Barbacenia graminifolia, a resurrection plant with high capacity of water retention

•Barbacenia graminifolia is a Brazilian resurrection plant.•B. graminifolia can be classified as poikilochlorophyllous.•Photosynthesis is affected only after severe water deficit.•Despite the partial return of carbon assimilation, fluorescence is fully recovered.•Long-term responses as a homoiohydri...

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Published in	Flora. Morphologie, Geobotanik, Oekophysiologie Vol. 267; p. 151604
Main Authors	do Nascimento, Alex, Suguiyama, Vanessa Fuentes, Sanches, Rodrigo Fazani Esteves, Braga, Marcia R., Silva, Emerson Alves da, Silva, João Paulo Naldi, Centeno, Danilo C.
Format	Journal Article
Language	English
Published	Elsevier GmbH 01.06.2020
Subjects	carbon dioxide fixation Carotenoids chlorophyll Chlorophyll a fluorescence Desiccation tolerance drought tolerance flora fluorescence gas exchange leaf relative water content Photosynthesis plant available water Poikilochlorophylly rehydration South America Velloziaceae water deprivation South America Poikilochlorophylly Chlorophyll a fluorescence Desiccation tolerance Carotenoids Photosynthesis Velloziaceae
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ISSN	0367-2530 1618-0585
DOI	10.1016/j.flora.2020.151604

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Abstract	•Barbacenia graminifolia is a Brazilian resurrection plant.•B. graminifolia can be classified as poikilochlorophyllous.•Photosynthesis is affected only after severe water deficit.•Despite the partial return of carbon assimilation, fluorescence is fully recovered.•Long-term responses as a homoiohydric plant. Desiccation tolerance (DT) in vegetative tissues is not a common ability, especially in Angiosperms. Barbacenia genus is distributed in tropical seasonally dry environments, such as rock outcrops, in South America. Some of the Barbacenia species are described as DT and are able to tolerate drastic water loss of their tissues during the desiccation process and to reestablish their metabolism after rehydration. In order to better understand this ability, we evaluated aspects related to leaf water status, gas exchange, photosynthetic pigments content and chlorophyll a fluorescence of B. graminifolia, during 32 days of water deprivation followed by rehydration. Carbon assimilation (A) remained active until the 24th day, when volumetric soil moisture was below 10%. Leaf relative water content (RWC) remained constant during 28 days of water withholding, decreasing significantly after this period, followed by the lowest gas exchange parameters and maximum quantum efficiency of photosystem II (Fv/Fm), and the highest degradation rates of chlorophyll and carotenoids in the course of the desiccation period. After rehydration, RWC was rapidly recovered, as well as Fv/Fm and photosynthetic parameters. This time frame was not enough for total recovery of A rates due, probably, to the slow restoration of chlorophyll a content. We classify, therefore, the species as a resurrection plant. Despite the similar decrease of photosynthetic rates found in other DT species before reaching the desiccated state, B. graminifolia maintains CO2 assimilation even under low soil water availability (10%) as physiological strategy when submitted to severe water deficit.
AbstractList	Desiccation tolerance (DT) in vegetative tissues is not a common ability, especially in Angiosperms. Barbacenia genus is distributed in tropical seasonally dry environments, such as rock outcrops, in South America. Some of the Barbacenia species are described as DT and are able to tolerate drastic water loss of their tissues during the desiccation process and to reestablish their metabolism after rehydration. In order to better understand this ability, we evaluated aspects related to leaf water status, gas exchange, photosynthetic pigments content and chlorophyll a fluorescence of B. graminifolia, during 32 days of water deprivation followed by rehydration. Carbon assimilation (A) remained active until the 24th day, when volumetric soil moisture was below 10%. Leaf relative water content (RWC) remained constant during 28 days of water withholding, decreasing significantly after this period, followed by the lowest gas exchange parameters and maximum quantum efficiency of photosystem II (Fv/Fm), and the highest degradation rates of chlorophyll and carotenoids in the course of the desiccation period. After rehydration, RWC was rapidly recovered, as well as Fv/Fm and photosynthetic parameters. This time frame was not enough for total recovery of A rates due, probably, to the slow restoration of chlorophyll a content. We classify, therefore, the species as a resurrection plant. Despite the similar decrease of photosynthetic rates found in other DT species before reaching the desiccated state, B. graminifolia maintains CO₂ assimilation even under low soil water availability (10%) as physiological strategy when submitted to severe water deficit. •Barbacenia graminifolia is a Brazilian resurrection plant.•B. graminifolia can be classified as poikilochlorophyllous.•Photosynthesis is affected only after severe water deficit.•Despite the partial return of carbon assimilation, fluorescence is fully recovered.•Long-term responses as a homoiohydric plant. Desiccation tolerance (DT) in vegetative tissues is not a common ability, especially in Angiosperms. Barbacenia genus is distributed in tropical seasonally dry environments, such as rock outcrops, in South America. Some of the Barbacenia species are described as DT and are able to tolerate drastic water loss of their tissues during the desiccation process and to reestablish their metabolism after rehydration. In order to better understand this ability, we evaluated aspects related to leaf water status, gas exchange, photosynthetic pigments content and chlorophyll a fluorescence of B. graminifolia, during 32 days of water deprivation followed by rehydration. Carbon assimilation (A) remained active until the 24th day, when volumetric soil moisture was below 10%. Leaf relative water content (RWC) remained constant during 28 days of water withholding, decreasing significantly after this period, followed by the lowest gas exchange parameters and maximum quantum efficiency of photosystem II (Fv/Fm), and the highest degradation rates of chlorophyll and carotenoids in the course of the desiccation period. After rehydration, RWC was rapidly recovered, as well as Fv/Fm and photosynthetic parameters. This time frame was not enough for total recovery of A rates due, probably, to the slow restoration of chlorophyll a content. We classify, therefore, the species as a resurrection plant. Despite the similar decrease of photosynthetic rates found in other DT species before reaching the desiccated state, B. graminifolia maintains CO2 assimilation even under low soil water availability (10%) as physiological strategy when submitted to severe water deficit.
ArticleNumber	151604
Author	Centeno, Danilo C. Suguiyama, Vanessa Fuentes Silva, João Paulo Naldi do Nascimento, Alex Sanches, Rodrigo Fazani Esteves Braga, Marcia R. Silva, Emerson Alves da
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Keywords	Poikilochlorophylly Chlorophyll a fluorescence Desiccation tolerance Carotenoids Photosynthesis Velloziaceae
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Snippet	•Barbacenia graminifolia is a Brazilian resurrection plant.•B. graminifolia can be classified as poikilochlorophyllous.•Photosynthesis is affected only after... Desiccation tolerance (DT) in vegetative tissues is not a common ability, especially in Angiosperms. Barbacenia genus is distributed in tropical seasonally dry...
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SubjectTerms	carbon dioxide fixation Carotenoids chlorophyll Chlorophyll a fluorescence Desiccation tolerance drought tolerance flora fluorescence gas exchange leaf relative water content Photosynthesis plant available water Poikilochlorophylly rehydration South America Velloziaceae water deprivation
Title	Barbacenia graminifolia, a resurrection plant with high capacity of water retention
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