts of the same plant resource.

Published

2014

48. Influence of global atmospheric change on the feeding behavior and growth performance of a mammalian herbivore, Microtus ochrogaster.

Author

Habeck CW and Lindroth RL

Subjects

Animals, Carbon Dioxide metabolism, Female, Fumigation, Least-Squares Analysis, Male, Ozone metabolism, Phytochemicals metabolism, Regression Analysis, Solidago chemistry, Solidago physiology, Species Specificity, Taraxacum chemistry, Taraxacum physiology, Arvicolinae growth & development, Arvicolinae physiology, Atmosphere chemistry, Herbivory physiology

Abstract

Global atmospheric change is influencing the quality of plants as a resource for herbivores. We investigated the impacts of elevated carbon dioxide (CO2) and ozone (O3) on the phytochemistry of two forbs, Solidago canadensis and Taraxacum officinale, and the subsequent feeding behavior and growth performance of weanling prairie voles (Microtus ochrogaster) feeding on those plants. Plants for the chemical analyses and feeding trials were harvested from the understory of control (ambient air), elevated CO2 (560 µl CO2 l(-1)), and elevated O3 (ambient × 1.5) rings at the Aspen FACE (Free Air CO2 Enrichment) site near Rhinelander, Wisconsin. We assigned individual voles to receive plants from only one FACE ring and recorded plant consumption and weanling body mass for seven days. Elevated CO2 and O3 altered the foliar chemistry of both forbs, but only female weanling voles on the O3 diet showed negative responses to these changes. Elevated CO2 increased the fiber fractions of both plant species, whereas O3 fumigation elicited strong responses among many phytochemical components, most notably increasing the carbon-to-nitrogen ratio by 40% and decreasing N by 26%. Consumption did not differ between plant species or among fumigation treatments. Male voles were unaffected by the fumigation treatments, whereas female voles grew 36% less than controls when fed O3-grown plants. These results demonstrate that global atmospheric change has the potential to affect the performance of a mammalian herbivore through changes in plant chemistry.

Published

2013

49. Patterns of phytochemical variation in Mimulus guttatus (yellow monkeyflower).

Author

Holeski LM, Keefover-Ring K, Bowers MD, Harnenz ZT, and Lindroth RL

Subjects

Animals, Biological Evolution, Butterflies drug effects, Butterflies growth & development, Butterflies physiology, Genetic Variation, Glucosides chemistry, Glucosides pharmacology, Glycosides chemistry, Glycosides pharmacology, Herbivory drug effects, Larva physiology, Mimulus genetics, Phenols chemistry, Phenols pharmacology, Phenotype, Pheromones pharmacology, Plant Leaves chemistry, Mimulus chemistry, Pheromones chemistry

Abstract

The search for general patterns in the production and allocation of plant defense traits will be facilitated by characterizing multivariate suites of defense, as well as by studying additional plant taxa, particularly those with available genomic resources. Here, we investigated patterns of genetic variation in phytochemical defenses (phenylpropanoid glycosides, PPGs) in Mimulus guttatus (yellow monkeyflower). We grew plants derived from several natural populations, consisting of multiple full-sibling families within each population, in a common greenhouse environment. We found substantial variation in the constitutive multivariate PPG phenotype and in constitutive levels of individual phytochemicals within plants (among leaves of different ages), within populations (among full-sibling families), and among populations. Populations consisting of annual plants generally, but not always, had lower concentrations of phytochemicals than did populations of perennial plants. Populations differed in their plastic response to artificial herbivory, both in the overall multivariate PPG phenotype and in the individual phytochemicals. The relationship between phytochemistry and another defense trait, trichomes, differed among populations. Finally, we demonstrated that one of the PPGs, verbascoside, acts as a feeding stimulant rather than a feeding deterrent for a specialist herbivore of M. guttatus, the buckeye caterpillar (Junonia coenia Nymphalidae). Given its available genetic resources, numerous, easily accessible natural populations, and patterns of genetic variation highlighted in this research, M. guttatus provides an ideal model system in which to test ecological and evolutionary theories of plant-herbivore interactions.

Published

2013

50. Rapid phytochemical analysis of birch (Betula) and poplar (Populus) foliage by near-infrared reflectance spectroscopy.

Author

Rubert-Nason KF, Holeski LM, Couture JJ, Gusse A, Undersander DJ, and Lindroth RL

Subjects

Nitrogen analysis, Starch analysis, Tannins analysis, Betula chemistry, Plant Extracts analysis, Plant Leaves chemistry, Populus chemistry, Spectroscopy, Near-Infrared methods

Abstract

Poplar (Populus) and birch (Betula) species are widely distributed throughout the northern hemisphere, where they are foundation species in forest ecosystems and serve as important sources of pulpwood. The ecology of these species is strongly linked to their foliar chemistry, creating demand for a rapid, inexpensive method to analyze phytochemistry. Our study demonstrates the feasibility of using near-infrared reflectance spectroscopy (NIRS) as an inexpensive, high-throughput tool for determining primary (e.g., nitrogen, sugars, starch) and secondary (e.g., tannins, phenolic glycosides) foliar chemistry of Populus and Betula species, and identifies conditions necessary for obtaining reliable quantitative data. We developed calibrations with high predictive power (residual predictive deviations ≤ 7.4) by relating phytochemical concentrations determined with classical analytical methods (e.g., spectrophotometric assays, liquid chromatography) to NIR spectra, using modified partial least squares regression. We determine that NIRS, although less sensitive and precise than classical methods for some compounds, provides useful predictions in a much faster, less expensive manner than do classical methods.

Published

2013