Nitrogen assimilation is the formation of organicnitrogen compounds likeamino acids from inorganic nitrogen compounds present in the environment. Organisms likeplants,fungi and certainbacteria that canfix nitrogen gas (N₂) depend on the ability to assimilatenitrate orammonia for their needs. Other organisms, like animals, depend entirely on organic nitrogen from their food.

Plants absorb nitrogen from the soil in the form of nitrate (NO₃⁻) and ammonium (NH₄⁺). In aerobic soils wherenitrification can occur, nitrate is usually the predominant form of available nitrogen that is absorbed.^[1][2] However this is not always the case as ammonia can predominate in grasslands^[3] and in flooded, anaerobic soils likerice paddies.^[4] Plant roots themselves can affect the abundance of various forms of nitrogen by changing the pH and secreting organic compounds or oxygen.^[5] This influences microbial activities like the inter-conversion of various nitrogen species, the release of ammonia from organic matter in the soil and the fixation of nitrogen bynon-nodule-forming bacteria.

Ammonium ions are absorbed by the plant viaammonia transporters. Nitrate is taken up by several nitrate transporters that use a proton gradient to power the transport.^[6][7] Nitrogen is transported from the root to the shoot via the xylem in the form of nitrate, dissolved ammonia and amino acids. Usually^[8] (but not always^[9]) most of the nitrate reduction is carried out in the shoots while the roots reduce only a small fraction of the absorbed nitrate to ammonia. Ammonia (both absorbed and synthesized) is incorporated into amino acids via theglutamine synthetase-glutamate synthase (GS-GOGAT) pathway.^[10] While nearly all^[11] the ammonia in the root is usually incorporated into amino acids at the root itself, plants may transport significant amounts of ammonium ions in the xylem to be fixed in the shoots.^[12] This may help avoid the transport of organic compounds down to the roots just to carry the nitrogen back as amino acids.

Nitrate reduction is carried out in two steps. Nitrate is first reduced tonitrite (NO₂⁻) in the cytosol bynitrate reductase using NADH or NADPH.^[7] Nitrite is then reduced to ammonia in the chloroplasts (plastids in roots) by aferredoxin dependentnitrite reductase. In photosynthesizing tissues, it uses an isoform of ferredoxin (Fd1) that is reduced byPSI while in the root it uses a form of ferredoxin (Fd3) that has a less negative midpoint potential and can be reduced easily by NADPH.^[13] In non photosynthesizing tissues, NADPH is generated byglycolysis and thepentose phosphate pathway.

In the chloroplasts,^[14] glutamine synthetase incorporates this ammonia as the amide group ofglutamine usingglutamate as a substrate. Glutamate synthase (Fd-GOGAT andNADH-GOGAT) transfer the amide group onto a 2-oxoglutarate molecule producing two glutamates. Further transaminations are carried out make other amino acids (most commonlyasparagine) from glutamine. While the enzymeglutamate dehydrogenase (GDH) does not play a direct role in the assimilation, it protects the mitochondrial functions during periods of high nitrogen metabolism and takes part in nitrogen remobilization.^[15]

Every nitrate ion reduced to ammonia produces one OH⁻ ion. To maintain a pH balance, the plant must either excrete it into the surrounding medium or neutralize it with organic acids. This results in the medium around the plants roots becoming alkaline when they take up nitrate.

To maintain ionic balance, every NO₃⁻ taken into the root must be accompanied by either the uptake of a cation or the excretion of an anion. Plants like tomatoes take up metal ions like K⁺, Na⁺, Ca²⁺ and Mg²⁺ to exactly match every nitrate taken up and store these as the salts of organic acids likemalate andoxalate.^[16] Other plants like the soybean balance most of their NO₃⁻ intake with the excretion of OH⁻ or HCO₃⁻.^[17]

Plants that reduce nitrates in the shoots and excrete alkali from their roots need to transport the alkali in an inert form from the shoots to the roots. To achieve this they synthesize malic acid in the leaves from neutral precursors like carbohydrates. The potassium ions brought to the leaves along with the nitrate in the xylem are then sent along with the malate to the roots via the phloem. In the roots, the malate is consumed. When malate is converted back to malic acid prior to use, an OH⁻ is released and excreted. (RCOO⁻ + H₂O -> RCOOH +OH⁻) The potassium ions are then recirculated up the xylem with fresh nitrate. Thus the plants avoid having to absorb and store excess salts and also transport the OH⁻.^[18]

Plants like castor reduce a lot of nitrate in the root itself, and excrete the resulting base. Some of the base produced in the shoots is transported to the roots as salts of organic acids while a small amount of the carboxylates are just stored in the shoot itself.^[19]

Nitrogen use efficiency (NUE) is the proportion of nitrogen present that a plant absorbs and uses. Improving nitrogen use efficiency and thus fertilizer efficiency is important to make agriculture more sustainable,^[20] by reducing pollution (fertilizer runoff) and production cost and increasing yield. Worldwide, crops generally have less than 50% NUE.^[21] Better fertilizers, improved crop management,^[21] selective breeding,^[22] andgenetic engineering^[20][23] can increase NUE.

Nitrogen use efficiency can be measured at various levels: the crop plant, the soil, by fertilizer input, by ecosystem productivity, etc.^[24] At the level of photosynthesis in leaves, it is termedphotosynthetic nitrogen use efficiency (PNUE).^[25][26]

• Nitrogen cycle
• Nitrogen
• Metabolism
• Plant physiology

• Articles with short description
• Short description is different from Wikidata