Soil NH4
+/NO3
− nitrogen characteristics in primary forests and the adaptability of some coniferous species |
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| Authors: | Xiaoyang Cui Jinfeng Song |
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| Institution: | (1) College of Forestry, Northeast Forestry University, Harbin, 150040, China |
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| Abstract: | In terrestrial ecosystems, soil nutrient regimes at a plant’s living site generally represent the plant’s “nutrition habitat”.
Plant species frequently well adapt to their original “nutrition habitat” during a long process of evolution, and the apparent
preference for ammonium or nitrate nitrogen source (NH4
+ or NO3
−) might be an important aspect of the adaptation. Plants typically favor the nitrogen form most abundant in their natural
habitats. Nitrate has been recognized as the dominant mineral nitrogen form in most agricultural soils and the main nitrogen
source for crops, but it is not usually the case in forest ecosystems. A large number of studies show that the “nutrition
habitats” associated with primary forest soils are typically dominated by NH4
+ rather than NO3
−, generally with NO3
− content much lower than NH4
+. Low levels of NO3
− in these forest soils generally correspond to low net rates of nitrification. The probable reasons for this phenomenon include:
1) nitrification limitations and/or inhibitions caused by lower pH, lower NH4
+ availability (autotrophic nitrifiers cannot successfully compete for NH4
+ with heterotrophic organisms and plants), or allelopathic inhibitors (tannins or higher-molecular-weight proanthocyanidins)
in the soil; or 2) substantial microbial acquisition of nitrate in the soils, which makes net nitrification rates substantially
less than gross nitrification rates even though the latter are relatively high.
Many coniferous species (especially such late successional tree species as Tsuga heterophylla, Pinus banksiana, Picea glauca, Pseudotsuga meziesii, Picea abies, etc.) fully adapt to their original NH4
+-dominated “nutrition habitats” so that their capacities of absorbing and using non-reduced forms of nitrogen (e.g., NO3
−) substantially decrease. These conifers typically show distinct preference to NH4
+ and reduced growth due to nitrogen-metabolism disorder when NO3
− is the main nitrogen source. The physiological and biochemical mechanisms that account for the adaptation to NH4
+-dominated systems (or limited ability to use NO3
−) for the coniferous species include: i) distribution and activity of enzymes for catalyzing nitrogen reduction and assimilation,
generally characterized by lower nitrate reductase (NR); ii) greater tolerance to NH4
+ or rapid detoxification of ammonium nitrogen in the roots; iii) lower capacity of absorption to NO3
− by roots that might be controlled by feedback regulations of certain N-transport compounds, such as glutamine; iv) relations
and balance between nitrogen and other elements (such as Ca2+, Mg2+, and Zn2+ etc.). Some NH4
+-preferred conifers might be more adapted (tolerant) to lower base cation conditions; v) NO3
− nutrition, rather than NH4
+, that may lead to the loss of considerable quantities of organic and inorganic carbon to the surrounding media and mycorrhizal
symbiont and probably contribute to slower growth; and vi) the metabolic cost of reducing NO3
− to NH4
+ that may make shade-tolerant conifers favor the uptake of reduced nitrogen (NH4
+).
The adaptation of late successional conifers to NH4
+-dominated habitats has profound ecological implications. First, it might be an important prerequisite for the climax forest
communities dominated by these conifers to maintain long-term stability. Second, primary coniferous or coniferous-broadleaved
forests have been widely perturbed because of commercial exploitation, where the soil ammonium nitrogen pool tends to be largely
transformed to nitrate after disturbance. In such a situation, the coniferous species that were dominant in undisturbed ecosystems
may become poor competitors for nitrogen, and the site will be occupied by early successional (pioneer) plants better adapted
to nitrate utilization. In other words, the implicit adaptation of many conifers dominant in undisturbed communities to ammonium
nitrogen will cause difficulties in their regeneration on disturbed sites, which must be taken into account in the practical
restoration of degraded temperate forest ecosystems.
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Translated from Acta Ecologica Sinica, 2005, 25(11): 3,082–3,092 译自: 生态学报] |
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| Keywords: | forest soil ammonium nitrate coniferous trees adaptation physiological and biochemical mechanisms |
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