Growth dynamics and climate sensitivities in alpine cushion plants: insights from Silene acaulis in the Swiss Alps

IF 2.6 3区 生物学 Q2 PLANT SCIENCES
Samresh Rai, Nikola Breme, Veronika Jandova, Vojtech Lanta, Jan Altman, Adam Taylor Ruka, Christian Rixen, Jiri Dolezal
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Abstract

Understanding alpine plants’ growth dynamics and responses to warming is essential for predicting climate change impacts on mountain ecosystems. Here, we examine growth determinants in the alpine cushion plant Silene acaulis in the Swiss Alps, exploring ontogeny, elevation, and climate influences. We collected 40 Silene individuals and 159 individuals from 38 co-occurring alpine species across 2200–3130 m elevations in the Swiss Alps, analyzing age and growth histories through annual growth rings. While comparing growth rates, we found that Silene was relatively slow-growing. However, Silene exhibited a dual growth strategy, initially rapid and then slowing after ~ 20 years, challenging perceptions of its longevity. Similar ontogenetic trends were observed in other alpine species, albeit with variations based on species and elevation. The consistent unimodal growth-elevation pattern in Silene and other alpine plants, peaking at ~ 2400 m, underscores shared environmental constraints on alpine plant growth. Additionally, cross-dating growth ring series and correlating with daily climate data enabled the precise assessment of warming impacts on growth. Silene’s growth is influenced by year-to-year climate variability, with warming-induced moisture stress and overheating during spring and summer adversely affecting its growth. Despite being low-statured, Silene is not completely decoupled from atmospheric influences. The heat-trapping function of Silene, effective in mature and well-formed cushions, makes it susceptible to adverse effects as temperatures rise. This sensitivity raises concerns about the potential dieback of Silene cushions, as witnessed during recent heatwaves, and emphasizes the broader ecological implications for alpine ecosystems, given Silene’s role as a crucial nurse plant.

Abstract Image

高山垫状植物的生长动态和气候敏感性:从瑞士阿尔卑斯山的 Silene acaulis 中获得的启示
了解高山植物的生长动态和对气候变暖的反应对于预测气候变化对山区生态系统的影响至关重要。在此,我们研究了瑞士阿尔卑斯山高山垫木植物 Silene acaulis 的生长决定因素,探讨了本体、海拔和气候的影响。我们在瑞士阿尔卑斯山海拔 2200 至 3130 米的地区采集了 40 个 Silene 个体和来自 38 个共生高山物种的 159 个个体,并通过年生长年轮分析了其年龄和生长历史。在比较生长速度时,我们发现 Silene 的生长速度相对较慢。然而,丝兰表现出双重生长策略,最初生长迅速,约 20 年后生长速度减慢,这对丝兰的长寿观念提出了挑战。在其他高山物种中也观察到了类似的个体发育趋势,只是因物种和海拔而异。丝兰和其他高山植物一致的单模生长-海拔模式(在海拔约 2400 米处达到顶峰)强调了高山植物生长的共同环境限制。此外,通过对生长环序列进行交叉定年并与每日气候数据进行关联,可以精确评估气候变暖对生长的影响。丝兰的生长受年与年之间气候多变性的影响,气候变暖引起的水分胁迫和春夏两季的过热对丝兰的生长产生了不利影响。尽管西番莲身材矮小,但它并没有完全脱离大气的影响。席琳的热捕捉功能在成熟和成形良好的垫层中很有效,这使其容易受到气温升高的不利影响。这种敏感性引起了人们对雪琳垫可能枯死的担忧,最近的热浪就证明了这一点,并强调了雪琳作为一种重要的哺乳植物对高山生态系统的广泛生态影响。
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来源期刊
Alpine Botany
Alpine Botany PLANT SCIENCES-
CiteScore
5.10
自引率
18.50%
发文量
15
审稿时长
>12 weeks
期刊介绍: Alpine Botany is an international journal providing a forum for plant science studies at high elevation with links to fungal and microbial ecology, including vegetation and flora of mountain regions worldwide.
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