Identifying resurrection genes through the differentially expressed genes between Selaginella tamariscina (Beauv.) spring and Selaginella moellendorffii Hieron under drought stress

Gu, Wei; Zhang, Aqin; Sun, Hongmei; Gu, Yuchen; Ji, Chao; Tian, Rong; Duan, Jin‐Ao

doi:10.1371/journal.pone.0224765

Cited by 15 publications

(9 citation statements)

References 64 publications

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“…Proteomic analysis identi ed many desiccation-responsive proteins in S. tamariscina associated with photosynthesis, antioxidant defense, and translational modi cation (Wang et al 2010). Similar ndings were showed in the study of Gu et al who found that multiple genes involved in antioxidant defense system, polyamine and carbohydrate metabolism, and stress-defensive protein biosynthesis such as dehydrins and aquaporins could contribute to desiccation tolerance of S. tamariscina due to bene cial roles of these metabolites and proteins in antioxidant, OA, and signal transduction (Gu et al 2019). In addition, abscisic acid signaling was one of important desiccation tolerance strategies in S. tamariscina (Liu et al 2008;Xu et al 2018).…”

Section: Introductionsupporting

confidence: 83%

“…. It has been reported that enhanced carbohydrate metabolism could be a positive strategy for adaptation to desiccation through comparing differential genes in drought-tolerant S. tamariscina and drought-sensitive S. moellendor i(Gu et al 2019). Desiccation-tolerant S. lepidophylla could also accumulate more sugars and sugar alcohols than desiccation-sensitive S. moellendor i when leaf RWC declined from 100-50%(Yobi et al 2012).…”

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confidence: 99%

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Physiological and metabolic changes in Selaginella tamariscina in response to desiccation and resurrection

Xi,

Cai,

2023

Preprint

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As a typical resurrection plant, Selaginella tamariscina exhibits remarkable drought tolerance and resurrection capacity. However, the mechanism of resurrection associated with the alteration of global organic metabolites in S. tamariscina has not been fully elucidated. Objectives of the study were to investigate drought tolerance and recovery capacity of S. tamariscina based on physiological response and to further reveal potential mechanism of resurrection related to changes in antioxidant defense and differential metabolites under drought stress and after rehydration. Results showed that severe drought reduced leaf relative water content from 90–18%, resulting in extreme declines in chlorophyll content and photochemical efficiency as well as a significant increase in malondialdehyde content in leaves, but S. tamariscina plants could rapidly recover within 3 days of rehydration. Superoxide dismutase, peroxidase, and catalase were significantly activated by dehydration and rehydration. In addition, drought-induced accumulations of citric acid and ribitol could be maintained at higher levels in response to rehydration. Although most of organic metabolites were not affected significantly by dehydration (lactic acid, ribonic acid, arabinitol, and erythritol) or decreased sharply under drought stress (glycine, alanine, γ-aminobutyric acid, proline, glyceric acid, vanillic acid, arabinose, and rhamnose), but S. tamariscia has the ability to quickly recover or increase the contents of these organic metabolite after rehydration. Current findings indicated that enhanced antioxidant defense system could be one of the main pathways for acquisition of desiccation tolerance and resurrection capacity, thereby alleviating oxidative damage to S. tamariscina plants. The accumulation of various organic metabolites played critical roles in underlying mechanism of resurrection due to their positive function associated with osmotic adjustment, osmoprotection, antioxidant, and energy metabolism.

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Section: Introductionsupporting

confidence: 83%

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confidence: 99%

Physiological and metabolic changes in Selaginella tamariscina in response to desiccation and resurrection

Xi,

Cai,

2023

Preprint

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“…superoxide dismutase, peroxidase, catalase and glutathione reductase) and the accumulation of osmolites ( e.g. proline and soluble sugars) to counteract the mechanical and oxidative stresses induced by drought (Xu et al, 2018; Gu et al, 2019). In particular, abscisic acid regulates drought resistance genes in plants and is involved in the accumulation of sugars, the regulation of closure of stomata and in redox balance (Liu et al, 2008; Liu et al, 2019).…”

Section: Looking For ‘Food’ – Between Light and Watermentioning

confidence: 99%

Plant behaviour: an evolutionary response to the environment?

2020

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Plants are not just passive living beings that exist in nature. They are complex and highly adaptable species that react sensitively to environmental forces/stimuli with movement, morphological changes and through the communication via volatile molecules. In a way, plants mimic some traits of animal and human behaviour; they compete for limited resources by gaining more area for more sunlight and spread their roots underground. Furthermore, in order to survive and thrive, they evolve and ‘learn’ to control various environmental stress factors in order to increase the yield of flowering, fertilization and germination processes. The concept of associating complex behaviour, such as intelligence, with plants is still a highly debatable topic among researchers worldwide. Recent studies have shown that plants are able to discriminate between positive and negative experiences and ‘learn’ from them. Some botanists have interpreted these behavioural data as a form of primitive cognitive processes. Others have evaluated these responses as biological automatisms of plants determined by adaptation to the environment and absence of intelligence. This review aims to explore adaptive behavioural aspects of various plant species distributed in different ecosystems by emphasizing their biological complexity and survival instincts.

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“…Interestingly, LEA-like proteins are also found in a variety of organisms, such as anhydrobiotic nematodes [111,112], brine shrimp [113], rotifers [114,115], and some bacterial species [108]. Although LEAs were first described in embryonic tissues, thirty years of intensive research showed that the expression of LEA genes is also significantly induced in vegetative organs (i.e., callus, flowers, roots, leaves, buds) under abiotic stresses such as desiccation, salinity, and cold [116][117][118][119][120].…”

Section: Late Embryogenesis Abundant (Lea) Proteins Accumulationmentioning

confidence: 99%

What Do We Know About the Genetic Basis of Seed Desiccation Tolerance and Longevity?

Kijak

Ratajczak

2020

IJMS

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Long-term seed storage is important for protecting both economic interests and biodiversity. The extraordinary properties of seeds allow us to store them in the right conditions for years. However, not all types of seeds are resilient, and some do not tolerate extreme desiccation or low temperature. Seeds can be divided into three categories: (1) orthodox seeds, which tolerate water losses of up to 7% of their water content and can be stored at low temperature; (2) recalcitrant seeds, which require a humidity of 27%; and (3) intermediate seeds, which lose their viability relatively quickly compared to orthodox seeds. In this article, we discuss the genetic bases for desiccation tolerance and longevity in seeds and the differences in gene expression profiles between the mentioned types of seeds.

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Identifying resurrection genes through the differentially expressed genes between Selaginella tamariscina (Beauv.) spring and Selaginella moellendorffii Hieron under drought stress

Cited by 15 publications

References 64 publications

Physiological and metabolic changes in Selaginella tamariscina in response to desiccation and resurrection

Physiological and metabolic changes in Selaginella tamariscina in response to desiccation and resurrection

Plant behaviour: an evolutionary response to the environment?

What Do We Know About the Genetic Basis of Seed Desiccation Tolerance and Longevity?

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