降香黄檀根瘤以及根瘤菌形态和超微结构特征

doi:10.12302/j.issn.1000-2006.202205001

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南京林业大学学报（自然科学版） ›› 2023, Vol. 47 ›› Issue (5): 259-267.doi: 10.12302/j.issn.1000-2006.202205001

降香黄檀根瘤以及根瘤菌形态和超微结构特征

邓家珍(), 叶绍明^*(), 林铭业, 蓝雅惠, 燕羽, 樊容源, 潘彩玲

广西大学林学院,广西森林生态与保育重点实验室,广西南宁 530004

收稿日期:2022-04-30 修回日期:2023-06-02 出版日期:2023-09-30 发布日期:2023-10-10
作者简介:邓家珍 (1079640413@qq.com)。
基金资助:
国家自然科学基金项目(31460196)

Morphological and ultrastructural characteristics of root nodules and rhizobium of Dalbergia odorifera

DENG Jiazhen(), YE Shaoming^*(), LIN Mingye, LAN Yahui, YAN Yu, FAN Rongyuan, PAN Cailing

College of Forestry, Guangxi Key Laboratory of Forest Ecology and Conservation, Guangxi University, Nanning 530004, China

Received:2022-04-30 Revised:2023-06-02 Online:2023-09-30 Published:2023-10-10

摘要/Abstract

摘要：

【目的】探明降香黄檀(Dalbergia odorifera)根瘤的形态特征、组织学特点以及超微结构,明晰瘤内根瘤菌的超微特征,为豆科植物根瘤的分类研究提供新的基础资料。【方法】以降香黄檀根瘤为材料,制作石蜡切片、超薄切片和扫描电镜样品,利用光学显微镜观察降香黄檀根瘤形态和显微结构,利用透射电镜和场发射扫描电镜观察根瘤细胞和根瘤菌在超微视野下的特征,并测定不同瘤龄的根瘤豆血红蛋白含量,分析根瘤结构与固氮功能的关系。【结果】 ①形态特征:降香黄檀根瘤从1 d发育至60 d,形状由圆形逐渐分化为椭圆形、杠铃形及不规则椭圆形等,颜色由黄白色向黄褐色转变,着生部位由侧根和基部逐渐向主根扩散;根瘤发育过程中,豆血红蛋白含量呈先升后降的趋势,在瘤龄3~5 d的根瘤中达到最高。②组织学特点:降香黄檀根瘤含有2~3个侵染区域;维管束分布于侵染区域周围,其内的环纹导管以端壁首尾相连。③超微结构:透射电镜观察下,降香黄檀根瘤侵染细胞与非侵染细胞存在明显不同。侵染细胞体积膨大,不含液泡,内含多个含有膜结构的泡囊,膜内包被着由根瘤菌分化成的类菌体,而线粒体和内质网等细胞器被挤至细胞壁边缘;非侵染细胞几乎被液泡充满,细胞壁厚薄不均,淀粉粒和一些质体围绕细胞核存在。形态各异的类菌体拥有细胞壁和细胞膜,内含多磷酸盐(PP)颗粒和聚-β-羟基丁酸盐(PHB)颗粒。降香黄檀根瘤侵染细胞内存在两种膜合成状态,一是膜小泡参与泡囊膜的合成,二是泡囊膜附近出现絮状膜物质,泡囊膜可解离。扫描电镜观察发现,大量长杆状根瘤菌类菌体交织缠绕,多个泡囊膜贴合在一起呈现连续状,形成紧密的膜系统。【结论】降香黄檀根瘤属于“有限型”根瘤。瘤龄显著影响降香黄檀根瘤豆血红蛋白含量。降香黄檀根瘤维管组织发达,瘤内类菌体数量多且含有储能功能的PP和PHB颗粒,根瘤细胞的泡囊膜系统强大,这些结构给降香黄檀根瘤的固氮功能提供了支持。

关键词: 降香黄檀, 根瘤, 根瘤菌, 超微结构, 类菌体, 共生固氮

Abstract:

【Objective】This study aims to elucidate the morphological characteristics, histological characteristics, and ultrastructure of Dalbergia odorifera root nodules and clarify the ultrastructure of rhizobium. The results from this study can provide an intuitive and precise primary data set for the classification of leguminous plant nodules.【Method】The paraffin sections, ultrathin sections and field emission scanning electron microscopy (FESEM) samples were all prepared from D. odorifera root nodules. Optical microscopy (OM) was used to observe the morphology and microscopic structure of nodules, while transmission electron microscopy (TEM) and FESEM were used to observe the ultrastructure of root nodule cells and rhizobium. Additionally, the leghemoglobin content of nodules in different periods was determined, and the relationship between root nodules structure and nitrogen fixation function was analyzed.【Result】(1) Morphological characteristics: from day one to day 60, the shape of D. odorifera root nodules gradually differentiated from round into oval, barbell and irregular oval, and the color changed from yellowish white to yellowish brown. The growing part of nodules gradually spread from the lateral root and base to the principal root. During the development of root nodules, the leghemoglobin content initially rose, then declined, with a peak at age of 3-5 d. (2) Histological traits: the root nodules of D. odorifera generally contained two to three infected areas. The vascular bundles were distributed around the infected areas, and the ringed vessels inside were connected by the end wall. (3) Ultrastructures: under TEM observation, the infected cells were significantly different from the uninfected cells. The volume of infected cells was enlarged without vacuoles and contained multiple vesicles with membranous structure. The vesicles were covered by bacteroids, which were differentiated from rhizobium, and organelles such as mitochondria and endoplasmic reticulum were squeezed to the edge of the cell wall. The uninfected cells were almost filled with vacuoles, and the cell wall was thick and uneven. Starch grains and some plastids existed around the nucleus. The morphologically diverse bacteroids have cell membranes and walls and contain polyphosphate (PP) particles and poly-β-hydroxybutyrate (PHB) particles. There were two membrane synthesis states in the infected cells of D. odorifera root nodules. In one, the membrane vesicles participated in the synthesis of peribacteroid membranes; in the other, a flocculent membrane appeared near the peribacteroid membranes and allowed the peribacteroid membrane to dissociate. FESEM showed a large number of long rod-like rhizobium intertwined and multiple peribacteroid membranes bonded together in a continuous shape to form a tight membrane system.【Conclusion】The D. odorifera root nodules are “determinate nodules”. The nodule age can significantly affect the leghemoglobin content in D. odorifera root nodules. The D. odorifera root nodules contain well-developed vascular tissues, and there are a large number of bacteroids that contain PP and PHB particles with an energy storage function as well as a strong peribacteroid membrane system. These structures provide supports to the nitrogen fixation function of D. odorifera root nodules.

Key words: Dalbergia odorifera, root nodule, rhizobium, ultrastructure, bacteroid, symbiotic nitrogen fixation

中图分类号:

S718

邓家珍,叶绍明,林铭业,等. 降香黄檀根瘤以及根瘤菌形态和超微结构特征[J]. 南京林业大学学报（自然科学版）, 2023, 47(5): 259-267.

DENG Jiazhen, YE Shaoming, LIN Mingye, LAN Yahui, YAN Yu, FAN Rongyuan, PAN Cailing. Morphological and ultrastructural characteristics of root nodules and rhizobium of Dalbergia odorifera[J].Journal of Nanjing Forestry University (Natural Science Edition), 2023, 47(5): 259-267.DOI: 10.12302/j.issn.1000-2006.202205001.

图/表 6

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瘤龄/d growing day	根瘤形状 nodules shape	根瘤颜色 nodules color	着生部位 growing part	根瘤长径/mm nodules size	豆血红蛋白含量/(mg·g^-1) leghemoglobin content
1	圆形	黄白色	侧根、侧根基部	< 1	527.06±1.11 b
3~5	圆形	淡黄色	侧根、侧根基部	[1,2)	716.08±15.70 a
7~10	圆形	黄色	主根、侧根	[2,3)	522.16±17.79 b
11~20	球形	黄褐色	主根、侧根	[3,4)	419.61±36.19 c
21~60	杠铃形、长椭圆形	黄褐色	主根、侧根	[4,5)	189.80±28.37 d

降香黄檀根瘤以及根瘤菌形态和超微结构特征

Morphological and ultrastructural characteristics of root nodules and rhizobium of Dalbergia odorifera

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