质外体pH值和单木质醇添加速率对玉米木质素形成和细胞壁降解性的影响

Apoplastic pH and monolignol addition rate effects on lignin formation and cell wall degradability in maize.

作者信息

Grabber John H, Hatfield Ronald D, Ralph John

机构信息

U.S. Dairy Forage Research Center, Agricultural Research Service, U.S. Department of Agriculture, 1925 Linden Drive West, Madison, Wisconsin 53706, USA.

出版信息

J Agric Food Chem. 2003 Aug 13;51(17):4984-9. doi: 10.1021/jf030027c.

DOI:10.1021/jf030027c

PMID:12903957

Abstract

Monolignol polymerization rate and apoplastic pH and may influence the formation of lignin and its interactions in cell walls. Primary maize walls were artificially lignified by gradual "end-wise" or rapid "bulk" polymerization of coniferyl alcohol at pH 4 or 5.5. Lignification efficiency was greatest for end-wise polymers at pH 5.5 (90-98%), intermediate for bulk polymers formed at either pH (54-82%), and lowest for end-wise polymers at pH 4 (41-53%). End-wise polymers had about 2.2-fold more ether inter-unit linkages and 70% fewer end-groups than bulk polymers. Low pH enhanced the formation of ether linkages in end-wise but not in bulk polymers. Differences in lignin structure did not influence the enzymatic degradability of cell walls, but lowering apoplastic pH from 5.5 to 4.0 during lignification reduced cell wall degradability by 25%. Further studies indicated this pH-dependent depression in degradability was related to cell wall cross-links formed via lignin quinone methide intermediates.

摘要

单体木质素聚合速率和质外体pH值可能会影响木质素的形成及其在细胞壁中的相互作用。通过在pH值为4或5.5的条件下，使松柏醇逐步“末端导向”或快速“整体”聚合，对玉米初生细胞壁进行人工木质化处理。在pH 5.5时，末端导向聚合物的木质化效率最高（90 - 98%），在任一pH值下形成的整体聚合物的木质化效率居中（54 - 82%），而在pH 4时末端导向聚合物的木质化效率最低（41 - 53%）。与整体聚合物相比，末端导向聚合物的醚键型单元间连接多约2.2倍，端基少70%。低pH值促进了末端导向聚合物中醚键的形成，但对整体聚合物没有影响。木质素结构的差异不影响细胞壁的酶解降解性，但在木质化过程中将质外体pH值从5.5降至4.0会使细胞壁降解性降低25%。进一步的研究表明，这种与pH值相关的降解性降低与通过木质素醌甲基化物中间体形成的细胞壁交联有关。

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质外体pH值和单木质醇添加速率对玉米木质素形成和细胞壁降解性的影响

Apoplastic pH and monolignol addition rate effects on lignin formation and cell wall degradability in maize.

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