Project description:State-Transition Analysis of Time-Sequential Gene Expression Identifies Critical Points That Predict Leukemia Development

Project description:State-Transition Analysis of Time-Sequential microRNA Expression Predicts Development of Acute Myeloid Leukemia

Project description:The vertebrate inner ear arises early in development from a thickened epithelium, the otic placode. Specification toward an otic fate requires diverse signals and complex transcriptional inputs that act sequentially and/or in parallel. To uncover and integrate novel genes with known molecular players in the gene regulatory network (GRN) underlying otic development, we have performed transcriptome analyses of the presumptive otic region at sequential early stages of commitment toward inner ear identity. Our results identify hundreds of genes enriched at specific developmental time points, revealing dynamic changes in gene expression as a function of time during the transition from progenitor to committed otic state. Initial functional analysis of selected enriched transcription factors demonstrates a genetic hierarchy amongst these genes underlying this critical transition. Our results not only characterize the otic transcriptome in unprecedented detail but also identify new links in the GRN responsible for development of the presumptive inner ear.

Project description:scRNAseq of sequential time points and CDKi-treated samples during endothelial-to-haematopoietic transition in cells derived by hPSC differentiation.

Project description:Transition state dynamics during a stochastic fate choice

Project description:We show that the microRNA transcriptome undergoes a global state transition during the initiation and progression of acute myeloid leukemia, and accurately predicts time to disease development.

Project description:The circadian clock drives the oscillatory expression of thousands of genes across all tissues and bears significant implications for human health. RNA-seq time-series experiments interrogate the mechanistic links between transcriptional rhythms and phenotypic outcomes. Analysis methods must overcome the challenges of sparse temporal sampling, noisy data, and non-strictly periodic dynamics. Moreover, there remains a need for differential cycling analysis methods that can identify complex changes in rhythmicity for 2-sample comparisons across experimental conditions. We present TimeChange -- a non-parametric and model-free method for the quantification of differential dynamics across experimental conditions. The method leverages a data transformation technique known as time-delay embedding to reconstruct the underlying state space for each gene-of-interest. Takens’ embedding theorem implies that rhythmic dynamics will exhibit circular patterns in the embedded space. TimeChange non-parametrically compares the distributions of points in the embedded space via the Fasano-Franceschini test to assess whether the topological structures differ significantly between phenotypes, thereby quantifying differences in transcriptional dynamics without requiring knowledge of the underlying model. Application of TimeChange to synthetic data shows that it accurately identifies changes in transcriptomic dynamics, including differences in amplitude/peaked-ness; changes in sawtooth asymmetries; and trending oscillatory drifts (e.g. linear, damped, and contractile). We further show that the method has potential utility beyond circadian dynamics. For instance, initial tests of TimeChange using erg rowing-machine data shows accurate classification of differential stroke dynamics in real time, suggesting potential uses of TimeChange in the field of sports science and medicine.

Project description:To understand nutrient dynamics during embryonic and cotyledonary photoheterotrophic transition to mature and germinating autotrophic seeds, TiO2-based phosphoproteomics study in three sequential seed developmental phases in chickpea was performed.

Project description:To understand nutrient dynamics during embryonic and cotyledonary photoheterotrophic transition to mature and germinating autotrophic seeds, 2-DE based proteomics study in six sequential seed developmental stages in chickpea was performed.

Project description:To understand nutrient dynamics during embryonic and cotyledonary photoheterotrophic transition to mature and germinating autotrophic seeds, 2-DE based phosphoproteomics study in six sequential seed developmental stages in chickpea was performed.