花叶矢竹矮化倒伏突变体DWF茎秆结构及细胞壁组分含量分析

doi:10.11707/j.1001-7488.LYKX20230621

摘要/Abstract

摘要：

目的: 通过探究花叶矢竹体细胞无性系变异株系茎秆形态、解剖结构及细胞壁组分等特征的动态变化，揭示花叶矢竹茎秆倒伏的生理机制。方法: 以发生体细胞无性系变异的花叶矢竹矮化倒伏突变体（dwarf and lodging mutant，DWF）为研究对象，以正常组织培养的花叶矢竹（WT）为对照，同时移栽90、180、270、和360天后，分别调查其新生竹秆的表型、横切面解剖结构、细胞壁组分含量的变化。结果: DWF在不同移栽时期中茎秆形态、解剖结构、细胞壁组分含量与WT差异显著。1）相较于WT，DWF茎秆在4个移栽时期中均发生不同程度的倒伏，移栽90天时茎秆与地面夹角为35.27°，茎秆倒伏程度最大，移栽360天时茎秆与地面夹角为73.13°，茎秆倒伏程度最小。2）DWF茎秆直径、茎秆高度、基部节间长度极显著低于WT，移栽360天时差异最大；DWF生长缓慢，移栽270~360天时，DWF新生茎秆高度增幅仅为WT的21.41%，新生茎秆直径增幅只有WT的17.49%。3）DWF大小维管束数量及面积均极显著低于WT，移栽360天时DWF大维管束数量及面积分别比WT低65.71%及55.35%，小维管束数量及面积分别比WT低75.44%及55.51%，WT新生茎秆大小维管束数量及面积快速增长时，DWF增幅缓慢；DWF厚壁组织厚度变薄，在4个时期中与WT均存在极显著差异，分别比WT低50.21%、55.77%、54.59%、45.41%；DWF髓腔发育缓慢，移栽270天与360天时出现髓腔，髓腔直径极显著低于WT。4）随着移栽时间的延长，DWF新生茎秆的木质素、纤维素含量增加，但极显著低于WT，且半纤维素含量无显著差异，节间木质素及纤维素沉积程度也低于WT。5）DWF茎秆倒伏程度与其茎秆直径存在显著负相关关系，与大小维管束数量及面积、厚壁组织厚度、木质素及纤维素含量存在极显著负相关关系。结论: 相较于花叶矢竹WT，DWF在发育过程中，茎秆高度增长滞缓和呈现矮化，茎秆强度弱和发生倒伏。DWF茎秆直径小、大小维管束的数量少和面积小、厚壁组织厚度低，是其发生倒伏的一个重要原因；DWF细胞壁的木质素及纤维素含量低，造成其茎秆强度弱，是其发生倒伏的另一原因。

关键词: 花叶矢竹, 突变体, 茎秆倒伏, 木质素, 纤维素

Abstract:

Objective: The development of bamboo culm has always been a research hotspot. This study aims to reveal the physiological mechanism of culm lodging, by exploring the dynamic changes in the morphological, anatomical, and cell wall composition characteristics of the culm of the somatic clone variant strain of Pseudosasa japonica f. akebonosuji. Method: The dwarf and lodging mutant (DWF) of P. japonica f. akebonosuji with somaclonal variation was used as the research object, and the normal tissue-cultured P. japonica f. akebonosuji (WT) served as the control. After 90, 180, 270, and 360 days of transplanting, the phenotype, cross-sectional anatomical structure, and changes in cell wall component content of the newly-grown bamboo culm were investigated. Result: There were significant differences in culm morphology, anatomical structure, and cell wall component content between DWF and WT at different transplanting stages. 1) Compared to WT, DWF culms experienced varying degrees of lodging during all four transplanting periods. At 90 days after transplanting, the angle between the stem and the ground was 35.27°, indicating the greatest degree of culm lodging. At 360 days after transplanting, the angle between the culm and the ground was 73.13°, indicating the least degree of culm lodging. 2) The stem diameter, stem height, and basal internode length of DWF were extremely significantly lower than those of WT, with the largest difference occurring at 360 days after transplanting. DWF grew slowly, and the height increase of new culms from 270 to 360 days after transplanting was only 21.41% of that of WT, and the diameter increase of new culms was only 17.49% of that of WT. 3) The number and area of vascular bundles in DWF were significantly lower than those in WT. At 360 days after transplanting, the number and area of large vascular bundles in DWF were 65.71% and 55.35% lower than those in WT, respectively, while the number and area of small vascular bundles were 75.44% and 55.51% lower than those in WT, respectively. When the number and area of vascular bundles of the new culms of WT increased rapidly, the increase in DWF was slow. The thickness of the DWF sclerenchyma decreased, and there were significant differences in sclerenchyma thickness between WT and DWF in all four periods, with DWF being 50.21%, 55.77%, 54.59%, and 45.41% smaller than WT, respectively. The development of the DWF pith cavity was slow, and the pith cavity appeared at 270 days and 360 days after transplanting, with a significantly smaller diameter than that of WT. 4) With the extension of transplanting time, though the lignin and cellulose content of the new culms of DWF increased, their content in DWF was significantly lower than that in WT. The degree of lignin and cellulose deposition in the internodes was also lower than that of WT, however there was no significant difference in hemicellulose content between WT and DWF. 5) There was a significant negative correlation between the degree of DWF stem lodging and its stem diameter, and there were highly significantly negative correlations between the degree of DWF stem lodging and the number and area of large and small vascular bundles, the thickness of sclerenchyma, as well as the content of lignin and cellulose. Conclusion: Compared to WT, DWF shows stunted growth and dwarfism in the development process, with weak culm strength and lodging. DWF stem diameter is smaller, the number and area of large and small vascular bundles are smaller, and the thickness of the sclerenchyma is also smaller, which all are the reason for its lodging. The low content of lignin and cellulose in the cell wall of DWF results in weak stem strength, which is another reason for its lodging.

Key words: Pseudosasa japonica f. akebonosuji, mutant, culm lodging, lignin, cellulose

中图分类号:

姜思成,王妮,高会彬,周国强,杨海芸. 花叶矢竹矮化倒伏突变体DWF茎秆结构及细胞壁组分含量分析[J]. 林业科学, 2025, 61(3): 158-168.

Sicheng Jiang,Ni Wang,Huibin Gao,Guoqiang Zhou,Haiyun Yang. Analysis of Culm Structure and Cell Wall Component Content in Dwarf Lodging Mutant of Pseudosasa japonica f. akebonosuji[J]. Scientia Silvae Sinicae, 2025, 61(3): 158-168.

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项目Item	木质素含量 Lignin content	纤维素含量 Cellulose content	半纤维素含量 Hemicellulose content
茎秆与地面夹角 Stem angle with the ground	0.647**	0.673**	0.444

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