Frontiers in Genetics (Nov 2015)

Mapping mammalian cell-type-specific transcriptional regulatory networks using KD-CAGE and ChIP-seq data in the TC-YIK cell line.

  • Marina eLizio,
  • Marina eLizio,
  • Yuri eIshizu,
  • Yuri eIshizu,
  • Masayoshi eItoh,
  • Masayoshi eItoh,
  • Masayoshi eItoh,
  • Timo eLassmann,
  • Timo eLassmann,
  • Akira eHasegawa,
  • Akira eHasegawa,
  • Atsutaka eKubosaki,
  • Jessica eSeverin,
  • Jessica eSeverin,
  • Hideya eKawaji,
  • Hideya eKawaji,
  • Hideya eKawaji,
  • Yukio eNakamura,
  • Harukazu eSuzuki,
  • Harukazu eSuzuki,
  • Yoshihide eHayashizaki,
  • Yoshihide eHayashizaki,
  • Piero eCarninci,
  • Piero eCarninci,
  • Alistair R R Forrest,
  • Alistair R R Forrest,
  • Alistair R R Forrest

DOI
https://doi.org/10.3389/fgene.2015.00331
Journal volume & issue
Vol. 6

Abstract

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Mammals are composed of hundreds of different cell types with specialized functions. Each of these cellular phenotypes are controlled by different combinations of transcription factors. Using a human non islet cell insulinoma cell line (TC-YIK) which expresses insulin and the majority of known pancreatic beta cell specific genes as an example, we describe a general approach to identify key cell-type-specific transcription factors (TFs) and their direct and indirect targets. By ranking all human TFs by their level of enriched expression in TC-YIK relative to a broad collection of samples (FANTOM5), we confirmed known key regulators of pancreatic function and development. Systematic siRNA mediated perturbation of these TFs followed by qRT-PCR revealed their interconnections with NEUROD1 at the top of the regulation hierarchy and its depletion drastically reducing insulin levels. For 15 of the TF knock-downs (KD), we then used Cap Analysis of Gene Expression (CAGE) to identify thousands of their targets genome-wide (KD-CAGE). The data confirm NEUROD1 as a key positive regulator in the transcriptional regulatory network (TRN), and ISL1 and PROX1 as antagonists. As a complimentary approach we used ChIP-seq on four of these factors to identify NEUROD1, LMX1A, PAX6 and RFX6 binding sites in the human genome. Examining the overlap between genes perturbed in the KD-CAGE experiments and genes with a ChIP-seq peak within 1kb of their promoter, we identified direct transcriptional targets of these TFs. Integration of KD-CAGE and ChIP-seq data shows that both NEUROD1 and LMX1A work as the main transcriptional activators. In the core TRN (i.e. TF-TF only), NEUROD1 directly transcriptionally activates the pancreatic TFs HSF4, INSM1, MLXIPL, MYT1, NKX6-3, ONECUT2, PAX4, PROX1, RFX6, ST18, DACH1 and SHOX2, while LMX1A directly transcriptionally activates DACH1, SHOX2, PAX6 and PDX1. Analysis of these complementary datasets suggests the need for caution in interpreting ChIP-seq datasets. 1. A large fraction of binding sites are at distal enhancer sites and cannot be directly associated to their targets, without chromatin conformation data. 2. Many peaks may be non-functional: even when there is a peak at a promoter, the expression of the gene may not be affected in the matching perturbation experiment.

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