Enhancing plant phosphorus use efficiency for sustainable cropping

Phosphorus (P) is one of the least available mineral nutrients to the plants in many cropping environments. Sub-optimal P nutrition can lead to yield losses in the range of 10% to 15% of the maximal yields. P deficiency is more critical in highly withered soils as well as in calcareous and alkaline soils. Amelioration attempts by addition of phosphatic fertilizers are economically and ecologically unsound as the efficiency of added phosphatic fertilizers is very low. Inoculation with the mineral phosphate solubilizing microbes has not helped much due to inconsistent performance of the inoculants under field conditions. These factors have led to examine the opportunities for developing genetically enhanced plants with better P use efficiency (PUE) through efficient P absorption, transportation and internal utilization. In order to improve the PUE in crop plants, it is important to explore genetic variation for all its associated traits. Inter- and intra-specific variations for these traits are known to exist and are shown to be under genetic and physiological controls, but modified by the plant–environment interactions. A more comprehensive understanding of the molecular and physiological basis of P uptake, transportation and utilization is leading to formulation of strategies aimed at developing better P efficient cultivars suited for sustainable cropping with less P fertilizer inputs. Issues relating to enhancing PUE through genetic manipulations of crop cultivar parameters are discussed.     

Phosphate excess increases susceptibility to pathogen infection in rice

Phosphorus (P) is an essential nutrient for plant growth and productivity. Due to soil fixation, however, phosphorus availability in soil is rarely sufficient to sustain high crop yields. The overuse of fertilizers to circumvent the limited bioavailability of phosphate (Pi) has led to a scenario of excessive soil P in agricultural soils. Whereas adaptive responses to Pi deficiency have been deeply studied, less is known about how plants adapt to Pi excess and how Pi excess might affect disease resistance. We show that high Pi fertilization, and subsequent Pi accumulation, enhances susceptibility to infection by the fungal pathogen Magnaporthe oryzae in rice. This fungus is the causal agent of the blast disease, one of the most damaging diseases of cultivated rice worldwide. Equally, MIR399f overexpression causes an increase in Pi content in rice leaves, which results in enhanced susceptibility to M. oryzae. During pathogen infection, a weaker activation of defence-related genes occurs in rice plants over-accumulating Pi in leaves, which is in agreement with the phenotype of blast susceptibility observed in these plants. These data support that Pi, when in excess, compromises defence mechanisms in rice while demonstrating that miR399 functions as a negative regulator of rice immunity. The two signalling pathways, Pi signalling and defence signalling, must operate in a coordinated manner in controlling disease resistance. This information provides a basis to understand the molecular mechanisms involved in immunity in rice plants under high Pi fertilization, an aspect that should be considered in management of the rice blast disease.     

The secretion of the bacterial phytase PHY‐US417 by Arabidopsis roots reveals its potential for increasing phosphate acquisition and biomass production during co‐growth

Phytic acid (PA) is a major source of inorganic phosphate (Pi) in the soil; however, the plant lacks the capacity to utilize it for Pi nutrition and growth. Microbial phytases constitute a group of enzymes that are able to remobilize Pi from PA. Thus, the use of these phytases to increase the capacity of higher plants to remobilize Pi from PA is of agronomical interest. In the current study, we generate transgenic Arabidopsis lines (ePHY) overexpressing an extracellular form of the phytase PHY‐US417 of Bacillus subtilis, which are characterized by high levels of secreted phytase activity. In the presence of PA as sole source of Pi, while the wild‐type plants show hallmark of Pi deficiency phenotypes, including the induction of the expression of Pi starvation‐induced genes (PSI, e.g. PHT1;4) and the inhibition of growth capacity, the ePHY overexpressing lines show a higher biomass production and no PSI induction. Interestingly, when co‐cultured with ePHY overexpressors, wild‐type Arabidopsis plants (or tobacco) show repression of the PSI genes, improvement of Pi content and increases in biomass production. In line with these results, mutants in the high‐affinity Pi transporters, namely pht1;1 and pht1;1‐1;4, both fail to accumulate Pi and to grow when co‐cultured with ePHY overexpressors. Taken together, these data demonstrate the potential of secreted phytases in improving the Pi content and enhancing growth of not only the transgenic lines but also the neighbouring plants.     

Phosphite: a novel P fertilizer for weed management and pathogen control

The availability of orthophosphate (Pi) is a key determinant of crop productivity because its accessibility to plants is poor due to its conversion to unavailable forms. Weed's competition for this essential macronutrient further reduces its bio‐availability. To compensate for the low Pi use efficiency and address the weed hazard, excess Pi fertilizers and herbicides are routinely applied, resulting in increased production costs, soil degradation and eutrophication. These outcomes necessitate the identification of a suitable alternate technology that can address the problems associated with the overuse of Pi‐based fertilizers and herbicides in agriculture. The present review focuses on phosphite (Phi) as a novel molecule for its utility as a fertilizer, herbicide, biostimulant and biocide in modern agriculture. The use of Phi‐based fertilization will help to reduce the consumption of Pi fertilizers and facilitate weed and pathogen control using the same molecule, thereby providing significant advantages over current orthophosphate‐based fertilization.     

Physiological integration impacts nutrient use and stoichiometry in three clonal plants under heterogeneous habitats

Physiological integration facilitates clonal plants to deal with heterogeneous resources. However, little is known about how nutrient patchiness affects its use and stoichiometry in clonal plants. We conducted an experiment with Cynodon dactylon, Glechoma longituba, and Potentilla reptans to address the effects of physiological integration on nutrient use efficiency and N:P ratios. For C. dactylon, the effects of nutrient patchiness on N use efficiency (NUE), P use efficiency (PUE), and N:P ratio were stronger in daughter ramets than in parent ramets; for G. longituba, nutrient patchiness affected PUE and N:P ratio of parent and daughter ramets, but not NUE; for P. reptans, nutrient patchiness decreased NUE, PUE, and N:P ratio, regardless of parent or daughter ramets. PUE was associated with N:P ratios in three clonal plants and this association of NUE with N:P ratios varied with species. Our findings suggest that physiological integration alters nutrient use efficiency and N:P ratios of clonal plants under patchy nutrients and that these effects are linked to clonal species identity.     

Acid phosphatases and growth of barley (<Emphasis Type="Italic">Hordeum vulgare</Emphasis> L.) cultivars under diverse phosphorus nutrition

The morphological and physiological responses of barley to moderate Pi deficiency and the ability of barley to grow on phytate were investigated. Barley cultivars (Hordeum vulgare L., Promyk, Skald and Stratus) were grown for 1–3 weeks on different nutrient media with contrasting phosphorus source: KH₂PO₄ (control), phytic acid (PA) and without phosphate (−P). The growth on −P medium strongly decreased Pi concentration in the tissues; culture on PA medium generally had no effect on Pi level. Decreased content of Pi reduced shoot and root mass but root elongation was not affected; Pi deficit had slightly greater impact on growth of barley cv. Promyk than other varieties. Barley varieties cultured on PA medium showed similar growth to control. Extracellular acid phosphatase activities (APases) in −P roots were similar to control, but in PA plants were lower. Histochemical visualization indicated for high APases activity mainly in the vascular tissues of roots and in rhizodermis. Pi deficiency increased internal APase activities mainly in shoot of barley cv. Stratus and roots of cv Promyk; growth on PA medium had no effect or decreased APase activity. Protein extracts from roots and shoots were run on native discontinuous PAGE to determine which isoforms may be affected by Pi deficiency or growth on PA medium; two of four isoforms in roots were strongly induced by conditions of Pi deficit, especially in barley cv. Promyk. In conclusion, barley cultivars grew equally well both on medium with Pi and where the Pi was replaced with phytate and only slightly differed in terms of acclimation to moderate deficiency of phosphate; they generally used similar pools of acid phosphatases to acquire Pi from external or internal sources.     

小麦磷酸丙糖转运器的特性及其对同化物分配的调节(英文)

磷酸丙糖转运器(triosephosphate/phosphatetranslocator,TPT)是源、库间光合产物分配的第一调控部位,研究TPT的特性及其对同化物分配的调节,对于提高光合作用同化物利用效率有着重要意义。我们首先采用Percoll密度梯度离心从小麦(TriticumaestivumL.)叶片中分离制备了完整性达91%以上、具有较高纯度的完整叶绿体。利用TPT不可逆抑制剂[H3]2-DIDS标记和SDS-PAGE,以及小麦TPT抗体进行Westernblotting分析,证明TPT蛋白仅存在于叶绿体被膜中,约占被膜总蛋白的15%,其分子量为35kD,而在液泡膜和线粒体膜上不存在。采用硅油离心法研究TPT对磷酸二羟丙酮(dihydroxyacetonephosphate,DHAP)、磷酸烯醇式丙酮酸(phosphoenolpyruvate,PEP)、葡萄糖-6-磷酸(glucose-6-phosphate,G6P)与Pi的反向运输动力学的结果表明,DHAP/Pi的最大运输活性最高,PEP/Pi次之,G6P/Pi最低。TPT与这些运输底物的Km值由小至大,分别为DHAP、Pi、PEP和G6P,证明TPT的最适运输底物为DHAP。用DIDS处理时,TPT对DHAP运输活性的抑制达95%。TPT运输活性受到抑制时,可导致叶绿体内大量积累淀粉。TPT在调控小麦叶绿体同化产物的分配中起着重要作用,在保证卡尔文循环正常运转的前提下,通过TPT外运到胞质中参与蔗糖合成和其他代谢活动的磷酸丙糖(triosep     

Phosphate starvation signaling in rice

Phosphorus is one of the most essential and limiting macronutrients for plants. Phosphate (Pi) deficiency could affect crop productivity seriously in agriculture. How to cope with this problem? Unveiling the molecular mechanism behind the Pi starvation responses of plants will be helpful to solve this issue. Rice is one of the most important crops, which feeds over one-third of the people in the world. In this review, we summarize the recent progress on Pi starvation signaling in rice with the intention to provide a further insight into the molecular mechanism of Pi starvation responses in rice and to give a new research direction to design transgenic plants with high Pi efficiency.Key words: rice, Pi starvation, signaling     

Exogenous strigolactones impact metabolic profiles and phosphate starvation signalling in roots

Strigolactones (SLs) are important ex-planta signalling molecules in the rhizosphere, promoting the association with beneficial microorganisms, but also affecting plant interactions with harmful organisms. They are also plant hormones in-planta, acting as modulators of plant responses under nutrient-deficient conditions, mainly phosphate (Pi) starvation. In the present work, we investigate the potential role of SLs as regulators of early Pi starvation signalling in plants. A short-term pulse of the synthetic SL analogue 2′-epi-GR24 promoted SL accumulation and the expression of Pi starvation markers in tomato and wheat under Pi deprivation. 2′-epi-GR24 application also increased SL production and the expression of Pi starvation markers under normal Pi conditions, being its effect dependent on the endogenous SL levels. Remarkably, 2′-epi-GR24 also impacted the root metabolic profile under these conditions, promoting the levels of metabolites associated to plant responses to Pi limitation, thus partially mimicking the pattern observed under Pi deprivation. The results suggest an endogenous role for SLs as Pi starvation signals. In agreement with this idea, SL-deficient plants were less sensitive to this stress. Based on the results, we propose that SLs may act as early modulators of plant responses to P starvation.     

小麦磷酸丙糖转运器的特性及其对同化物分配的调节

磷酸丙糖转运器(tnose phosphate/phosphatetranslocator,TPT)是源、库间光合产物分配的第一调控部位,研究TPT的特性及其对同化物分配的调节,对于提高光合作用同化物利用效率有着重要意义.我们首先采用Percoll密度梯度离心从小麦(Triticum aestivum L.)叶片中分离制备了完整性达91%以上、具有较高纯度的完整叶绿体.利用TPT不可逆抑制剂[H3]2-DIDS标记和SDS-PAGE,以及小麦TPT抗体进行Western blotting分析,证明TPT蛋白仅存在于叶绿体被膜中,约占被膜总蛋白的15%,其分子量为35 kD,而在液泡膜和线粒体膜上不存在.采用硅油离心法研究TPT对磷酸二羟丙酮(dihydroxyacetone phosphate,DHAP)、磷酸烯醇式丙酮酸(phosphoenolpyruvate,PEP)、葡萄糖-6-磷酸(glucose-6-phosphate,G6P)与Pi的反向运输动力学的结果表明,DHAP/Pi的最大运输活性最高,PEP/Pi次之,G6P/Pi最低.TPT与这些运输底物的Km值由小至大,分别为DHAP、Pi、PEP和G6P,证明TPT的最适运输底物为DHAP.用DIDS处理时,TPT对DHAP运输活性的抑制达95%.TPT运输活性受到抑制时,可导致叶绿体内大量积累淀粉.TPT在调控小麦叶绿体同化产物的分配中起着重要作用,在保证卡尔文循环正常运转的前提下,通过TPT外运到胞质中参与蔗糖合成和其他代谢活动的磷酸丙糖(triose phosphate,TP)约占93.6%,而用于叶绿体内合成淀粉的TP仅占6.4%.生理条件下其功能是高效率地把大部分光合同化产物TP及时运出叶绿体到胞质中,用于合成蔗糖并运输到其他库器官的需要.     

Improved phosphate metabolism and biomass production by overexpression of <Emphasis Type="Italic">AtPAP18</Emphasis> in tobacco

Limited availability of phosphate ion (Pi) reduces plant growth in natural ecosystems. Here, we report the functional effects of overexpressing an Arabidopsis thaliana purple acid phosphatase encoding gene, AtPAP18, in Nicotiana tabbacum as a crop model plant. Transgenic tobacco plants exhibited significant increases in acid phosphatase activity, total P and Pi contents leading to improved biomass production in both Pi-deficient and Pi-sufficient conditions. Transient expression of AtPAP18::green fluorescent fusion protein in onion epidermal cells indicated that AtPAP18 is a dual-targeted protein, which is detected mainly in the apoplast of the cells after 24 h and in the vacuole after 72 h. Possibly, AtPAP18 protein confers efficient retrieval of Pi from bonded extracellular compounds as well as expendable intracellular Pi-monoesters and anhydrides. These data clearly indicate that overexpression of AtPAP18 gene offers an effective approach for reducing the consumption of chemical Pi fertilizer through increased acquisition of soil Pi and mobilization of internal resources.