常见铁肥品种及其使用效果综述

铁是植物正常生长必需的微量营养元素之一。铁虽然在土壤中的丰度很高,但植物可以吸收利用的有效铁很少,导致植物极易缺铁,尤其是在干旱、半干旱的石灰性土壤上,缺铁现象较为严重。利用农艺和生物技术手段解决植物缺铁的效果尚不十分明显,施用铁肥仍是纠正植物缺铁常用的有效方法。国内常用铁肥品种主要有硫酸亚铁为主的无机铁肥和一些有机物与铁复合形成的铁肥(木质素磺酸铁、腐殖酸铁)。乙二胺四乙酸(EDTA)铁肥稳定性相对较低,且EDTA会转化成二酮哌嗪,成为持久性有机污染物。国外推广使用乙二胺二邻羟苯基乙酸(EDDHA)、乙二胺二(2-羟基-4-甲酰-苯基)乙酸(EDDHMA)、乙二胺二(2-羟基-4-磺基-苯基)乙酸(EDDHSA)等新型螯合铁肥,用作土施或叶面喷施。另外市场上也出现了新型缓释铁肥和一些可生物降解螯合铁肥,如亚氨基二琥珀酸铁(IDHA/Fe3+)和乙二胺二琥珀酸铁(EDDS/Fe3+)。本文就常见的铁肥品种及其性质与效果等方面的研究进展进行了综述。     

Nutrient deficiencies and toxicities in plants: Nitrogen

Current literature review and discussion of the N status of plants as related to their growth and yield and quality of produced product.     

A proposed method to determine adequate amount of fertilizers to be applied to crops

To determine the adequate amounts of fertilizers to be applied to crops is one of the most important problems in the field of soil science.     

Recent advances in the chemistry of nitrogen,phosphorus and potassium as fertilizers in soil: A review

The advent of civilization has made humans dependent on plants for food and medicine, leading to the intensification of agricultural production. The intense cultivation of crops has resulted in the depletion of available nutrients from soil, thereby demanding the application of excess nutrients to soil to improve yield. Thus, mineral fertilizer discovery and application have, in many ways, contributed greatly to meeting global food demands. However, aside from the positive effects of mineral fer...     

机器学习在氮循环领域的应用研究进展

氮循环是地球圈层中水-土-气-生多介质、多界面的复杂过程，与土壤健康、粮食安全、全球变暖、空气污染、水体质量等环境问题密切相关。近年来，得益于计算机技术的快速发展和海量、多源数据的产生，机器学习迅速成为研究氮素循环强有力的工具。本文系统梳理了机器学习的功能性概念，包括典型开发流程和学习应用场景等；总结了机器学习的典型应用算法，包括经典机器学习（如随机森林、支持向量机等）和深度学习（如卷积神经网络、长短期记忆网络等）；并综述了机器学习在氮循环研究领域的应用研究进展，包括大气、水体、土壤和植物/作物等介质的氮素代谢机制、模拟氮素循环过程及管理氮素流动等。未来基于大数据和机器学习技术的特征工程和模型融合的研究，将会给氮循环领域的数据分析与建模带来巨大变革。同时，将机器学习与基于物理过程的模型相结合解决氮循环过程中的复杂问题，可为服务国家“双碳”战略以及控制全球变暖、空气污染等环境问题提供重要支撑。     

Exogenous application of vitamins as regulators for growth and development of plants — a review

A survey of the recent literature on plant responses to exogenous vitamin application yielded the following results:

• Vitamins have been applied by soaking seeds, dipping cuttings, by sprays or dusts and as drenches to soils.
• Substantial yield increases due to exogenous vitamin application have been reported by a number of researchers.
• Vitamins may cause morphogenetic responses in plants. Most pronounced is the stimulation of root formation and of flowering under non-inductive conditions.
• Certain vitamins protect plants against ozone and sulfur dioxide, two important agents of air pollution.

     

The role of the apoplast in aluminium toxicity and resistance of higher plants: A review

In acid mineral soils excess of aluminium ions (AI) is one of the most important factors determining plant species and ecotype distribution, and limiting growth and yield of crops. Aluminium preferentially accumulates in the root tips as sites of cell division and cell elongation. Whether inhibition of cell-division rate is due to direct interaction of Al with the chromatin in the nuclei is rather questionable because of the low radial mobility of Al in the root and the rapidity of cessation of root elongation after Al addition to the growth medium. Externally applied Al instantaneously binds to binding sites in the apoplast. Cross binding of pectates by Al may affect extensibility and water permeability of the cell wall. Interaction of Al with other cell-wall constituents is most likely but needs clarification. Aluminium also affects plasma-membrane characteristics. Ca²⁺ influx and K⁺ efflux are inhibited, and synthesis of callose is induced. Induction of callose suggests an increase rather than a decrease in cytosolic Ca²⁺ as initial response to Al. There is little evidence suggesting major disruption of plasma membrane and cytoplasmic functions by AI. K⁺ uptake, H⁺ extrusion, Fe(III) reducing capacity and lipid peroxidation are hardly affected even in roots severely inhibited in elongation by Al. Al uptake and physiological/biochemical effects of Al on intact plant roots can be mimicked even more sensitively using cell suspension cultures which, therefore, represent a powerful tool for the study of Al toxicity. Large differences in Al resistance exist between plant species and cultivars of a species. Root elongation-rate and callose formation can be used as indicators for Al injury. Since short term Al injury is mainly expressed in the apoplast. Al resistance requires exclusion of Al from or/and inactivation of Al in the apoplast. Generally, Al-resistant genotypes are characterized by lower Al accumulation of the root apical meristems. This is achieved by a lower cation-exchange capacity/surface negativity or complexation of Al through root exudates (mucilage, organic acids). Long term exposure of plants to Al also inhibits shoot growth via induction of nutrient (Mg, Ca, P) deficiencies, drought stress and phytohormone imbalances. Such longer term effects have to be taken into consideration when selecting genotypes for high yielding capacity on acid soils high in available Al.     

植物对镉毒害的形态和生理响应研究进展

Cadmium (Cd) contamination has posed an increasing challenge to environmental quality and food security.In recent years,phytoremediation has been particularly scrutinized because it is cost-effective and environmentally friendly,especially the use of metal-hyperaccumulating plants to extract or mine heavy metals from polluted soils.Under Cd stress,responses of hyperaccumulator and non-hyperaccumulator plants differ in morphological responses and physiological processes such as photosynthesis and respiration,uptake,transport,and assimilation of minerals and nitrogen,and water uptake and transport,which contribute to their ability to accumulate and detoxify Cd.This review aims to provide a brief overview of the recent progresses in the differential responses of hyperaccumulator and non-accumulator plants to Cd toxicity in terms of growth and physiological processes.Such information might be useful in developing phytoremediation technology for contaminated soils.     

A review of the conservation threats to carnivorous plants

Over half of the carnivorous plant species assessed by the International Union for the Conservation of Nature (IUCN) are listed as threatened (i.e. vulnerable, endangered, or critically endangered), but the threats to carnivorous plants have not previously been quantified systematically. In this review, we quantify the conservation threats to carnivorous plant taxa worldwide. Using the IUCN Red List, a literature search of Web of Knowledge, and the National Red Lists database, we collected data on the threats to 48 species of carnivorous plants from nine genera. The most common threat was habitat loss from agriculture, followed by the collection of wild plants, pollution, and natural systems modifications. A principal coordinate analysis revealed that species within a genus often faced similar threats, and an indicator species analysis found positive associations among species in the genus Sarracenia and agricultural activities, over-collection, invasive species, and pollution. Future research should further quantify the effects of pollution on carnivorous plants, and more thoroughly examine the potential role of carnivorous plants as indicator species for wetland health. More research is also needed to quantify the extinction risk for many carnivorous plants, as presently only around 17% of species have been assessed by the IUCN. Ensuring the conservation of carnivorous plants will help maintain the important ecosystem services they provide and prevent secondary extinctions of specialist species that rely on them.     

Diversity and versatile functions of metallothioneins produced by plants: A review

Metal ions are essential for plant growth and development,but in excess,these compounds can become highly toxic.Plants have adopted numerous ways to maintain metal homeostasis while mitigating adverse effects of excess metal ions,including phytochelatin and the metal-chelating proteins metallothioneins(MTs).A family of cysteine(Cys)-rich,intracellular,and low-molecular-weight(4–8 kDa) MTs are proteins found in nearly all phyla including plants,animals,and fungi,and they have the potential to scavenge reactive oxygen species and detoxify toxic metals including copper,cadmium,and zinc.Based on their Cys numbers and residues,MTs have been categorized into three major classes.Class I MTs,which have highly conserved Cys residues,are found in animals,while class II MTs,with less conserved Cys residues,are present in plants and are classified further into four groups.Class III MTs include phytochelatins,a group of enzymatically synthesized Cys-rich proteins.The MTs have been an area of interest for five decades with extensive studies,which have been facilitated by advancements in instrumental techniques,protein science,and molecular biology tools.Here,we reviewed current advances in our understanding of the regulation of MT biosynthesis,their expression,and their potential roles in the alleviation of abiotic stresses(i.e.,drought,salinity,and oxidative stresses) and heavy metal detoxification and homeostasis.     

The effects of recreation on freshwater plants and animals: A review

This paper reviews the impacts of recreation on freshwater plants and animals. A distinction is made between water- and shore-based activities, and between physical and chemical effects. The impacts of water-based recreation, which result mainly from boating, are discussed in terms of wash, turbulence and turbidity, propeller action, direct contact, disturbance to animals, pollution from outboard motors and sewage. Those resulting from shore-based activities, such as angling and swimming, include trampling and associated effects, as well as sewage and other chemical impacts. The effects of management for recreation are also considered. There is relatively more information on the effects of recreational activities on plants than on animals, but the authors consider that further research is required in both fields. Some possible approaches are presented.     

植物修复金属污染土壤上丛枝菌根真菌与植物之间的交互作用

Metal contamination in the environment is a global concern due to its high toxicity to living organisms and its worldwide distribution.The principal goal of this review is to examine the current strategies and technologies for the remediation of metalcontaminated soils by metal-accumulating plants and assess the roles of arbuscular mycorrhizal(AM)fungi in remediation of soils under hyperaccumulator or non-accumulator plants.The use of plants to remove metals from the environment or reduce the toxicity,known as phytoremediation,is an environmentally sustainable and low cost remediation technology.The mechanisms of the use of hyperaccumulator plants for phytoremediation included solubilization of the metal in the soil matrix,the plant uptake of the metal,detoxification/chelation and sequestration,and volatilization.Recently,some ecologists have found that phytoremediation with the aids of mycorrhizae can enhance efciency in the removal of toxic metals.AM fungi can facilitate the survival of their host plants growing on metal-contaminated land by enhancing their nutrient acquisition,protecting them from the metal toxicity,absorbing metals,and also enhancing phytostabilization and phytoextraction.Such information may be useful for developing phytoremediation program at metal-contaminated sites.     

植物钾吸收的分子水平研究

本文从钾离子通道、高亲和力K+ 转运体和H+ -ATP酶等 3方面综述了K+营养的分子生物学、生理生化等的研究结果。植物钾吸收与这 3类转运蛋白的关系极为密切。主要论述K+转运体和K+通道及其介导高低亲和力钾吸收方面的作用 ,以及 3类转运蛋白的调节 ,蛋白的表达 ,调节影响K+的吸收运输和利用     

硅增强植物重金属耐性机理研究综述

In recent years, due to excessive emission of industrial waste, wastewater irrigation, and unreasonable utilization of fertilizers, pesticides and plastic sheeting, heavy metal pollution is increasing rapidly, resulting in many environmental problems. Silicon （Si）, as the second most abundant element in the soil, can not only stimulate plant growth, but alleviate various biotic and abiotic stresses, including heavy metal stress. Here, we reviewed recent advances in the mechanisms for Si-mediated heavy metal tolerance in plants. These mechanisms included reducing active heavy metal ions in growth media, reducing heavy metal transport to the shoot, stimulating enzymatic and non-enzymatic antioxidants, chelation, compartmentation, regulation of the expression of metal transport genes, and structural changes in plants. Further research orientation is also discussed.     

细菌、真菌及植物氮营养信号研究进展

氮素吸收代谢是所有生物生命活动的核心部分,因此,各种生物对氮的吸收与同化过程都有精细的调节。这种调节依赖于生物对体内氮素状况信号及体外（生长介质中）氮素信号的感受。过去几十年中,在细菌、真菌中已经对氮素营养信号有了较好的研究,而植物中则相对缓慢,但也有了一定的认识。本文重点比较细菌、真菌及植物中氮信号系统的组成,以期为进一步认识植物中的氮信号接受与转导系统提供启示。     

Solubilization of phosphate by rice plants growing in reduced soil: prediction of the amount solubilized and the resultant increase in uptake

Previous work has shown that rice plants growing in reduced soil are able to solubilize P by inducing an acidification in the rhizosphere through H⁺ produced in Fe²⁺ oxidation by root–released O₂, and by the direct release of H⁺ from the roots to balance excess intake of cations over anions. In this paper, equations for the diffusion and interaction of P and acid in soil are developed to predict the resultant increase in P uptake by the roots. Good agreement was obtained between the profiles of P and pH in the rhizosphere measured in the previous experiments, and those predicted using the equations with independently measured parameter values. The equations showed that solubilization accounted for over 80% of the P taken up. Measurements of the solubilization parameters in a range of reduced rice soils showed that H⁺ addition increased the quantity of P that could be desorbed per unit weight of soil and the concentration of P in solution, in all the soils tested. The quantity of P solubilized per unit H⁺ added at a given solution P concentration varied about 50–fold between soils, with a median of 11.9 mmol P per mol H⁺. The native soil solution P concentration varied 50–fold (median = 0.91 UM) and the soil pP buffer power (the quantity of P desorbed per unit decrease in –log of the P concentration in solution) varied 100–fold (median = 0.36 mmol kg^?1 pP^?1); the soil pH buffer power varied 7–fold (median = 0.075 mmol kg^?1 pH^?1). Calculations indicated that, in most of the soils tested, rice plants would depend upon solubilization for the bulk of their P.     

Nitrogen and phosphorus in runoff from grassland with buffer strips following application of fertilizers and manures

Abstract. We examined whether nitrogen (N) and phosphorus (P) export was enhanced from grassland receiving inorganic fertilizer and manures typical of intensive livestock production. Buffer strips were included in the study to determine if they could reduce nutrient export. Hillslope plots receiving granular inorganic fertilizer, liquid cattle slurry and solid cattle manure (FYM) were compared using rainfall simulation for 4 storms on consecutive days at 22 mm h^-1 and 35 minutes duration. The plots were hydrologically isolated in a randomized block layout of 4 treatments × 3 replicates and measured 30 × 5m; the upper 20m received either fertilizer, slurry or FYM, while the lower 10 m acted as an unfertilized grass buffer strip. Nitrogen and P export in surface runoff from grassland receiving inorganic fertilizer exceeded that from FYM or slurry treatments; concentrations up to46mgN1-^-1 and 15 mgP1^–1 were recorded.
Sixty eight % and 62% of the N from FYM and slurry respectively, was exported in organic form. Seventy four % (FYM) and 39% (slurry) of the P was in particulate or dissolved organic form. The buffer strip reduced N export in surface runoff by 94% and P export by 98% from inorganic fertilizer plots. A 75% reduction in N export was recorded from the buffer zone below slurry plots but only a 10% reduction in P, with most P remaining in the particulate or dissolved organic fraction. There was no significant difference in N export from the buffer zone between the inorganic fertilizer treatment and the untreated control.     

Nitrogen uptake pattern of herbaceous plants: coping strategies in altered neighbor species

The mechanisms for maintaining the species diversity of plant communities under conditions of resource limitation is an important subject in ecology. How interspecific relationships influence the pattern of nutrient absorption by coexisting species in N-limited ecosystems is still disputed. We investigated the effect of neighbor species on the uptake of inorganic and organic N by three common plant species using ¹⁵N tracer techniques in a semi-arid alpine steppe on the northern Tibet. The results showed that the plant species varied in their capacity to absorb NO₃ ^?-N, NH₄ ⁺-N, and glycine-N with or without neighbor species. Carex moorcroftii and Leontopodium nanum showed much more plasticity in resource utilization than Stipa purpurea when neighbor species were present. When C. moorcroftii and S. purpurea coexisted, they all increased their ¹⁵N uptake for the NO₃ ^?-N (C. moorcroftii 2.2-fold increase and S. purpurea 2.2-fold increase) and glycine-N treatments (C. moorcroftii 2.9-fold increase and S. purpurea 3.4-fold increase), which indicated that neighborhood had a positive effect for N absorption between the two species. However, L. nanum was a less effective competitor for N utilization than the neighbor species across almost all treatments. The dominant species appeared to have an inhibitory effect on N absorption by the accompanying species in this alpine steppe environment. Thus, interspecific neighbor pairs may result in both a mutually beneficial cooperative relationship and a competitive relationship among neighbors in resource use patterns in extreme environments. Resource use plasticity in altered neighbor species may be due to phenotypic plasticity based on the conditions of the realized niche, offering a valuable insight into niche complementarity and providing a general and important mechanism for resource partitioning in an alpine area.     

Nitrogen use efficiency with the application of controlled release fertilizers coated with Kraft pine lignin

The aim of the present paper is to assess the efficiency of several experimental fertilizers in a soil-plant system. The laboratory-prepared fertilizers consisted of granular urea coated with Kraft pine lignin. Five fertilizers were used with coatings differing in thickness and/or the addition of linseed oil as a sealing agent. The experiment was carried out in pots inside a glasshouse. The crop used was rye-grass. Results were compared with those from a urea control treatment without coating and a soil without fertilizer application.

The dry matter yield and the N uptake by the plant were higher in the treatments with coated controlled release fertilizers (CRF) than in those with uncoated urea. There was a lower nitrogen loss through leaching when using CRF (34 to 68%) was used than when using uncoated urea (over 74%) was used. The N use efficiency was lower for urea than for coated fertilizers. This index increased with the thickness of the coating and the addition of the sealing agent.     

植物对锌吸收运输及积累的生理与分子机制

锌是植物必需的营养元素,也是重金属污染元素之一。现代分子生物学的发展,极大地推动了植物体内与锌吸收运输有关转运蛋白的研究。目前发现,锌铁控制运转相关蛋白(ZIP)、自然抵抗相关巨噬细胞蛋白NRAMP、重金属ATPase酶、阳离子扩散协助蛋白CDF、Mg2+/H+的反向交换转运蛋白MHX等运输蛋白参与细胞内Zn2+离子的跨膜运输,调节植物细胞内Zn2+平衡与分配。利用数量遗传学手段在在水稻上已找到与缺锌植株死亡率和叶片青铜病发生率有关QTL位点。而在Thlaspi caerulescens 和Arabidopsis halleri植物上鉴定出控制锌含量的QTLs,为寻找控制植物高效积累Zn的遗传基础规律打下了基础。