Pages that link to "Q41909104"

The following pages link to Incorporating nucleosomes into thermodynamic models of transcription regulation (Q41909104):

Displaying 50 items.

• Comparative studies of gene expression and the evolution of gene regulation (Q22122000) (← links)
• Crop epigenetics and the molecular hardware of genotype × environment interactions (Q26776529) (← links)
• Linking genome to epigenome (Q26998850) (← links)
• Quantitative models of the mechanisms that control genome-wide patterns of transcription factor binding during early Drosophila development (Q28477071) (← links)
• Effect of promoter architecture on the cell-to-cell variability in gene expression (Q28477325) (← links)
• Discrimination between thermodynamic models of cis-regulation using transcription factor occupancy data (Q30703913) (← links)
• Computational models for large-scale simulations of facilitated diffusion (Q33556999) (← links)
• Modeling reveals bistability and low-pass filtering in the network module determining blood stem cell fate (Q33576702) (← links)
• Statistical mechanical model of coupled transcription from multiple promoters due to transcription factor titration (Q33707494) (← links)
• Evidence of association between nucleosome occupancy and the evolution of transcription factor binding sites in yeast (Q33917483) (← links)
• Nucleosome repositioning links DNA (de)methylation and differential CTCF binding during stem cell development. (Q34040886) (← links)
• What does physics have to do with cancer? (Q34208808) (← links)
• Manipulating nucleosome disfavoring sequences allows fine-tune regulation of gene expression in yeast (Q34283494) (← links)
• One Hand Clapping: detection of condition-specific transcription factor interactions from genome-wide gene activity data (Q34356274) (← links)
• Nucleosome-mediated cooperativity between transcription factors (Q34450175) (← links)
• Hybrid incompatibility arises in a sequence-based bioenergetic model of transcription factor binding (Q34471588) (← links)
• Changes in selective effects over time facilitate turnover of enhancer sequences (Q34537612) (← links)
• Estimating binding properties of transcription factors from genome-wide binding profiles (Q34883141) (← links)
• A framework for modelling gene regulation which accommodates non-equilibrium mechanisms (Q34887134) (← links)
• Nucleosome free regions in yeast promoters result from competitive binding of transcription factors that interact with chromatin modifiers. (Q34976936) (← links)
• From DNA sequence to transcriptional behaviour: a quantitative approach (Q34985690) (← links)
• The influence of transcription factor competition on the relationship between occupancy and affinity (Q35004798) (← links)
• Understanding variation in transcription factor binding by modeling transcription factor genome-epigenome interactions (Q35067178) (← links)
• A multi-scale model of hepcidin promoter regulation reveals factors controlling systemic iron homeostasis (Q35082168) (← links)
• Torsion-mediated interaction between adjacent genes (Q35238152) (← links)
• Thermodynamics of biological processes. (Q35689987) (← links)
• Unraveling determinants of transcription factor binding outside the core binding site (Q35793479) (← links)
• Predictive regulatory models in Drosophila melanogaster by integrative inference of transcriptional networks (Q36093899) (← links)
• Reverse engineering systems models of regulation: discovery, prediction and mechanisms (Q36337384) (← links)
• A comparison of nucleosome organization in Drosophila cell lines (Q36389394) (← links)
• DNase I sensitivity QTLs are a major determinant of human expression variation (Q36408973) (← links)
• Mapping nucleosome positions using DNase-seq (Q36633198) (← links)
• Differential binding of the related transcription factors Pho4 and Cbf1 can tune the sensitivity of promoters to different levels of an induction signal. (Q36814256) (← links)
• Mapping yeast transcriptional networks (Q37142704) (← links)
• Eukaryotic transcriptional dynamics: from single molecules to cell populations (Q37253556) (← links)
• Transcriptional regulatory circuits: predicting numbers from alphabets (Q37349865) (← links)
• Large-scale mapping of gene regulatory logic reveals context-dependent repression by transcriptional activators. (Q37548523) (← links)
• Challenges for modeling global gene regulatory networks during development: insights from Drosophila. (Q37623991) (← links)
• Time-scale separation--Michaelis and Menten's old idea, still bearing fruit (Q37710104) (← links)
• Impulse control: temporal dynamics in gene transcription (Q37854175) (← links)
• Strategies to discover regulatory circuits of the mammalian immune system (Q37957690) (← links)
• Taking into account nucleosomes for predicting gene expression (Q38092497) (← links)
• In pursuit of design principles of regulatory sequences (Q38218965) (← links)
• Cis-regulatory elements and human evolution (Q38248919) (← links)
• Mapping the fine structure of a eukaryotic promoter input-output function (Q38313315) (← links)
• Physical constraints determine the logic of bacterial promoter architectures. (Q38735778) (← links)
• Signal integration by the CYP1A1 promoter--a quantitative study (Q38879910) (← links)
• DNase-seq predicts regions of rotational nucleosome stability across diverse human cell types (Q39154610) (← links)
• Prediction of fine-tuned promoter activity from DNA sequence (Q39652879) (← links)
• A map of nucleosome positions in yeast at base-pair resolution (Q41968064) (← links)