Membrane transporters for nitrogen, phosphate and potassium uptake in plants

Nitrogen, phosphorous and potassium are essential nutrients for plant growth and development. However, their contents in soils are limited so that crop production needs to invest a lot for fertilizer supply. To explore the genetic potentialities of crops (or plants) for their nutrient utilization efficiency has been an important research task for many years. In fact, a number of evidences have revealed that plants, during their evolution, have developed many morphological, physiological,biochemical and molecular adaptation mechanisms for acquiring nitrate, phosphate and potassium under stress conditions.Recent discoveries of many transporters and channels for nitrate, phosphate and potassium up take have opened upopportunities to study the molecular regulatory mechanisms for acquisition of these nutrients. This review aims to briefly discuss the genes and gene families for these transporters and channels. In addition, the functions and regulation of some important transporters and channels are particularly emphasized.     

Sodium—A Functional Plant Nutrient

Plant scientists usually classify plant mineral nutrients based on the concept of “essentiality” defined by Arnon and Stout as those elements necessary to complete the life cycle of a plant. Certain other elements such as Na have a ubiquitous presence in soils and waters and are widely taken up and utilized by plants, but are not considered as plant nutrients because they do not meet the strict definition of “essentiality.” Sodium has a very specific function in the concentration of carbon dioxide in a limited number of C₄ plants and thus is essential to these plants, but this in itself is insufficient to generalize that Na is essential for higher plants. The unique set of roles that Na can play in plant metabolism suggests that the basic concept of what comprises a plant nutrient should be reexamined. We contend that the class of plant mineral nutrients should be comprised not only of those elements necessary for completing the life cycle, but also those elements which promote maximal biomass yield and/or which reduce the requirement (critical level) of an essential element. We suggest that nutrients functioning in this latter manner should be termed “functional nutrients.” Thus plant mineral nutrients would be comprised of two major groups, “essential nutrients” and “functional nutrients.” We present an array of evidence and arguments to support the classification of Na as a “functional nutrient,” including its requirement for maximal biomass growth for many plants and its demonstrated ability to replace K in a number of ways, such as being an osmoticium for cell enlargement and as an accompanying cation for long-distance transport. Although in this paper we have only attempted to make the case for Na being a “functional nutrient,” other elements such as Si and Se may also confirm to the proposed category of “functional nutrients.”     

Dynamic root growth and architecture responses to limiting nutrient availability: linking physiological models and experimentation

In recent years the study of root phenotypic plasticity in response to sub-optimal environmental factors and the genetic control of these responses have received renewed attention. As a path to increased productivity, in particular for low fertility soils, several applied research projects worldwide target the improvement of crop root traits both in plant breeding and biotechnology contexts. To assist these tasks and address the challenge of optimizing root growth and architecture for enhanced mineral resource use, the development of realistic simulation models is of great importance. We review this research field from a modeling perspective focusing particularly on nutrient acquisition strategies for crop production on low nitrogen and low phosphorous soils. Soil heterogeneity and the dynamics of nutrient availability in the soil pose a challenging environment in which plants have to forage efficiently for nutrients in order to maintain their internal nutrient homeostasis throughout their life cycle. Mathematical models assist in understanding plant growth strategies and associated root phenes that have potential to be tested and introduced in physiological breeding programs. At the same time, we stress that it is necessary to carefully consider model assumptions and development from a whole plant-resource allocation perspective and to introduce or refine modules simulating explicitly root growth and architecture dynamics through ontogeny with reference to key factors that constrain root growth. In this view it is important to understand negative feedbacks such as plant–plant competition. We conclude by briefly touching on available and developing technologies for quantitative root phenotyping from lab to field, from quantification of partial root profiles in the field to 3D reconstruction of whole root systems. Finally, we discuss how these approaches can and should be tightly linked to modeling to explore the root phenome.     

Endophyte roles in nutrient acquisition,root system architecture development and oxidative stress tolerance

Plants associate with communities of microbes (bacteria and fungi) that play critical roles in plant development, nutrient acquisition and oxidative stress tolerance. The major share of plant microbiota is endophytes which inhabit plant tissues and help them in various capacities. In this article, we have reviewed what is presently known with regard to how endophytic microbes interact with plants to modulate root development, branching, root hair formation and their implications in overall plant development. Endophytic microbes link the interactions of plants, rhizospheric microbes and soil to promote nutrient solubilization and further vectoring these nutrients to the plant roots making the soil-plant-microbe continuum. Further, plant roots internalize microbes and oxidatively extract nutrients from microbes in the rhizophagy cycle. The oxidative interactions between endophytes and plants result in the acquisition of nutrients by plants and are also instrumental in oxidative stress tolerance of plants. It is evident that plants actively cultivate microbes internally, on surfaces and in soils to acquire nutrients, modulate development and improve health. Understanding this continuum could be of greater significance in connecting endophytes with the hidden half of the plant that can also be harnessed in applied terms to enhance nutrient acquisition through the development of favourable root system architecture for sustainable production under stress conditions.     

矿质元素互作及重金属污染的研究进展

随着工农业的发展,重金属污染问题在我国越来越严重。矿质元素互作的研究是理解重金属植物体内迁移规律,解决矿质营养利用和重金属污染治理的矛盾以及重金属复合污染问题的必然要求。本文从几个与重金属关系密切的矿质元素入手,并结合离子组学的发展,简要介绍了矿质元素与重金属的互作方面的主要进展,并对解决重金属污染和重金属复合污染问题进行了探讨。     

Plant–microbe interactions at multiple scales across a high-elevation landscape

Here we review the numerous studies of plant–microbe interactions conducted at the Niwot Ridge LTER site in Colorado, USA. By synthesising work at scales ranging from the rhizosphere to the landscape, we offer a mechanistic view of how these interactions are essential to understanding the spatial and temporal structuring of plant and microbial communities across this diverse and changing landscape. These new insights are also important for making predictions about how both plant and microbial communities and populations will respond to future changes in this environment, especially with regard to the potential uphill movement of plants and microbes in response to climate change and nitrogen deposition. We predict that the uphill movement of plants and microbes will be especially apparent, and have the most impact, in areas of the alpine that are now mostly plant free. These areas are currently undergoing a shift from a microbe-dominated ecosystem to one where microbe–plant interactions will play a critical role in reducing nutrient losses to downstream ecosystems.     

Current developments in arbuscular mycorrhizal fungi research and its role in salinity stress alleviation: a biotechnological perspective

Arbuscular mycorrhizal fungi (AMF) form widespread symbiotic associations with 80% of known land plants. They play a major role in plant nutrition, growth, water absorption, nutrient cycling and protection from pathogens, and as a result, contribute to ecosystem processes. Salinity stress conditions undoubtedly limit plant productivity and, therefore, the role of AMF as a biological tool for improving plant salt stress tolerance, is gaining economic importance worldwide. However, this approach requires a better understanding of how plants and AMF intimately interact with each other in saline environments and how this interaction leads to physiological changes in plants. This knowledge is important to develop sustainable strategies for successful utilization of AMF to improve plant health under a variety of stress conditions. Recent advances in the field of molecular biology, “omics” technology and advanced microscopy can provide new insight about these mechanisms of interaction between AMF and plants, as well as other microbes. This review mainly discusses the effect of salinity on AMF and plants, and role of AMF in alleviation of salinity stress including insight on methods for AMF identification. The focus remains on latest advancements in mycorrhizal research that can potentially offer an integrative understanding of the role of AMF in salinity tolerance and sustainable crop production.     

When microbes and consumers determine the limiting nutrient of autotrophs: a theoretical analysis

Ecological stoichiometry postulates that differential nutrient recycling of elements such as nitrogen and phosphorus by consumers can shift the element that limits plant growth. However, this hypothesis has so far considered the effect of consumers, mostly herbivores, out of their food-web context. Microbial decomposers are important components of food webs, and might prove as important as consumers in changing the availability of elements for plants. In this theoretical study, we investigate how decomposers determine the nutrient that limits plants, both by feeding on nutrients and organic carbon released by plants and consumers, and by being fed upon by omnivorous consumers. We show that decomposers can greatly alter the relative availability of nutrients for plants. The type of limiting nutrient promoted by decomposers depends on their own elemental composition and, when applicable, on their ingestion by consumers. Our results highlight the limitations of previous stoichiometric theories of plant nutrient limitation control, which often ignored trophic levels other than plants and herbivores. They also suggest that detrital chains play an important role in determining plant nutrient limitation in many ecosystems.     

Can ectomycorrhizal weathering activity respond to host nutrient demands?

Ectomycorrhizal fungi may make a significant contribution to mineral weathering in temperate and boreal forests. It is important to know how this weathering activity will be affected by the changing nutrient demands of forests impacted by global change and nitrogen deposition. This review examines what is known about how plants sense and respond to nutrient demand and discusses the existing literature on ectomycorrhizal weathering in relation to plant nutrient demand. Plant physiology literature indicates that plants can respond to P limitation by allocating more carbon belowground and increasing root branching in areas of high P availability. Increased expression and upregulation of phosphorus and potassium uptake transporters has been observed under P- and K-limitation, respectively. There is evidence for a negative feedback between Mg- and K-deficiency and belowground carbon allocation. There are very few ectomycorrhizal weathering experiments that explicitly test how weathering activity responds to nutrient demand. Field studies suggest that hyphal colonization of readily available P sources does increase with increased P demand of the host. In microcosm studies there is indirect evidence that weathering activity may increase in response to P, K, or Mg demand. Recommendations are made for how future ectomycorrhizal research can better address this question. More research on how plants sense and respond to nutrient limitation, as well as genomic data from gymnosperms would also aid our understanding of this important aspect of forest ecology.     

Understanding the significance of sulfur in improving salinity tolerance in plants

Salinity is a major abiotic stress factor affecting plant growth and productivity worldwide. The salinity-induced reduction in photosynthesis, growth and development of plants is associated with ionic/osmotic effects, nutritional imbalance or oxidative stress. Plants develop several mechanisms to induce tolerance to overcome salinity effects. Of the several possible mechanisms to reduce the effects of salinity stress, management of mineral nutrients status of plants can be the efficient defense system. Sulfur (S) is an important plant nutrient involved in plant growth and development. It is considered fourth in importance after nitrogen, phosphorus, and potassium. It is an integral part of several important compounds, such as vitamins, co-enzymes, phytohormones and reduced sulfur compounds that decipher growth and vigor of plants under optimal and stress conditions. The present review focuses on improving our understanding on the salinity effects on physiology and metabolism of plants and the importance of sulfur in salinity tolerance.     

Study of the ionome and uptake fluxes in cherry tomato plants under moderate water stress conditions

Nutritional imbalance under water-deficit conditions depresses plant growth by affecting nutrient uptake, transport, and distribution. The present work analyses the variations in the foliar concentrations of macro- and micronutrients as well as the transport of these nutrients in five cherry tomato cultivars under well-watered and moderately water-stressed conditions with the aim of establishing whether the ionome of the plants is related to the degree of sensitivity or tolerance to this type of stress. The results show a general reduction in growth together with a lower concentrations and uptake both of macro- as well as micronutrients in all the cultivars studied, except for cv. Zarina, which showed better growth and increased in concentrations and uptake nitrogen, phosphorus, magnesium, potassium, and chloride with respect to control plants. In conclusion, in this work, our results suggest that a better understanding of the role of the mineral elements in plant resistance to drought could improve fertilization in arid and semi-arid regions in order to increase the tolerance of plants grown under these conditions.     

Improving crop nutrient efficiency through root architecture modifications

Improving crop nutrient ef ficiency becomes an essential consideration for environmentally friendly and sustainable agriculture. Plant growth and development is dependent on 17 essential nutrient elements,among them,nitrogen(N) and phosphorus(P) are the two most important mineral nutrients. Hence it is not surprising that low N and/or low P availability in soils severely constrains crop growth and productivity,and thereby have become high priority targets for improving nutrient ef ficiency in crops. Root exploration largely determines the ability of plants to acquire mineral nutrients from soils. Therefore,root architecture,the 3-dimensional con figuration of the plant's root system in the soil,is of great importance for improving crop nutrient ef ficiency. Furthermore,the symbiotic associations between host plants and arbuscular mycorrhiza fungi/rhizobial bacteria,are additional important strategies to enhance nutrient acquisition. In this review,we summarize the recent advances in the current understanding of crop species control of root architecture alterations in response to nutrient availability and root/microbe symbioses,through gene or QTL regulation,which results in enhanced nutrient acquisition.     

Nitrogen transport in the ectomycorrhiza association: the Hebeloma cylindrosporum-Pinus pinaster model

The function of the ectomycorrhizal mutualism depends on the ability of the fungal symbionts to take up nutrients (particularly nitrogen) available in inorganic and/or organic form in the soil and to translocate them (or their metabolites) to the symbiotic roots. A better understanding of the molecular mechanisms underlying nutrient exchanges between fungus and plant at the symbiotic interface is necessary to fully understand the function of the mycorrhizal symbioses. The present review reports the characterization of several genes putatively involved in nitrogen uptake and transfer in the Hebeloma cylindrosporum-Pinus pinaster ectomycorrhizal association. Study of this model system will further clarify the symbiotic nutrient exchange which plays a major role in plant nutrition as well as in resistance of plants against pathogens, heavy metals, drought stress, etc. Ultimately, ecological balance is maintained and/or improved with the help of symbiotic associations, and therefore, warrant further understanding.     

Potassium: a vital nutrient mediating stress tolerance in plants

Nutrients have been known to affect stress conditions, in fact, nutrient deprivations are stress conditions for plants itself. Likewise, three important nutrients Nitrogen (N), Phosphorus (P) and Potassium (K) mediates major stress responses in plants. Here, involvement of K has been discussed briefly in plant stress response along with its impact on plant development. K has been regarded as immensely important nutrient in agriculture, hence, its deficiency triggers various signaling cascades, finally enabling plants to activate stress adaptation responses. So far, K⁺ has been reported to play pivotal role in various abiotic stresses such as drought, cold, water stresses etc. However, the exact mechanism and interplay of these different abiotic stress regulation by K⁺ is not completely explored and demand further functional investigations. The in-depth understanding of components involved in K⁺ sensing, transport, and homeostasis will enable plant biologist to engineer crop varieties tolerant to abiotic stresses and nutrient deficient soil in near future.

     

固氮菌缓解氮限制环境中丛枝菌根真菌对加拿大一枝黄花的营养竞争

丛枝菌根真菌(AMF)能与大多数陆生植物的根系形成共生体, 有助于宿主植物吸收养分。但营养胁迫下, 根系微生物对AMF与宿主植物间关系的影响少见报道。该研究假设: 在营养极度匮乏(如氮胁迫)环境下, AMF与宿主植物可能产生营养竞争, 而固氮菌的介入能够缓解两者对营养的竞争关系。为了验证这一假设, 该文探究了加拿大一枝黄花(Solidago canadensis)生长受限的氮浓度, 并在氮受限条件下检验了AMF、加拿大一枝黄花及固氮菌三者间的关系。结果表明: 低氮处理明显抑制了加拿大一枝黄花的地上生物量和总生物量, 尤其以0.025 mmol·L^-1 N的氨态氮对加拿大一枝黄花的负影响更甚。在此氮浓度下, 单独添加AMF总体上都进一步抑制了加拿大一枝黄花的生长, 而固氮菌的添加在一定程度上提高了氮受限条件下AMF对宿主的根部侵染率及宿主植物生物量。这表明固氮菌能够缓和氮受限条件下AMF和加拿大一枝黄花间的营养竞争关系。研究结果加深了对外来植物在极度营养胁迫环境下与多种微生物互作的入侵机制的理解。     

Nitrogen-fixing bacteria alleviates competition between arbuscular mycorrhizal fungi and Solidago canadensis for nutrients under nitrogen limitation

丛枝菌根真菌(AMF)能与大多数陆生植物的根系形成共生体, 有助于宿主植物吸收养分。但营养胁迫下, 根系微生物对AMF与宿主植物间关系的影响少见报道。该研究假设: 在营养极度匮乏(如氮胁迫)环境下, AMF与宿主植物可能产生营养竞争, 而固氮菌的介入能够缓解两者对营养的竞争关系。为了验证这一假设, 该文探究了加拿大一枝黄花(Solidago canadensis)生长受限的氮浓度, 并在氮受限条件下检验了AMF、加拿大一枝黄花及固氮菌三者间的关系。结果表明: 低氮处理明显抑制了加拿大一枝黄花的地上生物量和总生物量, 尤其以0.025 mmol·L^-1 N的氨态氮对加拿大一枝黄花的负影响更甚。在此氮浓度下, 单独添加AMF总体上都进一步抑制了加拿大一枝黄花的生长, 而固氮菌的添加在一定程度上提高了氮受限条件下AMF对宿主的根部侵染率及宿主植物生物量。这表明固氮菌能够缓和氮受限条件下AMF和加拿大一枝黄花间的营养竞争关系。研究结果加深了对外来植物在极度营养胁迫环境下与多种微生物互作的入侵机制的理解。