11 research outputs found
Geomagnetic Field (Gmf) and Plant Evolution: Investigating the Effects of Gmf Reversal on Arabidopsis thaliana Development and Gene Expression
Reduction of the geomagnetic field delays Arabidopsis thaliana flowering time through downregulation of flowering-related genes
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Reduction of the geomagnetic field delays Arabidopsis thaliana flowering time through downregulation of flowering-related genes.
Variations in magnetic field (MF) intensity are known to induce plant morphological and gene expression changes. In Arabidopsis thaliana Col-0, near-null magnetic field (NNMF, i.e., <100 nT MF) causes a delay in the transition to flowering, but the expression of genes involved in this response has been poorly studied. Here, we showed a time-course quantitative analysis of the expression of both leaf (including clock genes, photoperiod pathway, GA20ox, SVP, and vernalization pathway) and floral meristem (including GA2ox, SOC1, AGL24, LFY, AP1, FD, and FLC) genes involved in the transition to flowering in A. thaliana under NNMF. NNMF induced a delayed flowering time and a significant reduction of leaf area index and flowering stem length, with respect to controls under geomagnetic field. Generation experiments (F1 - and F2 -NNMF) showed retention of flowering delay. The quantitative expression (qPCR) of some A. thaliana genes expressed in leaves and floral meristem was studied during transition to flowering. In leaves and flowering meristem, NNMF caused an early downregulation of clock, photoperiod, gibberellin, and vernalization pathways and a later downregulation of TSF, AP1, and FLC. In the floral meristem, the downregulation of AP1, AGL24, FT, and FLC in early phases of floral development was accompanied by a downregulation of the gibberellin pathway. The progressive upregulation of AGL24 and AP1 was also correlated to the delayed flowering by NNMF. The flowering delay is associated with the strong downregulation of FT, FLC, and GA20ox in the floral meristem and FT, TSF, FLC, and GA20ox in leaves. Bioelectromagnetics. 39:361-374, 2018. © 2018 The Authors. Bioelectromagnetics Published by Wiley Periodicals, Inc
Origanum vulgare Terpenoids Induce Oxidative Stress and Reduce the Feeding Activity of Spodoptera littoralis
Terpenoids are toxic compounds produced by plants as a defense strategy against insect herbivores. We tested the effect of Origanum vulgare terpenoids on the generalist herbivore Spodoptera littoralis and the response of the plant to herbivory. Terpenoids were analyzed by GC-FID and GC-MS and quantitative gene expression (qPCR) was evaluated on selected plant genes involved in both terpene biosynthesis. The insect detoxification response to terpenes was evaluated by monitoring antioxidant enzymes activity and expression of insect genes involved in terpene detoxification. O. vulgare terpenoid biosynthesis and gene expression was modulated by S. littoralis feeding. The herbivore-induced increased level of terpenoids (particularly carvacrol and p-cymene) interacted with the herbivore by decreasing larval survival and growth rate. The assimilation by S. littoralis of more than 50% of ingested terpenes correlated with the possible toxic effects of O. vulgare terpenoids. In choice test experiments, carvacrol and γ-terpinene mediated the larval feeding preferences, wherease the prolonged feeding on O. vulgare terpenoids (particularly on γ-terpinene) exerted relevant antinutritional effects on larvae. S. littoralis was found to react to O. vulgare terpenoids by increasing its antioxidant enzymes activities and gene expression, although this was not sufficient to sustain the toxicity of O. vulgare terpenoids
Geomagnetic field impacts on cryptochrome and phytochrome signaling
The geomagnetic field (GMF) is an environmental element whose instability affects plant growth and development. Despite known plant responses to GMF direction and intensity, the mechanism of magnetoreception in plants is still not known. Magnetic field variations affect many light-dependent plant processes, suggesting that the magnetoreception could require light. The objective of this work was to comprehensively investigate the influence of GMF on Arabidopsis thaliana (Col-0) photoreceptor signaling. Wild-type Arabidopsis seedlings and photoreceptor-deficient mutants (cry1cry2, phot1, phyA and phyAphyB) were exposed to near null magnetic field (NNMF, ≤40 nT) and GMF (~43 μT) under darkness and different light wavelengths. The GMF did not alter skotomorphogenic or photomorphogenic seedling development but had a significant impact on gene expression pathways downstream of cryptochrome and phytochrome photoactivation. GMF-induced changes in gene expression observed under blue light were partially associated with an alteration of cryptochrome activation. GMF impacts on phytochrome-regulated gene expression could be attributed to alterations in phytochrome protein abundance that were also dependent on the presence of cry1, cry2 and phot1. Moreover, the GMF was found to impact photomorphogenic-promoting gene expression in etiolated seedlings, indicating the existence of a light-independent magnetoreception mechanism. In conclusion, our data shows that magnetoreception alters photoreceptor signaling in Arabidopsis, but it does not necessarily depend on light
Effects of a new protein hydrosilates-based biostimulant in responses to severe water stress and relief from drought in Caspicum annum.
Geomagnetic Field (Gmf) and Plant Evolution: Investigating the Effects of Gmf Reversal on <em>Arabidopsis thaliana </em>Development and Gene Expression
Summer School ( scuola di dottorato) SIBV/TOMRES: "Stress resilience in plants: from molecules to field"
Origanum vulgare Terpenoids Induce Oxidative Stress and Reduce the Feeding Activity of Spodoptera littoralis
Soluble carbohydrates metabolism sustains energetics and xylem hydraulic functionality upon relief from drought in Populus tremula x alba
The role of non-structural carbohydrates (NSC) in tissues of woody plants during drought stress reveals different, sometimes contrasting, scenarios. A reduction of NSC level probably denotes that plant is undergoing a carbon starvation and consequently exposed to dieback. On the contrary, when soluble carbohydrates content increases, their possible role as osmotic compounds protecting from drought effects and trigging recovery is suggested. Our study focused on depicting the relationship between energetic metabolism and response to drought. Poplar trees were subjected to a drought treatment followed by a period of recovery (re-watering). Physiological measurements (water potential, growth parameters, PLC) were monitored in combination with analysis of hexose phosphate sugars, ATP and key-enzymes activity involved in glycolysis and starch-sugar metabolism. Drought treatment resulted in an alteration of carbohydrate metabolism, drawing a picture in which stem tissues (bark and wood) and xylem sap, differently responded to water stress and recovery, activating sugar oxidative pathways and using alternative sources of NSC. These mechanisms represent a natural trade-off between plant growth and energetic requirements. Our results pointed out that drought triggers an alteration of the energetic status aimed at regulating stress response and subsequent recovery