玉米中ca1ca2双突变体揭示碳酸酐酶在C4光合作用中的作用有限

A Limited Role for Carbonic Anhydrase in C4 Photosynthesis as Revealed by a ca1ca2 Double Mutant in Maize.

作者信息

Studer Anthony J, Gandin Anthony, Kolbe Allison R, Wang Lin, Cousins Asaph B, Brutnell Thomas P

机构信息

Donald Danforth Plant Science Center, St. Louis, Missouri 63132 (A.J.S., A.R.K., L.W., T.P.B.); andSchool of Biological Sciences, Washington State University, Pullman, Washington 99164 (A.G., A.B.C.).

Donald Danforth Plant Science Center, St. Louis, Missouri 63132 (A.J.S., A.R.K., L.W., T.P.B.); andSchool of Biological Sciences, Washington State University, Pullman, Washington 99164 (A.G., A.B.C.)

出版信息

Plant Physiol. 2014 Jun;165(2):608-617. doi: 10.1104/pp.114.237602. Epub 2014 Apr 4.

DOI:10.1104/pp.114.237602

PMID:24706552

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4044840/

Abstract

Carbonic anhydrase (CA) catalyzes the first biochemical step of the carbon-concentrating mechanism of C plants, and in C monocots it has been suggested that CA activity is near limiting for photosynthesis. Here, we test this hypothesis through the characterization of transposon-induced mutant alleles of Ca1 and Ca2 in maize (Zea mays). These two isoforms account for more than 85% of the CA transcript pool. A significant change in isotopic discrimination is observed in mutant plants, which have as little as 3% of wild-type CA activity, but surprisingly, photosynthesis is not reduced under current or elevated CO partial pressure (pCO). However, growth and rates of photosynthesis under subambient pCO are significantly impaired in the mutants. These findings suggest that, while CA is not limiting for C photosynthesis in maize at current pCO, it likely maintains high rates of photosynthesis when CO availability is reduced. Current atmospheric CO levels now exceed 400 ppm (approximately 40.53 Pa) and contrast with the low-pCO conditions under which C plants expanded their range approximately 10 million years ago, when the global atmospheric CO was below 300 ppm (approximately 30.4 Pa). Thus, as CO levels continue to rise, selective pressures for high levels of CA may be limited to arid climates where stomatal closure reduces CO availability to the leaf.

摘要

碳酸酐酶（CA）催化C₄植物碳浓缩机制的第一步生化反应，在C₄单子叶植物中，有人认为CA活性接近光合作用的限制因素。在此，我们通过对玉米（Zea mays）中Ca1和Ca2的转座子诱导突变等位基因进行表征来检验这一假设。这两种同工型占CA转录本库的85%以上。在CA活性仅为野生型3%的突变植株中观察到同位素歧视有显著变化，但令人惊讶的是，在当前或升高的CO₂分压（pCO₂）下，光合作用并未降低。然而，在低于环境pCO₂的条件下，突变体的生长和光合速率显著受损。这些发现表明，虽然在当前pCO₂水平下CA并非玉米C₄光合作用的限制因素，但当CO₂可用性降低时，它可能维持较高的光合速率。当前大气CO₂水平现已超过400 ppm（约40.53 Pa），与约1000万年前C₄植物扩展其分布范围时的低pCO₂条件形成对比，当时全球大气CO₂低于300 ppm（约30.4 Pa）。因此，随着CO₂水平持续上升，对高水平CA的选择压力可能仅限于干旱气候，在这些气候中气孔关闭会降低叶片对CO₂的可用性。

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