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Background In disease-suppressive soils, the rhizosphere microbiota protects plants from root disease(s). However, the soil microbiome follows distinct spatial patterns, and the biogeographic factors shaping plant–microbe interactions and soil suppressiveness remain poorly understood. Here, we use Swiss and Savoie soils suppressive or conducive to Thielaviopsis basicola -mediated black root rot of tobacco, to test the hypothesis that plant–microbe interactions and suppressiveness are influenced by both the geological origin and geographic positioning of soils. Soils are compared based on tobacco health, soil physicochemistry and organic matter profiles, taxonomic and functional microbial diversity, and plant physiological responses. Results Soil physicochemistry and metabolomic profiling of soil organic matter show differences based on suppressiveness status, soil geology and geography. The taxonomic (metabarcoding of prokaryotes and fungi) and functional (metagenomics) diversity of the tobacco rhizosphere reveals that the microbiota is influenced by geography and geology which, in turn, affects suppressiveness. Additionally, shoot metabolomics shows that tobacco responses are impacted by soil geography and geology, particularly in Savoie soils regarding two nicotinic derivatives. Conclusions Overall, suppressiveness is influenced by both the geological origin and geographic positioning of the soils, with distinct patterns in the two regions. In Swiss soils, suppressiveness is primarily associated with major differences in rhizosphere microbiota composition and functions between suppressive and conducive soils. In contrast, in Savoie soils, suppressiveness is linked to distinct plant physiological responses (pointing to induced systemic resistance) rather than strong microbial shifts. This study highlights the importance of considering the biogeographic features shaping disease-suppressive soils and their microbiota-plant interactions.

Background and aims Root-rot disease, a catastrophic disease of Panax quinquefolium L. causes yield reduction and serious economic losses. However, knowledge of the relationship between rhizosphere microbial community and root-rot disease is limited. This study is aim to test whether the bacteria and fungi community differed between the soil attached to healthy and rotten roots of American ginseng. Moreover, the effects of American ginseng cultivation for 4 years on changes of soil physiochemical properties and microbial community were also investigated. Methods High-throughput sequencing (Illumina MiSeq) was used to investigate the difference of microbial communities in the soils of new farmland (C) and the rhizosphere soils around healthy (H) and root rot diseased ginseng (R). Results Cultivation of American ginseng for 4 years not only changed the soil physicochemical properties, but also significantly increased the richness of the soil bacteria and decreased the fungal richness and diversity. Compared with other genera, the bacterial genera Nitrospira and the fungal genera Gibberella and Podospora were strongly enriched in the soil of new farmland. However, the relative abundance of Janthinobacterium, Nitrospira and Pedomicrobium in bacterial community, and Mrakia, Paradendryphiella, Sporopachydermia, Myrothecium and Racocetra in fungal community were significantly decreased after culture of American ginseng. The results also showed that the bacteria and fungi community differs between the soil attached to healthy and rotten roots of American ginseng. The richness indices of fungal community showed a significant decrease in rhizosphere soils of R comparing with H. The bacteria Rhodoplanes and Kaistobacter were the dominant genera in the H sample, whereas Sphingobium was dominant in the R sample. Notably, Monographella was significantly higher in the R sample (23.13%) than that of H sample (2.90%). In addition, the fungi Melanophyllum and Staphylotrichum were the most differently abundant in the H sample, whereas Mortierella and Cistella were the differently abundant genera in the R sample. Conclusions Our results indicate that cultivation of American ginseng changed the edaphic factors and the soil microbial community, and there are significant differences in the microbial community between the soil attached to healthy and rotten roots of American ginseng.

Background Plant health and growth are negatively affected by pathogen invasion; however, plants can dynamically modulate their rhizosphere microbiome and adapt to such biotic stresses. Although plant-recruited protective microbes can be assembled into synthetic communities for application in the control of plant disease, rhizosphere microbial communities commonly contain some taxa at low abundance. The roles of low-abundance microbes in synthetic communities remain unclear; it is also unclear whether all the microbes enriched by plants can enhance host adaptation to the environment. Here, we assembled a synthetic community with a disease resistance function based on differential analysis of root-associated bacterial community composition. We further simplified the synthetic community and investigated the roles of low-abundance bacteria in the control of Astragalus mongholicus root rot disease by a simple synthetic community. Results Fusarium oxysporum infection reduced bacterial Shannon diversity and significantly affected the bacterial community composition in the rhizosphere and roots of Astragalus mongholicus . Under fungal pathogen challenge, Astragalus mongholicus recruited some beneficial bacteria such as Stenotrophomonas , Achromobacter , Pseudomonas , and Flavobacterium to the rhizosphere and roots. We constructed a disease-resistant bacterial community containing 10 high- and three low-abundance bacteria enriched in diseased roots. After the joint selection of plants and pathogens, the complex synthetic community was further simplified into a four-species community composed of three high-abundance bacteria ( Stenotrophomonas sp., Rhizobium sp., Ochrobactrum sp.) and one low-abundance bacterium ( Advenella sp.). Notably, a simple community containing these four strains and a thirteen-species community had similar effects on the control root rot disease. Furthermore, the simple community protected plants via a synergistic effect of highly abundant bacteria inhibiting fungal pathogen growth and less abundant bacteria activating plant-induced systemic resistance. Conclusions Our findings suggest that bacteria with low abundance play an important role in synthetic communities and that only a few bacterial taxa enriched in diseased roots are associated with disease resistance. Therefore, the construction and simplification of synthetic communities found in the present study could be a strategy employed by plants to adapt to environmental stress. -VujMZjCpFzTumqS8Rf9nH Video abstract

Background and aims Field pea production is greatly impacted by multiple soil-borne fungal and oomycete pathogens in a complex. The objectives of this research were to 1) identify the soil-borne pathogens associated with field pea in North Dakota and; 2) develop prediction models incorporating the occurrence of the soil-borne pathogen communities, soil edaphic properties and disease incidence. Methods Soil and plants were sampled from 60 field pea fields in North Dakota during 2014 and 2015. Plants (1500 across two years) were rated for both root rot and soil-borne pathogens isolated from roots. Soils were analyzed for edaphic properties. Indicator species analysis was used to identify soil-borne pathogen communities. Logistic regression was used to determine associations and develop prediction models. Results Survey results from 2014 and 2015 indicated that the most prevalent soil-borne pathogens identified in field pea fields were Fusarium spp. and Aphanomyces euteiches. Five soil-borne pathogen communities were identified; three of which had statistically significant associations characterized by (1) Fusarium acuminatum , (3) A. euteiches , and (4) Fusarium sporotrichioides. The occurrence of the three communities were associated with clay content, soil pH, Fe 2+ , and K + . Disease incidence was associated with the presence of either community 1 or 3 and K + . Conclusions The results generated from this research will contribute to the development of management strategies by providing a soil-borne pathogen community prediction tool.

Background and aims Root rot is a catastrophic disease of perennial medicinal plants which could be caused by various soil-borne fungal pathogens. However, the understanding of the composition and diversity of root rot pathogenic fungi, their successions and potential drivers remains limited. Methods Sanqi ginseng ( Panax notoginseng ) was selected as a model plant and the rhizosphere soils of root rot-infected Sanqi ginseng at different growth years were collected. Phenolic acid content, pathogen abundance, and fungal microbiota were examined by using the high-performance liquid chromatography (HPLC), real-time PCR and Miseq sequencing. Results Pathogenic agents dominated in the rhizospheric fungal microbiota of rotten Sanqi ginseng and mainly comprised of Ilyonectria , Plectosphaerella , Clonostachys , Gibberella , Pestalotiopsis , Fusarium , and Chalara , with Ilyonectria and Fusarium being most abundant. The composition of pathogenic microbiota, but not α-diversity indices, changed considerably with Sanqi ginseng growth. The shifts of phenolic acid profile were an important driver in changes of rhizosphere pathogenic microbiota, and same phenolic acid exerted distinct functions on differential pathogenic taxa. Particularly, the contents of p -coumaric acid, ferulic acid, and benzoic acid were positively correlated with the abundance of genus Fusarium and negatively correlated with the abundance of genus Ilyonectria . Conclusions Root rot-infected Sanqi ginseng rhizosphere harbors dynamically pathogenic microbiota driven by the shift of phenolic acids. This study provides insights into the composition, variation, and driver of root rot pathogenic microbiota; these insights are important for the development of targeted measure for the prevention and control of root rot diseases.

Incorporating green chemistry concepts into nanotechnology is an important focus area in nanoscience. The demand for green metal oxide nanoparticle production has grown in recent years. The beneficial effects of using nanoparticles in agriculture have already been established. Here, we highlight some potential antifungal properties of Zizyphus spina leaf extract-derived copper oxide nanoparticles (CuO-Zs-NPs), produced with a spherical shape and defined a 13–30 nm particle size. Three different dosages of CuO-Zs-NPs were utilized and showed promising antifungal efficacy in vitro and in vivo against the selected fungal strain of F. solani  causes tomato root rot disease, which was molecularly identified with accession number (OP824846). In vivo  results indicated that, for all CuO-Zs-NPs concentrations, a significant reduction in Fusarium root rot disease occurred between 72.0 to 88.6% compared to 80.5% disease severity in the infected control. Although treatments with either the chemical fungicide (Kocide 2000) showed a better disease reduction and incidence with (18.33% and 6.67%) values, respectively, than CuO-Zs-NPs at conc. 50 mg/l, however CuO-Zs-NPs at 250 mg/l conc. showed the highest disease reduction (9.17 ± 2.89%) and lowest disease incidence (4.17 ± 3.80%). On the other hand, CuO-Zs-NPs at varied values elevated the beneficial effects of tomato seedling vigor at the initial stages and plant growth development compared to either treatment with the commercial fungicide or Trichoderma Biocide. Additionally, CuO-Zs-NPs treatments introduced beneficial results for tomato seedling development, with a significant increase in chlorophyll pigments and enzymatic activity for CuO-Zs-NPs treatments. Additionally, treatment with low concentrations of CuO-Zs-NPs led to a rise in the number of mature pollen grains compared to the immature ones.  however the data showed that CuO-Zs-NPs have a unique antifungal mechanism against F. solani , they  subsequently imply that CuO-Zs-NPs might be a useful environmentally friendly controlling agent for the Fusarium root rot disease that affects tomato plants. Graphical Abstract

Rosellinia necatrix is a prevalent soil-borne plant-pathogenic fungus that is the causal agent of white root rot disease in a broad range of host plants. The limited availability of genomic resources for R . necatrix has complicated a thorough understanding of its infection biology. Here, we sequenced nine R . necatrix strains with Oxford Nanopore sequencing technology, and with DNA proximity ligation we generated a gapless assembly of one of the genomes into ten chromosomes. Whereas many filamentous pathogens display a so-called two-speed genome with more dynamic and more conserved compartments, the R . necatrix genome does not display such genome compartmentalization. It has recently been proposed that fungal plant pathogens may employ effectors with antimicrobial activity to manipulate the host microbiota to promote infection. In the predicted secretome of R . necatrix , 26 putative antimicrobial effector proteins were identified, nine of which are expressed during plant colonization. Two of the candidates were tested, both of which were found to possess selective antimicrobial activity. Intriguingly, some of the inhibited bacteria are antagonists of R . necatrix growth in vitro and can alleviate R . necatrix infection on cotton plants. Collectively, our data show that R . necatrix encodes antimicrobials that are expressed during host colonization and that may contribute to modulation of host-associated microbiota to stimulate disease development.

Soil sterilization integrated with agronomic measures is an effective method to reduce soilborne replant diseases. However, the effect of vermicompost or biochar application after soil sterilization on soilborne diseases is poorly understood. A pot experiment was conducted in American ginseng to investigate the effects of vermicompost (VF), biochar (BF), and a combination of vermicompost and biochar (VBF) applied after soil sterilization on the incidence of Fusarium root rot using natural recovery (F) as control. After one growing season, the disease index of root rot, the phenolic acids, and the microbial communities of American ginseng rhizosphere soil were analyzed. The disease index of VF, BF, and VBF decreased by 33.32%, 19.03%, and 80.96%, respectively, compared with F. The highest bacterial richness and diversity were observed in the rhizosphere soil of VBF. Besides, VF and VBF significantly increased the relative abundance of beneficial bacteria (Pseudomonas, Lysobacter, and Chryseolinea) in the rhizosphere soil. Higher concentrations of vanillin, one of the phenolic acids in the roots exudates, were recorded in the rhizosphere soils of BF and VBF. The vanillin concentration showed a significant negative correlation with the disease index. To conclude, vermicompost improved the beneficial bacteria of the rhizosphere soil, while biochar regulated the allelopathic effect of the phenolic acids. The study proposes a combined application of biochar and vermicompost to the rhizosphere soil to control Fusarium root rot of replanted American ginseng effectively.Key pointsVermicompost improves the relative abundance of rhizosphere beneficial bacteria.Biochar inhibits the degradation of phenolic acids by adsorption.The combination of vermicompost and biochar enhances the disease control effect.

Cassava (Manihot esculenta Crantz) is a major staple food in many developing countries, including Brazil. However, it faces significant challenges due to diseases such as dry root rot (DRR) and black root rot (BRR) caused by soil-borne plant pathogenic fungi. This study explored the use of cover crops to suppress these diseases and to improve the agronomic traits of cassava. Over four cultivation cycles, various cover crops (sunn hemp, black oat, jack bean, maize, peanut and cowpea) were alternated with cassava varieties 'BRS Kiriris' (resistant) and 'BRS Formosa' (susceptible) in soil infested with DRR (Fusarium oxysporum, F. equiseti, F. verticillioides, F. solani, F. lateritium, F. chlamydosporum) and BRR (Lasiodiplodia theobramae, Neoscytalidium dimidiatum) pathogens. In the 2nd cycle, only germination showed significant differences, but by the 4th cycle, various agronomic parameters, including fresh weight (FW.AP), dry weight (DW.AP) of the aerial part, fresh weight (FW.Root), dry weight (DW.Root) of the roots, and plant vigor. Cowpea was identified as the most effective cover crop for reducing the disease index (DI %) by promoting healthier and taller cassava plants. Jack beans and peanuts also had positive effects on vigor, FW.AP, DW.AP, FW.root, and DW.root. In contrast, maize, black oats, Crotalaria ochroleuca, cassava, and fallow soils had minimal impacts. Throughout these cycles, the selected cover crops consistently contributed to disease reduction and improved the agronomic performance of the cassava. This study highlights the potential of holistic disease management strategies.

Background White root rot disease in rubber trees, caused by the pathogenic fungi Rigidoporus microporus , is currently considered a major problem in rubber tree plantations worldwide. Only a few reports have mentioned the response of rubber trees occurring at the non-infection sites, which is crucial for the disease understanding and protecting the yield losses. Results Through a comparative proteomic study using the two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) technique, the present study reveals some distal-responsive proteins in rubber tree leaves during the plant-fungal pathogen interaction. From a total of 12 selected differentially expressed protein spots, several defense-related proteins such as molecular chaperones and ROS-detoxifying enzymes were identified. The expression of 6 candidate proteins was investigated at the transcript level by Reverse Transcription Quantitative PCR (RT-qPCR). In silico, a highly-expressed uncharacterized protein LOC110648447 found in rubber trees was predicted to be a protein in the pathogenesis-related protein 10 (PR-10) class. In silico promoter analysis and structural-related characterization of this novel PR-10 protein suggest that it plays a potential role in defending rubber trees against R. microporus infection. The promoter contains WRKY-, MYB-, and other defense-related cis -acting elements. The structural model of the novel PR-10 protein predicted by I-TASSER showed a topology of the Bet v 1 protein family, including a conserved active site and a ligand-binding hydrophobic cavity. Conclusions A novel protein in the PR-10 group increased sharply in rubber tree leaves during interaction with the white root rot pathogen, potentially contributing to host defense. The results of this study provide information useful for white root rot disease management of rubber trees in the future.