Identification and Inhibitory Effect on Lasiodiplodia theobromae of Actinomycetes in Camellia sinensis Rhizosphere Soil
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摘要:
目的 从老枞根际土壤分离可培养放线菌,获取潜在新物种,并筛选可可毛色二孢菌拮抗菌株。 方法 采用土壤稀释涂布法和三区划线法进行分离和纯化,获得放线菌菌株;通过比对16S rRNA基因序列和构建系统发育树,对菌株进行初步分类和鉴定;采用平板对峙法进行抑菌活性筛选。 结果 (1)共获得81株不同放线菌菌株,分别隶属于链霉菌Streptomyces(54.32%)、节杆菌Arthrobacter(27.16%)、微杆菌Microbacterium(11.11%)、北里孢菌Kitasatospor(4.94%)和短小杆菌Curtobacterium(2.47%)5个属;(2)与已知模式菌株相比,相似度小于98.65%的潜在新种共有20 株;(3)经可可毛色二孢平板对峙试验筛选后,获得7株高抑菌活性链霉菌,其中链霉菌ON316885的抑菌率最高,达到63.92%。 结论 武夷山老枞根际土壤中蕴含着丰富的放线菌资源,具有深度挖掘研究的价值, 其中一些链霉菌具有较高的生防应用价值。 -
关键词:
- 老枞根际土壤 /
- 放线菌 /
- 可可毛色二孢 /
- 16S rRNA基因
Abstract:Objective Actinomycetes collected from the rhizosphere soils of old tea plants were isolated to screen for species unknown previously and their potential pathogenic inhibitory effect. Method Soil specimens were gathered from the target lots at Shuixian, Fujian to isolate actinomycetes by plate culture. Phylogenetic trees based on 16S rRNA gene for the isolates were constructed and diversity index calculated in the tea plant rhizosphere soils. Result (1) Eighty-one actinomycete strains were obtained that belonged to Streptomyces(54.32%), Arthrobacter (27.16%), Microbacterium (11.11%), Kitasatospora(4.94%), and Curtobacterium (2.47%). (2) In comparing with the reference strain, 20 of the 81 taxa showed less than 98.65% similarity. (3) Seven strains of the Streptomyces significantly inhibited the growth of Lasiodiplodia theobromae, of which, the one code-named WYS-24 reached the highest rate at 63.92%. Conclusion Abundantly diverse actinomycetes resided in the rhizosphere of old tea plants in Wuyishan region. They were a rich resource for in-depth studies and development for biological inhibitors against plant pathogens. -
Key words:
- Rhizosphere /
- Camellia sinensis /
- Lasiodiplodia theobromae /
- 16S rRNA gene
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图 1 武夷山老枞茶园根际土壤采样点分布
Figure 1. Sites for sampling actinomycetes in old tea plant rhizosphere soils at plantations in Wuyishan
图 2 放线菌物种组成
A. 放线菌属水平物种组成;B. 链霉菌组成;C. 节杆菌组成。
Figure 2. Actinomycetes taxa
A: Genera of Actinomycetes; B: species of Streptomyces; C: species of Arthrobacter.
图 3 老枞根际土壤中可培养放线菌系统发育进化树
粗体表示与模式菌株相似度小于98.65%。
Figure 3. Phylogenetic tree of culturable actinomycetes in old tea plant rhizosphere soil
Bold font indicates less than 98.65% similarity with reference strain.
图 4 强拮抗活性菌株对可可毛色二孢生长的抑制效果
A. 平板正面;B. 平板背面。
Figure 4. Inhibitory effects of highly active actinomycetes against L. theobromae
A: Front of petri dish; B: back of petri dish.
表 1 老枞根际土壤可培养放线菌代表菌株与最相似模式菌株比较
Table 1. Comparison between actinomycetes isolated from old tea plant rhizosphere and that closest to reference strain
菌株登录号
Accession No. of strain最相似菌株及登录号
The closest type strain and its accession中文名称
Chinese name相似度
Similarity/%ON165519 Microbacterium proteolyticum (KM359785) 蛋白水解微杆菌 98.08 ON165520 Microbacterium testaceum (BJML01000022) 种皮微杆菌 98.53 ON165521 Streptomyces acidiscabies (D63865) 酸性疮链霉菌 97.91 ON165522 Streptomyces pseudovenezuelae (KQ948163) 金霉素链霉菌 97.56 ON165523 Streptomyces acidiscabies (D63865) 酸性疮链霉菌 97.94 ON165524 Arthrobacter livingstonensis (GQ406811) 利文斯顿岛节杆菌 97.97 ON165525 Arthrobacter bambusae (KF150696) 竹节杆菌 98.63 ON165526 Arthrobacter bambusae (KF150696) 竹节杆菌 98.42 ON165527 Streptomyces xiamenensis (EF012099) 厦门链霉菌 97.55 ON165528 Streptomyces alanosinicus (AB184442) 阿拉诺链霉菌 97.43 ON165529 Streptomyces graminifolii (HQ267984) 禾叶链霉菌 98.58 ON165530 Streptomyces acidiscabies (D63865) 酸性疮链霉菌 97.96 ON165531 Arthrobacter livingstonensis (GQ406811) 利文斯顿岛节杆菌 97.46 ON165532 Streptomyces acidiscabies (D63865) 酸性疮链霉菌 98.56 ON165533 Streptomyces philanthi (DQ375802) 嗜酸链霉菌 96.73 ON165534 Kitasatospora psammotica (MT760550) — 98.54 ON165535 Streptomyces intermedius (AB184277) 中间型链霉菌 98.61 ON165536 Microbacterium proteolyticum (KM359785) 蛋白水解微杆菌 98.22 ON165537 Streptomyces griseocarneus (MT760576) 灰色链霉菌 97.80 ON165538 Streptomyces aquilus (MH718844) 棕色链霉菌 97.78 ON316876 Streptomyces ardesiacus (DQ026631) 桔橙链霉菌 99.16 ON316877 Streptomyces pratensis (JQ806215) 草地链霉菌 99.56 ON316878 Streptomyces mexicanus (AF441168) 墨西哥链霉菌 98.92 ON316879 Streptomyces halstedii (AB184142) 郝氏链霉菌 99.86 ON316880 Streptomyces microflavus (AB184284) 细黄链霉菌 99.36 ON316881 Streptomyces badius (AY999783) 栗褐链霉菌 99.03 ON316882 Streptomyces zaomyceticus (AB184346) 沙阿霉素链霉菌 98.95 ON316883 Streptomyces niveus (DQ442532) 雪百链霉菌 100.00 ON316884 Streptomyces xylanilyticus (LC128341) — 99.92 ON316885 Streptomyces rochei (MUMD01000370) 罗氏链霉菌 98.88 ON316886 Streptomyces coelicoflavus (AB184650) 天蓝黄链霉菌 98.95 ON316887 Kitasatospora xanthocidica (AB184427) — 99.50 ON316888 Arthrobacter bambusae (KF150696) 竹节杆菌 99.50 ON316889 Arthrobacter gyeryongensis (JX141781) 绞股蓝节杆菌 99.06 ON316890 Microbacterium proteolyticum (KM359785) — 99.02 ON316891 Microbacterium azadirachtae (JYIT01000023) — 99.29 ON316892 Microbacterium paraoxydans (BCRH01000180) — 99.22 ON316893 Curtobacterium citreum (X77436) 柠檬色短小杆菌 99.36 ON316894 Curtobacterium albidum (AM042692) — 98.79 粗体表示与模式菌株的相似度小于98.65%。
Bold font indicates a less than 98.65% similarity with reference strain.
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表 2 强拮抗活性菌株对可可毛色二孢的抑制作用
Table 2. Inhibitory effects of highly active actinomycetes against L. theobromae
菌株登记号
Accessions of strain病原菌直径
Diameter of pathogen/mm抑制率
Inhibition rate/%CK 90.000 — ON316884 59.725±0.111 33.64±0.37 ON165521 54.923±0.086 38.97±0.25 ON165523 52.211±0.095 41.99±0.25 ON165532 34.106±0.108 62.10±0.19 ON316885 32.476±0.106 63.92±0.18 ON165522 35.657±0.097 60.38±0.18 ON165537 39.736±0.062 55.85±0.12
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