Integrated microfluidic tools for the characterization of protein/DNA interactions in vitro and in vivo

The specific interaction between DNA and proteins constitutes one of the crucial elements in the regulation of gene expression. This thesis focuses on the development and optimization of two microfluidic-based technologies called SMiLE-seq and FloChIP that enable the sensitive and high-throughput analysis of two important aspects of protein/DNA interactions: respectively, 1) the transcription factor DNA-binding specificities and 2) the genome-wide distribution of chromatin-associated proteins.

In Chapter 1, we describe the core motivation, operating principles, optimization and results obtained with SMiLE-seq. As opposed to existing solutions, SMiLE-seq offers the possibility to screen a large library of randomized DNA for sequence-specific protein ligands in a miniaturized context. SMiLE-seq integrates in a single microfluidic chip the advantages of both HT-SELEX and MITOMI. We first demonstrate as proof-of-principle that SMiLE-seq successfully recapitulates with robustness and reproducibility the binding specificities of known factors belonging to different species and TF families. Subsequently, we target the numerous although largely uncharacterized family of TFs called KRAB-ZFPs. We initially set out to redesign the microfluidic and protocol architecture in order to attain maximal throughput and sensitivity. Next, we add the ability of probing the sensitivity of these factors to methylation by synthesizing randomized methylated DNA libraries. Finally, we proceed to test 101 KRAB-ZFPs with both methylated and non-methylated DNA. We obtain high confidence motifs for 43 factors, of which 22 we not sensitive to methylation, 10 yielded motifs only with methylated DNA and 10 only with non-methylated DNA. By integrating our SMiLE-seq data with published ChIP-exo data and in silico predictions, we develop a framework for systematically identifying which zinc fingers directly contribute to DNA binding for a given KRAB-ZFPs.

In Chapter 2, we describe the development and results obtained with FloChIP, a microfluidic implementation of the widespread ChIP-seq and sequential ChIP-seq protocols. FloChIP encompasses three main technological advances: 1) the multi-layered serface chemistry that allows any off-the-shelf antibody to be immobilized on-chip and and 2) a micropillar architecture that provides high surface-to-volume ratio and efficient removal of non-specific DNA. 3) The direct on-chip tagmentation of immunoprecipitated DNA. We validate our approach by first performing H3k27ac ChIP-seq on different number of sample inputs, i.e. from 500 to 10^6 cells. Next, we proceed to prove the flexibility of our approach by performing ChIP-seq on different histone marks â namely H3k27ac, H3k27me3, H3k4me3, H3k4me1 and H3k9me3 â and comparing them to existing ENCODE data. Both region-specific profiles and enrichment scores show high similarity with publicly available data. Subsequently, we set out to demonstrate the feasibility of on-chip sequential-ChIP-seq by performing consecutive H3k4me3 and H3k27me3 IP on chromatin derived from mouse embryonic stem cells. Finally, we illustrate the high-throughput feature of our technology by performing MEF2A-ChIP-seq on chromatin derived from 32 different lymphoblastoid cell lines.

The role of OCT4 and SOX2 in regulating chromatin accessibility and cell fate across the cell cycle in embryonic stem cells

Torgil Elias Friman

Precise spatiotemporal regulation of gene expression is essential for development and homeostasis of complex organisms. This is achieved in large part by sequence-specific transcription factors (TF) that bind to genomic regulatory elements to activate or repress transcription. DNA in eukaryotic nuclei is wrapped around histones into nucleosomes, which are inaccessible to most proteins. However, certain TFs can access their binding sites in the presence of histones and promote nucleosome eviction to increase chromatin accessibility, allowing for binding of other protein. These TFs, called pioneer factors, include OCT4 and SOX2, which are master regulators of embryonic stem (ES) cells. Dividing cells, including stem cells, must achieve proper gene regulation despite the progression of the cell cycle, which imposes several constraints. During S phase, the replication fork passes through the genome to make a copy of each chromosome, which leads to a loss of chromatin accessibility. Furthermore, the substantial chromatin compaction that occurs during mitosis to prepare for chromosome segregation is associated with eviction of most DNA-binding proteins and reduced accessibility at distal cis-regulatory elements including enhancers. How pioneer factors operate in the context of cell cycle progression is unclear. In this thesis, I will present work studying different features of OCT4 and SOX2, including how they interplay to regulate chromatin accessibility in ES cells, the impact of small endogenous fluctuations of their protein levels on cell fate and chromatin accessibility, and how their roles in regulating cell fate and chromatin accessibility is related to different stages of the cell cycle. Using live-cell imaging of fluorescently labeled proteins, we discovered that OCT4 and SOX2 were associated to mitotic chromatin. Using cell-cycle specific degradation strategies, we could show that the presence of SOX2 and OCT4 at the mitosis-G1 (M-G1) transition contributes to maintain the pluripotency of ES cells. We further showed that ES cells with high levels of OCT4 in G1, but not in S phase, are more prone to differentiate towards neuroectoderm and mesendoderm cell fates. Cells with high levels of OCT4 displayed increased chromatin accessibility at enhancers of differentiation genes, suggesting accessibility fluctuates with OCT4 levels and can prime cells for differentiation. To explore potential cell cycle-dependent regulation of chromatin accessibility, we degraded OCT4 at the M-G1 transition, which led to a reduction in accessibility at many OCT4-bound regions. When OCT4 returned later in the cell cycle, chromatin accessibility was recovered, although at many loci this recovery was incomplete, suggesting that OCT4 is required at the M-G1 transition to maintain these regions open. We then rapidly degraded OCT4 at other phases of the cell cycle. Surprisingly, loss of chromatin accessibility was highly similar at all cell cycle phases, showing that OCT4 is constantly required to maintain regulatory elements accessible. To explore the dynamic regulation of accessibility by OCT4, we performed time-course measurements of accessibility upon its degradation. This revealed that loss of accessibility was temporally correlated to the degradation of OCT4. These results suggest that chromatin accessibility is highly dynamic and continuously dependent on the presence of OCT4 across the cell cycle in ES cells.

EPFL2019

Computational study of transcription factor binding sites

Romain Fernand Pietro Groux

Any living organism contains a whole set of instructions encoded as genes on the DNA. This set of instructions contains all the necessary information that the organism will ever need, from its development to a mature individual to environment specific responses. Since all these instructions are not needed at the same time, the gene expression needs to be regulated. Eukaryotic genomes are stored inside nuclei as chromatin. The chromatin is the association of DNA with dedicated storage proteins - the histones - and the necessary machinery to regulate and express genes (RNA polymerases or RNAPs). In the nuclei, histones are assembled into octamers around which are wrapped ~148bp of DNA. This structure is known as the nucleosome. The repetition of nucleosomes along the genome allows to drastically compact the genome, eventually allowing to fit it inside the nucleus. However, this comes at the cost of rendering the DNA sequence inaccessible to DNA readers, such as the RNAPs and transcription factors (TFs). TFs are a class of proteins that have the remarkable property of recognizing and binding specific DNA sequences. More striking, each TF can recognize a multitude of different - but similar - DNA sequences providing TFs with a wide sequence specificity range. Eventually, this allows the cell to recruit TFs at dedicated locations in the genome called regulatory elements (REs). The action of TFs at REs is crucial to gene expression. Indeed, TFs are involved in many processes such as the opening of the chromatin structure or the recruitment of RNAPs. However if TFs can influence the chromatin structure, the opposite is also true as histones impede TF binding on DNA. Thus the regulation of genes relies on a subtle and complex crosstalk between the chromatin and TFs. To better understand how TFs and chromatin interact together to regulate gene expression, I lead several projects prospecting TF binding specificity and the chromatin structure at REs in human. First, I used ENCODE next generation sequencing (NGS) data to explore how TF binding influences the nearby nucleosome organization and the propensity of some TFs to bind together. The results suggest that regular nucleosome arrays are found near all TFs. They also point out two special cases. When CTCF binds with the cohesin complex, it seems to drive the nucleosome organization, which is a unique feature among all TFs investigated. Additionally I present evidence supporting that EBF1 is a pioneer factor - a special class of TFs able to bind nucleosome. Secondly, I developed several clustering algorithms and software to partition genomic regions according to NGS data and/or on their DNA sequences. These methods allow to discover important trends, for instance different nucleosome architectures . I illustrated the usefulness of these methods for the study of chromatin accessibility data and the identification of REs. Thirdly, I participated to the assessment of SMiLE-seq, a new microfluidic device that generates TF specificity data. The creation of TF specificity models and their comparison with other publicly available models demonstrated the value of SMiLE-seq to study TF specificity. Finally, I participated in the development of a software that predicts TF binding sites. A careful benchmarking suggested that this software is - at the time of writing - the best available software in terms of speed while showing other performances similar to its competitors.

EPFL2020

Exploring on Protein-DNA interactions

Alexandra Styliani Kalantzi

A variety of DNA-binding proteins organizes the chromosomal DNA and regulates gene transcription, and DNA replication and recombination. In particular, for gene regulation there is a category of DNA-binding proteins, the transcription factors, which can detect and bind to a specific set of DNA motifs. For the protein-DNA complexes there are some solved structures, but for some cases, it is difficult to define experimentally these structures at the atomistic level. However, there are various in silico methods, that alone or in combination with experimental techniques, are capable of predicting proteins structures with high accuracy. DNA-binding proteins contain DNA-binding domains and unfortunately, there are few protein-DNA complexes that have been characterized at atomistic resolution. Here we have developed artificial neural networks to predict the binding sites and the interface between proteins and the DNA, based on a structure-based approach. Specifically, we used different interface descriptors and we included a variety of protein-DNA complexes, in order to predict the correct localizations of the DNA on a protein. A large group of proteins that can recognize specific DNA sequences is the KRAB-ZFP family. DNA recognition by zinc finger proteins (ZFPs) plays an important role in gene regulation. However, the molecular determinants defining the recognition of specific DNA nucleotides by ZFP finger repeats has not yet been decoded. Here, we present a method that can predict which ZF repeats specifically bind to a DNA target sequence and what is the most probable DNA target sequence for these repeats. Our method is based on the structural analysis of the binding network of resolved protein DNA complexes, and is validated on a benchmark set of solved ZFP-DNA complexes. We also characterized the binding specificity of two KRAB-ZFPs (ZFP14 and ZNF145) integrating our predictions with SMiLE-seq (Selective Microfluidics-based Ligand Enrichment followed by sequencing) data. Subsequently, we use our recognition code on ChIP-exo data, in order to give an insight into the poly-ZF domains binding patterns. We determined the most probable binding motifs and we separated the ZFPs in two groups: the ones that have a potential canonical and non-canonical binding. Altogether, this work gives an insight into the proteins that interact with the DNA, through a better understanding of the various protein-DNA interfaces and the predictions of these complexes at the atomistic level.

EPFL2019

Exploring on Protein-DNA interactions

Alexandra Styliani Kalantzi

EPFL2019

The role of OCT4 and SOX2 in regulating chromatin accessibility and cell fate across the cell cycle in embryonic stem cells

Torgil Elias Friman

EPFL2019

Computational study of transcription factor binding sites

Romain Fernand Pietro Groux

EPFL2020