Molecular and physiological interactions of urea and nitrate uptake in plants

While nitrate acquisition has been extensively studied, less information is available on transport systems of urea. Furthermore, the reciprocal influence of the two sources has not been clarified, so far. In this review, we will discuss recent developments on plant response to urea and nitrate nutrition. Experimental evidence suggests that, when urea and nitrate are available in the external solution, the induction of the uptake systems of each nitrogen (N) source is limited, while plant growth and N utilization is promoted. This physiological behavior might reflect cooperation among acquisition processes, where the activation of different N assimilatory pathways (cytosolic and plastidic pathways), allow a better control on the nutrient uptake. Based on physiological and molecular evidence, plants might increase (N) metabolism promoting a more efficient assimilation of taken-up nitrogen. The beneficial effect of urea and nitrate nutrition might contribute to develop new agronomical approaches to increase the (N) use efficiency in crops.     

Variations in nitrogen use efficiency reflect the biochemical subtype while variations in water use efficiency reflect the evolutionary lineage of C4 grasses at inter‐glacial CO2

C₄ photosynthesis evolved multiple times in diverse lineages. Most physiological studies comparing C₄ plants were not conducted at the low atmospheric CO₂ prevailing during their evolution. Here, 24 C₄ grasses belonging to three biochemical subtypes [nicotinamide adenine dinucleotide malic enzyme (NAD‐ME), phosphoenolpyruvate carboxykinase (PCK) and nicotinamide adenine dinucleotide phosphate malic enzyme (NADP‐ME)] and six major evolutionary lineages were grown under ambient (400 μL L^?1) and inter‐glacial (280 μL L^?1) CO₂. We hypothesized that nitrogen‐related and water‐related physiological traits are associated with subtypes and lineages, respectively. Photosynthetic rate and stomatal conductance were constrained by the shared lineage, while variation in leaf mass per area (LMA), leaf N per area, plant dry mass and plant water use efficiency were influenced by the subtype. Subtype and lineage were equally important for explaining variations in photosynthetic nitrogen use efficiency (PNUE) and photosynthetic water use efficiency (PWUE). CO₂ treatment impacted most parameters. Overall, higher LMA and leaf N distinguished the Chloridoideae/NAD‐ME group, while NADP‐ME and PCK grasses were distinguished by higher PNUE regardless of lineage. Plants were characterized by high photosynthesis and PWUE when grown at ambient CO₂ and by high conductance at inter‐glacial CO₂. In conclusion, the evolutionary and biochemical diversity among C₄ grasses was aligned with discernible leaf physiology, but it remains unknown whether these traits represent ecophysiological adaptation.     

Energy,Nitrogen, and Farm Surplus Transitions in Agriculture from Historical Data Modeling. France, 1882–2013.

This article addresses agricultural metabolism and transitions for energy, nitrogen, farm production, self‐sufficiency, and surplus from historical data since the nineteenth century. It builds on an empirical data set on agricultural production and production means in France covering 130 consecutive years (1882–2013). Agricultural transitions have increased the net production and surplus of farms by a factor of 4 and have zeroed self‐sufficiency. The energy consumption remained quasi‐stable since 1882, but the energy and nitrogen structure of agriculture fully changed. With an EROI (energy return to energy invested) of 2 until 1950, preindustrial agriculture consumed as much energy to function as it provided in exportable surplus to sustain the nonagricultural population. The EROI doubled to 4 over the last 60 years, driven, on the one hand, by efficiency improvements in traction through the replacement of draft animals by motors and, on the other hand, by the joint increase in crop yields and efficiency in nitrogen use. Agricultural energy and nitrogen transitions shifted France from a self‐sufficiency agri‐food‐energy regime to a fossil‐dependent food export regime. Knowledge of resource conversion mechanisms over the long duration highlights the effects of changing agricultural metabolism on the system's feeding capacity. Farm self‐sufficiency is an asset against fossil fuel constraints, price volatility, and greenhouse gas emissions, but it equates to lower farm surplus in support of urbanization.     

Optimal use of leaf nitrogen explains seasonal changes in leaf nitrogen content of an understorey evergreen shrub

Background and Aims

Understorey evergreen species commonly have a higher leaf nitrogen content in winter than in summer. Tested here is a hypothesis that such changes in leaf nitrogen content maximize nitrogen-use efficiency, defined as the daily carbon gain per unit nitrogen, under given temperature and irradiance levels.

Methods

The evergreen shrub Aucuba japonica growing naturally at three sites with different irradiance regimes in Japan was studied. Leaf photosynthetic characteristics, Rubisco and leaf nitrogen with measurements of temperature and irradiance monthly at each site were determined. Daily carbon gain was determined as a function of leaf nitrogen content to calculate the optimal leaf nitrogen content that maximized daily nitrogen-use efficiency.

Key Results

As is known, the optimal leaf nitrogen content increased with increasing irradiance. The optimal leaf nitrogen content also increased with decreasing temperature because the photosynthetic capacity per Rubisco decreased. Across sites and months, the optimal leaf nitrogen content was close to the actual leaf nitrogen content and explained the variation in actual leaf nitrogen by 64 %. Sensitivity analysis showed that the effect of temperature on optimal nitrogen content was similar in magnitude to that of irradiance.

Conclusions

Understorey evergreen species regulate leaf nitrogen content so as to maximize nitrogen-use efficiency in daily carbon gain under changing irradiance and temperature conditions.     

膜下滴灌水氮调控对南疆棉花产量及水氮利用率的影响

为探明水氮调控对膜下滴灌棉花的生长特性、产量构成因素以及水氮利用效率的影响,设置了3个灌溉水量和5个氮素水平进行大田棉花膜下滴灌试验.结果表明: 随着灌溉水量的增加,棉花的株高、主茎叶数、果枝数和叶面积指数显著增加,棉花叶、茎干物质积累增加,但抑制了根系生长,与低(4950 mm·hm^-2)和高(6750 mm·hm^-2)灌水量处理相比,中灌水量(5850 mm·hm^-2)处理平均单株有效铃数和单铃质量分别增加0.96、0.4个和0.22、0.11 g.与其他施氮处理相比,施氮量为300 kg·hm^-2时棉花茎直径显著增加,促进了棉花蕾、铃和根系的发育,而且在灌水量为5850 mm·hm^-2条件下,棉花干物质由营养器官向生殖器官的分配比灌水量为4950和6750 mm·hm^-2处理分别增加5.1%和29.6%.灌溉水量对棉花产量有显著影响,对衣分率影响不显著,而施氮量对棉花产量和衣分率都有一定的影响,但灌溉水量过低会抑制氮肥增产效应的发挥.在本试验条件下,灌水量为5850 mm·hm^-2、施氮量为300 kg·hm^-2时,棉花生长健壮,株型结构优化,显著促进了干物质向生殖器官的运转,有效铃数、单铃质量和衣分增加,产量达到最高(6992 kg·hm^-2),水分利用效率和氮肥利用率分别达1.45 kg·m^-3和45.9%.     

青藏高原东部高山植物的水分利用效率与氮素利用效率研究

对生长在青藏高原东部隶属于23科、49属的71种高山植物(包括多年生和一年生植物)的稳定碳同位素比值、氮含量以及碳/氮比率进行了分析,并以稳定碳同位素比值及碳/氮比率来分别指示植物的水分利用效率和氮素利用效率.结果表明:(1)多年生植物稳定碳同位素比值显著高于一生年植物,而碳/氮比率显著低于一年生植物(P<0.01),氮含量两者无显著性差异.(2)多年生植物和一年生植物的稳定碳同位素比值均与碳/氮比率呈显著负相关(-0.643**和-0.707),而与氮含量均无明显相关性.研究证实,在自然条件下多年生植物的水分利用效率比一年生植物更高,而氮素利用效率却更低;高山植物水分利用效率和氮素利用效率存在明显的权衡",即植物不能同时提高水分利用效率和氮素利用效率,高水分利用效率的代价是降低氮素利用效率,青藏高原不同植物即使在相同环境条件下具有不同适应对策.     

向日葵种群中植株个体大小对其氮素利用策略的影响

我们利用Berendse和Aerts提出的氮素利用效率(NUE)概念及原理研究了高密度一年生草本植物向日葵(Helianthus annuus L.)种群中植株个体大小对其氮素吸收利用的影响,并对种内竞争进行了分析。结果表明,植株对氮素的吸收与其个体大小不成线性关系,说明种群内不同植株个体对土壤氮素的竞争属于非对称竞争。植株的氮素损失随着个体大小的增加而增加。个体较大的植株具有较高的氮素输入率和较低的氮素输出率,因而具有较高的氮素净增加值。植株的氮素生产力(NP)和氮素平均滞留时间(MRT)均与植株个体大小呈正相关。较大的植物个体具有较高的NP和较长的MRT,由于NUE为NP和MRT二者的乘积,因而较大个体植株的NUE高于个体较小的植株。同种植物的不同个体的NP和MRT之间不存在协衡关系。氮素回收效率(NRE)与植株个体大小密切相关。在个体水平上,较大的植株个体具有较高的NUE与其较高的NRE有关。种群内植株个体对土壤氮素的非对称竞争主要由于植株对氮素的吸收和利用效率不同所致。因此,Berendse和Aerts提出的氮素利用效率概念不仅适用于研究种间的养分利用策略,对于种内不同植株的养分策略研究也同样适用。