Reyes-Rivera Jorge, Soto-Hernández Marcos, Canché-Escamilla Gonzalo, Terrazas Teresa
Programa de Botánica, Colegio de Postgraduados en Ciencias Agrícolas, Texcoco, Estado de México, Mexico.
Centro de Investigación Científica de Yucatán, Unidad de Materiales, Mérida, Mexico.
Front Plant Sci. 2018 Oct 17;9:1518. doi: 10.3389/fpls.2018.01518. eCollection 2018.
Wood lignin composition strongly depends on anatomical features and it has been used as a marker for characterizing major plant groups. Wood heterogeneity in Cactaceae is involved in evolutionary and adaptive processes within this group; moreover, it is highly correlated to the species growth form. Here we studied the lignin structure from different types of woods in four Cactaceae species with different stem morphologies (, tree/fibrous wood; and , tree/succulent fibrous wood; , cylindrical stem/dimorphic wood) in order to determine their relationship with the wood anatomy in an evolutionary-adaptive context. Dioxane lignin was isolated and analyzed by pyrolysis coupled with gas chromatography and mass spectrometry (Py-GC/MS), two-dimensional nuclear magnetic resonance spectroscopy (2D-NMR) and attenuated total reflectance-Fourier transform infrared spectroscopy (ATR-FTIR). The main linkages are the β-O-4' ether (67-85%), the β-β' resinol (10-26%) and the β-5' and α-O-4' linkages of the phenylcoumaran structures (≤7%). Spirodienone structures have a considerable abundance (5%) in the dimorphic wood of . In addition, low contents (≤3%) of α,β-diaryl ether, α-oxidized β-O-4' ether and dibenzodioxocin structures were found. The sinapyl- and coniferyl acetates are not part of the wood lignin in any of the studied species. The low (≤5%) γ-acetylation in the and wood lignin is here interpreted as an evidence of a high specialization of the wood elements in the conduction/storage of water. The lignin of the studied Cactaceae is composed predominantly of guaiacyl and syringyl units (S/G: 0.9-16.4). High abundance of syringyl units (62-94%) in three of the four species is considered as a defense mechanism against oxidative agents, it is a very conspicuous trait in the most succulent species with dimorphic wood. Furthermore, it is also associated with ferulates and the herein called γ-acetylated guaiacyl-syringaresinol complexes acting as nucleation sites for lignification and as cross-links between lignin and carbohydrates at the wide-band tracheid-fiber junctions.
木材木质素组成强烈依赖于解剖学特征,并且已被用作表征主要植物类群的标志物。仙人掌科植物木材的异质性参与了该类群内部的进化和适应过程;此外,它与物种的生长形态高度相关。在此,我们研究了四种具有不同茎形态的仙人掌科植物(,乔木/纤维状木材;和,乔木/肉质纤维状木材;,圆柱形茎/二型木材)不同类型木材的木质素结构,以便在进化适应背景下确定它们与木材解剖结构的关系。通过热解结合气相色谱和质谱(Py-GC/MS)、二维核磁共振光谱(2D-NMR)以及衰减全反射-傅里叶变换红外光谱(ATR-FTIR)对二氧六环木质素进行分离和分析。主要连接键为β-O-4'醚键(67-85%)、β-β'树脂醇键(10-26%)以及苯基香豆素结构的β-5'和α-O-4'连接键(≤7%)。螺二烯酮结构在的二型木材中具有相当高的丰度(5%)。此外,还发现了低含量(≤3%)的α,β-二芳基醚、α-氧化β-O-4'醚和二苯并二恶英结构。在所研究的任何物种中,芥子酰和松柏酰乙酸酯都不是木材木质素的组成部分。和木材木质素中低水平(≤5%)的γ-乙酰化在此被解释为木材细胞在水分传导/储存方面高度特化的证据。所研究的仙人掌科植物的木质素主要由愈创木基和紫丁香基单元组成(S/G:0.9-16.4)。四个物种中的三个物种中紫丁香基单元的高丰度(62-94%)被认为是一种抗氧化剂的防御机制,这在具有二型木材的最肉质物种中是一个非常显著的特征。此外,它还与阿魏酸以及此处所称的γ-乙酰化愈创木基-紫丁香树脂醇复合物相关,这些复合物在宽带管胞-纤维连接处作为木质化的成核位点以及木质素与碳水化合物之间的交联点。
