Functional analysis of lactate dehydrogenase during hypoxic stress in Arabidopsis

Dolferus, Rudy; Wolansky, Mark; Carroll, Rebecka T.; Miyashita, Yo; Ismond, Kathleen P.; Good, Allen G.

doi:10.1071/fp07228

Cited by 62 publications

(62 citation statements)

References 32 publications

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“…The high activity of LDH (Figure 10), and consequently, the signaling mechanism is required to initiate or promote the activity of ADH in the stimulation of ethanolic fermentation, by consuming more protons than lactic, increasing the cytosolic pH survivability of plants subjected to waterlogged conditions (Dolferus et al, 2008), which explains the results obtained in this study.…”

Section: Conditionssupporting

confidence: 76%

Ecophysiological and biochemical behavior in young plants of Parkia gigantocarpa Ducke subjected to waterlogging conditions

Waldemar¹,

Benedito²,

ndido³

et al. 2016

Afr. J. Agric. Res.

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The Parkia gigantocarpa is a neotropical tree that naturally occurs in terra firme forest and floodplain. The aim of the study was to evaluate the physiological and biochemical behavior in young plants of P. gigantocarpa subjected to waterlogging conditions. The waterlogging was imposed at approximately 5 cm above the blade surface of the soil using pots with a capacity of 14 kg of substrate. The experimental design was completely randomized with two water conditions (control and waterlogging) combined with five evaluation times (0, 4, 8, 12 and 16-days waterlogging conditions). The variables evaluated were: Predawn water potential ( p Ψ); the foliar xylem water potential ( x Ψ); hydraulic conductivity; concentration of nitrate; nitrate-reductase activity (NRA); glutamine-synthetase (GS); total soluble amino acids; proline; glycine-betaine; alcohol-dehydrogenase (ADH) and lactatedehydrogenase activity (LDH). The significant reduction in x Ψ and hydraulic conductivity continued until the 8th day in plants subjected to waterlogging, with subsequent stabilization. The concentration of nitrate, NRA, GS, and total soluble amino acids reduced significantly, in the leaves of plants subjected to waterlogging. The waterlogging increased the proline and glycine-betaine, mainly, in the leaves. The ADH activity was significantly higher in the root of the flooded plants, especially, on the 16th day of flooding. In the same period, the LDH activity showed the highest values, mainly, in the leaves of flooded plants. The results showed susceptibility of young plants of P. gigantocarpa subject to waterlogging conditions.

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Section: Conditionssupporting

confidence: 76%

Ecophysiological and biochemical behavior in young plants of Parkia gigantocarpa Ducke subjected to waterlogging conditions

Waldemar¹,

Benedito²,

ndido³

et al. 2016

Afr. J. Agric. Res.

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“…Overexpression of PDC, considered to be rate limiting in ethanol fermentation, has been shown to increase Arabidopsis survival Ismond et al, 2003). Increased root survival was also observed in LACTATE DEHYDROGENASE (LDH)-overexpressing Arabidopsis lines (Dolferus et al, 2008). Altering the expression of ALANINE AMINO-TRANSFERASE, which controls the Ala fermentation pathway, did not affect tolerance to low oxygen in Arabidopsis Miyashita et al, 2007).…”

mentioning

confidence: 89%

The Low-Oxygen-Induced NAC Domain Transcription Factor ANAC102 Affects Viability of Arabidopsis Seeds following Low-Oxygen Treatment

et al. 2009

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Low-oxygen stress imposed by field waterlogging is a serious impediment to plant germination and growth. Plants respond to waterlogging with a complex set of physiological responses regulated at the transcriptional, cellular, and tissue levels. The Arabidopsis (Arabidopsis thaliana) NAC domain-containing gene ANAC102 was shown to be induced under 0.1% oxygen within 30 min in both roots and shoots as well as in 0.1% oxygen-treated germinating seeds. Overexpression of ANAC102 altered the expression of a number of genes, including many previously identified as being low-oxygen responsive. Decreasing ANAC102 expression had no effect on global gene transcription in plants but did alter expression patterns in low-oxygen-stressed seeds. Increasing or decreasing the expression of ANAC102 did not affect adult plant survival of low-oxygen stress. Decreased ANAC102 expression significantly decreased germination efficiency following a 0.1% oxygen treatment, but increased expression had no effect on germination. This protective role during germination appeared to be specific to low-oxygen stress, implicating ANAC102 as an important regulator of seed germination under flooding.

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“…Multiple signaling pathways are triggered transcriptionally in response to flooding (Klok et al, 2002;Fukao and Bailey-Serres, 2008;Hattori et al, 2009). Functional studies of plant flooding and the effects of low oxygen have mainly focused on altering the expression of the genes encoding the enzymes for fermentation and glycolysis (Ellis et al, 1999;Kürsteiner et al, 2003;Bieniawska et al, 2007;Dolferus et al, 2008). Transcriptomic studies have revealed that expression of huge numbers of genes (;10% genes assayed) is altered upon flooding (Klok et al, 2002;Liu et al, 2005;Kreuzwieser et al, 2009;van Dongen et al, 2009;Hsu et al, 2011), suggesting that global transcriptional regulatory networks play important roles in response to flooding.…”

Section: Introductionmentioning

confidence: 99%

Submergence Confers Immunity Mediated by the WRKY22 Transcription Factor in Arabidopsis

et al. 2013

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Functional analysis of lactate dehydrogenase during hypoxic stress in Arabidopsis

Cited by 62 publications

References 32 publications

Ecophysiological and biochemical behavior in young plants of Parkia gigantocarpa Ducke subjected to waterlogging conditions

Ecophysiological and biochemical behavior in young plants of Parkia gigantocarpa Ducke subjected to waterlogging conditions

The Low-Oxygen-Induced NAC Domain Transcription Factor ANAC102 Affects Viability of Arabidopsis Seeds following Low-Oxygen Treatment

Submergence Confers Immunity Mediated by the WRKY22 Transcription Factor in Arabidopsis

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