Evolution of halophytes: multiple origins of salt tolerance in land plants

Flowers, T. J.; Galal, Hanan; Bromham, Lindell

doi:10.1071/fp09269

Cited by 592 publications

(376 citation statements)

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“…Briefly, they reported that studies of halophyte growth at high concentrations of salts 'offer a rather bewildering array of data'. As halophytes occur in at least 37 orders of plants, (see also Flowers et al 2010), this should not be unexpected. Optimal growth salinities range from 20 to 500 mM with large differences even within single genera (e.g.…”

Section: The Problem Of Organismal Integration In Saline Environmentsmentioning

confidence: 99%

The integration of activity in saline environments: problems and perspectives

Cheeseman

2013

Functional Plant Biol.

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Abstract. The successful integration of activity in saline environments requires flexibility of responses at all levels, from genes to life cycles. Because plants are complex systems, there is no 'best' or 'optimal' solution and with respect to salt, glycophytes and halophytes are only the ends of a continuum of responses and possibilities. In this review, I briefly examine seven major aspects of plant function and their responses to salinity including transporters, secondary stresses, carbon acquisition and allocation, water and transpiration, growth and development, reproduction, and cytosolic function and 'integrity'. I conclude that new approaches are needed to move towards understanding either organismal integration or 'salt tolerance', especially cessation of protocols dependent on sudden, often lethal, shock treatments and the embracing of systems level resources. Some of the tools needed to understand the integration of activity and even 'salt stress' are already in hand, such as those for whole-transcriptome analysis. Others, ranging from discovery studies of the nature of the cytosol to expanded tool kits for proteomic, metabolomic and epigenomic studies, still need to be further developed. After resurrecting the distinction between applied stress and the resultant strain and noting that with respect to salinity, the strain is manifest in changes at all -omic levels, I conclude that it should be possible to model and quantify stress responses.

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Section: The Problem Of Organismal Integration In Saline Environmentsmentioning

confidence: 99%

The integration of activity in saline environments: problems and perspectives

Cheeseman

2013

Functional Plant Biol.

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“…With the evolution of land plants (Graham, 1993), the salt tolerance of their ancestral marine algae, consisting of a salt requirement for amongst other membrane stability and enzyme functioning, has been lost. There are some salt tolerant mosses (Flowers et al, 2010), ferns show no salt tolerance, so most likely salt tolerance secondarily evolved in angiosperms (Fig. 2, Rozema, 1991Rozema, , 1996Flowers et al, 2008Flowers et al, , 2010.…”

Section: Evolution Of Salt Tolerance In Terrestrial Dicotyledonae Andmentioning

confidence: 99%

Salt tolerance of halophytes, research questions reviewed in the perspective of saline agriculture

Rozema

Schat

2013

Environmental and Experimental Botany

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“…Attempts to improve the salinity tolerance of conventional crops have not been successful so far. This is because tolerance to salinity is a complex trait [4], involving multiple genes and having evolved multiple times independently among different lineages [7], leading to different mechanisms of salinity tolerance. A different promising strategy is to focus on the de novo domestication of halophytes.…”

Section: Introductionmentioning

confidence: 99%