Atomic Force Microscopy of Biological Systems: Quantitative Imaging and Nanomotion Detection

Petar Stupar
EPFL, 2018
Thèse EPFL

Résumé

The core of this thesis is the application of different modalities of atomic force microscopy to study living systems. After a brief introduction, quantitative imaging state of the art is presented and the applications for mammalian, plant, bacterial, and yeast cells are reviewed. The same chapter contains research effort about exploring nanomechanical properties of bone cells exposed to conditions that simulate the ones in outer space, in order to investigate the changes in architectural rearrangements of cells during space flight. The next section takes the focus on probing bacterial adhesion sites with an antibody-modified tip, a research important for the understanding of how bacterial cells adhere to the host and establish an infection. Plant cells and their nanomechanical profiles are also covered in the chapter. A large portion of the thesis consists in development of a new nanomechanical sensing technique, and the exploration of its potential applications. The technique is based on the AFM detection method and focuses on transducing small fluctuations that define living systems into a measurable mechanical change in the cantilever. The fact that there is a disproportionate rise in antimicrobial-resistant bacteria and that our lives depend on the new drugs and diagnostic tools to fight them has fueled the first and largest application of the technique â rapid antimicrobial susceptibility resting. Chapter 3 starts with the introduction of the technique, basic principles and guidelines for its use, and continues on potential applications. Proof of principle of the technique is presented, showing experimental results using blind clinical samples of bloodstream infectious agents. A separate section is devoted to investigations concerning slow-growing bacteria and the application of the technique to rapidly determine which antibiotic would best work against them. It then expands on the applications towards detecting metabolic activity of mitochondria and their response to substrates and inhibition. Furthermore, the method has been described as a rapid anti-cancer profiling tool that might pave the way towards a diagnostic platform for personalized medical treatment. The final section of the third chapter contains the current knowledge of the origins of oscillatory movement that governs the nanomotion technique. It presents different hypothesis and results towards exploring them. The thesis ends with a summary of the main ideas and conclusions about the presented work and future perspectives.

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https://infoscience.epfl.ch/record/254877?ln=fr

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Petar Stupar
EPFL, 2018
Thèse EPFL

Résumé

Official source

https://infoscience.epfl.ch/record/254877?ln=fr

À propos de ce résultat

Concepts associés (20)

Concepts associés

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Publications associées (26)

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Bacterial adhesion is the first and a significant step in establishing infection. This adhesion normally occurs in the presence of flow of fluids. Therefore, bacterial adhesins must be able to provide high strength interactions with their target surface in order to maintain the adhered bacteria under hydromechanical stressing conditions. In the case of B. pertussis, a Gram-negative bacterium responsible for pertussis, a highly contagious human respiratory tract infection, an important protein participating in the adhesion process is a 220 kDa adhesin named filamentous haemagglutinin (FHA), an outer membrane and also secreted protein that contains recognition domains to adhere to ciliated respiratory epithelial cells and macrophages. In this work, we obtained information on the cell-surface localization and distribution of the B. pertussis adhesin FHA using an antibody-functionalized AFM tip. Through the analysis of specific molecular recognition events we built a map of the spatial distribution of the adhesin which revealed a non-homogeneous pattern. Moreover, our experiments showed a force induced reorganization of the adhesin on the surface of the cells, which could explain a reinforced adhesive response under external forces. This single-molecule information contributes to the understanding of basic molecular mechanisms used by bacterial pathogens to cause infectious disease and to gain insights into the structural features by which adhesins can act as force sensors under mechanical shear conditions.

Royal Society of Chemistry2015

Chargement

Mycobacterium tuberculosis, the etiological agent for the tuberculosis disease, is a bacterial pathogen thought to infect about a quarter of the global human population. It is the first cause of death among infectious diseases, and is most prevalent in low-income populations. Much remains unknown about how these bacteria grow, divide, and manage to persist in the host even during month-long antibiotic treatments. Bacteria are typically at the edge of the spatial resolution that conventional optical microscopy techniques can offer, and so new tools are required to study bacterial substructures or surface morphologies with nanometer resolution. We developed a platform for automated optical microscopy and atomic force microscopy (AFM) in order to study the morphogenesis of mycobacteria. What is the growth dynamics of mycobacteria? Opposite models coexist in the literature for the pole growth dynamics of mycobacteria: the unipolar model and the bipolar model. We show that the growth dynamics of mycobacteria follows a new end take off NETO model. There is a surprising similarity between the NETO growth dynamics of mycobacteria and of fission yeast, which hints at shared mechanisms for pole growth in evolutionarily distant pole growing organisms. How do pole-growing organisms maintain their shape through insertion of new cell wall material at the tip? To explore further pole growth morphogenesis, we developed a method for imaging with AFM the pole of a growing rod-shaped microorganism. We observed the formation of a stiff fibril mesh on the pole of fission yeast cells, and showed that this mesh is stretched as the cell grows and insert new cell wall material at the tip. How do mycobacteria divide into two sibling cells? Another essential aspect of morphogenesis of rod-shaped cell is the division of a mother cell into two sibling cells. Using AFM, we measured the relative contributions of mechanical forces and molecular mechanisms driving the division process in mycobacteria. We showed that there is a concentration of mechanical stress at the future division site, using a combination of COMSOL finite element modeling and AFM measurements while controlling the cell turgor pressure. The accumulation of mechanical stress, in combination of enzymatic activity, ultimately leads to mechanical fracture and separation of the sibling bacteria. Conventional optical microscopy techniques tend to have low resolution and high speed, while conventional AFMs have comparatively high resolution and low speed. We designed and built a 3D-printed structured illumination (SIM) module, the openSIM, as an add-on for fluorescence microscopes. It provides structured illumination to obtain SIM images with higher resolution. With the aim of improving the imaging speed of AFM, we implemented photothermal actuation in a tip-scanning AFM head, and quantified the design constraints for high-speed photothermal off-resonance tapping imaging. AFM is most often used to scan and acquire high-resolution images of a sample. Its nanometer precision make it a unique tool for other applications. We combined an AFM head with a volcano-shaped probe for electrogram measurements, and demonstrated simultaneous recording of extracellular field potentials and contraction of the cell. This new tool opens the way for future studies exploring the intriguing links between mechanobiology and electrophysiology, with single-cell resolution.

EPFL2020

Chargement

Investigation of Biophysical Properties of Biomolecules by Means of Atomic Force Microscopy

Jae Sun Jeong

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

Investigation of Biophysical Properties of Biomolecules by Means of Atomic Force Microscopy

Jae Sun Jeong

EPFL2012

EPFL2020