叶片与根系暗呼吸过程中相反的碳同位素分馏作用——综述。

Opposite carbon isotope discrimination during dark respiration in leaves versus roots - a review.

机构信息

Laboratoire d'Ecologie, Systématique et Evolution (ESE), CNRS UMR8079, Bâtiment 362, Université de Paris-Sud (XI), F-91405, Orsay Cedex, France.

Consiglio per la Ricerca e la sperimentazione in Agricoltura, Genomics research centre (CRA - GPG), Via San Protaso, 302, 29017, Fiorenzuola d'Arda (PC), Italy.

出版信息

New Phytol. 2014 Feb;201(3):751-769. doi: 10.1111/nph.12563. Epub 2013 Nov 19.

DOI:10.1111/nph.12563

PMID:24251924

Abstract

In general, leaves are (13) C-depleted compared with all other organs (e.g. roots, stem/trunk and fruits). Different hypotheses are formulated in the literature to explain this difference. One of these states that CO2 respired by leaves in the dark is (13) C-enriched compared with leaf organic matter, while it is (13) C-depleted in the case of root respiration. The opposite respiratory fractionation between leaves and roots was invoked as an explanation for the widespread between-organ isotopic differences. After summarizing the basics of photosynthetic and post-photosynthetic discrimination, we mainly review the recent findings on the isotopic composition of CO2 respired by leaves (autotrophic organs) and roots (heterotrophic organs) compared with respective plant material (i.e. apparent respiratory fractionation) as well as its metabolic origin. The potential impact of such fractionation on the isotopic signal of organic matter (OM) is discussed. Some perspectives for future studies are also proposed .

摘要

一般来说，与其他器官（如根、茎/干和果实）相比，叶子中的 C 含量较低（13）。文献中提出了不同的假设来解释这种差异。其中一种观点认为，叶片在黑暗中呼吸产生的 CO2 与叶片有机物质相比，（13）C 含量较高，而在根呼吸的情况下，（13）C 含量较低。叶片和根系之间相反的呼吸分馏被认为是广泛存在的器官间同位素差异的解释。在总结了光合作用和光合作用后分馏的基础知识后，我们主要回顾了最近关于叶片（自养器官）和根（异养器官）呼吸的 CO2 同位素组成与相应植物材料（即明显呼吸分馏）以及其代谢起源的发现。还讨论了这种分馏对有机物质（OM）同位素信号的潜在影响。还提出了未来研究的一些观点。

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叶片与根系暗呼吸过程中相反的碳同位素分馏作用——综述。

Opposite carbon isotope discrimination during dark respiration in leaves versus roots - a review.

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