Abstract
The consideration as to how plants uptake and transport phosphorus (P) is of significant agronomic and economic importance, in part driven by finite reserves of rock phosphate. Our understanding of these mechanisms has been greatly advanced, particularly with respect to the responses of plants to P deficiency and the genetic dissection of the signalling involved. Further, the realization that there are two tiers of transcriptional responses, the local, in which inorganic P (Pi) acts as an external signal independent of the endogenous P level, and the systemic involving root–shoot signalling, has now added a dimension of both clarity and complexity. Notwithstanding, it is now clear that the hormone ethylene plays a key role in mediating both levels of responses. This review, therefore, covers the role of ethylene in terms of mediating responses to P deficiency. The evidence that Pi supply regulates ethylene biosynthesis and sensitivity, and that this, in turn, regulates changes in root system architecture and in Pi-deprivation responses is examined here. While ethylene is the focus, the key interactions with auxin are also assessed, but interactions with the other hormone groups, which have recently been reviewed, are not covered. The emerging view that ethylene is a multi-faceted hormone in terms of mediating responses to P deficiency invites the dissection of the transcriptional cues that mediate changes in ethylene biosynthesis and/or sensitivity. Knowledge of the nature of such cues will subsequently reveal more of the underpinning interactions that govern P responses and provide avenues for the production of germplasm with an improved phosphate use efficiency.
Highlights
The mechanisms by which plants access sufficient phosphate (P) from the soil are of intense agronomic and academic interest
We focus on one aspect of this control: the interaction of Pi level and ethylene biosynthesis and signalling
Hernandez et al (2007) detected the up-regulation of an ACC oxidase (ACO) gene in bean that was confirmed using quantitative polymerase chain reaction expression analysis. This confirmed an earlier study in which gene cluster analysis across five legume species was used to extend the annotation of P. vulgaris genes where, again, an up-regulation of an ACO gene was observed (Graham et al 2006). In their large-scale transcriptome study in Arabidopsis, Thibaud et al (2010) identified an ACO gene (AtACO4) as a member of a cadre of up-regulated genes that are locally induced, suggesting that an early response of plant roots to P deprivation is the induction of ACO irrespective of root Pi status
Summary
The mechanisms by which plants access sufficient phosphate (P) from the soil are of intense agronomic and academic interest. In their large-scale transcriptome study in Arabidopsis, Thibaud et al (2010) identified an ACO gene (AtACO4) as a member of a cadre of up-regulated genes that are locally induced, suggesting that an early response of plant roots to P deprivation is the induction of ACO (and possible stimulation of ethylene biosynthesis) irrespective of root Pi status In another Arabidopsis transcriptome study, Chacon-Lopez et al (2011) compared gene changes in the low phosphorus insensitive 4 mutant background with wild type. A link with ethylene signalling in the P response was established when it was shown that added Ag repressed the observed increase in severity of phenotype in low P These workers observed that the mutant accumulated a higher auxin content in the apical 5 mm root tips as well as displaying an increased expression of auxin-biosynthesis-associated genes in harvested seedlings, leading the mechanism back to the phenomenon described in this review of ethylene-induced changes in auxin biosynthesis and signalling. These results do support the contention that ethylene may have pleiotropic effects in terms of mediating the responses of plant roots to P deficiency, and it is likely that further roles will be identified in the future
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