about
An integrated view of protein evolutionFunctional wiring of the yeast kinome revealed by global analysis of genetic network motifsThe ancient mariner sails again: transposition of the human Hsmar1 element by a reconstructed transposase and activities of the SETMAR protein on transposon endsGenome-wide analysis of the context-dependence of regulatory networksMapping pathways and phenotypes by systematic gene overexpression.The genetic landscape of a cellTurning gold into 'junk': transposable elements utilize central proteins of cellular networksComputational identification of obligatorily autocatalytic replicators embedded in metabolic networksModuLand plug-in for Cytoscape: determination of hierarchical layers of overlapping network modules and community centrality.An integrated approach to characterize genetic interaction networks in yeast metabolism.Phenotypic activation to discover biological pathways and kinase substrates.Co-regulation of metabolic genes is better explained by flux coupling than by network distance.Stochasticity in protein levels drives colinearity of gene order in metabolic operons of Escherichia coli.Adaptive evolution of complex innovations through stepwise metabolic niche expansion.Broad metabolic sensitivity profiling of a prototrophic yeast deletion collection.Chance and necessity in the evolution of minimal metabolic networks.Antagonism between bacteriostatic and bactericidal antibiotics is prevalentNetwork-level architecture and the evolutionary potential of underground metabolism.Dosage sensitivity and the evolution of gene families in yeast.Genetic interactions reveal the evolutionary trajectories of duplicate genes.The genomic landscape of compensatory evolutionPlasticity of genetic interactions in metabolic networks of yeastMolecular chaperones as regulatory elements of cellular networks.Erroneous energy-generating cycles in published genome scale metabolic networks: Identification and removalPhenotypic heterogeneity promotes adaptive evolution.Systematic genome reductions: theoretical and experimental approaches.Metabolic reconstruction and analysis for parasite genomes.A critical view of metabolic network adaptations.Systems-biology approaches for predicting genomic evolution.Use of genome-scale metabolic models in evolutionary systems biology.The dawn of evolutionary genome engineering.Collateral sensitivity of antibiotic-resistant microbes.No Evidence That Protein Noise-Induced Epigenetic Epistasis Constrains Gene Expression Evolution.Molecular mechanisms underlying COPD-muscle dysfunction unveiled through a systems medicine approach.From passengers to drivers: Impact of bacterial transposable elements on evolvabilityBacterial evolution of antibiotic hypersensitivity.Perturbation of iron homeostasis promotes the evolution of antibiotic resistance.Highly expressed genes in yeast evolve slowly.Competition between transposable elements and mutator genes in bacteria.Metabolic modeling of endosymbiont genome reduction on a temporal scale
P50
Q22122015-1E30F07F-0B72-4844-B83B-29D15776BDE0Q24606805-0E7A8269-8548-4003-8AA3-838F7AC210C0Q24683138-925B6BA4-8CD2-4CBE-A5DA-E5B65D31E496Q24796086-E187E487-AA5F-44F8-B760-A421ACF1FC5EQ27930674-17B5E64A-CA4E-4CF8-9BEE-C01A5CCE6C0FQ28131628-2F8833A3-B6CB-4BFE-BC6C-A7D4EC6586B4Q28703601-F20A0A4E-6E42-417C-B90D-1FE2BCAA601FQ28754423-ED0A4B6B-BEFD-474B-A9C2-BC2136F977C7Q30418313-B48F8FFF-450B-4CAE-897C-1B480C805D6EQ30501688-F5BC7483-38F1-4F1B-9F9A-9A92B89243EBQ33251088-6E5493FA-4987-456F-8C1A-557F60E55422Q33316819-E36B8AB7-A126-4ECF-948C-C6277AE7645FQ33459140-4798E4AA-CA42-47DC-9BB1-57FB49146916Q33622451-7AFAA605-56F9-43E3-8983-1C15A8909ADCQ33742644-3780B965-6F85-4C5A-9409-E8773C853595Q33994506-B3F3AC09-B2F7-4557-AA13-5FF8B0DA313FQ34058001-B6A03F79-9911-480F-9920-D63F1570F41BQ34060771-D7F131AC-36D2-42B2-934D-1CA088237545Q34213245-F56169C4-7910-433B-941A-857D23DE2016Q34439935-49C647B6-E204-472D-80D7-C2E9B5B7AE45Q35231934-71E1AB5B-A5A0-4066-B8DC-C4666FE98B41Q35844612-19078F39-40D5-4876-AF8B-9734E0ED5B8FQ36076080-94239AAE-F756-4EE7-A7ED-44EB430C9F98Q36349637-3D28D7EF-26AE-4E3E-9D95-266921C56BBBQ36367007-1C913AA0-82EF-4C0B-9134-6112F22D7E12Q36885042-B2443E59-6B0B-4782-9DA3-7B2FE5A40F95Q36976714-0F61BE3D-6120-4C56-A03A-E0C980724C51Q37210415-D20AE773-B1F6-485F-B9D7-9F969B67759BQ37909892-3CF341BC-78C4-406C-808B-30029E3ECCA5Q37921687-2F818975-A082-4BA2-B9B0-E6F3F0217990Q38215368-D9E48C9E-1445-4AA1-AA30-5CADBB08295EQ38394500-434B6A1C-94D2-4534-874B-B185D227B2AEQ39063396-C44B5285-6016-4794-BC26-6BF93EF50257Q39235602-344A15F5-F86E-4C16-8F46-418650D403ACQ40929065-5A6E223D-6C69-4CE1-BA22-D294E98F7FF2Q41867646-6138C6B4-46DC-49AA-B383-457277A0604DQ42022178-81A92E35-6B8D-415E-AED1-B700F5CC98D5Q42541336-0A2E4DF1-286A-4F5E-974C-5CC8C5292A3CQ42673777-303F4080-056C-47F6-85D8-7EDE73034BBAQ42733463-6A0DADE7-236B-44AB-913D-1C8B50E35BD7
P50
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P106
P21
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