Resource allocation strategies among vegetative growth, sexual reproduction, asexual reproduction and defense during growing season of Aconitum kusnezoffii Reichb

Resource allocation strategies among vegetative growth, sexual reproduction, asexual reproduction and defense during growing season of Aconitum kusnezoffii Reichb

SUMMARY Natural plants must actively allocate their limited resources for survival and reproduction. Although vegetative growth, sexual reproduction, asexual reproduction and defense are all basic processes in the life cycle of plants, the strategies used to allocate resources between these processe...

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Veröffentlicht in:The Plant journal : for cell and molecular biology 2021-02, Vol.105 (4), p.957-977
Hauptverfasser: Tang, Mingze, Zhao, Wei, Xing, Ming, Zhao, Jiaxin, Jiang, Zhang, You, Jian, Ni, Biao, Ni, Yuanbo, Liu, Chengbai, Li, Jiangnan, Chen, Xia
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Sprache:eng
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Accumulation
Aconitum
Aconitum kusnezoffii Reichb
Asexual reproduction
Asexuality
Defense
Dry matter
Flowering
Flowers
Gene expression
Growing season
lateral root (daughter root fuzi)
Life cycles
Metabolites
Morphology
Organic carbon
Photosynthesis
Reproduction
Reproduction (biology)
Resource allocation
secondary metabolite (SM)
Sexual reproduction
sexual–asexual reproduction
Total organic carbon
transcriptome
Transcriptomes
vegetative growth
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container_issue 4
container_start_page 957
container_title The Plant journal : for cell and molecular biology
container_volume 105
creator Tang, Mingze
Zhao, Wei
Xing, Ming
Zhao, Jiaxin
Jiang, Zhang
You, Jian
Ni, Biao
Ni, Yuanbo
Liu, Chengbai
Li, Jiangnan
Chen, Xia
description SUMMARY Natural plants must actively allocate their limited resources for survival and reproduction. Although vegetative growth, sexual reproduction, asexual reproduction and defense are all basic processes in the life cycle of plants, the strategies used to allocate resources between these processes are poorly understood. These processes are conspicuous in naturally grown Aconitum kusnezoffii Reichb., which makes it a suitable study subject. Here, the morphology, dry matter, total organic carbon, total nitrogen and aconitum alkaloid levels of shoot, principal root (PR) and lateral roots were measured throughout the growing season. Then, transcriptome and metabolite content analyses were performed. We found that vegetative growth began first. After vegetative growth ceased, sexual development began. Flower organ development was accompanied by increased photosynthesis and the PR consumed temporarily stored resources after flower formation. Asexual propagule development initiated earlier than sexual reproduction and kept accumulating resources after that. Development was slow before flower formation, mainly manifesting as increasing length; then, after flower formation it accelerated via enhanced material transport and accumulation. Defense compounds were maintained at low levels before flowering. In particular, the turnover of defense compounds was enhanced before and after flower bud emergence, providing resources for other processes. After flower formation, defense compounds were accumulated. The pattern found herein provides a vivid example for further studies on resource allocation strategies. The exciting finding that the PR, as a more direct storage site for photosynthate, is a buffer unit for resources, and that defense compounds can be reused for other processes, suggests a need to explore potential mechanisms. Significance Statement The pattern found herein provides a vivid example for further studies on resource allocation strategies among vegetative growth, sexual reproduction, asexual reproduction and defense. The exciting finding that the principal root, as a more direct storage site for photosynthate, is a buffer unit for resources, and that defense compounds can be reused for other processes (i.e., growth and reproduction) suggests a need to explore potential mechanisms.
doi_str_mv 10.1111/tpj.15080
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Although vegetative growth, sexual reproduction, asexual reproduction and defense are all basic processes in the life cycle of plants, the strategies used to allocate resources between these processes are poorly understood. These processes are conspicuous in naturally grown Aconitum kusnezoffii Reichb., which makes it a suitable study subject. Here, the morphology, dry matter, total organic carbon, total nitrogen and aconitum alkaloid levels of shoot, principal root (PR) and lateral roots were measured throughout the growing season. Then, transcriptome and metabolite content analyses were performed. We found that vegetative growth began first. After vegetative growth ceased, sexual development began. Flower organ development was accompanied by increased photosynthesis and the PR consumed temporarily stored resources after flower formation. Asexual propagule development initiated earlier than sexual reproduction and kept accumulating resources after that. Development was slow before flower formation, mainly manifesting as increasing length; then, after flower formation it accelerated via enhanced material transport and accumulation. Defense compounds were maintained at low levels before flowering. In particular, the turnover of defense compounds was enhanced before and after flower bud emergence, providing resources for other processes. After flower formation, defense compounds were accumulated. The pattern found herein provides a vivid example for further studies on resource allocation strategies. The exciting finding that the PR, as a more direct storage site for photosynthate, is a buffer unit for resources, and that defense compounds can be reused for other processes, suggests a need to explore potential mechanisms. Significance Statement The pattern found herein provides a vivid example for further studies on resource allocation strategies among vegetative growth, sexual reproduction, asexual reproduction and defense. 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Although vegetative growth, sexual reproduction, asexual reproduction and defense are all basic processes in the life cycle of plants, the strategies used to allocate resources between these processes are poorly understood. These processes are conspicuous in naturally grown Aconitum kusnezoffii Reichb., which makes it a suitable study subject. Here, the morphology, dry matter, total organic carbon, total nitrogen and aconitum alkaloid levels of shoot, principal root (PR) and lateral roots were measured throughout the growing season. Then, transcriptome and metabolite content analyses were performed. We found that vegetative growth began first. After vegetative growth ceased, sexual development began. Flower organ development was accompanied by increased photosynthesis and the PR consumed temporarily stored resources after flower formation. Asexual propagule development initiated earlier than sexual reproduction and kept accumulating resources after that. Development was slow before flower formation, mainly manifesting as increasing length; then, after flower formation it accelerated via enhanced material transport and accumulation. Defense compounds were maintained at low levels before flowering. In particular, the turnover of defense compounds was enhanced before and after flower bud emergence, providing resources for other processes. After flower formation, defense compounds were accumulated. The pattern found herein provides a vivid example for further studies on resource allocation strategies. The exciting finding that the PR, as a more direct storage site for photosynthate, is a buffer unit for resources, and that defense compounds can be reused for other processes, suggests a need to explore potential mechanisms. Significance Statement The pattern found herein provides a vivid example for further studies on resource allocation strategies among vegetative growth, sexual reproduction, asexual reproduction and defense. 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Although vegetative growth, sexual reproduction, asexual reproduction and defense are all basic processes in the life cycle of plants, the strategies used to allocate resources between these processes are poorly understood. These processes are conspicuous in naturally grown Aconitum kusnezoffii Reichb., which makes it a suitable study subject. Here, the morphology, dry matter, total organic carbon, total nitrogen and aconitum alkaloid levels of shoot, principal root (PR) and lateral roots were measured throughout the growing season. Then, transcriptome and metabolite content analyses were performed. We found that vegetative growth began first. After vegetative growth ceased, sexual development began. Flower organ development was accompanied by increased photosynthesis and the PR consumed temporarily stored resources after flower formation. Asexual propagule development initiated earlier than sexual reproduction and kept accumulating resources after that. Development was slow before flower formation, mainly manifesting as increasing length; then, after flower formation it accelerated via enhanced material transport and accumulation. Defense compounds were maintained at low levels before flowering. In particular, the turnover of defense compounds was enhanced before and after flower bud emergence, providing resources for other processes. After flower formation, defense compounds were accumulated. The pattern found herein provides a vivid example for further studies on resource allocation strategies. The exciting finding that the PR, as a more direct storage site for photosynthate, is a buffer unit for resources, and that defense compounds can be reused for other processes, suggests a need to explore potential mechanisms. Significance Statement The pattern found herein provides a vivid example for further studies on resource allocation strategies among vegetative growth, sexual reproduction, asexual reproduction and defense. The exciting finding that the principal root, as a more direct storage site for photosynthate, is a buffer unit for resources, and that defense compounds can be reused for other processes (i.e., growth and reproduction) suggests a need to explore potential mechanisms.</abstract><cop>England</cop><pub>Blackwell Publishing Ltd</pub><pmid>33180340</pmid><doi>10.1111/tpj.15080</doi><tpages>21</tpages><orcidid>https://orcid.org/0000-0002-9032-0600</orcidid><oa>free_for_read</oa></addata></record>
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subjects Accumulation
Aconitum
Aconitum kusnezoffii Reichb
Asexual reproduction
Asexuality
Defense
Dry matter
Flowering
Flowers
Gene expression
Growing season
lateral root (daughter root fuzi)
Life cycles
Metabolites
Morphology
Organic carbon
Photosynthesis
Reproduction
Reproduction (biology)
Resource allocation
secondary metabolite (SM)
Sexual reproduction
sexual–asexual reproduction
Total organic carbon
transcriptome
Transcriptomes
vegetative growth
title Resource allocation strategies among vegetative growth, sexual reproduction, asexual reproduction and defense during growing season of Aconitum kusnezoffii Reichb
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