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Any living organism contains a whole set of instructions encoded as genes on the DNA. This set of instructions contains all the needed 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.
In the nuclei, histones are assembled into octamers around which ~148bp of DNA are wrapped. 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 nuclei. However, this come at the cost of rendering the DNA sequence inaccessible to DNA readers, such as the transcriptional machinery 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 TF with a wide sequence specificity. Eventually, this allows the cell to recruit TFs at dedicated locations in the genome called regulatory elements (RE).
The action of TF at RE is crucial to gene expression. Indeed, TFs are involved in many processes such the opening of the chromatin structure or the recruitment of the transcriptional machinery. However if TFs can influence the chromatin structure, the reverse is also true as histones impede TFs binding on DNA. Thus the regulation of gene relies on a subtle and complex interaction between the chromatin and TFs.
To better understand how TF 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 TFs to bind together. The results suggest that regular nucleosome arrays are found near all TFs. It also points out two special cases. When CTCF binds with the cohesin complex, they seem to drive the nucleosome organization, which is a unique feature among all TFs investigates. Additionally I present evidences suggesting that EBF1 is a pioneer factor - a special class of TFs able to bind nucleosome.
Second, I developed several unsupervised 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.
Third, I participated to the assessment 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 remaining as specific and sensitive as its competitors.