Computational approaches to understand transcription regulation in development

Sande, Maarten van der; Frölich, Siebren; Heeringen, Simon J. van

doi:10.1042/bst20210145

Cited by 9 publications

(11 citation statements)

References 185 publications

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“…We first performed quantile normalization along subclasses using the Python package qnorm (v0.8.0) 95 to normalize the mC fractions and compartment scores. We then calculated the PCC between the compartment scores of nonoverlapping chromosome 100Kb bins with the corresponding bin's mCH or mCG fractions across cell subclasses.…”

Section: Compartment Score and MC Fraction Correlationmentioning

confidence: 99%

“…We first performed quantile normalization along subclasses using the Python package qnorm (v0.8.0) 95 to normalize the transcript body mC fractions and chromosome 25Kb bin boundary probabilities. We then calculated the PCC between the differential boundary probabilities of 25Kb bins with the transcript body mCH and mCG fractions.…”

Section: Domain Boundary Probability and Transcript Body MC Fraction ...mentioning

confidence: 99%

“…To investigate the relationship between gene status and the surrounding chromatin conformation diversity, we first performed quantile normalization along subclasses using the Python package qnorm (v0.8.0) 95 to normalize the transcript body mCH fractions and contact strengths of highly variable interactions. We then calculated PCC between the transcript body mCH fraction and the highly variable interactions if any anchor of the interactions had overlapped with the gene body.…”

Section: Interaction Strength and MC Fraction Correlationmentioning

confidence: 99%

“…The basis of each pairwise edge was the correlation between the methylation fractions of the two genome elements across cell subclasses. We performed quantile normalization along subclasses using the Python package qnorm (v0.8.0) 95 to normalize the two matrices involved in calculating the correlation. Gene body mCH fraction was used as a proxy for TF and target gene activity, and mCG fractions were used to represent DMR status.…”

Section: Gene Regulatory Network (Grn) Analysismentioning

confidence: 99%

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Single-cell DNA Methylome and 3D Multi-omic Atlas of the Adult Mouse Brain

Liu

Zeng

Zhou

et al. 2023

Preprint

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Cytosine DNA methylation is essential in brain development and has been implicated in various neurological disorders. A comprehensive understanding of DNA methylation diversity across the entire brain in the context of the brain's 3D spatial organization is essential for building a complete molecular atlas of brain cell types and understanding their gene regulatory landscapes. To this end, we employed optimized single-nucleus methylome (snmC-seq3) and multi-omic (snm3C-seq) sequencing technologies to generate 301,626 methylomes and 176,003 chromatin conformation/methylome joint profiles from 117 dissected regions throughout the adult mouse brain. Using iterative clustering and integrating with companion whole-brain transcriptome and chromatin accessibility datasets, we constructed a methylation-based cell type taxonomy that contains 4,673 cell groups and 261 cross-modality-annotated subclasses. We identified millions of differentially methylated regions (DMRs) across the genome, representing potential gene regulation elements. Notably, we observed spatial cytosine methylation patterns on both genes and regulatory elements in cell types within and across brain regions. Brain-wide multiplexed error-robust fluorescence in situ hybridization (MERFISH) data validated the association of this spatial epigenetic diversity with transcription and allowed the mapping of the DNA methylation and topology information into anatomical structures more precisely than our dissections. Furthermore, multi-scale chromatin conformation diversities occur in important neuronal genes, highly associated with DNA methylation and transcription changes. Brain-wide cell type comparison allowed us to build a regulatory model for each gene, linking transcription factors, DMRs, chromatin contacts, and downstream genes to establish regulatory networks. Finally, intragenic DNA methylation and chromatin conformation patterns predicted alternative gene isoform expression observed in a companion whole-brain SMART-seq dataset. Our study establishes the first brain-wide, single-cell resolution DNA methylome and 3D multi-omic atlas, providing an unparalleled resource for comprehending the mouse brain's cellular-spatial and regulatory genome diversity.

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Section: Compartment Score and MC Fraction Correlationmentioning

confidence: 99%

Section: Domain Boundary Probability and Transcript Body MC Fraction ...mentioning

confidence: 99%

Section: Interaction Strength and MC Fraction Correlationmentioning

confidence: 99%

Section: Gene Regulatory Network (Grn) Analysismentioning

confidence: 99%

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Single-cell DNA Methylome and 3D Multi-omic Atlas of the Adult Mouse Brain

Liu

Zeng

Zhou

et al. 2023

Preprint

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“…Thus, cracking the code of neuronal fate may elicit novel pharmacological strategies, no longer oriented to the cellular hardware but, rather, the nuclear transcriptional regulatory mechanisms. Reconstruction of this cellular program by “reverse engineering” of gene regulatory networks (GRNs) poses great opportunities in systems biology [ 88 , 89 , 90 , 91 , 92 , 93 , 94 , 95 , 96 , 97 ] and allows to build accurate models of physiological and pathological processes, including those implicated in neuronal fate and development [ 98 , 99 , 100 , 101 , 102 , 103 ]. The impact of using these gene regulatory models to understand human diseases and find new treatments is profound, since they may allow to identify disease driver genes and promising biomarkers and therapeutic targets more efficiently and accurately [ 99 , 103 , 104 , 105 , 106 ].…”

Section: Cracking the Transcriptional Regulatory Programs Of Neuronal...mentioning

confidence: 99%

Cracking the Code of Neuronal Cell Fate

Morello

Cognata

Guarnaccia

et al. 2023

Cells

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Transcriptional regulation is fundamental to most biological processes and reverse-engineering programs can be used to decipher the underlying programs. In this review, we describe how genomics is offering a systems biology-based perspective of the intricate and temporally coordinated transcriptional programs that control neuronal apoptosis and survival. In addition to providing a new standpoint in human pathology focused on the regulatory program, cracking the code of neuronal cell fate may offer innovative therapeutic approaches focused on downstream targets and regulatory networks. Similar to computers, where faults often arise from a software bug, neuronal fate may critically depend on its transcription program. Thus, cracking the code of neuronal life or death may help finding a patch for neurodegeneration and cancer.

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