sameAs
Chromosome painting using repetitive DNA sequences as probes for somatic chromosome identification in maizeIn search of the molecular basis of heterosisUnraveling the genetic basis of hybrid vigorThe role of DNA sequence in centromere formationDiscovering the seeds of diversity in plant genomesWhat's in a centromere?Plant artificial chromosome technology and its potential application in genetic engineeringPolyploids as a "model system" for the study of heterosisBiological consequences of dosage dependent gene regulatory systemsDosage balance in gene regulation: biological implicationsPlant science: Hybrid vigour characterizedDynamic epigenetic states of maize centromeresDosage dependent gene regulation and the compensation of the X chromosome in Drosophila malesTelomere-mediated chromosomal truncation in maizeRNAi-mediated pathways in the nucleusConstruction and behavior of engineered minichromosomes in maizeA fluorescence in situ hybridization system for karyotyping soybeanThe gene balance hypothesis: implications for gene regulation, quantitative traits and evolutionGlobal analysis of siRNA-mediated transcriptional gene silencing.From Gigabyte to Kilobyte: A Bioinformatics Protocol for Mining Large RNA-Seq Transcriptomics Data.Maize centromere structure and evolution: sequence analysis of centromeres 2 and 5 reveals dynamic Loci shaped primarily by retrotransposons.Drosophila KDM2 is a H3K4me3 demethylase regulating nucleolar organization.Interploidy hybridization barrier of endosperm as a dosage interaction.Understanding mechanisms of novel gene expression in polyploids.Heterochromatic silencing and HP1 localization in Drosophila are dependent on the RNAi machinery.High frequency of centromere inactivation resulting in stable dicentric chromosomes of maizeNonadditive gene expression in diploid and triploid hybrids of maizeGene expression analysis of the function of the male-specific lethal complex in Drosophila.The dominant inhibitory chalcone synthase allele C2-Idf (inhibitor diffuse) from Zea mays (L.) acts via an endogenous RNA silencing mechanismMarcus rhoades, preferential segregation and meiotic drive.Retroelement genome painting: cytological visualization of retroelement expansions in the genera Zea and Tripsacum.Quantitatively increased somatic transposition of transposable elements in Drosophila strains compromised for RNAiUbiquitous RNA-dependent RNA polymerase and gene silencingDistinct DNA methylation patterns associated with active and inactive centromeres of the maize B chromosomeMisregulation of sex-lethal and disruption of male-specific lethal complex localization in Drosophila species hybridsSequential de novo centromere formation and inactivation on a chromosomal fragment in maizeCytological visualization of DNA transposons and their transposition pattern in somatic cells of maizeA molecular view of plant centromeres.Single-gene detection and karyotyping using small-target fluorescence in situ hybridization on maize somatic chromosomes.Fluorescence in situ hybridization-based karyotyping of soybean translocation lines.
P50
Q22066370-34D2CD1E-E29C-4C52-8249-8112530B4A2AQ24558368-D0708150-AD9A-4EEE-89AD-CF4B3BA3BFB9Q24678323-23DC8D99-15E2-447D-9855-EA1B0E528E65Q24798714-DBEDA9A0-F293-4F08-A03A-91811CCD7D13Q24801352-33F6F9DF-9D25-406D-94BD-2AD8CB7BA147Q24801381-82963887-264F-4485-917F-9FD9014883B3Q26787071-11CDD973-DE52-4696-AE04-3DFAE2FDC3F6Q26809961-B10EDFC5-7A7B-4301-AF02-C24E6EF6D4E7Q26810016-DF46CE17-E0F8-4C39-84CB-D79EB3699A25Q26810030-A5319F5B-7EA1-4082-B39A-E7388BCEC776Q27133323-8BECD741-D535-4444-BE37-4EB24EAE0B29Q28088836-9D46B232-3A25-43A2-90D5-29D0614EC476Q28201869-06C8FB5E-16AA-4727-BD6A-D0583821A784Q28272443-FBED6165-3449-4B12-B723-726496984AB9Q28300961-2C6CFF26-7E86-4D78-9E59-9F5CC68721F0Q28302253-5A1C41E8-C9AB-433C-AA35-540218E15932Q28750283-4292FE84-91F1-44C0-8E0D-545623D2054FQ28752488-B0113414-A0A4-4852-8DD9-447001684584Q30803395-1F856661-7B23-4B24-9EF7-0032914E5120Q30938549-D07BA9F1-5F8A-48FE-B983-DB81AEAB8BF9Q30946313-E4276E50-63EA-4BFD-9E67-3CA0B360756EQ33512123-0403444D-F1FD-4971-9BD8-2EFB6EDAF7FEQ33810371-56CEFCC9-1232-4E25-B799-D3C810695F87Q34180932-EBA2B073-9B36-4ABA-BE2F-D05C35C46EADQ34293738-ADE0A375-133B-4BEA-88C8-ED033AC73C47Q34480146-28CC2C48-2518-421D-99A5-6DA40A2EE579Q34570009-B3C5E6D9-764D-4A89-B5EA-DCC79FA06B76Q34572669-D375F60F-7780-4A15-AFD2-A598407B48F4Q34573474-948BF81A-ED2B-4181-9907-207730813ECEQ34617954-1249C8DF-07DA-44D8-B89B-B417761EACF7Q34895546-8D37580B-1426-4C28-9C19-1E1636E23BBEQ34938346-93D97DAE-2D9E-45AB-903E-C444506F671AQ34964498-872C71B4-42A5-40C9-BFC5-B82F27096467Q35020139-E0563F58-08BB-4851-B697-4BA541F3B8FAQ35175997-0B1B4DFD-9567-426F-8C57-BAEC5C84A7F1Q35212767-3774F444-DD64-42A6-A34B-87A964611AC9Q35598486-D437F026-F832-49A2-B229-BB1E24D5F54AQ35601829-C97A8B88-1324-401E-9AF9-DDC0FBAF254DQ35730046-43D71997-DC20-41F9-AC1A-B14BB8C718BBQ35746691-0DDC17DA-DAF7-43D4-8799-20698EFDD385
P50
description
bioloog
@nl
hulumtues
@sq
researcher
@en
name
James Birchler
@ast
James Birchler
@en
James Birchler
@es
James Birchler
@nl
James Birchler
@sl
Бирчлер, Джеймс
@ru
type
label
James Birchler
@ast
James Birchler
@en
James Birchler
@es
James Birchler
@nl
James Birchler
@sl
Бирчлер, Джеймс
@ru
altLabel
James A Birchler
@en
prefLabel
James Birchler
@ast
James Birchler
@en
James Birchler
@es
James Birchler
@nl
James Birchler
@sl
Бирчлер, Джеймс
@ru
P106
P166
P1960
MTM2HVQAAAAJ
P21
P31
P496
0000-0003-3643-2756