about
Gene Transfer from Bacteria and Archaea Facilitated Evolution of an Extremophilic EukaryoteAn integrated view of protein evolutionEvidence for widespread degradation of gene control regions in hominid genomesUnusual linkage patterns of ligands and their cognate receptors indicate a novel reason for non-random gene order in the human genomeGenome-wide acceleration of protein evolution in flies (Diptera).sybil – Efficient constraint-based modelling in RForty years of The Selfish Gene are not enoughComparative functional analysis of the Caenorhabditis elegans and Drosophila melanogaster proteomesEvolview v2: an online visualization and management tool for customized and annotated phylogenetic treesEnergy efficiency trade-offs drive nucleotide usage in transcribed regionsPhylogenomic analysis reveals bees and wasps (Hymenoptera) at the base of the radiation of Holometabolous insectsAmino acid composition in endothermic vertebrates is biased in the same direction as in thermophilic prokaryotes.An integrated approach to characterize genetic interaction networks in yeast metabolism.WhopGenome: high-speed access to whole-genome variation and sequence data in R.Improved Metabolic Models for E. coli and Mycoplasma genitalium from GlobalFit, an Algorithm That Simultaneously Matches Growth and Non-Growth Data Sets.ColorTree: a batch customization tool for phylogenic trees.Does negative auto-regulation increase gene duplicability?Shotgun proteomics data from multiple organisms reveals remarkable quantitative conservation of the eukaryotic core proteome.Co-expression of neighbouring genes in Arabidopsis: separating chromatin effects from direct interactions.Adaptive evolution of complex innovations through stepwise metabolic niche expansion.HOTAIR rs7958904 polymorphism is associated with increased cervical cancer risk in a Chinese population.A gene's ability to buffer variation is predicted by its fitness contribution and genetic interactions.The effects of network neighbours on protein evolution.The role of photorespiration during the evolution of C4 photosynthesis in the genus Flaveria.Chance and necessity in the evolution of minimal metabolic networks.Clustering of housekeeping genes provides a unified model of gene order in the human genome.Human functional genetic studies are biased against the medically most relevant primate-specific genes.TreeSnatcher plus: capturing phylogenetic trees from images.EvolView, an online tool for visualizing, annotating and managing phylogenetic trees.The evolutionary dynamics of eukaryotic gene order.Horizontal gene acquisitions by eukaryotes as drivers of adaptive evolution.X-chromosome-wide profiling of MSL-1 distribution and dosage compensation in Drosophila.Human SNP variability and mutation rate are higher in regions of high recombination.Coexpression of linked gene pairs persists long after their separationOGEE: an online gene essentiality database.Erroneous energy-generating cycles in published genome scale metabolic networks: Identification and removalSimilar gene expression profiles do not imply similar tissue functions.Mitochondrial 2-hydroxyglutarate metabolism.Co-expressed yeast genes cluster over a long range but are not regularly spaced.Assessing the influence of adjacent gene orientation on the evolution of gene upstream regions in Arabidopsis thaliana
P50
Q22065589-30CEF0C7-8CE0-448B-BAC8-2328B8583111Q22122015-30FAC2D3-C097-47B5-A868-826409C2B64BQ24804367-21E64F75-D4A2-442D-9740-5A002A968FDFQ24815834-37AF440B-6DFA-4E0A-A491-F8975318F940Q25255543-1543DEF9-CF20-42DB-9850-157685A21DA8Q27499049-BC3BB737-239A-446E-811E-11AA46034EC7Q28067633-D9D0CFC8-CA4D-43F3-98B7-3E1B3BDC603DQ28474965-A15113ED-6A16-4806-8CA4-BF12AE2F1A14Q28597766-04FBAD07-7538-4C68-99E5-77B14405A35AQ28603766-CD6754D2-4547-49E4-B36D-4AEA270AE10EQ28766915-928C954B-8947-4C4A-9BFB-A767C65461D3Q30393184-7FF4ECD8-DE9A-4343-BFFD-A033B43AC502Q30501688-5345EA34-6BED-4F92-ADC3-45758CB30447Q30856876-9D6F0E76-F72F-4223-B4EA-7C6D613601D7Q31119097-6A31E868-5D50-421B-9278-CDF1A606C716Q33489049-610543CE-EF00-471D-ABDF-468B1D20A51FQ33491803-0417FC80-A9EA-42ED-9AB4-44E715A95AD3Q33524451-96EF2879-6ED3-4F59-82C6-F3EE39521E05Q33541277-F80D1F9A-7A2F-42CD-A743-036D22FED699Q33622451-4A719922-42C7-48F9-99AD-EDBA8DFCF694Q33784557-5FB99121-512B-43E3-82B6-09890FB4DC61Q33847031-8BBF8F08-8CF7-412B-8F61-D7B0A79E9C91Q33885848-6EA665B9-4482-4A76-935E-A77299ACA371Q33920736-1538B122-7025-470E-96D1-2ADAD6A7B205Q33994506-0463E53C-FE0E-4861-89A6-3DB5E1309664Q34126902-77F54163-F328-47C0-9E59-C56D51D7AA17Q34267655-3C678BAC-8C4D-4862-BE91-30415E8F1F7DQ34280363-47473A3A-3F69-4930-8F18-F7075B7608DDQ34281281-6C50B3F2-408E-46CB-A4E0-CBDAF8C31D0FQ34319346-9668CA7B-BBDF-47DA-9D36-3C3E75832514Q34390817-2CBCC61E-0CDC-4E9A-9D8B-FB6CD437C6C2Q34649154-E96F82E3-E724-4233-984A-A599AC4E8924Q34750287-0AE1EADB-9B08-4EBE-9DD0-9BCE68D27561Q35165974-CA06553D-B3CA-4F04-A8B0-3CFCBCFAED8BQ35630912-CE8D8CE4-C681-451F-9F3F-9D0051200C3DQ36349637-D8195F45-4CFC-48FA-98EA-8E45EBD39321Q36397495-6A6AE9CF-13D3-44CC-9CCE-B40E44D805A9Q38190378-2E3E3CE5-E138-44C6-ADF9-9FB97F2F1C89Q38313999-29AACD1B-0029-4810-93A8-E4516465BFF7Q40896309-CDA16B89-95FB-4D28-916B-003B4D3C69E6
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Martin J. Lercher
@en
Martin J. Lercher
@es
Martin J. Lercher
@nl
Martin J. Lercher
@sl
Martin Lercher
@fr
type
label
Martin J. Lercher
@en
Martin J. Lercher
@es
Martin J. Lercher
@nl
Martin J. Lercher
@sl
Martin Lercher
@fr
altLabel
Martin J Lercher
@en
prefLabel
Martin J. Lercher
@en
Martin J. Lercher
@es
Martin J. Lercher
@nl
Martin J. Lercher
@sl
Martin Lercher
@fr
P1053
K-7939-2013
P106
P21
P2456
P31
P3829
P496
0000-0003-3940-1621