about
Phylum Verrucomicrobia representatives share a compartmentalized cell plan with members of bacterial phylum PlanctomycetesStructure of the archaeal community of the rumenA proposed taxonomy of anaerobic fungi (class neocallimastigomycetes) suitable for large-scale sequence-based community structure analysisLambs fed fresh winter forage rape (Brassica napus L.) emit less methane than those fed perennial ryegrass (Lolium perenne L.), and possible mechanisms behind the differenceTwo different bacterial community types are linked with the low-methane emission trait in sheepRumen microbial community composition varies with diet and host, but a core microbiome is found across a wide geographical rangeRIM-DB: a taxonomic framework for community structure analysis of methanogenic archaea from the rumen and other intestinal environmentsSimultaneous amplicon sequencing to explore co-occurrence patterns of bacterial, archaeal and eukaryotic microorganisms in rumen microbial communitiesPhylogeny of intestinal ciliates, including Charonina ventriculi, and comparison of microscopy and 18S rRNA gene pyrosequencing for rumen ciliate community structure analysis.Cultivation of globally distributed soil bacteria from phylogenetic lineages previously only detected in cultivation-independent surveys.Laboratory cultivation of widespread and previously uncultured soil bacteria.Chthoniobacter flavus gen. nov., sp. nov., the first pure-culture representative of subdivision two, Spartobacteria classis nov., of the phylum VerrucomicrobiaDefluvicoccus vanus gen. nov., sp. nov., a novel Gram-negative coccus/coccobacillus in the 'Alphaproteobacteria' from activated sludge.Haloquadratum walsbyi gen. nov., sp. nov., the square haloarchaeon of Walsby, isolated from saltern crystallizers in Australia and Spain.Combined use of cultivation-dependent and cultivation-independent methods indicates that members of most haloarchaeal groups in an Australian crystallizer pond are cultivable.Identifying the dominant soil bacterial taxa in libraries of 16S rRNA and 16S rRNA genes.Effect of pH on isolation and distribution of members of subdivision 1 of the phylum Acidobacteria occurring in soil.Halonotius pteroides gen. nov., sp. nov., an extremely halophilic archaeon recovered from a saltern crystallizer.Natronomonas moolapensis sp. nov., non-alkaliphilic isolates recovered from a solar saltern crystallizer pond, and emended description of the genus Natronomonas.Detection of a reproducible, single-member shift in soil bacterial communities exposed to low levels of hydrogenGenome sequence of the verrucomicrobium Opitutus terrae PB90-1, an abundant inhabitant of rice paddy soil ecosystems.Methane yield phenotypes linked to differential gene expression in the sheep rumen microbiome.Variability of the Chlamydia trachomatis omp1 gene detected in samples from men tested in male-only saunas in Melbourne, Australia.Three genomes from the phylum Acidobacteria provide insight into the lifestyles of these microorganisms in soils.Secretory antibodies do not affect the composition of the bacterial microbiota in the terminal ileum of 10-week-old mice.Genome sequence of "Pedosphaera parvula" Ellin514, an aerobic Verrucomicrobial isolate from pasture soilGenome sequence of Chthoniobacter flavus Ellin428, an aerobic heterotrophic soil bacterium.Internal transcribed spacer 1 secondary structure analysis reveals a common core throughout the anaerobic fungi (Neocallimastigomycota).Considerations in the use of fluorescence in situ hybridization (FISH) and confocal laser scanning microscopy to characterize rumen methanogens and define their spatial distributions.Chronic Helicobacter pylori infection does not significantly alter the microbiota of the murine stomachRUMINANT NUTRITION SYMPOSIUM: Use of genomics and transcriptomics to identify strategies to lower ruminal methanogenesis.Buccal swabbing as a noninvasive method to determine bacterial, archaeal, and eukaryotic microbial community structures in the rumen.Natural variation in methane emission of sheep fed on a lucerne pellet diet is unrelated to rumen ciliate community type.Phylogenetic analysis by 16S ribosomal DNA sequence comparison reveals two unrelated groups of species within the genus Ruminococcus.Rumen metagenome and metatranscriptome analyses of low methane yield sheep reveals a Sharpea-enriched microbiome characterised by lactic acid formation and utilisation.Progress in the development of vaccines against rumen methanogens.A modified version of the Molly rumen model to quantify methane emissions from sheep.The complete genome sequence of Eubacterium limosum SA11, a metabolically versatile rumen acetogen.A1Ao-ATP synthase of Methanobrevibacter ruminantium couples sodium ions for ATP synthesis under physiological conditionsA member of the delta subgroup of proteobacteria from a pyogenic liver abscess is a typical sulfate reducer of the genus Desulfovibrio
P50
Q21263040-B42B5F58-CBBF-4B6B-A849-7CE3A4BC0CB9Q24647099-E61FB2A0-6127-4139-AC19-1444DD1967F3Q27303094-AB83CB82-FAEA-4969-B897-B79963E3A0C6Q27311675-69F4AF62-5586-443D-AB00-95F4ED213844Q27318117-204B2F16-195C-4D6E-82B6-9F273D93F023Q28606606-32D46D7D-36E1-41F8-9363-765C728B79B8Q28654454-4860C64B-E7B2-48F4-9A8C-52A83CCF1930Q28709077-8B8CBBAF-A724-4AE3-9315-A5F11A7016DEQ30627366-005DA9A6-A047-4E50-A3AA-2B1AE203264BQ30750881-F198C017-B8C4-497D-A1FB-7A5A17D65F69Q30885664-AD7A4747-A82F-408B-97F4-14F52D46CF8EQ30968204-5F1BBEDA-2083-43B0-BD8B-79A7C503560BQ31004905-9F6C600B-EA01-41A6-9665-480811C90B42Q31096956-788F14F2-7192-4A01-983B-1D0E32004498Q33206422-4394B407-A0AB-42D1-A2FA-E85065F8E90AQ33235504-71F58E87-4CD8-4515-894A-55314FB66BBAQ33235509-A65EB83F-8160-4A32-A660-59A08F46ADF3Q33492206-304557F9-8D39-4077-872A-8DAA1D61C664Q33492220-07A48413-6E17-4731-8BFC-4E7BA665A8E5Q33704645-CE042507-D537-4605-80E3-13BD1DE6FD78Q33844591-41C035D9-3146-4DAB-95FD-F49F7CCEC112Q34153777-773A686A-AF0B-4445-AE6E-C6131B28FBFFQ34784553-060AA532-5366-442D-B5E6-7052FAE411ABQ34939991-A406B603-FCF2-4867-A058-F26F4247474EQ34993355-A182E3E1-D11C-4691-84B3-AADE6B055B95Q35096040-AE1704B7-5BD7-4E43-B8FA-7CF3C08F3E93Q35096073-1AA0CFBE-94A2-49C6-933D-A6136B5AE49BQ35129326-9042A9EA-E939-4461-8A6F-EA8096A0AFE3Q35617875-D34AF8FA-690B-41C0-B466-5CAA152284A2Q35641978-1E632B63-C997-4813-8B07-816786385ED9Q35644439-9054C84A-E6A2-4A19-9277-4DC81A00A6F9Q35746850-9D69B923-A9C8-4B9D-8833-63614FA399A6Q35905275-8C2F74D3-AE58-4C44-9DA0-9D0D55E48AA6Q36707615-44AF3C01-8E61-433F-AE0C-AB3465F42B85Q37349621-DE70A74F-BF10-4B43-A048-EECAE83F2B87Q38112279-A927335D-5948-4750-BAC9-8D5EC726C067Q38956258-012D8F6C-2552-495F-A5A2-4E922917C810Q39003569-ECA58B3B-5812-4E28-A330-4C446FBF41DAQ39244025-B34B9D55-2516-47B9-B18E-C17D70787458Q39463530-B7DA4E98-D6D3-44D2-99A9-8E115AFA78DB
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Peter H. Janssen
@ast
Peter H. Janssen
@en
Peter H. Janssen
@es
Peter H. Janssen
@nl
Peter H. Janssen
@sl
type
label
Peter H. Janssen
@ast
Peter H. Janssen
@en
Peter H. Janssen
@es
Peter H. Janssen
@nl
Peter H. Janssen
@sl
altLabel
Petrus Hendricus Janssen
@en
prefLabel
Peter H. Janssen
@ast
Peter H. Janssen
@en
Peter H. Janssen
@es
Peter H. Janssen
@nl
Peter H. Janssen
@sl
P106
P1153
7201762494
P21
P31
P496
0000-0002-1022-3502