Climate warming drives Himalayan alpine plant growth and recruitment dynamics

Doležal, Jiří; Jandová, Veronika; Macek, Martin; Mudrák, Ondřej; Altman, Jan; Schweingruber, Fritz Hans; Liancourt, Pierre

doi:10.1111/1365-2745.13459

Cited by 38 publications

(27 citation statements)

References 69 publications

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“…Microscopic images of these sections were taken using Olympus BX53 microscope, Olympus DP73 camera and cellSense Entry 1.9 software. This enabled us both count the consecutive number of rings and measure the annual radial growth increments (Dolezal et al., 2020).…”

Section: Methodsmentioning

confidence: 99%

“…Data available from the Dryad Digital Repository https://doi.org/10.5061/dryad.ksn02v72k (Dolezal et al., 2020).…”

Section: Data Availability Statementmentioning

confidence: 99%

“…Given the overall small plant size and short path length for water transport from roots to leaves, the stomatal conductance limitation is less likely to explain the relative root prioritization in large alpine and subnival P. pamirica plants. Instead, there is probably additional mechanical stability gained from investing in roots to help reduce the risk of plant damage caused by frost heave and solifluction from repeated cycles of soil freezing and thawing (Neuner & Hacker, 2012), which poses a major challenge for larger plants in alpine and especially subnival zone (Dolezal et al, 2016(Dolezal et al, , 2020. We assume that both constant leaf fraction and root prioritization in large plants can significantly contribute to P. pamirica's long life span.…”

Section: Importance Of Plant Size and Age Interactions For Biomass mentioning

confidence: 99%

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Contrasting biomass allocation responses across ontogeny and stress gradients reveal plant adaptations to drought and cold

et al. 2020

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1. How plants allocate their biomass to different organs is essential to understanding plant adaptations and distributions. Overall, biomass allocation may follow fixed rules across taxa. They are also likely to exhibit substantial departure from these rules during ontogeny and in response to particular limiting factors to optimize their growth and maximize their survival. However, how plants adjust their allocation priorities depending on size and age across stress gradients remain largely unknown in wild populations. 2. We examined ontogenetic variation in biomass allocation in Himalayan forb Potentilla pamirica across its 5,250-5,900-m elevation range, between populations from dry steppe, wet alpine and cold subnival zone. We evaluated whether biomass allocation followed optimal partitioning or fixed allometric rules using organ mass in 1,019 individuals spanning 1-73 years. 3. We found shifting biomass fractions with plant size and age, supporting the optimal partitioning theory. Young plants (<10 years) allocated similar proportions of biomass to leaves, stems and roots, intermediate-aged plants (10-30 years) allocated more biomass to roots, while the oldest plants had 90% biomass in belowground stems. 4. Major developmental processes including secondary thickening, branching and flowering begin 10-15 years earlier under more thermally favourable steppe conditions. Young steppe plants are larger than alpine and subnival plants, but these differences disappear in plants aged ~30, and the oldest alpine and subnival plants are larger than steppe plants. 5. Plant age exerted significant control over biomass allocation after controlling for plant size. While in steppe plants the preference for stem biomass allocation increases with both size and age, for large alpine and subnival plants the stem prioritization decreases with age in favour of root and leaf mass fractions. We interpret root and leaf prioritization in older plants as a way to reduce carbon imbalances and the risk of frost damage to secure long life. 6. Our analyses rejected ontogenetically fixed allometry and instead found high variation in biomass allocation depending on age, size and environment, supporting optimal partitioning theory. The uneven allocation of resources to different structures and functions during ontogenesis reflects plant adaptations | 33 Functional Ecology DOLEZAL Et AL.

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Section: Methodsmentioning

confidence: 99%

“…Data available from the Dryad Digital Repository https://doi.org/10.5061/dryad.ksn02v72k (Dolezal et al., 2020).…”

Section: Data Availability Statementmentioning

confidence: 99%

Section: Importance Of Plant Size and Age Interactions For Biomass mentioning

confidence: 99%

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Contrasting biomass allocation responses across ontogeny and stress gradients reveal plant adaptations to drought and cold

et al. 2020

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“…However, little is known about the species-specific responses of plants to environmental change drivers, such as recent accelerated warming and frequent summer droughts (Brun et al, 2020; Dolezal et al, 2020). Moreover, while responses to current climate change are extensively documented in trees and shrubs (Francon et al, 2020; Altman et al, 2020), comprehensive assessments of long-term regeneration and growth responses to climate change are still rare in herbs, yet they encompass a vast majority of the plant species globally (Dee & Stambaugh, 2019; Dolezal et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…This makes it possible to directly trace past impacts of environmental fluctuations on plant performance several decades back (Büntgen et al, 2015). Nevertheless, to our knowledge, most research so far has focused on tree species, while only a few studies explored the potential of perennial dicot herbs in capturing the effects of environmental changes and extreme events on plant recruitment and growth dynamics (Dolezal et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

Climate fluctuations drive the recruitment and growth of temperate grassland plants

Doležal

Altman

Jandová

et al. 2021

Preprint

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Recent climate warming is associated with the increasing magnitude and frequency of extreme events, including heatwaves and drought periods worldwide. Such events can have major effects on the species composition of plant communities, hence on biodiversity and ecosystem functioning. Here we studied responses of Central European dry grassland plants to fluctuating temperature and precipitation over the last thirty years with monthly temporal resolution. We assessed the seasonal and annual dynamics of plant recruitment and growth based on the analysis of annual growth rings from the root collar. Although most studies so far applied such methods to trees and shrubs, we focused on typical grassland plants, two forbs and two chamaephytes. We related the recruitment and annual growth to monthly and annual precipitation, temperature and aridity between 1991 and 2019. We revealed species-specific responses, namely the (i) recruitment of deep-rooted, heavy-seeded species was positively affected by precipitation in both late winter-early spring and summer, whereas recruitment of shallow-rooted, light-seeded species was weakly influenced by climate fluctuations; (ii) growth of shallow-rooted species was more adversely affected by high summer temperature and drought than the growth of deep-rooted species. The population age structure of all the studied species was affected by the climate of the past decades. Most individuals established in the wet period of the 2000s, fewer in the precipitation-poorer 1990s, and the establishment was considerably reduced in the dry and warm period of the 2010s. Our findings indicate that the change towards warmer and drier climate has a profound effect even on drought-adapted ecosystems such as temperate dry grasslands. However, plant responses to various climatic extremes are species-specific, depending on their characteristics, such as life form or rooting depth. Consequently, the ongoing and anticipated climate warming will likely result in complex changes in species composition and other ecosystem properties of temperate grasslands.

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Alpine community recruitment potential is determined by habitat attributes in the alpine ecosystems of the Himalaya‐Hengduan Mountains, SW China

Chen

Qian

Zhang

et al. 2021

Ecology and Evolution

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Climate warming drives Himalayan alpine plant growth and recruitment dynamics

Cited by 38 publications

References 69 publications

Contrasting biomass allocation responses across ontogeny and stress gradients reveal plant adaptations to drought and cold

Contrasting biomass allocation responses across ontogeny and stress gradients reveal plant adaptations to drought and cold

Climate fluctuations drive the recruitment and growth of temperate grassland plants

Alpine community recruitment potential is determined by habitat attributes in the alpine ecosystems of the Himalaya‐Hengduan Mountains, SW China

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