about
Spatial and topological organization of DNA chains induced by gene co-localizationRobustness can evolve gradually in complex regulatory gene networks with varying topologyRandomizing genome-scale metabolic networksA large maize (Zea mays L.) SNP genotyping array: development and germplasm genotyping, and genetic mapping to compare with the B73 reference genomeNeutral network sizes of biological RNA molecules can be computed and are not atypically small.Genotype networks in metabolic reaction spacesChallenges in experimental data integration within genome-scale metabolic models.Amplifying recombination genome-wide and reshaping crossover landscapes in Brassicas.Intraspecific variation of recombination rate in maize.Phenotypic plasticity can facilitate adaptive evolution in gene regulatory circuitsCODA (crossover distribution analyzer): quantitative characterization of crossover position patterns along chromosomesCrossover localisation is regulated by the neddylation posttranslational regulatory pathway.Combined fluorescent and electron microscopic imaging unveils the specific properties of two classes of meiotic crossovers.Toward a theory of marker-assisted gene pyramiding.Two- and three-locus tests for linkage analysis using recombinant inbred linesDistribution of parental genome blocks in recombinant inbred lines.Patterns of recombination and MLH1 foci density along mouse chromosomes: modeling effects of interference and obligate chiasma.Constrained Allocation Flux Balance AnalysisRecombination patterns in maize reveal limits to crossover homeostasis.Detailed recombination studies along chromosome 3B provide new insights on crossover distribution in wheat (Triticum aestivum L.).Hot regions of noninterfering crossovers coexist with a nonuniformly interfering pathway in Arabidopsis thaliana.Drivers of structural features in gene regulatory networks: From biophysical constraints to biological function.Sinusoidal swinging dynamics of the telomere repair and cell growth activation functions of telomerase in rat liver cancer cells.Short relaxation times but long transient times in both simple and complex reaction networks.Return probabilities and hitting times of random walks on sparse Erdös-Rényi graphs.Quantifying slow evolutionary dynamics in RNA fitness landscapes.Finite population-size effects in projection Monte Carlo methods.Haldane, Waddington and recombinant inbred lines: extension of their work to any number of genes.Responses to auxin signals: an operating principle for dynamical sensitivity yet high resilience.A congruence index for testing topological similarity between trees.Statistical Physics Methods Provide the Exact Solution to a Long-Standing Problem of Genetics.Adaptive networks of trading agents.Phenotypic robustness can increase phenotypic variability after nongenetic perturbations in gene regulatory circuits.New structural variation in evolutionary searches of RNA neutral networks.From simple to complex networks: inherent structures, barriers, and valleys in the context of spin glasses.Temperature chaos, rejuvenation, and memory in Migdal-Kadanoff spin glasses.Hierarchical approach for computing spin glass ground states.Memory capacity in large idiotypic networks.High-throughput measurement of recombination rates and genetic interference in Saccharomyces cerevisiae.A numerical study of persistence length effects on DNA conformation in sequencing electrophoresis.
P50
Q27335092-3818D4B5-C9CE-4E9C-9137-5B107999D825Q28469133-0A5E3B73-4D82-4E0D-973C-67A69BD235A7Q28479041-39B37FEB-BD77-4C4A-B2DF-32FA30A2E506Q28741696-22D07330-94C5-4047-9FB6-FAB93387A842Q30485948-F0E546BF-FDF6-4B82-95E3-560EE64F620FQ33543376-0753F474-6AE1-46AA-AFEB-C6BC763661D6Q33562246-7E57FD1E-19D5-4FD9-ACDB-1E96B038F65AQ33728711-08B4C0DE-850B-4133-AB2F-6CCB637565C2Q33741859-FFB6BDE8-A5B7-458C-B0F6-532E1FA97EEAQ33787403-FA9A38E8-CAC0-4E78-AF36-7E0385DF61B7Q33798521-6F168297-4F0F-4DCB-967B-7A93C0A37B85Q34035751-66F8C846-7A32-49F8-BE79-052865679D91Q34218228-9A63BD3E-7CE6-46B1-B12F-F00A75EC8083Q34567285-8B122292-2901-4235-8711-ABC313BB14AFQ34611413-F4855B90-B893-401D-BFE5-145B4492339DQ35297935-14719C74-6647-4C19-8492-CCDDE1D6B59CQ35911013-5224E179-C2C9-4915-B1EB-DB0CAE68E462Q36063811-713C999B-0B3B-4F91-B77B-703E4DB2E703Q36435366-45ECC7AF-81A5-4F29-9664-5B77563F987AQ37102583-39AA85EF-8915-48A1-9C42-2044D15E0871Q37269805-8048D1AF-91DF-4EA9-9C50-11AA6A06EADEQ38882785-D0F7EE22-BA88-4CB9-9BCC-95F5EE8CB811Q40191882-8E0B9083-AE59-4044-BBCD-4FE7B9BD99E8Q42150678-A1910BC6-BD44-4679-A249-895EC75C0EC7Q43568654-2C12C965-9515-4228-9F0D-B80E73102C94Q44725979-7439E285-0F90-4A8A-AD90-89D9BEB05226Q47355993-726F471B-3DA4-4818-AC8B-2B1584D71D79Q47577203-6E2658F6-A1B4-48CE-85D6-A1E069CF3C11Q48094104-7928F191-818F-42E3-8780-96E438657441Q48379604-8B16FCC4-6049-428F-B8C3-7FA033B1FFB0Q50879285-85336D6B-1805-4BAB-AB75-E9B431876458Q51863676-54DDBE8F-C5BD-4AE6-8AC5-FCE22DEDEE12Q51875929-0903BF9E-FB8F-44A0-9F36-FA9DBCCEF42EQ51923609-C3756CDF-D804-4B2D-B0E9-0BF4E89538CCQ51944093-DAC772CC-6B4B-4B41-A0B9-4B6FE010E81DQ52005265-7B9C6037-B6A1-4826-B390-9D8D853BEEC4Q52050584-5C598350-6F33-486A-8E29-A8EFAA1CF827Q52055040-E0CE72F8-519E-424E-A4C2-1EAA1EA7C1AFQ52724226-4F587F04-CD75-438D-9ABF-4A2AC12C8E08Q52890817-E3560BD1-77F4-43E6-8B6D-56CAD57C6E1B
P50
description
hulumtues
@sq
researcher
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wetenschapper
@nl
հետազոտող
@hy
name
Olivier C. Martin
@ast
Olivier C. Martin
@en
Olivier C. Martin
@es
Olivier C. Martin
@nl
Olivier C. Martin
@sl
type
label
Olivier C. Martin
@ast
Olivier C. Martin
@en
Olivier C. Martin
@es
Olivier C. Martin
@nl
Olivier C. Martin
@sl
prefLabel
Olivier C. Martin
@ast
Olivier C. Martin
@en
Olivier C. Martin
@es
Olivier C. Martin
@nl
Olivier C. Martin
@sl
P1053
B-6656-2012
P106
P21
P2456
P2798
P31
P3829
P496
0000-0002-5295-5963