Bulliform Cell‐Induced Leaf Curling Contributes to Water Loss and Water Potential Regulation of Bamboos During Dry Season
ABSTRACT A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water regulation mechanisms across bamboo species remain poorly understood. This study quantified the relative contributions of soil water‐u...
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| Published in | Physiologia plantarum Vol. 177; no. 4; pp. e70463 - n/a |
|---|---|
| Main Authors | , , , , , , , , , , |
| Format | Journal Article |
| Language | English |
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Oxford, UK
Blackwell Publishing Ltd
01.07.2025
Wiley Subscription Services, Inc |
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| Abstract | ABSTRACT
A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water regulation mechanisms across bamboo species remain poorly understood. This study quantified the relative contributions of soil water‐uptake depth, leaf water storage and retention capacity, and related anatomical traits to daytime and seasonal variations in leaf water potential across nine co‐occurring bamboo species. The results revealed that the studied bamboos obtained 50% of their water from soil depth shallower than 32 cm. The studied bamboo species have low saturated water content (SWC) and short‐to‐average leaf dehydration time to 70% of its SWC (T70 = 74.5–250.4 min). They exhibited large interspecific variation in dry‐season midday leaf water potential (Ψdry.md). Higher T70 (i.e., slow desiccation rate) was significantly correlated with less negative Ψdry.md, but Ψdry.md was not related to soil water‐uptake depth or leaf water storage. Leaf anatomy, curling rate, and curling intensity analyses demonstrated two complementary water regulation mechanisms: (1) high density of bulliform cells enabled rapid leaf curling under water deficit, resulting in high predawn water potential in the dry season; and (2) large bulliform cell aperture promoted intensive leaf area reduction during water stress, slowing water loss, thus enabling less negative Ψdry.md. This study provides evidence of the synergy between bulliform cell structures and leaf water retention capacity across bamboo species and their contribution to water regulation under drought stress, highlighting structural adaptations in the leaves of bamboos enabling their success in seasonal tropical forests. |
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| AbstractList | A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water regulation mechanisms across bamboo species remain poorly understood. This study quantified the relative contributions of soil water-uptake depth, leaf water storage and retention capacity, and related anatomical traits to daytime and seasonal variations in leaf water potential across nine co-occurring bamboo species. The results revealed that the studied bamboos obtained 50% of their water from soil depth shallower than 32 cm. The studied bamboo species have low saturated water content (SWC) and short-to-average leaf dehydration time to 70% of its SWC (T70 = 74.5-250.4 min). They exhibited large interspecific variation in dry-season midday leaf water potential (Ψdry.md). Higher T70 (i.e., slow desiccation rate) was significantly correlated with less negative Ψdry.md, but Ψdry.md was not related to soil water-uptake depth or leaf water storage. Leaf anatomy, curling rate, and curling intensity analyses demonstrated two complementary water regulation mechanisms: (1) high density of bulliform cells enabled rapid leaf curling under water deficit, resulting in high predawn water potential in the dry season; and (2) large bulliform cell aperture promoted intensive leaf area reduction during water stress, slowing water loss, thus enabling less negative Ψdry.md. This study provides evidence of the synergy between bulliform cell structures and leaf water retention capacity across bamboo species and their contribution to water regulation under drought stress, highlighting structural adaptations in the leaves of bamboos enabling their success in seasonal tropical forests.A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water regulation mechanisms across bamboo species remain poorly understood. This study quantified the relative contributions of soil water-uptake depth, leaf water storage and retention capacity, and related anatomical traits to daytime and seasonal variations in leaf water potential across nine co-occurring bamboo species. The results revealed that the studied bamboos obtained 50% of their water from soil depth shallower than 32 cm. The studied bamboo species have low saturated water content (SWC) and short-to-average leaf dehydration time to 70% of its SWC (T70 = 74.5-250.4 min). They exhibited large interspecific variation in dry-season midday leaf water potential (Ψdry.md). Higher T70 (i.e., slow desiccation rate) was significantly correlated with less negative Ψdry.md, but Ψdry.md was not related to soil water-uptake depth or leaf water storage. Leaf anatomy, curling rate, and curling intensity analyses demonstrated two complementary water regulation mechanisms: (1) high density of bulliform cells enabled rapid leaf curling under water deficit, resulting in high predawn water potential in the dry season; and (2) large bulliform cell aperture promoted intensive leaf area reduction during water stress, slowing water loss, thus enabling less negative Ψdry.md. This study provides evidence of the synergy between bulliform cell structures and leaf water retention capacity across bamboo species and their contribution to water regulation under drought stress, highlighting structural adaptations in the leaves of bamboos enabling their success in seasonal tropical forests. ABSTRACT A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water regulation mechanisms across bamboo species remain poorly understood. This study quantified the relative contributions of soil water‐uptake depth, leaf water storage and retention capacity, and related anatomical traits to daytime and seasonal variations in leaf water potential across nine co‐occurring bamboo species. The results revealed that the studied bamboos obtained 50% of their water from soil depth shallower than 32 cm. The studied bamboo species have low saturated water content (SWC) and short‐to‐average leaf dehydration time to 70% of its SWC (T70 = 74.5–250.4 min). They exhibited large interspecific variation in dry‐season midday leaf water potential (Ψdry.md). Higher T70 (i.e., slow desiccation rate) was significantly correlated with less negative Ψdry.md, but Ψdry.md was not related to soil water‐uptake depth or leaf water storage. Leaf anatomy, curling rate, and curling intensity analyses demonstrated two complementary water regulation mechanisms: (1) high density of bulliform cells enabled rapid leaf curling under water deficit, resulting in high predawn water potential in the dry season; and (2) large bulliform cell aperture promoted intensive leaf area reduction during water stress, slowing water loss, thus enabling less negative Ψdry.md. This study provides evidence of the synergy between bulliform cell structures and leaf water retention capacity across bamboo species and their contribution to water regulation under drought stress, highlighting structural adaptations in the leaves of bamboos enabling their success in seasonal tropical forests. A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water regulation mechanisms across bamboo species remain poorly understood. This study quantified the relative contributions of soil water-uptake depth, leaf water storage and retention capacity, and related anatomical traits to daytime and seasonal variations in leaf water potential across nine co-occurring bamboo species. The results revealed that the studied bamboos obtained 50% of their water from soil depth shallower than 32 cm. The studied bamboo species have low saturated water content (SWC) and short-to-average leaf dehydration time to 70% of its SWC (T = 74.5-250.4 min). They exhibited large interspecific variation in dry-season midday leaf water potential (Ψ ). Higher T (i.e., slow desiccation rate) was significantly correlated with less negative Ψ , but Ψ was not related to soil water-uptake depth or leaf water storage. Leaf anatomy, curling rate, and curling intensity analyses demonstrated two complementary water regulation mechanisms: (1) high density of bulliform cells enabled rapid leaf curling under water deficit, resulting in high predawn water potential in the dry season; and (2) large bulliform cell aperture promoted intensive leaf area reduction during water stress, slowing water loss, thus enabling less negative Ψ . This study provides evidence of the synergy between bulliform cell structures and leaf water retention capacity across bamboo species and their contribution to water regulation under drought stress, highlighting structural adaptations in the leaves of bamboos enabling their success in seasonal tropical forests. A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water regulation mechanisms across bamboo species remain poorly understood. This study quantified the relative contributions of soil water‐uptake depth, leaf water storage and retention capacity, and related anatomical traits to daytime and seasonal variations in leaf water potential across nine co‐occurring bamboo species. The results revealed that the studied bamboos obtained 50% of their water from soil depth shallower than 32 cm. The studied bamboo species have low saturated water content (SWC) and short‐to‐average leaf dehydration time to 70% of its SWC (T 70 = 74.5–250.4 min). They exhibited large interspecific variation in dry‐season midday leaf water potential (Ψ dry.md ). Higher T 70 (i.e., slow desiccation rate) was significantly correlated with less negative Ψ dry.md , but Ψ dry.md was not related to soil water‐uptake depth or leaf water storage. Leaf anatomy, curling rate, and curling intensity analyses demonstrated two complementary water regulation mechanisms: (1) high density of bulliform cells enabled rapid leaf curling under water deficit, resulting in high predawn water potential in the dry season; and (2) large bulliform cell aperture promoted intensive leaf area reduction during water stress, slowing water loss, thus enabling less negative Ψ dry.md . This study provides evidence of the synergy between bulliform cell structures and leaf water retention capacity across bamboo species and their contribution to water regulation under drought stress, highlighting structural adaptations in the leaves of bamboos enabling their success in seasonal tropical forests. A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water regulation mechanisms across bamboo species remain poorly understood. This study quantified the relative contributions of soil water‐uptake depth, leaf water storage and retention capacity, and related anatomical traits to daytime and seasonal variations in leaf water potential across nine co‐occurring bamboo species. The results revealed that the studied bamboos obtained 50% of their water from soil depth shallower than 32 cm. The studied bamboo species have low saturated water content (SWC) and short‐to‐average leaf dehydration time to 70% of its SWC (T70 = 74.5–250.4 min). They exhibited large interspecific variation in dry‐season midday leaf water potential (Ψdry.md). Higher T70 (i.e., slow desiccation rate) was significantly correlated with less negative Ψdry.md, but Ψdry.md was not related to soil water‐uptake depth or leaf water storage. Leaf anatomy, curling rate, and curling intensity analyses demonstrated two complementary water regulation mechanisms: (1) high density of bulliform cells enabled rapid leaf curling under water deficit, resulting in high predawn water potential in the dry season; and (2) large bulliform cell aperture promoted intensive leaf area reduction during water stress, slowing water loss, thus enabling less negative Ψdry.md. This study provides evidence of the synergy between bulliform cell structures and leaf water retention capacity across bamboo species and their contribution to water regulation under drought stress, highlighting structural adaptations in the leaves of bamboos enabling their success in seasonal tropical forests. |
| Author | Chen, Ya‐Jun Aritsara, Amy Ny Aina Zhang, Yong‐Jiang Zhang, Shu‐Bin Wei, Yang Yu, Jia‐Rui Han, Lu Zhao, Gao‐Juan Liu, Jia‐Bao Cao, Kun‐Fang Maenpuen, Phisamai |
| Author_xml | – sequence: 1 givenname: Amy Ny Aina orcidid: 0000-0001-9246-6577 surname: Aritsara fullname: Aritsara, Amy Ny Aina organization: Chinese Academy of Sciences – sequence: 2 givenname: Kun‐Fang surname: Cao fullname: Cao, Kun‐Fang organization: Guangxi University – sequence: 3 givenname: Yong‐Jiang surname: Zhang fullname: Zhang, Yong‐Jiang organization: University of Maine – sequence: 4 givenname: Lu surname: Han fullname: Han, Lu organization: Chinese Academy of Sciences – sequence: 5 givenname: Phisamai surname: Maenpuen fullname: Maenpuen, Phisamai organization: University of the Chinese Academy of Sciences – sequence: 6 givenname: Shu‐Bin surname: Zhang fullname: Zhang, Shu‐Bin organization: Chinese Academy of Sciences – sequence: 7 givenname: Gao‐Juan surname: Zhao fullname: Zhao, Gao‐Juan organization: Chinese Academy of Sciences – sequence: 8 givenname: Yang surname: Wei fullname: Wei, Yang organization: Chinese Academy of Sciences – sequence: 9 givenname: Jia‐Bao orcidid: 0000-0001-8373-3899 surname: Liu fullname: Liu, Jia‐Bao organization: Chinese Academy of Sciences – sequence: 10 givenname: Jia‐Rui surname: Yu fullname: Yu, Jia‐Rui organization: Chinese Academy of Sciences – sequence: 11 givenname: Ya‐Jun orcidid: 0000-0001-5753-5565 surname: Chen fullname: Chen, Ya‐Jun email: chenyj@xtbg.org.cn organization: Chinese Academy of Sciences |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/40831236$$D View this record in MEDLINE/PubMed |
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| Keywords | bamboo bulliform cells water potential water relations drought leaf curling climate change |
| Language | English |
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| Notes | Funding This work was supported by the National Natural Science Foundation of China (32371576, 32071735, W2433080, 41861144016); Yunnan Provincial Science and Technology Department (202403AM140010, 202501AT070486, 202501AS070174); Yunnan Revitalization Talents Support Plan (YNWR‐QNBJ‐2019177); Yunnan High‐end Foreign Expert Project to A.N.A.A. (XDYC‐GDWZ‐2024‐0018); the Youth Academic and Technical Leading Talent Reserve Program in Yunnan Province (202405AC350012); China Postdoctoral Science Foundation (2024M753473); and Yunnan “Caiyun” Postdoctoral program to A.N.A.A., P.M. and Y.W. CAS “Light of West China” Program of Chinese Academy of Sciences; the 14th Five‐Year Plan of the Xishuangbanna Tropical Botanical Garden, Chinese Academy of Sciences (XTBG‐1450101 and XTBG‐1450102). ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 14 content type line 23 |
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| PublicationTitle | Physiologia plantarum |
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A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the... A balanced water supply and demand is critical for plant growth and survival. Despite the ecological importance of bamboos in tropical ecosystems, the water... |
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| SubjectTerms | Bamboo bulliform cells climate change Dehydration Desiccation Drought Dry season Environmental regulations Leaf area leaf curling Leaves Moisture content Plant anatomy Plant growth Plant Leaves - anatomy & histology Plant Leaves - cytology Plant Leaves - physiology Poaceae - physiology Retention capacity Seasonal variations Seasons Soil - chemistry Soil depth Soil water Tropical forests Water Water - metabolism Water - physiology Water content Water deficit Water depth Water loss Water potential water relations Water shortages Water storage Water stress Water supply |
| Title | Bulliform Cell‐Induced Leaf Curling Contributes to Water Loss and Water Potential Regulation of Bamboos During Dry Season |
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