Using Imaging Flow Cytometry to Quantify and Optimize Giant Vesicle Production by Water-in-oil Emulsion Transfer Methods.

Many biologists, biochemists, and biophysicists study giant vesicles, which have a diameter of >1 μm, owing to their ease of characterization using standard optical methods. More recently, there has been interest in using giant vesicles as model systems for living cells and for the construction of artificial cells. In fact, there have been a number of reports about functionalizing giant vesicles using membrane-bound pore proteins and encapsulating biochemical reactions. Among the various methods for preparing giant vesicles, the water-in-oil emulsion transfer method is particularly well established. However, the giant vesicles prepared by this method have complex and heterogeneous properties, such as particle size and membrane structure. Here, we demonstrate the characterization of giant vesicles by imaging flow cytometry to provide quantitative and qualitative information about the vesicle products prepared by the water-in-oil emulsion transfer method. Through image-based analyses, several kinds of protocol byproducts, such as oil droplets and vesicles encapsulating no target molecules, were identified and successfully quantified. Further, the optimal agitation conditions for the water-in-oil emulsion transfer method were found from detailed analysis of imaging flow cytometry data. Our results indicate that a sonication-based water-in-oil emulsion transfer method exhibited a higher efficiency in producing giant vesicles, about 10 times or higher than that of vortex and rumble strip-based methods. It is anticipated that these approaches will be useful for fine-tuning giant vesicle production and subsequent applications.

[1]  Ilia Platzman,et al.  Mastering Complexity: Towards Bottom-up Construction of Multifunctional Eukaryotic Synthetic Cells , 2018, Trends in biotechnology.

[2]  Fabio Mavelli,et al.  Extrinsic stochastic factors (solute partition) in gene expression inside lipid vesicles and lipid-stabilized water-in-oil droplets: a review , 2018, Synthetic biology.

[3]  Masahito Hayashi,et al.  Repetitive stretching of giant liposomes utilizing the nematic alignment of confined actin , 2018 .

[4]  T. Pomorski,et al.  Membrane protein reconstitution into giant unilamellar vesicles: a review on current techniques , 2017, European Biophysics Journal.

[5]  T. Yomo,et al.  Sustainable proliferation of liposomes compatible with inner RNA replication , 2015, Proceedings of the National Academy of Sciences.

[6]  K. Guevorkian,et al.  Mechanics of Biomimetic Liposomes Encapsulating an Actin Shell , 2015, Biophysical journal.

[7]  P. Beales,et al.  Nature's lessons in design: nanomachines to scaffold, remodel and shape membrane compartments. , 2015, Physical chemistry chemical physics : PCCP.

[8]  Fabio Mavelli,et al.  Recent Biophysical Issues About the Preparation of Solute-Filled Lipid Vesicles , 2015 .

[9]  J. Spatz,et al.  Model systems for studying cell adhesion and biomimetic actin networks , 2014, Beilstein journal of nanotechnology.

[10]  Shin'ichi Ishiwata,et al.  Supporting Information Quantitative analysis of the lamellarity of giant liposomes prepared by the inverted emulsion method , 2014 .

[11]  Pasquale Stano,et al.  A remarkable self-organization process as the origin of primitive functional cells. , 2013, Angewandte Chemie.

[12]  G. Rivas,et al.  Giant vesicles: a powerful tool to reconstruct bacterial division assemblies in cell-like compartments. , 2013, Environmental microbiology.

[13]  K. Yoshikawa,et al.  Dynamical formation of lipid bilayer vesicles from lipid-coated droplets across a planar monolayer at an oil/water interface. , 2013, Soft matter.

[14]  Kheya Sengupta,et al.  Giant vesicles as cell models. , 2012, Integrative biology : quantitative biosciences from nano to macro.

[15]  T. Yomo,et al.  Size control of giant unilamellar vesicles prepared from inverted emulsion droplets. , 2012, Journal of colloid and interface science.

[16]  Pasquale Stano,et al.  Spontaneous Crowding of Ribosomes and Proteins inside Vesicles: A Possible Mechanism for the Origin of Cell Metabolism , 2011, Chembiochem : a European journal of chemical biology.

[17]  A. Kros,et al.  Model systems for membrane fusion. , 2011, Chemical Society reviews.

[18]  Tetsuya Yomo,et al.  Detection of association and fusion of giant vesicles using a fluorescence-activated cell sorter. , 2010, Langmuir : the ACS journal of surfaces and colloids.

[19]  P. Luisi,et al.  Spontaneous Protein Crowding in Liposomes: A New Vista for the Origin of Cellular Metabolism , 2010, Chembiochem : a European journal of chemical biology.

[20]  Pasquale Stano,et al.  Giant Vesicles: Preparations and Applications , 2010, Chembiochem : a European journal of chemical biology.

[21]  Masanori Fujinami,et al.  Population analysis of structural properties of giant liposomes by flow cytometry. , 2009, Langmuir : the ACS journal of surfaces and colloids.

[22]  H. Rehage,et al.  Characterization of giant vesicles formed by phase transfer processes , 2009 .

[23]  Mun'delanji C. Vestergaard,et al.  Construction of asymmetric cell-sized lipid vesicles from lipid-coated water-in-oil microdroplets. , 2008, The journal of physical chemistry. B.

[24]  Kazufumi Hosoda,et al.  Quantitative study of the structure of multilamellar giant liposomes as a container of protein synthesis reaction. , 2008, Langmuir : the ACS journal of surfaces and colloids.

[25]  Kenichi Yoshikawa,et al.  Entrapping desired amounts of actin filaments and molecular motor proteins in giant liposomes. , 2008, Langmuir : the ACS journal of surfaces and colloids.

[26]  C. Vipulanandan,et al.  Evaluation of asymmetric liposomal nanoparticles for encapsulation of polynucleotides. , 2008, Langmuir : the ACS journal of surfaces and colloids.

[27]  M. Kozlov,et al.  Mechanics of membrane fusion , 2008, Nature Structural &Molecular Biology.

[28]  Kenichi Yoshikawa,et al.  Spontaneous transfer of phospholipid-coated oil-in-oil and water-in-oil micro-droplets through an oil/water interface. , 2006, Langmuir : the ACS journal of surfaces and colloids.

[29]  Tetsuya Yomo,et al.  Quantification of structural properties of cell-sized individual liposomes by flow cytometry. , 2006, Journal of bioscience and bioengineering.

[30]  Tetsuya Yomo,et al.  Expression of a cascading genetic network within liposomes , 2004, FEBS letters.

[31]  Irene A. Chen,et al.  The Emergence of Competition Between Model Protocells , 2004, Science.

[32]  Martin M. Hanczyc,et al.  Experimental Models of Primitive Cellular Compartments: Encapsulation, Growth, and Division , 2003, Science.

[33]  Sophie Pautot,et al.  Engineering asymmetric vesicles , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[34]  David A. Weitz,et al.  Production of Unilamellar Vesicles Using an Inverted Emulsion , 2003 .

[35]  R. Dowben,et al.  Formation and properties of thin‐walled phospholipid vesicles , 1969, Journal of cellular physiology.

[36]  M. Tomita,et al.  Efficient formation of giant liposomes through the gentle hydration of phosphatidylcholine films doped with sugar. , 2009, Colloids and surfaces. B, Biointerfaces.

[37]  M. Angelova,et al.  Preparation of giant vesicles by external AC electric fields. Kinetics and applications , 1992 .