Variation of vegetative and floral traits in the alpine plant Solidago minuta: evidence for local optimum along an elevational gradient

Kiełtyk, Piotr

doi:10.1007/s00035-017-0197-7

Cited by 17 publications

(15 citation statements)

References 59 publications

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“…In the current study, we found a significant decrease in plant height of both species of Roscoea ( R. alpina and R. purpurea ) with increased elevation. Reduction of plant height in these alpine gingers with increased elevation is consistent with several previous findings reported for tree species (Körner, 1998; Cordell et al, 1998; Kronfus & Havranek, 1999; Paulsen, Weber & Korner, 2000; Kogami et al, 2001; Li, Yang & Kräuchi, 2003; Shi et al, 2006) and herbaceous species (Takahashi & Matsuki, 2017; Kiełtyk, 2018). Similarly, a decrease of leaf length of R. alpina with the increased elevation in the current study is consistent with the previous findings (Hansen-Bristow, 1986; Schoettle, 1990; Kajimoto, 1993; Kao & Chang, 2001; Kiełtyk, 2018).…”

Section: Discussionsupporting

confidence: 92%

“…Although several previous studies have documented the effects of elevational gradient on the growth, morphology and physiology of the plants, most of the studies are focused on tree species (Cordell et al, 1998; Hultine & Marshall, 2000; Li et al, 2008). Recently a few studies have been conducted to understand how the elevational gradients affect the herbaceous plants (Gonzalo-Turpin & Hazard, 2009; Scheepens, Frei & Stöcklin, 2010; Hulshof et al, 2013; Bastida, Rey & Alcántara, 2015; Takahashi & Matsuki, 2017; Kiełtyk, 2018). These studies particularly focused on the variation of a specific trait, such as vegetative trait, reproductive trait or leaf trait.…”

Section: Introductionmentioning

confidence: 99%

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The effect of elevational gradient on alpine gingers (Roscoea alpina and R. purpurea) in the Himalayas

Paudel

Dyer

Garcia

et al. 2019

PeerJ

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There is currently enormous interest in how morphological and physiological responses of herbaceous plants may be affected by changing elevational gradient. Mountain regions provide an excellent opportunity to understand how closely related species may adapt to the conditions that rapidly change with elevation. We investigated the morphological and physiological responses of two Himalayan alpine gingers (Roscoea alpina and R. purpurea) along two different vertical transects of 400 m, R. purpurea between 2,174–2,574 m a.s.l and R. alpina between 2,675–3,079 m a.s.l. We measured the variables of plant height, leaf length, leaf area, specific leaf area, and stomata density at five plots, along the vertical transect at an elevational gap of ca. 100 m. Results revealed that with increased elevation plant height, and leaf area decreased while stomata density increased, whereas changes in specific leaf area, were not correlated with the elevation. Our results reveal that these alpine gingers undergo local adaptation by modifying their plant height, leaf area and stomata density in response to the varying selection pressure associated with the elevational gradient. Thus, the findings of this research provide valuable information on how a narrow range of elevational gradient affects the herbaceous plants at the alpine habitat of the Himalayas.

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Section: Discussionsupporting

confidence: 92%

Section: Introductionmentioning

confidence: 99%

The effect of elevational gradient on alpine gingers (Roscoea alpina and R. purpurea) in the Himalayas

Paudel

Dyer

Garcia

et al. 2019

PeerJ

View full text Add to dashboard Cite

show abstract

“…alpina with the increased elevation in the current study is consistent with the previous findings (Hansen-Bristow, 1986;Schoettle, 1990;Kajimoto, 1993;Kao & Chang, 2001;Kiełtyk, 2018).…”

Section: Variations Of Morphological Traits With Elevationsupporting

confidence: 93%

“…In the current study, we found a significant decrease in plant height of both species of Roscoea (R. alpina and R. purpurea) with increased elevation. Reduction of plant height in these alpine gingers with increased elevation is consistent with several previous findings reported for tree species (Körner, 1998;Cordell et al, 1998;Kronfus & Havranek, 1999;Paulsen, Weber & Korner, 2000;Kogami et al, 2001;Li, Yang & Kräuchi, 2003;Shi et al, 2006) and herbaceous species (Takahashi & Matsuki, 2017;Kiełtyk, 2018). Similarly, a decrease of leaf length of R.…”

Section: Variations Of Morphological Traits With Elevationsupporting

confidence: 92%

Peer Review #1 of "The effect of elevational gradient on alpine gingers (Roscoea alpina and R. purpurea) in the Himalayas (v0.1)"

2019

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There is currently enormous interest in how morphological and physiological responses of herbaceous plants may be affected by changing elevational gradient. Mountain regions provide an excellent opportunity to understand how closely related species may adapt to the conditions that rapidly change with elevation. We investigated the morphological and physiological responses of two Himalayan alpine gingers (Roscoea alpina and R. purpurea) along two different vertical transects of 400 m, R. purpurea between 2174-2574 m a.s.l and R. alpina between 2675-3079 m a.s.l. We measured the variables of plant height, leaf length, leaf area, specific leaf area, and stomata density at five plots, along the vertical transect at an elevational gap of ca. 100 m. Results revealed that with increased elevation plant height, and leaf area decreased while stomata density increased, whereas changes in specific leaf area, were not correlated with the elevation. Our results reveal that these alpine gingers undergo local adaptation by modifying their plant height, leaf area and stomata density in response to the varying selection pressure associated with the elevational gradient. Thus, the findings of this research provide valuable information on how a narrow range of elevational gradient affects the herbaceous plants at the alpine habitat of the Himalayas.

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“…Our current study illustrates a similar effect of snowmelt timing but also reveals spatial structuring of the community across the gradient that contributes to productivity differences. If species are able to locally shift upward in elevation ( Lenoir et al, 2008 ; Kiełtyk, 2017 ) or seek refuge in nearby microclimates (e.g., local depressions) where snowmelt changes are less pronounced ( Opedal et al, 2015 ), productivity changes will reflect both the immediate effects of earlier snowmelt and the longer term effects of community change.…”

Section: Discussionmentioning

confidence: 99%

Snowmelt Timing Regulates Community Composition, Phenology, and Physiological Performance of Alpine Plants

et al. 2018

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The spatial patterning of alpine plant communities is strongly influenced by the variation in physical factors such as temperature and moisture, which are strongly affected by snow depth and snowmelt patterns. Earlier snowmelt timing and greater soil-moisture limitations may favor wide-ranging species adapted to a broader set of ecohydrological conditions than alpine-restricted species. We asked how plant community composition, phenology, plant water relations, and photosynthetic gas exchange of alpine-restricted and wide-ranging species differ in their responses to a ca. 40-day snowmelt gradient in the Colorado Rocky Mountains (Lewisia pygmaea, Sibbaldia procumbens, and Hymenoxys grandiflora were alpine-restricted and Artemisia scopulorum, Carex rupestris, and Geum rossii were wide-ranging species). As hypothesized, species richness and foliar cover increased with earlier snowmelt, due to a greater abundance of wide-ranging species present in earlier melting plots. Flowering initiation occurred earlier with earlier snowmelt for 12 out of 19 species analyzed, while flowering duration was shortened with later snowmelt for six species (all but one were wide-ranging species). We observed >50% declines in net photosynthesis from July to September as soil moisture and plant water potentials declined. Early-season stomatal conductance was higher in wide-ranging species, indicating a more competitive strategy for water acquisition when soil moisture is high. Even so, there were no associated differences in photosynthesis or transpiration, suggesting no strong differences between these groups in physiology. Our findings reveal that plant species with different ranges (alpine-restricted vs. wide-ranging) could have differential phenological and physiological responses to snowmelt timing and associated soil moisture dry-down, and that alpine-restricted species’ performance is more sensitive to snowmelt. As a result, alpine-restricted species may serve as better indicator species than their wide-ranging heterospecifics. Overall, alpine community composition and peak % cover are strongly structured by spatio-temporal patterns in snowmelt timing. Thus, near-term, community-wide changes (or variation) in phenology and physiology in response to shifts in snowmelt timing or rates of soil dry down are likely to be contingent on the legacy of past climate on community structure.

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Variation of vegetative and floral traits in the alpine plant Solidago minuta: evidence for local optimum along an elevational gradient

Cited by 17 publications

References 59 publications

The effect of elevational gradient on alpine gingers (Roscoea alpina and R. purpurea) in the Himalayas

The effect of elevational gradient on alpine gingers (Roscoea alpina and R. purpurea) in the Himalayas

Peer Review #1 of "The effect of elevational gradient on alpine gingers (Roscoea alpina and R. purpurea) in the Himalayas (v0.1)"

Snowmelt Timing Regulates Community Composition, Phenology, and Physiological Performance of Alpine Plants

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