Show threadAnnals of BotanyJan 20

🌍 Synthetic microbial communities offer a promising path toward more resilient and sustainable agriculture, bridging microbiology and ecology to restore balance and productivity in farming systems. (8/8)

👉 https://doi.org/qm7h

#SynComs #SustainableAgriculture #PlantMicrobiome #CropProtection #Agroecology #MicrobialEcology #AoBpapers #PlantScience

Annals of BotanyJan 20

🦠🌱 Join us to learn about the newly published “High throughput design of defined microbial consortia for crop protection” in @AnnBot by Temitope Ruth Folorunso and co-authors. (1/10)

👉 https://doi.org/qm7h

#SynComs #SustainableAgriculture #PlantMicrobiome #AoBpapers

NIOO-KNAWDec 19
New publication: Disentangling the molecular mechanisms of disease suppression by endophytic #Flavobacterium sp. 98. #plantmicrobiome #plantgrowth
https://doi.org/10.1016/j.micres.2025.128415
PLOS BiologySep 9, 2025
Reproducibility in #plant #microbiome experiments. This collaborative effort involving 5 labs achieved consistent, inoculum-dependent results, providing detailed protocols, datasets & best practices to promote #reproducibility in #PlantMicrobiome studies @PLOSBiology https://plos.io/41IVzzk
NIOO-KNAWSep 5, 2025
New publication: The soil-plant-human gut microbiome axis into perspective. #microbialcommunities #soilmicrobiome #plantmicrobiome #gutmicrobiome
https://doi.org/10.1038/s41467-025-62989-z
Show threadBenedikt HaugAug 14, 2025

Paper of the week - week 33:

Gfeller et al. 2025:

Crop genotype modulates root rot resistance-associated microbial community composition and abundance of key taxa

"#Pea genotype markedly affected both fungal and bacterial community composition, and these genotype-specific #microbiota were associated with root rot resistance. For example, genotype resistance was correlated (R2 = 19%) with root fungal community composition. Further, several key microbes, showing a high relative abundance, heritability, connectedness with other #microbes, and correlation with plant resistance, were identified."

https://link.springer.com/article/10.1186/s40793-025-00755-w

First authored by my former colleage at FiBL, Valentin Gfeller, and co-authored by my PhD supervisor Pierre Hohmann @plant_holobiont

congrats!

#Breeding #Microbiome #Holobiont #PlantMicrobiome #Phyotpathology #PlantMicrobiomeInteraction #Roots #Root #benediktspapersoftheweek

Crop genotype modulates root rot resistance-associated microbial community composition and abundance of key taxa - Environmental Microbiome

Background Plants are constantly challenged by pathogens, which can cause substantial yield losses. The aggressiveness of and damage by pathogens depends on the host-associated microbiome, which might be shaped by plant genetics to improve resistance. How different crop genotypes modulate their microbiota when challenged by a complex of pathogens is largely unknown. Here, we investigate if and how pea (Pisum sativum L.) genotypes shape their root microbiota upon challenge by soil-borne pathogens and how this relates to a genotype’s resistance. Building on the phenotyping efforts of 252 pea genotypes grown in naturally infested soil, we characterized root fungi and bacteria by ITS region and 16 S rRNA gene amplicon sequencing, respectively. Results Pea genotype markedly affected both fungal and bacterial community composition, and these genotype-specific microbiota were associated with root rot resistance. For example, genotype resistance was correlated (R2 = 19%) with root fungal community composition. Further, several key microbes, showing a high relative abundance, heritability, connectedness with other microbes, and correlation with plant resistance, were identified. Conclusions Our findings highlight the importance of crop genotype-specific root microbiota under root rot stress and the potential of the plant to shape its associated microbiota as a second line of defense.

SpringerLink
ScienceOpenAug 6, 2025

📗 'Effects of the #Rhizosphere microbial community in interspecific #Intercropping of rice on the resistance against rice blast' - an article from the Journal of #SouthernAgriculture on #ScienceOpen:

🔗 https://www.scienceopen.com/document?vid=1bc5d884-fdd9-4e8c-866f-502dcdd87731

#PlantPathology #RiceResearch #PlantMicrobiome

Effects of the rhizosphere microbial community in interspecific intercropping of rice on the resistance against rice blast

<p xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" dir="auto" id="d5884627e151"> <b>[Objective]</b> The objective of this study was to reveal the relationship between rhizosphere soil bacterial community and rice blast resistance under rice interspecies mixed intercropping. This study provided theoretical basis for clarifying the internal mechanism of rice blast control under rice diverse mixed intercropping. </p><p xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" dir="auto" id="d5884627e156"> <b>[Method]</b> A traditional rice blast susceptible variety HKN and four modern rice blast resistant varieties SY63, LY838, LY1259 and YG101 were used to conduct mixed intercropping and monoculture. When the rice grew to the yellow maturity stage, the occurrence of rice neck blast was investigated by the five-point sampling method. The diversity and composition changes of soil bacterial communities in the rhizosphere of rice diverse mixed intercropping were analyzed by 16S rDNA sequencing. </p><p xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" dir="auto" id="d5884627e161"> <b>[Results]</b> Mixed intercropping treatment could effectively reduce the occurrence of rice blast, and the control effect of HKN (susceptible variety) under different combinations reached 42.14%-73.27%. The results of rice rhizosphere bacterial community diversity showed that mixed intercropping had slight effects on the Alpha diversity of rice rhizosphere bacterial community. The results of principal coordinate analysis showed that except that the rhizosphere bacterial community structure in the HKN‖YG101 combination had no significant change in the rhizosphere bacterial community structure before and after intercroppting ( <i>P</i>>0.05), and the rhizosphere bacterial community structure of the other main varieties and intercropped varieties showed significant changes before and after intercropping ( <i>P<</i>0.05, the same below). The dominant bacterial phyla were Actinobacteriota, Chloroflexi, Firmicutes, Proteobacteria and Acidobacteriota. There were 7 genus with high relative abundance in the rhizosphere and significant changes after HKN intercropping, among which relative abundance of <i>Bradyrhizobium</i> was significantly and positively correlated with the incidence and disease index of rice blast, the relative abundance of <i>Marmoricola</i> was significantly and negatively correlated with the incidence and disease index of rice blast. </p><p xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" dir="auto" id="d5884627e178"> <b>[Conclusion]</b> Diverse mixed intercropping can greatly change the rice rhizosphere bacterial community structure and reduce the occurrence of rice blast by enriching <i>Marmoricola</i> and increasing the resistance of susceptible varieties to rice blast. </p><p xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" class="first" dir="auto" id="d5884627e187"> <b>摘要:【目的】</b> 揭示水稻种内混合间栽下根际土壤细菌群落与稻瘟病抗性的关系, 为明确水稻多样性混合间栽控 制稻瘟病的内在机理提供理论基础。 <b>【方法】</b>以1个感稻瘟病传统品种黄壳糯 (HKN) 分别与4个云南主栽抗稻瘟病水 稻品种汕优63 (SY63) 、Ⅱ优838 (LY838) 、两优1259 (LY1259) 、云光101 (YG101) 进行混合间栽及净栽。水稻长至黄 熟期, 采用五点取样法调查穗颈瘟发生情况;利用16S rDNA测序分析水稻多样性混合间栽根际土壤细菌群落多样性 及组成变化。 <b>【结果】</b>混合间栽后能有效减轻稻瘟病发生程度, 不同组合下对感病品种黄壳糯的防治效果达42.14%~ 73.27%。水稻根际细菌群落多样性分析结果显示, 混合间栽对水稻根际细菌群落Alpha多样性影响较小;主坐标分 析结果显示, 除HKN‖YG101组合中的黄壳糯在间栽前后根际细菌群落结构无显著改变 ( <i>P</i>>0.05) 外, 其他组合主栽 品种和间栽品种在间栽前后根际细菌群落结构均出现显著变化 ( <i>P</i><0.05, 下同) 。各处理优势细菌菌门为放线菌门 (Actinobacteriota) 、绿弯菌门 (Chloroflexi) 、厚壁菌门 (Firmicutes) 、变形菌门 (Proteobacteria) 和酸杆菌门 (Acidobacteriota) 。黄壳糯间栽后根际细菌相对丰度较高且发生显著变化的属有7种, 其中慢生根瘤菌属 ( <i>Bradyrhizobium</i>) 相对 丰度与稻瘟病发病率和病情指数呈显著正相关, 大理石雕菌属 ( <i>Marmoricola</i>) 相对丰度与稻瘟病发病率和病情指数 呈显著负相关。 <b>【结论】</b>多样性混合间栽能明显改变水稻根际细菌群落结构, 并通过富集大理石雕菌属提高感病品种 稻瘟病抗性, 从而减轻稻瘟病发病率。 </p>

ScienceOpen
NIOO-KNAWJul 25, 2025
New publication: Harnessing the #phyllosphere #microbiota of wild foxtail millet for designing beneficial cross-kingdom synthetic communities. #plantmicrobiome #domesticatedcrops
https://doi.org/10.1093/ismeco/ycaf066
Show threadBenedikt HaugMay 19, 2025
2/9 Pierre is an absolute specialist when it comes to #PlantMicrobiome interaction. He actually doesn’t talk so much about an isolated #Microbiome, but rather of a combination of the plant and its microbiome:
Plant + Microbiome = #Holobiont.
Ingolf KühnJan 31, 2024

#newPaper accepted: Rhizosphere assembly alters along a chronosequence in the Hallstätter glacier forefield (Dachstein, Austria), by Wisnu Adi Wicaksono, Christian Berg, Gabriele Berg and others. Great collaboration with the colleagues from TU Graz.

https://academic.oup.com/femsec/advance-article/doi/10.1093/femsec/fiae005/7589709

#newPublication #glaciers #succesion #microbiology #plantMicrobiome #rhizosphere #ecology #Alps #Austria #Dachstein

Rhizosphere assembly alters along a chronosequence in the Hallstätter glacier forefield (Dachstein, Austria)

Abstract. Rhizosphere microbiome assembly is essential for plant health, but the temporal dimension of this process remains unexplored. We used a chronosequence

OUP Academic