Oomycete Species Associated with Soybean Seedlings in North America—Part II: Diversity and Ecology in Relation to Environmental and Edaphic Factors

Rojas, J. Alejandro; Jacobs, James J.; Napieralski, Stephanie A.; Karaj, Behirda; Bradley, Carl A.; Chase, Thomas E.; Esker, Paul D.; Giesler, Loren J.; Jardine, Douglas J.; Malvick, Dean; Markell, Samuel G.; Nelson, Berlin D.; Robertson, Alison E.; Rupe, J. C.; Smith, Damon; Sweets, Laura; Tenuta, Albert; Wise, Kiersten; Chilvers, Martin I.

doi:10.1094/phyto-04-16-0176-r

Cited by 85 publications

(58 citation statements)

References 46 publications

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“…The oomycete richness we detected was comparable to alpha diversity associated with soybean seedlings (Rojas et al ., ), but was considerably lower compared to 34 taxa found in Sphagnum‐dominated peatland (Singer et al ., ). This could be attributed to several reasons.…”

Section: Discussionmentioning

confidence: 70%

Protists are an integral part of the Arabidopsis thaliana microbiome

Sapp

Ploch

Fiore‐Donno

et al. 2017

Environmental Microbiology

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SummaryAlthough protists occupy a vast range of habitats and are known to interact with plants among other things via disease suppression, competition or growth stimulation, their contributions to the 'phytobiome' are not well described. To contribute to a more comprehensive picture of the plant holobiont, we examined cercozoan and oomycete taxa living in association with the model plant Arabidopsis thaliana grown in two different soils. Soil, roots, leaves and wooden toothpicks were analysed before and after surface sterilization. Cercozoa were identified using 18S rRNA gene metabarcoding, whereas the Internal Transcribed Spacer 1 was used to determine oomycetes. Subsequent analyses revealed strong spatial structuring of protist communities between compartments, although oomycetes appeared more specialized than Cercozoa. With regards to oomycetes, only members of the Peronosporales and taxa belonging to the genus Globisporangium were identified as shared members of the A. thaliana microbiome. This also applied to cercozoan taxa belonging to the Glissomonadida and Cercomonadida. We identified a strong influence by edaphic factors on the rhizosphere, but not for the phyllosphere. Distinct differences of Cercozoa found preferably in wood or fresh plant material imply specific niche adaptations. Our results highlight the importance of microeukaryotes for the plant holobiont.

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Section: Discussionmentioning

confidence: 70%

Protists are an integral part of the Arabidopsis thaliana microbiome

Sapp

Ploch

Fiore‐Donno

et al. 2017

Environmental Microbiology

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“…The SoyNAM population can serve as a diverse resource to map QDRL and compare mechanisms across pathogens and isolates. regional distribution (Rojas et al, 2017a), as well as a range of pathogenicity between and within species (Broders et al, 2007;Jiang et al, 2012;Zitnick-Anderson and Nelson, 2015;Rojas et al, 2017b;Huzar-Novakowiski and Dorrance, 2018). Despite this diversity in distribution and pathogenicity among soilborne pathogens, as J.C. Walker (1975aWalker ( , 1975b stated, "…resistance still holds a properly important place in the field of root rot diseases.…”

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confidence: 99%

Quantitative Disease Resistance Loci towards Phytophthora sojae and Three Species of Pythium in Six Soybean Nested Association Mapping Populations

et al. 2019

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Comparison of quantitative disease resistance loci (QDRL) towards the diverse array of soilborne pathogens that affect soybean [Glycine max (L.) Merr.] is key to the incorporation of resistance in breeding programs. The water molds Phytophthora sojae (Kauffman & Gerdmann), Pythium irregulare (Buisman), Pythium ultimum var. ultimum (Trow), and Pythium ultimum var. sporangiiferum (Drechsler) contribute to soybean yield losses annually. Six Soybean Nested Association Mapping (SoyNAM) populations were evaluated for resistance to one or more of these pathogens. Four were screened with a tray test to measure lesion length after inoculation with Ph. sojae; cup assays were used to screen three, three, and two populations for resistance towards Py. irregulare, Py. ultimum var. ultimum, and Py. ultimum var. sporangiiferum, respectively. There were two to eight major or minor QDRL identified within each SoyNAM population towards one or more of these water molds for a total of 33 QDRL. The SoyNAM populations evaluated for resistance to two or more water molds had different QDRL towards each pathogen, indicating that within a source of resistance, mechanisms are potentially specific to the pathogen. Only 3 of the 33 QDRL were associated with resistance to more than one pathogen. There was a major QDRL on chromosome 3 associated with resistance to Py. ultimum var. ultimum and Py. ultimum var. sporangiiferum, and QDRL on chromosomes 13 and 17 shared a flanking marker for both Py. irregulare and Py. ultimum var. ultimum. The SoyNAM population can serve as a diverse resource to map QDRL and compare mechanisms across pathogens and isolates.

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“…Surveys of microbial communities on wild plants and agricultural systems have been conducted but the studies of agricultural plants have been limited in scope. Many have focused on root-associated microbiota (for example Nettles et al 2016;Peiffer et al 2013;Rojas et al 2017), and many have focused on bacterial communities only (for example Mashiane et al 2017;Rascovan et al 2016). Studies of fungal communities in row crops have often focused on one plant organ, most commonly roots or rhizosphere, and less commonly leaves or phyllosphere (for example Karlsson et al 2017;Sapkota et al 2017).…”

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confidence: 99%

Influence of plant host and organ, management strategy, and spore traits on microbiome composition

Gdanetz

Noel

Trail

2020

Preprint

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Microbiomes from maize and soybean were characterized in a long-term crop rotation research site, under four different land management strategies, to begin unraveling the effects of common farming practices on microbial communities. The fungal and bacterial communities of leaves, stems, and roots in all crops were characterized across the growing season using amplicon sequencing. The wheat rotation has been previously characterized and included here for comparison. Communities differed across plant growth stages and organs, and these effects were most pronounced in the bacterial communities of wheat and maize above-ground organs. Roots consistently had the highest number of unique bacterial OTUs compared to above-ground organs, whereas the alpha diversity of fungi was similar above- and below-ground. Network analyses identified putatively influential members of the microbial communities of the three crops. The fungal OTUs specific to roots, stems or leaves were examined to determine if the specificity reflected their life histories based on previous studies. The analysis suggests that fungal dispersal mechanisms are drivers in organ specificity of the fungal community. Understanding the microbial community structure across the organs of crop plants and identifying influential taxa will provide a critical resource for researchers in future manipulations of naturally occurring microbial communities to reduce plant diseases and to increase crop yields. The ability to predict how these microbes will be dispersed to the target organ will enhance our ability to introduce them sustainably.

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Oomycete Species Associated with Soybean Seedlings in North America—Part II: Diversity and Ecology in Relation to Environmental and Edaphic Factors

Cited by 85 publications

References 46 publications

Protists are an integral part of the Arabidopsis thaliana microbiome

Protists are an integral part of the Arabidopsis thaliana microbiome

Quantitative Disease Resistance Loci towards Phytophthora sojae and Three Species of Pythium in Six Soybean Nested Association Mapping Populations

Influence of plant host and organ, management strategy, and spore traits on microbiome composition

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