Isolate and plant host specificity of rhizosphere competence in Trichoderma species

IF 2.9 3区生物学 Q2 MYCOLOGY

Fungal biology Pub Date : 2025-02-22 DOI:10.1016/j.funbio.2025.101554

N. Cripps-Guazzone , H.J. Ridgway , L.M. Condron , K.L. McLean , A. Stewart , E.E. Jones

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Abstract

Rhizosphere competence, the ability of a microorganism to colonise and proliferate in the rhizosphere of developing roots, is often studied when mechanisms of individual Trichoderma biocontrol agents are investigated. However, the extent of rhizosphere competence of Trichoderma species and isolates within species has not been widely studied. The rhizosphere competence of 22 Trichoderma isolates from a range of species was assessed using Trichoderma coated sweet corn (Zea mays) seeds grown in non-sterile soil. Results showed that 82 % of the Trichoderma isolates inoculated onto the seeds produced rhizosphere populations significantly greater than the control, indicating rhizosphere competence was widespread within the species that were tested. The least and most rhizosphere-competent isolates belonged to the same species indicating that rhizosphere competence was not species specific. The three least (T. crassum LU555, Trichoderma harzianum LU672, and T. virens LU556) and most (Trichoderma atroviride LU132, T. harzianum LU151, and LU673) rhizosphere-competent isolates were assessed on six plant species (sweet corn, ryegrass, cauliflower, carrot, onion, and white clover). Ryegrass and cauliflower were the most receptive plants to colonisation of the rhizosphere by Trichoderma species, and clover the least. Preferential rhizosphere colonisation was observed between some Trichoderma isolates and the plant species indicating that overall rhizosphere competence was dependent on specific interactions between the Trichoderma isolate and the plant species. However, some isolates were more broadly rhizosphere-competent than others and may have greater potential as plant protection agents. Since only one time point was sampled, future work is required to determine the temporal dynamics of rhizosphere colonisation as well as the spatial colonisation along the length of the root to determine whether different isolates preferentially colonise different regions of the root over different time periods.

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木霉种根际能力的分离和植物寄主特异性

根际能力，即微生物在发育中的根的根际定殖和增殖的能力，在研究单个木霉生物防治剂的机制时经常被研究。然而，木霉种间和种内分离株的根际能力程度尚未得到广泛的研究。利用在非无菌土壤中生长的木霉包被甜玉米（Zea mays）种子，对22株不同种类木霉分离株的根际能力进行了评价。结果表明，接种木霉种子的菌株中，有82%的菌株根际种群数量显著高于对照，表明根际竞争能力在被试物种中广泛存在。根际能力最少和最多的菌株属于同一种，表明根际能力不具有种特异性。对6种植物（甜玉米、黑麦草、花椰菜、胡萝卜、洋葱和白三叶草）的根际活性进行了评价，筛选出了3株对根际活性最低的菌株（葡萄木霉LU555、哈茨木霉LU672和virens LU556）和对根际活性最高的菌株（atroviride木霉LU132、哈茨木霉LU151和LU673）。黑麦草和花椰菜是最易受木霉在根际定殖的植物，三叶草最不容易。观察到一些木霉分离株和植物物种之间有优先的根际定殖，这表明整体根际能力取决于木霉分离株和植物物种之间的特定相互作用。然而，一些分离株比其他分离株具有更广泛的根际能力，可能具有更大的作为植物保护剂的潜力。由于只对一个时间点进行了采样，未来的工作需要确定根际定殖的时间动态以及沿根长度的空间定殖，以确定不同的分离株是否在不同的时间段优先定殖在根的不同区域。

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来源期刊

Fungal biology MYCOLOGY-

CiteScore

5.80

自引率

4.00%

发文量

审稿时长

49 days

期刊介绍： Fungal Biology publishes original contributions in all fields of basic and applied research involving fungi and fungus-like organisms (including oomycetes and slime moulds). Areas of investigation include biodeterioration, biotechnology, cell and developmental biology, ecology, evolution, genetics, geomycology, medical mycology, mutualistic interactions (including lichens and mycorrhizas), physiology, plant pathology, secondary metabolites, and taxonomy and systematics. Submissions on experimental methods are also welcomed. Priority is given to contributions likely to be of interest to a wide international audience.