Factors contributing to the acid sulfate soil scalding process in the coastal floodplains of New South Wales, Australia

Rosicky, Mark A; Sullivan, Leigh A; Slavich, Peter G; Hughes, Mike

doi:10.1071/sr03076

Cited by 16 publications

(7 citation statements)

References 8 publications

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“…The identification of key genes involved in plant resistance to H + stress is crucial if we wish to improve crop growth in acid soil conditions, such as in organic acid and acid sulfate soils, where H + stress frequently limits crop growth (Rosicky et al, 2004;Lumsdon et al, 2005). However, little information is available regarding the molecular mechanism underlying H + resistance in plants.…”

Section: Discussionmentioning

confidence: 99%

Alleviation of proton toxicity by nitrate uptake specifically depends on nitrate transporter 1.1 in Arabidopsis

et al. 2016

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SummaryProtons in acid soil are highly rhizotoxic to plants, but the mechanism of tolerance of plants to protons is largely unknown. Nitrate uptake by root cells is accompanied by the uptake of protons. Therefore, nitrate uptake transporters (NRTs) may be involved in plant tolerance to proton toxicity.We investigated the root nitrate uptake response to proton stress in Arabidopsis and its association with proton tolerance using NRT-related mutants and pharmacological methods.Lack of NRT1.1 in knockout nrt1.1 mutants led to impaired proton tolerance in nitratesufficient growth medium, whereas no difference was seen between wild-type plants and NRT1.2-, NRT2.1-, NRT2.2-, and NRT2.4-null mutants. Another nrt1.1 point mutant, which is defective in nitrate uptake but has a normal nitrate-sensing function, also had impaired proton tolerance compared with the wild-type plant. Furthermore, proton stress induced NRT1.1-mediated nitrate uptake. These results indicate that NRT1.1-conferred proton tolerance depends on nitrate uptake activity. In addition, the rooting medium was alkalified by wild-type plants, but not by knockout nrt1.1 mutants, and in pH-buffered medium, there were no differences in proton tolerance between wild-type plants and knockout nrt1.1 mutants.We conclude that NRT1.1-mediated nitrate uptake plays a crucial role in plant proton tolerance by alkalifying the rhizosphere.

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Section: Discussionmentioning

confidence: 99%

Alleviation of proton toxicity by nitrate uptake specifically depends on nitrate transporter 1.1 in Arabidopsis

et al. 2016

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“…Proton rhizotoxicity is also observed under certain soil conditions such as organic acid soil (15) and acid sulfate soil (16). Therefore, identification of genes that regulate H ϩ tolerance is also important for the molecular breeding of crops tolerant to acid soils.…”

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confidence: 99%

Zinc finger protein STOP1 is critical for proton tolerance in Arabidopsis and coregulates a key gene in aluminum tolerance

Iuchi

Koyama

Iuchi

et al. 2007

Proc. Natl. Acad. Sci. U.S.A.

389

366

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Acid soil syndrome causes severe yield losses in various crop plants because of the rhizotoxicities of ions, such as aluminum (Al 3؉ ). Although protons (H ؉ ) could be also major rhizotoxicants in some soil types, molecular mechanisms of their tolerance have not been identified yet. One mutant that was hypersensitive to H ؉ rhizotoxicity was isolated from ethyl methanesulfonate mutagenized seeds, and a single recessive mutation was found on chromosome 1. Positional cloning followed by genomic sequence analysis revealed that a missense mutation in the zinc finger domain in a predicted Cys2His2-type zinc finger protein, namely sensitive to proton rhizotoxicity (STOP)1, is the cause of hypersensitivity to H ؉ rhizotoxicity. The STOP1 protein belongs to a functionally unidentified subfamily of zinc finger proteins, which consists of two members in Arabidopsis based on a Blast search. The stop1 mutation resulted in no effects on cadmium, copper, lanthanum, manganese and sodium chloride sensitivitities, whereas it caused hypersensitivity to Al 3؉ rhizotoxicity. This stop1 mutant lacked the induction of the AtALMT1 gene encoding a malate transporter, which is concomitant with Al-induced malate exudation. There was no induction of AtALMT1 by Al 3؉ treatment in the stop1 mutant. These results indicate that STOP1 plays a critical role in Arabidopsis tolerance to major stress factors in acid soils. aluminum toxicity ͉ Arabidopsis thaliana ͉ Cys2His2-type zinc finger protein ͉ proton-rhizotoxicity ͉ sensitive to proton rhizotoxicity

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“…Tidal wetlands will be more restricted and freshwater wetlands will occur where groundwater is at or near the surface, and fossil blue carbon that has accumulated within substrates over the Holocene may have had considerable time to undergo diagenesis (Rogers et al 2019a). As tides deliver sulfates to substrates over millennia, 'fossil' blue carbon stores may convert to acid sulfate soils when exposed to aerobic conditions (Rosicky et al 2004;Johnston et al 2016). Preservation of saline anaerobic conditions serves to both preserve fossil blue carbon and prevent development of acid sulfate soils.…”

Section: Influence Of Coastal Geomorphology On Blue Carbon In Wave-do...mentioning

confidence: 99%

Coastal wetland rehabilitation first-pass prioritisation for blue carbon and associated co-benefits

et al. 2022

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Context. The Australian Government has developed a methodology for payment for carbon services provided by blue carbon ecosystems that focuses on avoided emissions and carbon additionality resulting from tidal restoration of coastal wetlands. Aims. This study is a firstpass prioritisation for tidal restoration of coastal wetlands in New South Wales (NSW). Methods. A pixel-based approach was applied using readily available datasets, with particular focus on watersheds above in-stream tidal barriers. Key results. Many sites were identified, to investigate in detail, opportunities to restore tidal flows to coastal wetlands. More were associated with the broad coastal floodplains of northern NSW than narrower floodplains of southern NSW. Conclusions. Information is needed about the location, ownership, land tenure, structure, condition and height of in-stream and over-land flow barriers, particularly in the context of rising sea levels. Decisions about managing in-stream drainage and flood mitigation infrastructure should be made cognisant of opportunities to increase blue carbon, and provide associated co-benefits, including mitigating other deleterious impacts from coastal wetland drainage. Implications. Decision support tools for evaluating economic and environmental costs and benefits of tidal barriers will assist decision-makers assessing future proposals to repair or remove aging barriers, or create new tidal barriers.

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Factors contributing to the acid sulfate soil scalding process in the coastal floodplains of New South Wales, Australia

Cited by 16 publications

References 8 publications

Alleviation of proton toxicity by nitrate uptake specifically depends on nitrate transporter 1.1 in Arabidopsis

Alleviation of proton toxicity by nitrate uptake specifically depends on nitrate transporter 1.1 in Arabidopsis

Zinc finger protein STOP1 is critical for proton tolerance in Arabidopsis and coregulates a key gene in aluminum tolerance

Coastal wetland rehabilitation first-pass prioritisation for blue carbon and associated co-benefits

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