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3

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Plant Physiol. 1989 Oct;91(2):780-7. doi: 10.1104/pp.91.2.780.

4

Proton and copper adsorption to maize and soybean root cell walls.

Plant Physiol. 1989 Mar;89(3):823-32. doi: 10.1104/pp.89.3.823.

5

In VivoP NMR Studies of Corn Root Tissue and Its Uptake of Toxic Metals.

Plant Physiol. 1986 Jan;80(1):77-84. doi: 10.1104/pp.80.1.77.

6

Titration of Isolated Cell Walls of Lemna minor L.

Plant Physiol. 1979 Jun;63(6):1117-22. doi: 10.1104/pp.63.6.1117.

7

Exchange Properties of Isolated Cell Walls of Lemna minor L.

Plant Physiol. 1978 Oct;62(4):477-81. doi: 10.1104/pp.62.4.477.

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The Structure of Plant Cell Walls: VI. A Survey of the Walls of Suspension-cultured Monocots.

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两种对锰毒性具有不同耐受性的烟草基因型的纯化根细胞壁的表面化学性质。

Surface chemical properties of purified root cell walls from two tobacco genotypes exhibiting different tolerance to manganese toxicity.

作者信息

Wang J, Evangelou B P, Nielsen M T

机构信息

Agronomy Department, University of Kentucky, Lexington, Kentucky 40546-0091.

出版信息

Plant Physiol. 1992 Sep;100(1):496-501. doi: 10.1104/pp.100.1.496.

DOI:10.1104/pp.100.1.496

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1075577/

Abstract

Surface chemical characteristics of root cell walls extracted from two tobacco genotypes exhibiting differential tolerance to Mn toxicity were studied using potentiometric pH titration and Fourier transform infrared spectroscopy. The Mn-sensitive genotype KY 14 showed a stronger interaction of its cell wall surface with metal ions than did the Mn-tolerant genotype Tobacco Introduction (T.I.) 1112. This observation may be attributed to the relatively higher ratio of COO(-) to COOH in KY 14 cell walls than that found in the cell walls of T.I. 1112 in the pH range of 4 to 10. For both genotypes, the strength of binding between metal ions and cell wall surface was in the order of Cu > Ca > Mn > Mg > Na. However, a slightly higher preference of Ca over Mn was observed with the T.I. 1112 cell wall. This may explain the high accumulation of Mn in the leaves of Mn-tolerant genotype T.I. 1112 rather than the high accumulation of Mn in roots, as occurred in Mn-sensitive KY 14. It is concluded that surface chemical characteristics of cell walls may play an important role in plant metal ion uptake and tolerance.

摘要

利用电位滴定法和傅里叶变换红外光谱法，研究了两种对锰毒性具有不同耐受性的烟草基因型根系细胞壁的表面化学特征。对锰敏感的基因型KY 14，其细胞壁表面与金属离子的相互作用比耐锰基因型烟草引进种（T.I.）1112更强。这一观察结果可能归因于在4至10的pH范围内，KY 14细胞壁中COO(-)与COOH的比例相对高于T.I. 1112细胞壁中的比例。对于这两种基因型，金属离子与细胞壁表面的结合强度顺序为Cu > Ca > Mn > Mg > Na。然而，在T.I. 1112细胞壁中观察到Ca对Mn的偏好略高。这可能解释了耐锰基因型T.I. 1112叶片中锰的高积累，而不是像对锰敏感的KY 14那样根系中锰的高积累。得出的结论是，细胞壁的表面化学特征可能在植物对金属离子的吸收和耐受性中起重要作用。