Field
Value
Language
dc.contributor.author
Super, Laura
datacite.creator.affiliationIdentifier
https://ror.org/03rmrcq20
en_US
datacite.creator.affiliation
University of British Columbia
en_US
datacite.creator.nameIdentifier
https://orcid.org/0000-0002-5259-8708
en_US
dc.date.accessioned
2023-10-12T21:37:00Z
dc.date.available
2023-10-24
dc.date.issued
2023-10-24
dc.identifier.uri
https://www.frdr-dfdr.ca/repo/dataset/9131f74b-16c2-43d4-9657-b40293615f09
dc.identifier.uri
https://doi.org/10.20383/103.0828
dc.description
In a growth chamber experiment, we tested simulated clear-cut soil conditions on shoot biomass, total soil nematode density, and the shoot and root mycobiome of Douglas-fir, Pseudotsuga menziesii (Mirb.) Franco, seedlings. Soil treatments included unamended bare soil and soil amended with root segments of kinnikinnick, Arctostaphylos uva-ursi (L.) Spreng., pinegrass, Calamagrostis rubescens Buckley, or P. menziesii seedlings. We used next-generation Illumina sequencing and the PIPITS pipeline to obtain fungal taxa used for mycobiome community richness and Jaccard-based taxonomic normalized stochasticity ratio to assess mycobiome community assembly stochasticity.
For further information, see Super, L.; Gorzelak, M.A.; Guy, R.D. (2023). Root Fragment Amendments Increase Nematode Density and Mycobiome Stochasticity in Douglas-Fir Seedlings. Forests.
en_US
dc.publisher
Federated Research Data Repository / dépôt fédéré de données de recherche
dc.rights
Creative Commons Attribution 4.0 International (CC BY 4.0)
en_US
dc.rights.uri
https://creativecommons.org/licenses/by/4.0/
en_US
dc.subject
Phyllosphere
en_US
dc.subject
rhizosphere
en_US
dc.subject
soil disturbance
en_US
dc.subject
soil refugia
en_US
dc.subject
stochasticity
en_US
dc.title
Data for root fragment amendments increase nematode density and mycobiome stochasticity in Douglas-fir seedlings
en_US
globus.shared_endpoint.name
f163c1b3-9c88-42f6-a7bb-5839ed6c4063
globus.shared_endpoint.path
/1/published/publication_823/
datacite.publicationyear
2023
datacite.resourcetype
Dataset
en_US
datacite.relatedidentifier.IsCitedBy
https://doi.org/10.3390/f14112120
datacite.fundingReference.funderIdentifier
https://ror.org/01h531d29
en_US
datacite.fundingReference.funderName
Natural Sciences and Engineering Research Council of Canada
en_US
datacite.fundingReference.awardNumber
CGS-D3
en_US
datacite.fundingReference.awardTitle
Canada Graduate Scholarships – Doctoral
en_US
datacite.fundingReference.funderIdentifier
https://ror.org/01h531d29
en_US
datacite.fundingReference.funderName
Natural Sciences and Engineering Research Council of Canada
en_US
datacite.fundingReference.awardNumber
STPGP 478832-15
en_US
datacite.fundingReference.awardTitle
Designing Successful Forest Renewal Practices for Our Changing Climate
en_US
datacite.fundingReference.funderIdentifier
https://ror.org/051dzs374
en_US
datacite.fundingReference.funderName
Agriculture and Agri-Food Canada
en_US
datacite.fundingReference.awardNumber
J-00179
en_US
datacite.fundingReference.awardTitle
Research Accelerating Innovation: Rhizosphere Processes
en_US
frdr.crdc.code
RDF1060906
en_US
frdr.crdc.group_en
Biological sciences
en_US
frdr.crdc.class_en
Plant biology
en_US
frdr.crdc.field_en
Plant microbiota
en_US
frdr.crdc.group_fr
Sciences biologiques
fr_CA
frdr.crdc.class_fr
Phytobiologie
fr_CA
frdr.crdc.field_fr
Microbiote des plantes
fr_CA
datacite.description.other
Item exited embargo and became publicly available on 2023-10-24
