Provenance- and life-history stage-specific responses of the dwarf shrub Calluna vulgaris to elevated vapour pressure deficit

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Provenance- and life-history stage-specific responses of the dwarf shrub Calluna vulgaris to elevated vapour pressure deficit. / Ibe, Karin; Walmsley, David; Fichtner, Andreas et al.
in: Plant Ecology, Jahrgang 221, Nr. 12, 01.12.2020, S. 1219-1232.

Publikation: Beiträge in ZeitschriftenZeitschriftenaufsätzeForschungbegutachtet

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@article{796fd55ccf814b83a97721119bee4a52,
title = "Provenance- and life-history stage-specific responses of the dwarf shrub Calluna vulgaris to elevated vapour pressure deficit",
abstract = "Climate change may alter microscale-effective ecosystem properties such as atmospheric water vapour pressure, but consequences for plant growth are insufficiently understood. Within a northwest German heathland an open-top chamber experiment was established to analyse the effects of elevated vapour pressure deficit (eVPD) on growth responses of Calluna vulgaris considering both plant origin (Atlantic (AP), sub-Atlantic (SAP), sub-Continental (SCP)) and life-history stage (1-year vs. 10-year old plants). We hypothesised that the plants{\textquoteright} sensitivity to eVPD decreases (i) from AP to SCP and (ii) with progressing life-history stage. Elevated VPD caused a provenance-specific decrease of shoot increment whilst aboveground biomass productivity remained unaffected. AP and SAP responded with increasing belowground biomass δ 13C signatures to eVPD, whereas δ 13C values decreased for SCP. Moreover, eVPD increased and decreased belowground biomass δ 13C signatures of 1- and 10-year old plants, respectively. These responses to eVPD were related to differences in morphological-chemical traits and the plants{\textquoteright} trait plasticity in response to eVPD. SCP showed the highest aboveground tissue mass density and significantly increased tissue C:N ratios under eVPD. One-year old plants had a tenfold higher shoot:root ratio than 10-year old plants, making young plants more sensitive to eVPD. Our findings demonstrate that the atmospheric water status affects the morphology and physiology of Calluna independent of the soil water status. The results have implications for the conservation of heathlands under climate change: (i) SCP may constitute an appropriate ecotype for assisted migration-approaches, and (ii) management needs to weigh different options for heathland rejuvenation. ",
keywords = "Ecosystems Research, Climate change, VPD, d13C signature, C:N ratio, Open-top chamber, Climate change, VPD, δ13C signature, C:N ratio, Open-top chamber",
author = "Karin Ibe and David Walmsley and Andreas Fichtner and Heinz Coners and Christoph Leuschner and Werner H{\"a}rdtle",
year = "2020",
month = dec,
day = "1",
doi = "10.1007/s11258-020-01076-3",
language = "English",
volume = "221",
pages = "1219--1232",
journal = "Plant Ecology",
issn = "1385-0237",
publisher = "Springer Netherlands",
number = "12",

}

RIS

TY - JOUR

T1 - Provenance- and life-history stage-specific responses of the dwarf shrub Calluna vulgaris to elevated vapour pressure deficit

AU - Ibe, Karin

AU - Walmsley, David

AU - Fichtner, Andreas

AU - Coners, Heinz

AU - Leuschner, Christoph

AU - Härdtle, Werner

PY - 2020/12/1

Y1 - 2020/12/1

N2 - Climate change may alter microscale-effective ecosystem properties such as atmospheric water vapour pressure, but consequences for plant growth are insufficiently understood. Within a northwest German heathland an open-top chamber experiment was established to analyse the effects of elevated vapour pressure deficit (eVPD) on growth responses of Calluna vulgaris considering both plant origin (Atlantic (AP), sub-Atlantic (SAP), sub-Continental (SCP)) and life-history stage (1-year vs. 10-year old plants). We hypothesised that the plants’ sensitivity to eVPD decreases (i) from AP to SCP and (ii) with progressing life-history stage. Elevated VPD caused a provenance-specific decrease of shoot increment whilst aboveground biomass productivity remained unaffected. AP and SAP responded with increasing belowground biomass δ 13C signatures to eVPD, whereas δ 13C values decreased for SCP. Moreover, eVPD increased and decreased belowground biomass δ 13C signatures of 1- and 10-year old plants, respectively. These responses to eVPD were related to differences in morphological-chemical traits and the plants’ trait plasticity in response to eVPD. SCP showed the highest aboveground tissue mass density and significantly increased tissue C:N ratios under eVPD. One-year old plants had a tenfold higher shoot:root ratio than 10-year old plants, making young plants more sensitive to eVPD. Our findings demonstrate that the atmospheric water status affects the morphology and physiology of Calluna independent of the soil water status. The results have implications for the conservation of heathlands under climate change: (i) SCP may constitute an appropriate ecotype for assisted migration-approaches, and (ii) management needs to weigh different options for heathland rejuvenation.

AB - Climate change may alter microscale-effective ecosystem properties such as atmospheric water vapour pressure, but consequences for plant growth are insufficiently understood. Within a northwest German heathland an open-top chamber experiment was established to analyse the effects of elevated vapour pressure deficit (eVPD) on growth responses of Calluna vulgaris considering both plant origin (Atlantic (AP), sub-Atlantic (SAP), sub-Continental (SCP)) and life-history stage (1-year vs. 10-year old plants). We hypothesised that the plants’ sensitivity to eVPD decreases (i) from AP to SCP and (ii) with progressing life-history stage. Elevated VPD caused a provenance-specific decrease of shoot increment whilst aboveground biomass productivity remained unaffected. AP and SAP responded with increasing belowground biomass δ 13C signatures to eVPD, whereas δ 13C values decreased for SCP. Moreover, eVPD increased and decreased belowground biomass δ 13C signatures of 1- and 10-year old plants, respectively. These responses to eVPD were related to differences in morphological-chemical traits and the plants’ trait plasticity in response to eVPD. SCP showed the highest aboveground tissue mass density and significantly increased tissue C:N ratios under eVPD. One-year old plants had a tenfold higher shoot:root ratio than 10-year old plants, making young plants more sensitive to eVPD. Our findings demonstrate that the atmospheric water status affects the morphology and physiology of Calluna independent of the soil water status. The results have implications for the conservation of heathlands under climate change: (i) SCP may constitute an appropriate ecotype for assisted migration-approaches, and (ii) management needs to weigh different options for heathland rejuvenation.

KW - Ecosystems Research

KW - Climate change

KW - VPD

KW - d13C signature

KW - C:N ratio

KW - Open-top chamber

KW - Climate change

KW - VPD

KW - δ13C signature

KW - C:N ratio

KW - Open-top chamber

UR - http://www.scopus.com/inward/record.url?scp=85090305276&partnerID=8YFLogxK

UR - https://www.mendeley.com/catalogue/2111894f-16a5-38e9-8277-44cbf73cb447/

U2 - 10.1007/s11258-020-01076-3

DO - 10.1007/s11258-020-01076-3

M3 - Journal articles

VL - 221

SP - 1219

EP - 1232

JO - Plant Ecology

JF - Plant Ecology

SN - 1385-0237

IS - 12

ER -

DOI