Core-Shell Modeling of Light Scattering by Vesicles: Effect of Size, Contents, and Lamellarity

Wang, Anna; Miller, Christopher Chan; Szostak, Jack W.

doi:10.1016/j.bpj.2019.01.006

Cited by 48 publications

(82 citation statements)

References 55 publications

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“…3 D and E suggest that the serine-induced increase in turbidity is due to an increase in vesicle lamellarity. This interpretation is consistent with a recent theoretical analysis predicting a strong effect of lamellarity on turbidity (38). We rule out that the increased turbidity is due to oil drops forming (SI Appendix, Fig.…”

Section: Resultssupporting

confidence: 93%

Prebiotic amino acids bind to and stabilize prebiotic fatty acid membranes

Cornell

Black

Xue

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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The membranes of the first protocells on the early Earth were likely self-assembled from fatty acids. A major challenge in understanding how protocells could have arisen and withstood changes in their environment is that fatty acid membranes are unstable in solutions containing high concentrations of salt (such as would have been prevalent in early oceans) or divalent cations (which would have been required for RNA catalysis). To test whether the inclusion of amino acids addresses this problem, we coupled direct techniques of cryoelectron microscopy and fluorescence microscopy with techniques of NMR spectroscopy, centrifuge filtration assays, and turbidity measurements. We find that a set of unmodified, prebiotic amino acids binds to prebiotic fatty acid membranes and that a subset stabilizes membranes in the presence of salt and Mg2+. Furthermore, we find that final concentrations of the amino acids need not be high to cause these effects; membrane stabilization persists after dilution as would have occurred during the rehydration of dried or partially dried pools. In addition to providing a means to stabilize protocell membranes, our results address the challenge of explaining how proteins could have become colocalized with membranes. Amino acids are the building blocks of proteins, and our results are consistent with a positive feedback loop in which amino acids bound to self-assembled fatty acid membranes, resulting in membrane stabilization and leading to more binding in turn. High local concentrations of molecular building blocks at the surface of fatty acid membranes may have aided the eventual formation of proteins.

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Section: Resultssupporting

confidence: 93%

Prebiotic amino acids bind to and stabilize prebiotic fatty acid membranes

Cornell

Black

Xue

et al. 2019

Proc. Natl. Acad. Sci. U.S.A.

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“…Monitoring EV separation in the turbidity range (400–600 nm) could be a better approach for EV detection. Indeed, the hydrophobic interlayer of the EV membrane scatters light in the visible spectrum range of light, making the lipid vesicle-containing solution turbid [ 40 ]. On the other hand, the UV spectrum range (190–350 nm) is essential, as it contains critical information regarding the nature, the concentration, and the purity of organic molecules.…”

Section: Resultsmentioning

confidence: 99%

“…Fortunately, the UV-Vis measurements in our system are coupled with a high-resolution size-guided separation that yielded the populations of the monodisperse particles per fraction. This monodispersity implies that the particle size can be directly inferred from the turbidity spectra, whether by applying the exact Lorenz-Mie solution [ 40 ] or the Rayleigh-Gans-Debye approximation [ 46 ], without the need to invoke a distribution function, such as the log-normal Gaussian distribution [ 47 ]. Indeed, turbidity represents the attenuation of incident light due to light scattering and determination of the particle size spectrophotometrically.…”

Section: Resultsmentioning

confidence: 99%

Development of Novel High-Resolution Size-Guided Turbidimetry-Enabled Particle Purification Liquid Chromatography (PPLC): Extracellular Vesicles and Membraneless Condensates in Focus

Kaddour

Lyu

Shouman

et al. 2020

IJMS

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Acellular particles (extracellular vesicles and membraneless condensates) have important research, drug discovery, and therapeutic implications. However, their isolation and retrieval have faced enormous challenges, impeding their use. Here, a novel size-guided particle purification liquid chromatography (PPLC) is integrated into a turbidimetry-enabled system for dye-free isolation, online characterization, and retrieval of intact acellular particles from biofluids. The chromatographic separation of particles from different biofluids—semen, blood, urine, milk, and cell culture supernatants—is achieved using a first-in-class gradient size exclusion column (gSEC). Purified particles are collected using a fraction collector. Online UV–Vis monitoring reveals biofluid-dependent particle spectral differences, with semen being the most complex. Turbidimetry provides the accurate physical characterization of seminal particle (Sp) lipid contents, sizes, and concentrations, validated by a nanoparticle tracking analysis, transmission electron microscopy, and naphthopyrene assay. Furthermore, different fractions of purified Sps contain distinct DNA, RNA species, and protein compositions. The integration of Sp physical and compositional properties identifies two archetypal membrane-encased seminal extracellular vesicles (SEV)—notably SEV large (SEVL), SEV small (SEVS), and a novel non-archetypal-membraneless Sps, herein named membraneless condensates (MCs). This study demonstrates a comprehensive yet affordable platform for isolating, collecting, and analyzing acellular particles to facilitate extracellular particle research and applications in drug delivery and therapeutics. Ongoing efforts focus on increased resolution by tailoring bead/column chemistry for each biofluid type.

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“…Under these conditions, an initial assessment of self‐assembly was obtained by UV/Vis turbidity measurements, monitoring the absorbance at 400 nm ( A 400 ) with dinucleolipid concentration. As none of the studied compounds present any absorption band at such a wavelength (Figure S1), this kind of measurement accounted for the scattering caused by the obtained assemblies . In particular, Figure A was assembled from three different series of concentration‐dependent UV/Vis spectra (i.e., for 1 A , 1 T and 1 A⋅1 T ; see Figure S2 as an example).…”

Section: Resultsmentioning

confidence: 99%

“…All samples were prepared by injecting small volumes of stock solutions in dimethyl sulfoxide (DMSO) (normally 1.5 or 10 mm,d epending on the final target concentration) into freshly prepared HEPES buffer,e nsuring that the final proportion of DMSO was < 5%.U nder these conditions, an initial assessment of self-assembly was obtained by UV/Vis turbidity measurements, monitoringt he absorbance at 400 nm (A 400 ) with dinucleolipid concentration.A sn one of the studied compounds present any absorption band at such aw avelength ( Figure S1), this kind of measurement accounted for the scattering caused by the obtained assemblies. [36,37] In particular, Figure2Aw as assembled from three different series of concentration-dependentU V/Vis spectra (i.e.,f or 1A, 1T and 1A·1 T;s ee Figure S2 as an example). The scattering increased gradually with dinucleolipid concentration,s howing that both 1A and 1T self-assembled in the aqueousm edium,b ut the extento fs elf-assembly wasm uch more prominent for the 1A·1 T mixture.…”

Section: Resultsmentioning

confidence: 99%

Programmed Recognition between Complementary Dinucleolipids To Control the Self‐Assembly of Lipidic Amphiphiles

Morales-Reina

Giri

Leclercq

et al. 2020

Chemistry A European J

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One of the major goals in systems chemistry is to create molecular assemblies with emergent properties that are characteristic of life. An interesting approach toward this goal is based on mergingd ifferent biological building blocks into synthetic systems with properties arising from the combination of their molecular components. The covalentl inkage of nucleic acids (or their constituents:n ucleotides,n ucleosides and nucleobases) with lipids in the same hybrid molecule leads, for example, to the so-called nucleolipids. Herein, we describen ucleolipids with av ery short sequence of two nucleobases per lipid, which, in combination with hydrophobic effectsp romoted by the lipophilic chain, allow controlo ft he self-assembly of lipidic amphiphiles to be achieved. The presentw ork describes as pectroscopic and microscopy study of the structural features and dynamic selfassembly of dinucleolipids that contain adenine or thymine moieties, either pure or in mixtures. This approach leads to different self-assembled nanostructures, which include spherical, rectangulara nd fibrillara ssemblies, as af unction of the sequence of nucleobases and chiral effects of the nucleolipidsinvolved.W ealso show evidencethat the resulting architectures can encapsulate hydrophobic molecules,r evealing their potential as drug delivery vehicles or as compartmentstoh ost interesting chemistries in their interior.

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Core-Shell Modeling of Light Scattering by Vesicles: Effect of Size, Contents, and Lamellarity

Cited by 48 publications

References 55 publications

Prebiotic amino acids bind to and stabilize prebiotic fatty acid membranes

Prebiotic amino acids bind to and stabilize prebiotic fatty acid membranes

Development of Novel High-Resolution Size-Guided Turbidimetry-Enabled Particle Purification Liquid Chromatography (PPLC): Extracellular Vesicles and Membraneless Condensates in Focus

Programmed Recognition between Complementary Dinucleolipids To Control the Self‐Assembly of Lipidic Amphiphiles

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