about
Evaluation of the ISO standard 11063 DNA extraction procedure for assessing soil microbial abundance and community structureSoil Fungal:Bacterial Ratios Are Linked to Altered Carbon CyclingVegetation exerts a greater control on litter decomposition than climate warming in peatlands.Raman microscopic analysis of single microbial cells.Raman-FISH: combining stable-isotope Raman spectroscopy and fluorescence in situ hybridization for the single cell analysis of identity and function.Vegetation affects the relative abundances of dominant soil bacterial taxa and soil respiration rates in an upland grassland soil.Field scale molecular analysis for the monitoring of bacterial community structures during on-site diesel bioremediation.Effects of sieving, drying and rewetting upon soil bacterial community structure and respiration rates.The bacterial biogeography of British soils.Plant soil interactions alter carbon cycling in an upland grassland soil.Catchment-scale biogeography of riverine bacterioplanktonPlant diversity increases soil microbial activity and soil carbon storage.Niche specialization of terrestrial archaeal ammonia oxidizers.Differences in soil micro-eukaryotic communities over soil pH gradients are strongly driven by parasites and saprotrophs.PIPITS: an automated pipeline for analyses of fungal internal transcribed spacer sequences from the Illumina sequencing platformSoil networks become more connected and take up more carbon as nature restoration progresses.Global change pressures on soils from land use and management.Bacterial Physiological Adaptations to Contrasting Edaphic Conditions Identified Using Landscape Scale Metagenomics.Rhizosphere bacterial carbon turnover is higher in nucleic acids than membrane lipids: implications for understanding soil carbon cyclingRapid method for coextraction of DNA and RNA from natural environments for analysis of ribosomal DNA- and rRNA-based microbial community compositionRNA stable isotope probing, a novel means of linking microbial community function to phylogeny.Ecological consequences of ingestion of Bacillus cereus on Bacillus thuringiensis infections and on the gut flora of a lepidopteran host.Functional and compositional comparison of two activated sludge communities remediating coking effluent.Detecting macroecological patterns in bacterial communities across independent studies of global soils.13CO2 pulse labelling of plants in tandem with stable isotope probing: methodological considerations for examining microbial function in the rhizosphere.Insights into the fate of a 13C labelled phenol pulse for stable isotope probing (SIP) experiments.Closely related protist strains have different grazing impacts on natural bacterial communities.Soil bacterial networks are less stable under drought than fungal networksA method of establishing a transect for biodiversity and ecosystem function monitoring across EuropeLand use driven change in soil pH affects microbial carbon cycling processesEcological network analysis reveals the inter-connection between soil biodiversity and ecosystem function as affected by land use across EuropeSoil parameters, land use, and geographical distance drive soil bacterial communities along a European transectDivergent national-scale trends of microbial and animal biodiversity revealed across diverse temperate soil ecosystemsHarnessing rhizosphere microbiomes for drought-resilient crop productionZones of influence for soil organic matter dynamics: A conceptual framework for data and models
P50
Q28483669-2D35EEA6-7B40-4B34-A31B-4850B8A5DDE9Q28831078-EC58D62E-56CD-4021-BE6F-75113B623568Q30984679-CC4EB810-89E8-4882-AD01-CF7004445742Q31102699-B4C75B1F-2542-4957-B7F1-96EC98249C47Q33291043-25967E17-846D-413B-A6A1-AB3DBBFAA433Q33496472-D29DEC36-57FD-4A62-BB86-2EC13A77770CQ33543525-F26ABC24-C537-46A0-86F8-D2E70ECC7011Q33651811-CE05AE9C-1E86-4101-B9E1-6E460D3074E2Q33877836-E9F4F328-41DC-4C97-8F89-BA4B04CBE739Q34994142-85D5642A-5842-46D7-9A84-A4716959BCACQ35002751-7E328484-00AC-49D6-AA69-1D5DBB290CA3Q35596157-BD7F32BA-685D-484F-8298-7725848A914EQ35641357-7941DBF5-7B20-4851-B448-55F95778BAFEQ35894516-E161375D-08F2-4121-8F60-4E7EA16E0664Q36115589-BC358ABC-159F-4140-8862-05D24F50C09EQ36273724-1450F58D-1595-4BF5-AEA9-E1538A19585CQ38572437-9F26194C-49E8-4F28-94C9-2442C695D0A1Q38662406-B93D93F7-A615-460C-BB0C-730AEF050B38Q39440643-6158F967-D708-4D5C-918C-F3FF9CA4675BQ39488821-0E6A176B-D6AC-4115-8467-AD97B128F30CQ39661863-7863A868-8B9C-45DA-8319-7AE942F29849Q42029025-F3E91789-5ABC-4AD7-B234-CADFEE82AFACQ43320740-9A8131E6-4E1C-4C8B-B466-8AB51D2BB650Q45943740-91D2D562-4AE3-46A7-9CB9-FF7C29DA2949Q47973367-DC23D343-F722-4791-B3BE-2497328B3E73Q48474681-CBB2EECB-8EBF-4FAB-A4D8-635CDC51F566Q51626616-665334AD-DB6D-4482-A454-FB5949F55CE6Q57171203-B57BF36C-C38A-4F1E-953B-3A24785F3F7AQ57202713-2F09C028-3C11-4C26-A8F0-DA0CEE2C45A0Q58765423-38DE8516-1604-4176-9B51-9703594FE987Q58848130-C30D154B-BC9F-4ED1-8C28-C9BC9A24398CQ61444648-C42A5401-7EF5-4DCC-862C-96CD827EA97FQ64122717-4893CF5E-1CB7-4BA6-A1E0-35D8FC68EE82Q91998174-2512DF2C-89D3-428A-BC1D-E07A52F5AC67Q92451918-C550265C-FBE6-490C-B413-8177460DB69D
P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Robert Griffiths
@ast
Robert Griffiths
@en
Robert Griffiths
@es
Robert Griffiths
@nl
Robert Griffiths
@sl
type
label
Robert Griffiths
@ast
Robert Griffiths
@en
Robert Griffiths
@es
Robert Griffiths
@nl
Robert Griffiths
@sl
prefLabel
Robert Griffiths
@ast
Robert Griffiths
@en
Robert Griffiths
@es
Robert Griffiths
@nl
Robert Griffiths
@sl
P106
P21
P31
P496
0000-0002-3341-4547