Phenological responses to nitrogen and water addition are linked to plant growth patterns in a desert herbaceous community

Huang, Gang; Li, Chenhua; Li, Yan

doi:10.1002/ece3.4001

Cited by 35 publications

(30 citation statements)

References 69 publications

(114 reference statements)

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“…Many studies have shown that water plays an important role in driving plant phenology, such as budburst ( Hayden et al., 2010 ), green-up ( Zhang et al, 2005 ; Liu et al., 2013 ), flowering ( Crimmins et al., 2010 ; Lesica and Kittelson, 2010 ; Crimmins et al., 2011 ; Crimmins et al., 2013 ; Kigel et al., 2013 ; Sakkir et al., 2014 ; Huang et al., 2018 ), and fruiting ( Lotfi and Mohamed, 2006 ; Galindo et al., 2014 ), in water-limited ecosystems. However, most of these studies are focused on natural conditions, while the relationship between water increase and phenological events based on water addition experiments has not been explored, nor has the effects of water addition on branch phenology of desert plants.…”

Section: Discussionmentioning

confidence: 99%

“…Precipitation increases likely impose substantial impacts on plant phenology in these deserts in response to climate change. Few studies examined the effects of water addition on reproductive phenology of six annuals on the southern fringe of the Gurbantunggut Desert in northwestern China and the results were only based on a short-time manipulative experiment (Huang et al, 2018). The results showed that water addition consistently advanced both the flowering and fruiting time of four spring ephemerals; however, their effects on two spring-summer annuals were inconsistent, where advances were found in one species, while delays were found in another (Huang et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

“…The phenological responses of plants in desert ecosystems in particular are causing increasing concern (Ghazahfar, 1997;Ogle and Reynolds, 2004;Leeuwen et al, 2010;Kigel et al, 2013;Sakkir et al, 2014;Yan et al, 2016;Huang et al, 2018). Desert ecosystems cover approximately 30% of the land surface and are strongly controlled by water availability (Patrick et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

“…Few studies examined the effects of water addition on reproductive phenology of six annuals on the southern fringe of the Gurbantunggut Desert in northwestern China and the results were only based on a short-time manipulative experiment (Huang et al, 2018). The results showed that water addition consistently advanced both the flowering and fruiting time of four spring ephemerals; however, their effects on two spring-summer annuals were inconsistent, where advances were found in one species, while delays were found in another (Huang et al, 2018). Since this study only focused on ephemerals, it remains unknown how the desert plant phenology of dominant perennials responds to an increase in precipitation, especially long-term precipitation increases.…”

Section: Introductionmentioning

confidence: 99%

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Water Addition Prolonged the Length of the Growing Season of the Desert Shrub Nitraria tangutorum in a Temperate Desert

et al. 2020

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Climate models often predict that more extreme precipitation events will occur in arid and semiarid regions, where plant phenology is particularly sensitive to precipitation changes. To understand how increases in precipitation affect plant phenology, this study conducted a manipulative field experiment in a desert ecosystem of northwest China. In this study, a long-term in situ water addition experiment was conducted in a temperate desert in northwestern China. The following five treatments were used: natural rain plus an additional 0, 25, 50, 75, and 100% of the local mean annual precipitation. A series of phenological events, including leaf unfolding (onset, 30%, 50%, and end of leaf unfolding), cessation of new branch elongation (30, 50, and 90%), and leaf coloration (80% of leaves turned yellow), of the locally dominant shrub Nitraria tangutorum were observed from 2012 to 2018. The results showed that on average, over the seven-year-study and in all treatments water addition treatments advanced the spring phenology (30% of leaf unfolding) by 1.29-3.00 days, but delayed the autumn phenology (80% of leaves turned yellow) by 1.18-11.82 days. Therefore, the length of the growing season was prolonged by 2.11-13.68 days, and autumn phenology contributed more than spring phenology. In addition, water addition treatments delayed the cessation of new branch elongation (90%) by 5.82-12.61 days, and nonlinear relationships were found between the leaves yellowing (80% of leaves) and the amount of watering. Linear relationships were found between the cessation of new branch elongation (90%), the length of the growing season, and amount of water addition. The two response patterns to water increase indicated that predictions of phenological events in the future should not be based on one trend only.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Water Addition Prolonged the Length of the Growing Season of the Desert Shrub Nitraria tangutorum in a Temperate Desert

et al. 2020

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“…It also affects species distribution, community characteristics (Xu et al, 2007;Li et al, 2010), and plant zonation (Cooper et al, 2006;Rzepecki et al, 2011) by driving water availability (Liu et al, 2017). Precipitation patterns influence the aboveground net primary production of sand-fixing vegetation (Li and Zhao, 2017), community structure (Cheng et al, 2006), annual plant phenology (Huang et al, 2018), photosynthesis (Liu et al, 2012), and carbon cycle (Thomey et al, 2011). Dune mobility affects the settlement and expansion of desert plants (Hernández-Cordero et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Desert vegetation distribution and species-environment relationships in an oasis-desert ecotone of northwestern China

Zhao

et al. 2019

J. Arid Land

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Environmental heterogeneity significantly affects the structure of ecological communities. Exploring vegetation distribution and its relationship with environmental factors is essential to understanding the abiotic mechanism(s) driving vegetation succession, especially in the ecologically fragile areas. In this study, based on the quantitative analysis of plant community and environmental factors in 68 plots at 10 different transects in the Minqin oasis-desert ecotone (ODE) of northwestern China, we investigated desert vegetation distribution and species-environment relationships using multivariate analysis. Two-way indicator species analysis (TWINSPAN), detrended correspondence analysis (DCA), and canonical correspondence analysis (CCA) methods were used. A total of 28 species, belonging to 27 genera in 8 families, were identified. Chenopodiaceae, Zygophyllaceae, Gramineae, and Leguminosae were the largest families. Annual and perennial herbs accounted for 28.60% of the total number of plants, while shrubs (42.90%) were the most dominant. Nitraria tangutorum was the constructive species of the desert plant community. We divided the 68 plots surveyed in this study into 7 community types, according to the results of TWINSPAN. The distribution of these 7 communities in the DCA ordination graph showed that species with a similar ecotype were clustered together. Results of CCA indicated that groundwater was the dominant factor influencing vegetation distribution, while distance between plot and oasis (Dis) and soil electrical conductivity (EC) were the local second-order factors. Our study suggests that optimizing the utilization of groundwater in oases is key to controlling the degradation of desert vegetation. The favorable topographic conditions of sand dunes should be fully utilized for vegetal dune stabilization, and the influence of soil salinity on the selection of afforestation tree species should be considered.

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Evolutionary effects of nitrogen are not easily predicted from ecological responses

Waterton

Hammond

Lau

2022

American J of Botany

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Premise: Anthropogenic nitrogen (N) addition alters the abiotic and biotic environment, potentially leading to changes in patterns of natural selection (i.e., trait-fitness relationships) and the opportunity for selection (i.e., variance in relative fitness). Because N addition favors species with light acquisition strategies (e.g., tall species), we predicted that N would strengthen selection favoring those same traits. We also predicted that N could alter the opportunity for selection via its effects on mean fitness and/or competitive asymmetries. Methods: We quantified the strength of selection and the opportunity for selection in replicated populations of the annual grass Setaria faberi (giant foxtail) growing in a long-term N addition experiment. We also correlated these population-level parameters with community-level metrics to identify the proximate causes of N-mediated evolutionary effects. Results: N addition increased aboveground productivity, light asymmetry, and reduced species diversity. Contrary to expectations, N addition did not strengthen selection for trait values associated with higher light acquisition such as greater height and specific leaf area (SLA); rather, it strengthened selection favoring lower SLA. Light asymmetry and species diversity were associated with selection for height and SLA, suggesting a role for these factors in driving N-mediated selection. The opportunity for selection was not influenced by N addition but was negatively associated with species diversity. Conclusions: Our results indicate that anthropogenic N enrichment can affect evolutionary processes, but that evolutionary changes in plant traits within populations are unlikely to parallel the shifts in plant traits observed at the community level.

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Phenological responses to nitrogen and water addition are linked to plant growth patterns in a desert herbaceous community

Cited by 35 publications

References 69 publications

Water Addition Prolonged the Length of the Growing Season of the Desert Shrub Nitraria tangutorum in a Temperate Desert

Water Addition Prolonged the Length of the Growing Season of the Desert Shrub Nitraria tangutorum in a Temperate Desert

Desert vegetation distribution and species-environment relationships in an oasis-desert ecotone of northwestern China

Evolutionary effects of nitrogen are not easily predicted from ecological responses

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