The minimal chemotactic cell

The movement of cells and microorganisms in response to chemical gradients, chemotaxis, is fundamental to the evolution of myriad biological processes. In this work, we demonstrate that even the simplest cell-like structures are capable of chemotactic navigation. By encapsulating enzymes within lipid vesicles that incorporate a minimal number of membrane pores, we reveal that a solitary vesicle can actively propel itself toward an enzyme substrate gradient. Specifically, vesicles loaded with either glucose oxidase or urease and embedded with corresponding transmembrane proteins were tracked within a microfluidic device under a controlled substrate gradient. Our findings establish that a system comprising only an encapsulated enzyme and a single transmembrane pore is sufficient to initiate chemotaxis. This proof-of-concept model underscores the minimalistic yet powerful nature of cellular navigation mechanisms, providing a previously unknown perspective on the origins and evolution of chemotactic behavior in biological systems.

• Publication year

  2025

• Venue

  Science Advances

• Publication date

  2025-07-25

• Fields of study

  Biology, Medicine, Chemistry, Engineering

• Identifiers
  DOI 10.1126/sciadv.adx9364PMID 40712034PMCID 12292904
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar, PubMed

• No claims are published for this paper.

• No concepts are published for this paper.

• Interplay of phoresis and self-phoresis in active particles: Transport properties, phoretic, and self-phoretic coefficients.

  2024influential reference
• Convection Confounds Measurements of Osmophoresis for Lipid Vesicles in Solute Gradients.

  2023cited by this paper
• Atomization Characteristics of Hydrogen Peroxide Solutions in Electrostatic Field

  2022cited by this paper
• Diffusion of Glucose in Water: a Molecular Dynamics Study

  2021cited by this paper
• Diffusioosmotic and convective flows induced by a nonelectrolyte concentration gradient

  2020cited by this paper
• LipoBots: Using Liposomal Vesicles as Protective Shell of Urease‐Based Nanomotors

  2020cited by this paper
• Motility of Enzyme-Powered Vesicles

  2019cited by this paper
• An improved 96 well plate format lipid quantification assay for standardisation of experiments with extracellular vesicles

  2019cited by this paper
• Artificial photosynthetic cell producing energy for protein synthesis

  2019cited by this paper
• Positive and negative chemotaxis of enzyme-coated liposome motors

  2019cited by this paper
• Osmosis, from molecular insights to large-scale applications.

  2019cited by this paper
• The Role of Lipid Interactions in Simulations of the α-Hemolysin Ion-Channel-Forming Toxin.

  2018cited by this paper
• Preparation of asymmetric phospholipid vesicles for use as cell membrane models

  2018cited by this paper
• Liposomes and polymersomes: a comparative review towards cell mimicking.

  2018cited by this paper
• Migration of Deformable Vesicles Induced by Ionic Stimuli.

  2018cited by this paper
• Migration of blood cells and phospholipid vesicles induced by concentration gradients in microcavities.

  2018cited by this paper
• Phoresis and Enhanced Diffusion Compete in Enzyme Chemotaxis.

  2018cited by this paper
• Fundamental Aspects of Enzyme-Powered Micro- and Nanoswimmers.

  2018cited by this paper
• Measurement and mitigation of free convection in microfluidic gradient generators.

  2018cited by this paper
• Eppur si muove, and yet it moves: Patchy (phoretic) swimmers☆

  2017cited by this paper
• Migration of Phospholipid Vesicles Can Be Selectively Driven by Concentration Gradients of Metal Chloride Solutions.

  2017cited by this paper
• Artificial cell mimics as simplified models for the study of cell biology

  2017cited by this paper
• Phoretic Self-Propulsion

  2017cited by this paper
• Urea-Water-Solution Properties: Density, Viscosity, and Surface Tension in an Under-Saturated Solution

  2017cited by this paper
• Chemotactic synthetic vesicles: Design and applications in blood-brain barrier crossing

  2016cited by this paper
• Dissecting the self-assembly kinetics of multimeric pore-forming toxins

  2016cited by this paper
• Compartmentalization and Transport in Synthetic Vesicles

  2016cited by this paper
• Active Particles in Complex and Crowded Environments

  2016cited by this paper
• Migration of phospholipid vesicles in response to OH(-) stimuli.

  2016cited by this paper
• Self-diffusiophoresis of chemically active colloids

  2016cited by this paper
• Structural basis for pore-forming mechanism of staphylococcal α-hemolysin.

  2015cited by this paper
• Size-dependent control of colloid transport via solute gradients in dead-end channels

  2015cited by this paper
• How Lipid Membranes Affect Pore Forming Toxin Activity.

  2015cited by this paper
• Vesicle-based artificial cells as chemical microreactors with spatially segregated reaction pathways

  2014cited by this paper
• Phoretic self-propulsion at finite Péclet numbers

  2014cited by this paper
• Selecting the swimming mechanisms of colloidal particles: bubble propulsion versus self-diffusiophoresis.

  2014cited by this paper
• Smallest Unit of Life: Cell Biology

  2014cited by this paper
• α-Hemolysin membrane pore density measured on liposomes

  2013cited by this paper
• An engineered dimeric protein pore that spans adjacent lipid bilayers

  2013cited by this paper
• Enzyme molecules as nanomotors.

  2013cited by this paper
• Lipid and phase specificity of α-toxin from S. aureus.

  2013cited by this paper
• Encapsulation of biomacromolecules within polymersomes by electroporation.

  2012cited by this paper
• Rapid assembly of a multimeric membrane protein pore.

  2011cited by this paper
• Development of an artificial cell, from self-organization to computation and self-reproduction

  2011cited by this paper
• α-Hemolysin pore formation into a supported phospholipid bilayer using cell-free expression.

  2011cited by this paper
• Building artificial cells and protocell models: experimental approaches with lipid vesicles.

  2010cited by this paper
• Sugar synthesis in a protocellular model leads to a cell signalling response in bacteria.

  2009cited by this paper
• Structure of functional Staphylococcus aureus alpha-hemolysin channels in tethered bilayer lipid membranes.

  2009cited by this paper
• Artificial cells: building bioinspired systems using small-scale biology.

  2008cited by this paper
• Chemotaxis of nonbiological colloidal rods.

  2007cited by this paper
• Self-motile colloidal particles: from directed propulsion to random walk.

  2007cited by this paper
• Propulsion of a molecular machine by asymmetric distribution of reaction products.

  2005cited by this paper
• High resolution crystallographic studies of α‐hemolysin–phospholipid complexes define heptamer–lipid head group interactions: Implication for understanding protein–lipid interactions

  2004cited by this paper
• A vesicle bioreactor as a step toward an artificial cell assembly.

  2004cited by this paper
• Making sense of it all: bacterial chemotaxis

  2004cited by this paper
• Artificial cells: prospects for biotechnology.

  2002cited by this paper
• VESICLES AS OSMOTIC MOTORS

  1999cited by this paper
• Structure of Staphylococcal α-Hemolysin, a Heptameric Transmembrane Pore

  1996cited by this paper
• Methods of Digital Video Microscopy for Colloidal Studies

  1996cited by this paper
• Kinetic Phenomena in the boundary layers of liquids 1. the capillary osmosis

  1993cited by this paper
• Molecular Biology of the Cell

  1990cited by this paper
• Colloid Transport by Interfacial Forces

  1989cited by this paper
• Movement of a semipermeable vesicle through an osmotic gradient

  1983cited by this paper
• Theory of self-assembly of hydrocarbon amphiphiles into micelles and bilayers

  1976cited by this paper
• Surface Tension of Sugar Factory Products.

  1924cited by this paper

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