From polymers to gene regulation

Aleksandre Japaridze
EPFL, 2015
Thèse EPFL

Résumé

DNA molecule is the fundamental component of every living organism, since it encodes the hereditary information. Although the genetic code of almost 200 species has been sequenced, the direct connection between gene sequence, DNA structure and biological function remains poorly understood. The aim of this thesis was to investigate the connection between DNA function and structure. Throughout the thesis we will discuss experiments testing the link between different physical properties of DNA with its biological function. For this purpose we used atomic force microscopy (AFM), a high resolution imaging technique. The first chapter is devoted to explain the basic concepts of AFM technique, as well as the composition and structure of DNA molecules. We also describe some of the polymer physics models of DNA, defining basic quantities like the persistence and the critical exponent. In chapter 2 we discuss experiments, in which we studied changes in the physical properties of DNA molecules, when bound to the substrate surface with various methods. We show that, when DNA is strongly bound to the surface, it retains its physiological B-form. On contrary, when weakly bound, a conformational B-to-A-form transition takes place. We also discuss a novel experimental method, combining nanometer sized PDMS slits with AFM, for studying DNA in geometrical confinement. When DNA is weakly confined, DNA persistence length increases, molecules elongate and adopt more anisotropic shapes. Under stronger confinement, DNA hairpins form. In chapter 3 we study binding of staining dyes, proteins and RNA polymerase (RNAP) to DNA molecules. First we show that DNA physical properties are significantly affected when stained with dyes. Depending on the dye binding mode, either the contour length, or the persistence length or both simultaneously change. We move further and investigate the role of protein amino acids and DNA sequence in the formation of nucleoprotein complexes. On the example of EspR protein, a key virulence regulator in Mycobacterium tuberculosis (MTB), we show that single amino acid mutations, lead to lower DNA binding affinity. These mutations also impair the formation of higher order protein-DNA complexes, silencing the MTB virulence. Afterwards, on the examples of RNAP and H-NS protein, we show the importance of DNA sequence for the binding and higher order oligomerization. By introducing DNA mutations disrupting the helical phasing between RNAP binding sites in the fis promoter sequence, we significantly lower the RNAP binding affinity. The helical phasing of the binding sites somehow coordinates the cooperative binding of RNAP to the promoter. Finally on the model of H-NS protein, we show how different spatial arrangements of strong binding sites for an architectural protein in the DNA, determine the final 3D structure of the assembled nucleoprotein complex. The final chapter, is fully devoted to the study of a completely new type of DNA organisation, which we call Hyperplectonemes. Hyperplectonemes are very ordered DNA structures, formed by large supercoiled molecules, in the presence of attractive DNA-DNA potential. First, we describe their structure and its dependence on various environmental factors, than their binding to nucleoid associated proteins. We argue that this emerging DNA organisation is the basic structure of the bacterial chromatin, which is further modulated by numerous DNA binding and condensing proteins in vivo.

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https://infoscience.epfl.ch/record/213530?ln=fr

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Aleksandre Japaridze
EPFL, 2015
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/213530?ln=fr

À propos de ce résultat

Concepts associés (34)

Concepts associés

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Publications associées (125)

Publications associées

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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

Chargement

Biomolecules are the building blocks of living organisms and perform the most important functions in a biological process. The aim of biophysics is to understand the biological functions of biomolecules in terms of their structure: structure and function of biomolecules has been an active research for several decades. Despite the evolution and emergence of new investigation techniques during the last 60 years, biological processes still present enormous challenges to our understanding due to the complex biological system spanning a wide range of spatial and temporal scales. An ideal biophysical method should have the capability to observe atomic level structures and dynamics of biological molecules in their physiological environment. It would also permit the visualization of the structures that form throughout the course of conformational changes or chemical reactions, regardless of the time scale. In this thesis, we have investigated two representative biomolecules using the well-defined biophysical methods in terms of behaviour and biophysical properties of biomolecules: Deoxyribonucleic acid (DNA) and the Amyloid-β (Aβ) peptide. Many different biophysical and biochemical tools were employed, where atomic force microscopy (AFM) was the primary instrument to observe the behaviour of the biomolecules in physiological conditions as well as the dynamic changes of structure of biomolecules. Moreover, AFM was used to measure the mechanical properties of biomolecules via direct and indirect methods. What is the behaviour of DNA molecules in an electric field? The behaviour of DNA molecules in an electric field is crucial for understanding interactions of DNA with electrically charged membrane that serves as a template for DNA based sensors and microarray applications, particularly under an electric field. Taken together, the ability to deposit a single DNA molecule on the electrode is essential to increase its specificity. To achieve this, we optimized the operational conditions in order to control a single DNA molecule adsorbing at +300 mV of potential and desorbing to/from the electrode at -25 mV of potential. Simultaneously dynamic imaging enabled us to analyse its morphological behaviour using real-time Electrochemical AFM (EC-AFM) in aqueous conditions. What is the molecular mechanism underlying Aβ42-fibrillogenesis and its role in pathogenesis? The molecular mechanism underlying Aβ42-fibrillogenesis is essential for defining the key determinant in the pathogenesis of Alzheimer’s disease. In this thesis, we carried out detailed biophysical studies to elucidate the structural changes associated with different stages of amyloid formation and provided unique perspectives on the molecular and structural basis underling the polymorphism of amyloid fibrils in Alzheimer’s disease. For the first time, we provided direct evidence of the existence of secondary-nucleation sites on the surfaces of Aβ42-fibrils and demonstrated that Aβ42-monomers play a crucial role in determining the structural properties and heterogeneity of the formed fibrils. In addition, real-time observation with in situ AFM was performed to define the mechanisms underlying oligomerization and the formation of protofibrils of Aβ42 in physiological conditions. Investigation of the elastic property of Aβ42 fibrils using two techniques based on the AFM. The self-assembly process of Aβ peptides into highly ordered amyloid fibrils is a crucial phenomenon in the cascade of pathological events that culminates in Alzheimer’s disease. Further, the assessment of the elastic properties of Aβ fibrils has recently attracted a lot of attention due to their potential biological applications. We measured the elastic property of Aβ42-fibrils immobilized on two types of substrate (positively charged mica and hydrophobic highly oriented pyrolytic graphite) and compared their properties using two techniques based on the AFM: Statistical analysis of thermal fluctuations and AFM based nanoindentation. The results from our studies show that the values of Young’s modulus of Aβ42 fibrils from the two substrates were similar (1.8 to 2.0 GPa), however they were different in the statistical analysis of thermal fluctuations (1.4 GPa, 2.3 GPa on mica and highly oriented pyrolytic graphite, respectively). These results imply that the method of thermal fluctuations was based on the shape of fibrils affected by the interaction force between the substrate and the fibrils.

EPFL2012

Chargement

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Fluorescent dyes are widely used for staining and visualization of DNA in optical microscopy based methods. Even though for some dyes the mechanism of binding is known, how this binding affects DNA remains poorly understood. Here we present a novel experimental study of the influence of staining dyes on DNA properties. We use atomic force microscopy which allows quantification and measurement of structural properties of stained DNA with nanometer resolution. We studied the influence of dyes on the persistence length, the total contour length, and the morphology of individual DNA molecules. We tested three widely used dyes known to differently bind DNA molecules, namely PicoGreen, Dapi, and DRAQ5. Based on our measurements, when imaged at typical concentrations (manufacturer suggested concentrations used for cell imaging), PicoGreen dye showed little effect, Dapi dye decreased the DNA persistence length, and DRAQ5 decreased the persistence length and elongated the DNA. When used at high concentrations, all of the dyes induced drastic changes in the DNA morphology. Our study clearly shows that DNA-binding dyes, irrespective of their DNA binding mechanisms, strongly influence the physical properties of DNA. These changes are strongly dose and dye type dependent and therefore should be taken into consideration when conducting experiments with DNA.

American Chemical Society2015

Chargement

Computational study of transcription factor binding sites

Romain Fernand Pietro Groux

EPFL2020

EPFL2012