about
Myxococcus xanthus gliding motors are elastically coupled to the substrate as predicted by the focal adhesion model of gliding motilityThe mechanistic basis of Myxococcus xanthus rippling behavior and its physiological role during predationThe motility of mollicutes.Transient heterogeneity in extracellular protease production by Bacillus subtilisStatistical image analysis reveals features affecting fates of Myxococcus xanthus developmental aggregates.Pattern formation and traveling waves in myxobacteria: theory and modelingAdaptable functionality of transcriptional feedback in bacterial two-component systems.Modeling reveals bistability and low-pass filtering in the network module determining blood stem cell fate.Dynamic disorder in quasi-equilibrium enzymatic systems.Tunable protease-activatable virus nanonodesUnraveling the regulatory connections between two controllers of breast cancer cell fateInterplay of gene expression noise and ultrasensitive dynamics affects bacterial operon organization.Bistable responses in bacterial genetic networks: designs and dynamical consequencesBreaking symmetry in myxobacteria.Role of Autoregulation and Relative Synthesis of Operon Partners in Alternative Sigma Factor Networks.Ultrasensitivity of the Bacillus subtilis sporulation decision.Non-transcriptional regulatory processes shape transcriptional network dynamicsA biochemical oscillator explains several aspects of Myxococcus xanthus behavior during development.Slowdown of growth controls cellular differentiation.Distinctive topologies of partner-switching signaling networks correlate with their physiological roles.Single-cell measurement of the levels and distributions of the phosphorelay components in a population of sporulating Bacillus subtilis cells.Hysteretic and graded responses in bacterial two-component signal transduction.Thermodynamic models of combinatorial gene regulation by distant enhancers.Signalling network with a bistable hysteretic switch controls developmental activation of the sigma transcription factor in Bacillus subtilis.Rippling of myxobacteria.Developmental waves in myxobacteria: A distinctive pattern formation mechanism.Triggering sporulation in Bacillus subtilis with artificial two-component systems reveals the importance of proper Spo0A activation dynamics.Mathematical model of a gene regulatory network reconciles effects of genetic perturbations on hematopoietic stem cell emergence.Dynamic disorder-driven substrate inhibition and bistability in a simple enzymatic reaction.Kinetic control of stationary flux ratios for a wide range of biochemical processesOptogenetic control of Bacillus subtilis gene expressionTrade-Offs between Error, Speed, Noise, and Energy Dissipation in Biological Processes with ProofreadingA synthetic system for asymmetric cell division in Escherichia coliAn Engineered B. subtilis Inducible Promoter System with over 10 000-Fold Dynamic RangeTrade-Offs between Speed, Accuracy, and Dissipation in tRNAIle Aminoacylation
P50
Q27322580-EE096982-12E0-476C-9E94-0A0245BD0EA6Q27329659-B6417682-D5D8-4100-A595-B9715B887A2CQ30476426-7A44662B-E080-43DB-B110-001609F339FEQ30481955-FE03359E-5AA8-4FCC-A179-A3A0FCFDD15EQ30499707-2CB72A63-4DD7-42C5-AE31-A66B806BAAB6Q30857014-F27E9CF0-9B39-446A-B215-1C9726B378D1Q30978121-370781E3-D467-46F2-AD38-99032D8EDDF0Q33576702-1492BB65-73C0-4A26-A65F-5A5E6A30DC03Q33680137-9FCF59C4-4D9C-45A0-8BE2-6E58382497A6Q33680137-D6C8EBEB-1B31-4955-8570-193580FDF223Q33716080-F8B39C52-5523-4C3A-A8B0-537810D9EC77Q33791223-D61A25B6-1196-4772-B2DE-A3677EC95EB2Q34407774-89889748-36E2-4856-9A2E-B3FB180FECAFQ34984026-F5250D63-E518-4A5E-AD34-7CE40915ADFCQ35808714-5F90457D-2492-4CE0-8221-DDF41A780141Q36224692-1A5FAE93-6138-4C27-AC22-002B49F6EFC5Q36483629-49EDE2B9-2F46-4375-AE8A-9476866E35C2Q37128860-723388D8-D5D2-405F-A873-2E9A42F27933Q37595901-979AABB7-9AA1-48F5-A8D1-E7576BC388C9Q37621285-7129707C-A820-475A-847B-75734805258FQ43069033-69A6EA3C-8031-4EDD-AFDD-6F579E014440Q43088351-05C04F8A-01A0-419C-A39A-313F70B7FB14Q43191527-9C686F40-18F1-4FB6-B0EF-912BFC682F36Q43493950-55A08EB7-49CE-4D9F-BD1D-FCBA332CB50BQ45995301-F53EF184-6725-4D00-B54F-BB4E582FC2F1Q46651147-6DCECFB0-5E88-4F18-BCDD-DF94EDD894B0Q46676477-F8401FD8-D20C-4C9E-8154-CA6FBC78DF68Q47827455-41046F71-3EB6-4069-9131-5B80F307580AQ50746835-C66C4A63-7C26-4F99-B4C1-E0CF3952B97AQ51793024-7B3AA649-DFAA-4205-A7FE-0A9C38E20FF3Q91707194-3A11A92C-8220-408F-8690-B4FD341DDFFCQ91902402-10141779-FEC3-4867-AA6A-0F79369E1B0BQ91916225-D0576017-B8DF-4C32-A7BB-48E536D18666Q92579002-B7C10980-1FBE-4134-BD82-6EFC4A386B17Q92632759-0922726A-CDCE-46F5-909C-03A79FDB48EBQ94471649-AAE151F7-BB55-40DD-AA33-442E0729B157
P50
description
hulumtues
@sq
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Oleg A Igoshin
@ast
Oleg A Igoshin
@en
Oleg A Igoshin
@es
Oleg A Igoshin
@nl
Oleg A Igoshin
@sl
type
label
Oleg A Igoshin
@ast
Oleg A Igoshin
@en
Oleg A Igoshin
@es
Oleg A Igoshin
@nl
Oleg A Igoshin
@sl
prefLabel
Oleg A Igoshin
@ast
Oleg A Igoshin
@en
Oleg A Igoshin
@es
Oleg A Igoshin
@nl
Oleg A Igoshin
@sl
P1053
P-3937-2014
P106
P21
P2456
P31
P3829
P496
0000-0002-1449-4772