Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field?

Kazemi-Dinan A, Sauer J, Stein RJ, Krämer U, Müller C (2015)
Oecologia 178(2): 369-378.

Zeitschriftenaufsatz | Veröffentlicht | Englisch
 
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DOI
Autor*in
Kazemi-Dinan, ArdeshirUniBi; Sauer, JanUniBi; Stein, RJ; Krämer, U; Müller, CarolineUniBi
Einrichtung
Fakultät für Biologie > Chemische Ökologie
Abstract / Bemerkung
Several plant species are able to not only tolerate but also hyperaccumulate heavy metals in their aboveground tissues. Thus, in addition to secondary metabolites acting as organic defences, metal hyperaccumulators possess an elemental defence that can act as protection against antagonists. Whereas several laboratory studies have determined potential relationships or trade-offs between organic and inorganic defences, little is known about whether these traits are interconnected in the field and which factors determine the compositions of organic defences and elements of leaf tissues most. To target these questions, we collected young leaves of Arabidopsis halleri, a Brassicaceae capable of hyperaccumulating Cd and Zn, as well as soil samples in the field from 16 populations. We detected wide variation in the composition of glucosinolates-the characteristic secondary metabolites of this plant family-among plants, with two distinct chemotypes occurring. Distance-based redundancy analyses revealed that variation in glucosinolate composition was determined mainly by population affiliation and to a lesser degree by geographic distance. Likewise, elemental composition of the leaves was mainly influenced by the location at which samples were collected. Therefore, the particular abiotic and biotic conditions and potential genetic relatedness at a particular locality affect the plant tissue chemistry. A slight indication of a trade-off between glucosinolate-based organic and inorganic defences was found, but only in the less abundant chemotype. A large variation in defence composition and potential joint effects of different defences may be highly adaptive ways of protecting against a wide arsenal of biotic antagonists.
Stichworte
Metal hyperaccumulation; Glucosinolates; Trade-off; Joint effects
Erscheinungsjahr
2015
Zeitschriftentitel
Oecologia
Band
178
Ausgabe
2
Seite(n)
369-378
ISSN
0029-8549
Page URI
https://pub.uni-bielefeld.de/record/2710299

Zitieren

Kazemi-Dinan A, Sauer J, Stein RJ, Krämer U, Müller C. Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field? Oecologia. 2015;178(2):369-378.
Kazemi-Dinan, A., Sauer, J., Stein, R. J., Krämer, U., & Müller, C. (2015). Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field? Oecologia, 178(2), 369-378. doi:10.1007/s00442-014-3218-x
Kazemi-Dinan, Ardeshir, Sauer, Jan, Stein, RJ, Krämer, U, and Müller, Caroline. 2015. “Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field?”. Oecologia 178 (2): 369-378.
Kazemi-Dinan, A., Sauer, J., Stein, R. J., Krämer, U., and Müller, C. (2015). Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field? Oecologia 178, 369-378.
Kazemi-Dinan, A., et al., 2015. Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field? Oecologia, 178(2), p 369-378.
A. Kazemi-Dinan, et al., “Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field?”, Oecologia, vol. 178, 2015, pp. 369-378.
Kazemi-Dinan, A., Sauer, J., Stein, R.J., Krämer, U., Müller, C.: Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field? Oecologia. 178, 369-378 (2015).
Kazemi-Dinan, Ardeshir, Sauer, Jan, Stein, RJ, Krämer, U, and Müller, Caroline. “Is there a trade-off between glucosinolate-based organic and inorganic defences in a metal hyperaccumulator in the field?”. Oecologia 178.2 (2015): 369-378.

7 Zitationen in Europe PMC

Daten bereitgestellt von Europe PubMed Central.

Analysis of ambient temperature-responsive transcriptome in shoot apical meristem of heat-tolerant and heat-sensitive broccoli inbred lines during floral head formation.
Lin CW, Fu SF, Liu YJ, Chen CC, Chang CH, Yang YW, Huang HJ., BMC Plant Biol 19(1), 2019
PMID: 30606114
Variation in defence strategies in the metal hyperaccumulator plant Noccaea caerulescens is indicative of synergies and trade-offs between forms of defence.
Fones HN, Preston GM, Smith JAC., R Soc Open Sci 6(1), 2019
PMID: 30800336
Effect of Cadmium Accumulation on the Performance of Plants and of Herbivores That Cope Differently With Organic Defenses.
Godinho DP, Serrano HC, Da Silva AB, Branquinho C, Magalhães S., Front Plant Sci 9(), 2018
PMID: 30546373
Zinc hyperaccumulation substitutes for defense failures beyond salicylate and jasmonate signaling pathways of Alternaria brassicicola attack in Noccaea caerulescens.
Gallego B, Martos S, Cabot C, Barceló J, Poschenrieder C., Physiol Plant 159(4), 2017
PMID: 27734509
Effects of Cd, Zn or Pb stress in Populus alba berolinensis on the development and reproduction of Lymantria dispar.
Jiang D, Yan S., Ecotoxicology 26(10), 2017
PMID: 28951982
Local adaptation is associated with zinc tolerance in Pseudomonas endophytes of the metal-hyperaccumulator plant Noccaea caerulescens.
Fones HN, McCurrach H, Mithani A, Smith JA, Preston GM., Proc Biol Sci 283(1830), 2016
PMID: 27170725
The Footprint of Polygenic Adaptation on Stress-Responsive Cis-Regulatory Divergence in the Arabidopsis Genus.
He F, Arce AL, Schmitz G, Koornneef M, Novikova P, Beyer A, de Meaux J., Mol Biol Evol 33(8), 2016
PMID: 27189540

55 References

Daten bereitgestellt von Europe PubMed Central.

Seasonal variation in leaf glucosinolates and insect resistance in two types of Barbarea vulgaris ssp. arcuata.
Agerbirk N, Olsen CE, Nielsen JK., Phytochemistry 58(1), 2001
PMID: 11524118

MJ, Austral Ecol 26(), 2001

MJ, 2004
Metabolic and evolutionary costs of herbivory defense: systems biology of glucosinolate synthesis.
Bekaert M, Edger PP, Hudson CM, Pires JC, Conant GC., New Phytol. 196(2), 2012
PMID: 22943527
Ontogenic profiling of glucosinolates, flavonoids, and other secondary metabolites in Eruca sativa (salad rocket), Diplotaxis erucoides (wall rocket), Diplotaxis tenuifolia (wild rocket), and Bunias orientalis (Turkish rocket).
Bennett RN, Rosa EA, Mellon FA, Kroon PA., J. Agric. Food Chem. 54(11), 2006
PMID: 16719527
Ecology of metal hyperaccumulation.
Boyd RS., New Phytol. 162(3), 2004
PMID: IND43668240

R, Plant Soil 293(), 2007
Plant defense using toxic inorganic ions: Conceptual models of the defensive enhancement and joint effects hypotheses
Boyd RS., Plant Sci. 195(), 2012
PMID: IND44785249
Exploring tradeoffs in hyperaccumulator ecology and evolution.
Boyd RS., New Phytol. 199(4), 2013
PMID: 23909800
Abiotic induction of changes to glucosinolate profiles in Brassica species and increased resistance to the specialist aphid Brevicoryne brassicae.
Cole R., Entomol. Exp. Appl. 80(1), 1996
PMID: IND20537281

TW, HortScience 39(), 2004

AUTHOR UNKNOWN, 0
Strategies of heavy metal uptake by three plant species growing near a metal smelter.
Dahmani-Muller H, van Oort F, Gelie B, Balabane M., Environ. Pollut. 109(2), 2000
PMID: 15092894
Dynamics of Ni-based defence and organic defences in the Ni hyperaccumulator, Streptanthus polygaloides (Brassicaceae).
Davis MA, Boyd RS., New Phytol. 146(2), 2000
PMID: IND22059236
Role of phytohormones in insect-specific plant reactions.
Erb M, Meldau S, Howe GA., Trends Plant Sci. 17(5), 2012
PMID: 22305233

AUTHOR UNKNOWN, 0
Interaction of heavy metals with the sulphur metabolism in angiosperms from an ecological point of view.
Ernst WH, Krauss GJ, Verkleij JA, Wesenberg D., Plant Cell Environ. 31(1), 2007
PMID: 17999660
The chemical diversity and distribution of glucosinolates and isothiocyanates among plants.
Fahey JW, Zalcmann AT, Talalay P., Phytochemistry 56(1), 2001
PMID: 11198818

HN, Plant Pathol 62(), 2013

C, Comput J 41(), 1998
Root herbivores and detritivores shape above-ground multitrophic assemblage through plant-mediated effects.
Megias AG, Muller C., J Anim Ecol 79(4), 2010
PMID: 20302605
Biology and biochemistry of glucosinolates.
Halkier BA, Gershenzon J., Annu Rev Plant Biol 57(), 2006
PMID: 16669764
Biotic element analysis in biogeography.
Hausdorf B, Hennig C., Syst. Biol. 52(5), 2003
PMID: 14530138
Species delimitation using dominant and codominant multilocus markers.
Hausdorf B, Hennig C., Syst. Biol. 59(5), 2010
PMID: 20693311

AUTHOR UNKNOWN, 0
Genome-wide transcriptome profiling of the early cadmium response of Arabidopsis roots and shoots.
Herbette S, Taconnat L, Hugouvieux V, Piette L, Magniette ML, Cuine S, Auroy P, Richaud P, Forestier C, Bourguignon J, Renou JP, Vavasseur A, Leonhardt N., Biochimie 88(11), 2006
PMID: 16797112
Role of glucosinolates in insect-plant relationships and multitrophic interactions.
Hopkins RJ, van Dam NM, van Loon JJ., Annu. Rev. Entomol. 54(), 2009
PMID: 18811249

EM, Plant Ecol 183(), 2006
Zinc and cadmium hyperaccumulation act as deterrents towards specialist herbivores and impede the performance of a generalist herbivore.
Kazemi-Dinan A, Thomaschky S, Stein RJ, Kramer U, Muller C., New Phytol. 202(2), 2014
PMID: 24383491

AUTHOR UNKNOWN, 0
Intraspecific plant chemical diversity and its relation to herbivory.
Kleine S, Muller C., Oecologia 166(1), 2010
PMID: 21053017
Evolution and genetic differentiation among relatives of Arabidopsis thaliana.
Koch MA, Matschinger M., Proc. Natl. Acad. Sci. U.S.A. 104(15), 2007
PMID: 17404224

J, Psychometrika 29(), 1964
The dose-dependent influence of zinc and cadmium contamination of soil on their uptake and glucosinolate content in white cabbage (Brassica oleracea var. capitata f. alba).
Kusznierewicz B, Baczek-Kwinta R, Bartoszek A, Piekarska A, Huk A, Manikowska A, Antonkiewicz J, Namiesnik J, Konieczka P., Environ. Toxicol. Chem. 31(11), 2012
PMID: 22886927

P, Ecol Monogr 69(), 1999
Endogenous jasmonic and salicylic acids levels in the Cd-hyperaccumulator Noccaea (Thlaspi) praecox exposed to fungal infection and/or mechanical stress.
Llugany M, Martin SR, Barcelo J, Poschenrieder C., Plant Cell Rep. 32(8), 2013
PMID: 23539290

W, Acta Physiol Plant 29(), 2007

AUTHOR UNKNOWN, 0

J, Environ Exp Bot 105(), 2014
Do metal-rich plants deter herbivores? A field test of the defence hypothesis.
Noret N, Meerts P, Vanhaelen M, Dos Santos A, Escarre J., Oecologia 152(1), 2007
PMID: 17216212

P, 2010
Heavy metal hyperaccumulating plants: How and why do they do it? And what makes them so interesting
Rascio N, Navari-Izzo F., Plant Sci. 180(2), 2011
PMID: IND44469827

AUTHOR UNKNOWN, 0

AUTHOR UNKNOWN, 0

SY, Trends Ecol Evol 17(), 2002

XM, Water Air Soil Poll 200(), 2009

S, Phytochem Rev 8(), 2009
Influence of zinc hyperaccumulation on glucosinolates in Thlaspi caerulescens.
Tolra RP, Poschenrieder C, Alonso R, Barcelo D, Barcelo J., New Phytol. 151(3), 2001
PMID: IND23236723

R, Plant Soil 288(), 2006

N, Funct Ecol 22(), 2008

NM, Phytochem Rev 8(), 2009

A, Plant Soil 362(), 2013
A heritable glucosinolate polymorphism within natural populations of Barbarea vulgaris.
van Leur H, Raaijmakers CE, van Dam NM., Phytochemistry 67(12), 2006
PMID: 16777152
Factors affecting the glucosinolate content of kale (Brassica oleracea acephala group).
Velasco P, Cartea ME, Gonzalez C, Vilar M, Ordas A., J. Agric. Food Chem. 55(3), 2007
PMID: 17263499

AS, Plant Soil 281(), 2006
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