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日本慢生根瘤菌非运动性Tn7突变体在非无菌土壤中的结瘤竞争力

Nodulating Competitiveness of a Nonmotile Tn7 Mutant of Bradyrhizobium japonicum in Nonsterile Soil.

作者信息

Liu Ruilong, Tran Van Mai, Schmidt E L

机构信息

Department of Soil Science, University of Minnesota, St. Paul, Minnesota 55108.

出版信息

Appl Environ Microbiol. 1989 Aug;55(8):1895-1900. doi: 10.1128/aem.55.8.1895-1900.1989.

DOI:10.1128/aem.55.8.1895-1900.1989
PMID:16347986
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC202975/
Abstract

A nonmotile mutant of Bradyrhizobium japonicum serogroup 127 was generated by Tn7 mutagenesis and matched with the wild type against a common competitor in studies of soybean nodulation in nonsterile soil. The Tn7 mutant was very similar to the wild type in growth rate in culture, soybean lectin-binding ability, flagellar morphology, and nodulating capability, but it had a longer lag phase. Competing strains were distributed uniformly in soil in various ratios and at different population densities prior to planting. Mutant and wild type were equally prevalent in the seedling rhizosphere at about the time of nodule initiation, suggesting that motility conferred no advantage in rhizosphere colonization. Nodulation success of the Tn7 mutant was lower than that of the wild type under all test conditions. Differences were greatest at low soil populations of competitors and much less pronounced at initial populations of 10 g. The longer lag phase of the Tn7 mutant may have contributed to its decreased competitiveness, especially at the higher inoculation levels. The antibiotic and motility markers were stable, and the rifampin resistance derived from the parent did not affect adversely the competitiveness of the Tn7 mutant. We found motility to be of limited importance to the competitiveness of a strain in normal nonsterile soil, where the significance, if any, of this ability may be in migration at the immediate root surface in soils sparsely populated with rhizobial symbionts.

摘要

通过Tn7诱变产生了日本慢生根瘤菌血清型127的一个非运动突变体,并在非无菌土壤中大豆结瘤研究中,将其与野生型针对一个共同竞争者进行了比较。Tn7突变体在培养物中的生长速率、大豆凝集素结合能力、鞭毛形态和结瘤能力方面与野生型非常相似,但它有更长的延迟期。在种植前,竞争菌株以各种比例和不同种群密度均匀分布在土壤中。在根瘤开始形成时,突变体和野生型在幼苗根际中的普遍程度相同,这表明运动性在根际定殖中没有优势。在所有测试条件下,Tn7突变体的结瘤成功率均低于野生型。在竞争者土壤种群数量较低时差异最大,而在初始种群数量为10 g时差异则小得多。Tn7突变体较长的延迟期可能导致其竞争力下降,尤其是在较高接种水平时。抗生素和运动性标记是稳定的,源自亲本的利福平抗性并未对Tn7突变体的竞争力产生不利影响。我们发现,在正常的非无菌土壤中,运动性对菌株竞争力的重要性有限,在这种土壤中,这种能力的重要性(如果有的话)可能在于在根际共生体稀少的土壤中在根表面附近迁移。

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