Chromosomal translocation | EPFL Graph Search

In genetics, chromosome translocation is a phenomenon that results in unusual rearrangement of chromosomes. This includes balanced and unbalanced translocation, with two main types: reciprocal, and Robertsonian translocation. Reciprocal translocation is a chromosome abnormality caused by exchange of parts between non-homologous chromosomes. Two detached fragments of two different chromosomes are switched. Robertsonian translocation occurs when two non-homologous chromosomes get attached, meaning that given two healthy pairs of chromosomes, one of each pair "sticks" and blends together homogeneously. A gene fusion may be created when the translocation joins two otherwise-separated genes. It is detected on cytogenetics or a karyotype of affected cells. Translocations can be balanced (in an even exchange of material with no genetic information extra or missing, and ideally full functionality) or unbalanced (where the exchange of chromosome material is unequal resulting in extra or miss

Force Transmission in Migrating Cells

Maxime Fred Maurice Fournier

Ability to migrate is a fundamental property of all animal cells. Cell migration underlies such important physiological and pathological processes as embryonic development, immune response, tissue regeneration and cancer metastasis. As cell migration involves forces and motion, it is ultimately a physical phenomenon that should be understood in terms of fundamental physical laws. Cell migration mechanisms are based on the activity of the cytoskeleton, a system of intracellular filaments and motor proteins. During cell migration, forces developed by the cytoskeleton are transmitted, through specific adhesions complexes, to the substrate. Composition and dynamics of the cytoskeleton has been subject of many studies, but it remains poorly understood how the cytoskeleton reactions and its interaction with extra cellular matrix are orchestrated to result in coordinated migration behavior. The main part of this thesis consists of the experiments and analysis of force transmission during cell migration in the experimental system of fish epidermal keratocytes. Our experimental approaches involved microinjection for proteins dynamics quantification, micromanipulation, use of compliant substrate, simultaneous imaging of cytoskeleton and substrate deformation, and the use of cytoskeletal inhibitors. In parallel with the experiments, significant computational work has been performed to program and adapt existing algorithms to analyze experimental data. Thanks to the combination of our experimental and computational approaches, we were able to correlate actin dynamics and traction forces over the whole cell, to map the efficiency of force transmission, and to reveal slipping and gripping mechanisms differentially involved in stress transmission in different parts of the cell. We also investigated contributions of actin assembly and myosin-dependent contractility to force generation and provided evidence that cell translocation could be powered by two different engines. Additionally, we performed micromanipulation experiments to identify the cell polarity cues associated with specific cytoskelatal reactions and regions of the cell. We have also collaborated with the laboratory of one of the leading modellers in the field of cell biophysics to validate a new mathematical model of cell migration and force transmission.

EPFL2011

Comparative maps of motion and assembly of filamentous actin and myosin II in migrating cells

Sophie Bohnet, Jean-Jacques Meister, Sébastien Schaub

To understand the mechanism of cell migration, one needs to know how the parts of the motile machinery of the cell are assembled and how they move with respect to each other. Actin and myosin II are thought to be the major structural and force-generating components of this machinery (Mitchison and Cramer, 1996; Parent, 2004). The movement of myosin II along actin filaments is thought to generate contractile force contributing to cell translocation, but the relative motion of the two proteins has not been investigated. We use fluorescence speckle and conventional fluorescence microscopy, image analysis, and computer tracking techniques to generate comparative velocity and assembly maps of actin and myosin II over the entire cell in a simple model system of persistently migrating fish epidermal keratocytes. The results demonstrate contrasting polarized assembly patterns of the two components, indicate force generation at the lamellipodium-cell body transition zone, and suggest a mechanism of anisotropic network contraction via sliding of myosin II assemblies along divergent actin filaments.

American Society for Cell Biology2007

Dynamics of actin and myosin II during cell polarization and directional locomotion

Sophie Bohnet

Crawling cell motility is characteristic of most animal cells and is involved in many important biological processes such as embryogenesis, immune response, and wound healing. It involves several steps: protrusion (dynamic surface extension) at the front of the cell, attachment to the substratum, and forward translocation of the cell body accompanied by the detachment and retraction of the rear portion of the cell. Crawling motion is believed to be based on actin, a major component of the cytoskeleton, and myosin II, a motor protein that is believed to produce contraction force by moving along actin filaments. Actin and myosin II are the two major structural and force-generating components of the cell's motile machinery. Protrusion is thought to be driven by the assembly of a dense actin network that is attached to the substrate through integrin-containing adhesions. Previous studies estimated the forces generated by actin polymerization and the adhesion forces, but the net force developed by the protruding leading edge has not been yet determined. The forward translocation of the cell body is believed to depend on the interaction of myosin with the actin network, but the exact mechanisms behind this interaction are still unclear. Moreover, it is still poorly understood how the molecular reactions involved in each step of the crawling motion are coordinated to result in the integrated cellular response. In this thesis work, we have quantitatively characterized the assembly and motion of actin and myosin II in the stationary and migratory states of the cell, and during the transition between these two steady-states. We have also measured the force developed by the protruding leading edge. The experimental system used is the fish epidermal keratocytes, one of the most spectacular models of cell locomotion. These cells are characterized by fast and persistent migration, and a stable and simple cytoskeletal organization. Enhanced phase contrast, interference reflection, classical fluorescence and fluorescent speckles microscopy were used as imaging techniques along with computer-based tracking approaches. We have first studied actin movement and assembly in the lamellipodium of keratocyte (thin, sheet-like extension at the leading edge of the cell). Actin dynamics in the lamellipodia of many cell types are characterized by retrograde flow of the actin network away from the leading edge. This flow is believed to result from membrane resistance to actin assembly and contractile forces in the network, and was speculated to play a role in controlling the cell shape and motion. Retrograde flow was previously observed in every crawling cell with the exception of keratocytes. We have for the first time detected actin retrograde flow throughout the keratocyte lamellipodium at velocities of 1–3 µm/min and analyzed its organization and relation to the cell motion during both unobstructed persistent migration and events of cell collision. We have found that freely moving cells exhibited a graded flow velocity increasing toward the sides of the lamellipodium, whereas in colliding cells, the velocity decreased markedly at the site of collision, with striking alteration of the flow in other lamellipodial regions. Our findings support the universality of the flow phenomenon and indicate that maintenance of the keratocyte shape during locomotion depends on the regulation of retrograde flow and actin polymerization. We have subsequently quantitatively characterized the assembly and movement of actin and myosin II throughout the entire keratocyte. Actin exhibited a slow backward motion in the lamellipodium and a faster forward motion in the trailing cell body. The change of direction occurred along the line parallel to the leading edge of the cell just in front of the front boundary of the cell body. Myosin II also moved forward in the cell body, but no motion with respect to the substratum was detected in the lamellipodium. At the cell sides, actin and myosin II exhibited motion towards the cell center with velocities increasing with the distance from the center. Net assembly of actin occurred locally at the leading edge of the lamellipodium, and disassembly at the back of the lamellipodium. Myosin II assembled in a distributed manner in the lamellipodium and disassembled in the cell body. Eventually, a simultaneous tracking of actin and myosin II revealed that myosin II moved forward relatively to actin throughout the cell. Taken together, these results suggest a longitudinal and transverse contraction along the lamellipodium/cell body junction. To understand how the polarized patterns of the organization of actin/myosin machinery were first established, we have studied in the next part of the work random cell polarization, i.e. the spontaneous transition between the stationary and the migratory state of a cell in the absence of external directional stimuli. Cell polarization and directional locomotion are believed to involve asymmetry in actin assembly, contractility, and substrate adhesion. We have analyzed the distribution and dynamics of actin and myosin II and the dynamics of substrate adhesions during cell polarization. In the stationary state, the cells exhibited lamellipodia with a uniform rate of actin retrograde flow all around the cell perimeter. Upon initiation of directional movement, retrograde flow accelerated at the prospective rear of the cell, but the lamellipodia initially persisted all around the perimeter. The assembly of actin network also continued all around the cell. Local areas of detachment from the substrate were observed at the base of rear lamellipodia. Treatment with myosin inhibitor blebbistatin nearly completely blocked the polarization. Depolymerization of microtubules with nocodazole resulted in attenuated polarization. Taken together, these results suggest that initial polarization results from asymmetry in actin retrograde flow, which is induced by myosin-dependent contraction and stabilized by microtubules. Finally, we have estimated the force necessary to stall the protruding leading edge of the keratocytes. We arrested the leading edge of a moving cell with a hydrodynamic load generated by a fluid flow from a micropipette. The flow arrested the protrusion locally, as the cell approached the pipette, causing an arc-shaped indentation and upward folding of the leading edge. Modeling of the fluid flow gave a surprisingly low value for the arresting force of just a few piconewtons per micrometer. This small force did not abolish actin polymerization nor disrupt the adhesions formed before the arrest, but rather interfered with the weak nascent adhesions at the very front of the cell. We conclude that a weak external force is sufficient to reorient the growing actin network at the leading edge and to stall the cell protrusion. Our study of the dynamics of actin and myosin II in polarizing and migrating cells provides novel and important insights into the cell motility mechanism and establishes a fundamental quantitative data set necessary to test and improve theoretical models of cell motility.

EPFL2006