Chemotaxis

Summary

Chemotaxis (from chemo- + taxis) is the movement of an organism or entity in response to a chemical stimulus. Somatic cells, bacteria, and other single-cell or multicellular organisms direct their movements according to certain chemicals in their environment. This is important for bacteria to find food (e.g., glucose) by swimming toward the highest concentration of food molecules, or to flee from poisons (e.g., phenol). In multicellular organisms, chemotaxis is critical to early development (e.g., movement of sperm towards the egg during fertilization) and development (e.g., migration of neurons or lymphocytes) as well as in normal function and health (e.g., migration of leukocytes during injury or infection). In addition, it has been recognized that mechanisms that allow chemotaxis in animals can be subverted during cancer metastasis. The aberrant chemotaxis of leukocytes and lymphocytes also contribute to inflammatory diseases such as atherosclerosis, asthma, and arthritis. Sub-cell

Official source

https://en.wikipedia.org/wiki/Chemotaxis

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Engineering biosensors that sensitively recognize specific biomolecules and trigger functional cellular responses is a holy grail of diagnostics and synthetic cell biology. Biosensor design approaches have mostly focused on binding structurally well-defined molecules. Coupling the sensing of flexible compounds to complex cellular responses would considerably expand biosensor applications, but remains challenging. We developed a computational strategy for designing highly sensitive receptor biosensors of flexible peptides. Using the method, we created ultrasensitive chemotactic GPCR:peptide pairs capable of eliciting potent chemotaxis in human primary T cells. Through mutual induced fit, our flexible structure design approach enhanced peptide contacts with binding and allosteric sites in the ligand pocket to achieve unprecedented signaling efficacy and potency. The approach paves the road for designing peptide-sensing receptors and expanding the biosensor toolbox for basic and therapeutic applications.

bioRxiv2022

Three-dimensional chemotaxis-driven aggregation of tumor cells

Alessandro De Simone, Andrea Gamba

One of the most important steps in tumor progression involves the transformation from a differentiated epithelial phenotype to an aggressive, highly motile phenotype, where tumor cells invade neighboring tissues. Invasion can occur either by isolated mesenchymal cells or by aggregates that migrate collectively and do not lose completely the epithelial phenotype. Here, we show that, in a three-dimensional cancer cell culture, collective migration of cells eventually leads to aggregation in large clusters. We present quantitative measurements of cluster velocity, coalescence rates, and proliferation rates. These results cannot be explained in terms of random aggregation. Instead, a model of chemotaxis-driven aggregation - mediated by a diffusible attractant - is able to capture several quantitative aspects of our results. Experimental assays of chemotaxis towards culture conditioned media confirm this hypothesis. Theoretical and numerical results further suggest an important role for chemotactic-driven aggregation in spreading and survival of tumor cells.

Nature Publishing Group2015

Dendritic cells (DCs) are crucial for the onset of adaptive immunity. Their outstanding migratory capacities in combination with their antigen presenting properties make them perfectly suited to pick up antigens in the periphery and transport them to the lymph nodes, where antigen presentation to T-cells is most efficient [1]. Their migration from the periphery to the lymph nodes, called DCs cell homing, is involved in both mounting effective adaptive immune responses as well as maintaining tolerance to self-antigens [2]. Both of them need to be balanced to maintain a healthy organism. So far two alternative mechanisms have been proposed to guide DCs from the interstitium through the extracellular matrix to the proximal lymphatic vessel [3]. One of these mechanisms is based on paracrine chemotaxis towards a CCL21 gradient created by the proximal lymphatic vessel. The second mechanism, called autologous chemotaxis, describes how cells can follow an autocrine gradient, created by the biasing of self-secreted chemokine by interstitial flow [4, 5]. To answer the question of how these two mechanisms contribute to DC homing, a quantitative understanding of how cells respond to gradients and interstitial flow present in their physiological microenvironment is needed [6]. To date, appropriate tools to study DC migration under defined gradients and in the presence of tunable interstitial flow rates in a 3D environment have been lacking. Within this thesis, we present two micro-scale devices that allow live cell observation on an inverted microscope. The first was optimized to expose cells to a steady-state chemokine gradient within a 3D microenvironment and is based on a microfluidic agarose scaffold which functions as a gradient buffer (Chapter 3). The novelty of a gradient buffer allows us to quickly establish stable gradients, which is an important feature in order to create stable and precisely defined gradients during tracking of fast-moving cells like DCs. We then performed an in-depth study of DC cell chemotactic responses towards the CCR7 ligands (CCL19 and CCL21) in 3D using this new agarose chamber (Chapter 4). With the help of an integrated computational model, we could precisely predict the gradient formation of matrix-bound CCL21 versus soluble CCL19 in the microcellular environment and found that DC answer differently to the two chemokines in response to gradient steepness. Furthermore, CCL21 was more chemoattractive than CCL19 when cells were exposed to competing gradients of both chemokines, and this was independent of the CCL21-binding properties. This represents the first quantitative study of CCR7-mediated DC chemotaxis in 3D in response to well-defined ligand gradients. The second device we developed for studying the effects of the physiological flow environment, which cells experience in capillary-fed tissues, on cell migration [6]. A 2-gel strategy allowed us to flexibly fine tune interstitial flow velocities and to precisely determine the actual flow rate for each position imaged on a microscope. We exposed DCs to a wide range of flow rates and observed an increase in persistence under flow compared to static (Chapter 6). In conclusion, this work presents quantitative insights into DC migration within precisely controlled 3D-microenvironments using new devices. It also highlights the role of a quantitative understanding of biological processes to distinguish between chemotactic mechanisms of DC cells.

EPFL2010