Janice A. Lake scite author profile

SummaryAn Arabidopsis thaliana drought-tolerant mutant, altered expression of APX2 (alx8), has constitutively increased abscisic acid (ABA) content, increased expression of genes responsive to high light stress and is reported to be drought tolerant. We have identified alx8 as a mutation in SAL1, an enzyme that can dephosphorylate dinucleotide phosphates or inositol phosphates. Previously identified mutations in SAL1, including fiery (fry1-1), were reported as being more sensitive to drought imposed by detachment of rosettes. Here we demonstrate that alx8, fry1-1 and a T-DNA insertional knockout allele all have markedly increased resistance to drought when water is withheld from soil-grown intact plants. Microarray analysis revealed constitutively altered expression of more than 1800 genes in both alx8 and fry1-1. The up-regulated genes included some characterized stress response genes, but few are inducible by ABA. Metabolomic analysis revealed that both mutants exhibit a similar, dramatic reprogramming of metabolism, including increased levels of the polyamine putrescine implicated in stress tolerance, and the accumulation of a number of unknown, potential osmoprotectant carbohydrate derivatives. Under well-watered conditions, there was no substantial difference between alx8 and Col-0 in biomass at maturity; plant water use efficiency (WUE) as measured by carbon isotope discrimination; or stomatal index, morphology or aperture. Thus, SAL1 acts as a negative regulator of predominantly ABA-independent and also ABA-dependent stress response pathways, such that its inactivation results in altered osmoprotectants, higher leaf relative water content and maintenance of viable tissues during prolonged water stress.

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Systemic signalling of environmental cues in Arabidopsis leaves

Coupe¹,

Palmer²,

Lake³

et al. 2005

153

148

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Light intensity and atmospheric CO2 partial pressure are two environmental signals known to regulate stomatal numbers. It has previously been shown that if a mature Arabidopsis leaf is supplied with either elevated CO2 (750 ppm instead of ambient at 370 ppm) or reduced light levels (50 micromol m-2 s-1 instead of 250 micromol m-2 s-1), the young, developing leaves that are not receiving the treatment grow with a stomatal density as if they were exposed to the treatment. But the signal(s) that it is believed is generated in the mature leaves and transmitted to developing leaves are largely unknown. Photosynthetic rates of treated, mature Arabidopsis leaves increased in elevated CO2 and decreased when shaded, as would be expected. Similarly, the levels of sugars (glucose, fructose, and sucrose) in the treated mature leaves increased in elevated CO2 and decreased with shade treatment. The levels of sugar in developing leaves were also measured and it was found that they mirrored this result even though they were not receiving the shade or elevated CO2 treatment. To investigate the effect of these treatments on global gene expression patterns, transcriptomics analysis was carried out using Affymetrix, 22K, and ATH1 arrays. Total RNA was extracted from the developing leaves after the mature leaves had received either the ambient control treatment, the elevated CO2 treatment, or the shade treatment, or both elevated CO2 and shade treatments for 2, 4, 12, 24, 48, or 96 h. The experiment was replicated four times. Two other experiments were also conducted, one to compare and contrast gene expression in response to plants grown at elevated CO2 and the other to look at the effect of these treatments on the mature leaf. The data were analysed and 915 genes from the untreated, signalled leaves were identified as having expression levels affected by the shade treatment. These genes were then compared with those whose transcript abundance was affected by the shade treatment in the mature treated leaves (1181 genes) and with 220 putative 'stomatal signalling' genes previously identified from studies of the yoda mutant. The results of these experiments and how they relate to environmental signalling are discussed, as well as possible mechanisms for systemic signalling.

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Isotope Fractionation and Atmospheric Oxygen: Implications for Phanerozoic O ₂ Evolution

Berner

Petsch

Lake

et al. 2000

Science

209

134

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Models describing the evolution of the partial pressure of atmospheric oxygen over Phanerozoic time are constrained by the mass balances required between the inputs and outputs of carbon and sulfur to the oceans. This constraint has limited the applicability of proposed negative feedback mechanisms for maintaining levels of atmospheric O(2) at biologically permissable levels. Here we describe a modeling approach that incorporates O(2)-dependent carbon and sulfur isotope fractionation using data obtained from laboratory experiments on carbon-13 discrimination by vascular land plants and marine plankton. The model allows us to calculate a Phanerozoic O(2) history that agrees with independent models and with biological and physical constraints and supports the hypothesis of a high atmospheric O(2) content during the Carboniferous (300 million years ago), a time when insect gigantism was widespread.

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Response of stomatal numbers to CO₂ and humidity: control by transpiration rate and abscisic acid

2008

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Summary• The observation that stomatal density (number mm −2 ) on herbarium leaves had decreased over the last century represents clear evidence that plants have responded to anthropogenic increases in CO 2 concentration. The mechanism of the response has proved elusive but here it is shown that density responses to both CO 2 concentration and humidity are correlated with changes in whole-plant transpiration and leaf abscisic acid (ABA) concentration.• The transpiration rate of a range of accessions of Arabidopsis thaliana was manipulated by changing CO 2 concentration, humidity and by exogenous application of ABA. Stomatal density increased with transpiration and leaf ABA concentration.• A common property of signal transduction systems is that they rapidly lose their ability to respond to the co-associated stimulus. Pathways of water movement within the plant are connected and so variations in supply and demand can be signalled throughout the plant directly, modifying stomatal aperture of mature leaves and stomatal density of developing leaves. Furthermore, the system identified here does not conform to the loss of ability to respond.• A putative mechanism is proposed for the control of stomatal density by transpiration rate and leaf ABA concentration.

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Janice A. Lake

Signals from mature to new leaves

The nucleotidase/phosphatase SAL1 is a negative regulator of drought tolerance in Arabidopsis

Systemic signalling of environmental cues in Arabidopsis leaves

Isotope Fractionation and Atmospheric Oxygen: Implications for Phanerozoic O ₂ Evolution

Response of stomatal numbers to CO₂ and humidity: control by transpiration rate and abscisic acid

Contact Info

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Resources

About

Janice A. Lake

Signals from mature to new leaves

The nucleotidase/phosphatase SAL1 is a negative regulator of drought tolerance in Arabidopsis

Systemic signalling of environmental cues in Arabidopsis leaves

Isotope Fractionation and Atmospheric Oxygen: Implications for Phanerozoic O 2 Evolution

Response of stomatal numbers to CO2 and humidity: control by transpiration rate and abscisic acid

Contact Info

Product

Resources

About

Isotope Fractionation and Atmospheric Oxygen: Implications for Phanerozoic O ₂ Evolution

Response of stomatal numbers to CO₂ and humidity: control by transpiration rate and abscisic acid