Abstract
Early protocells are commonly assumed to consist of an amphiphilic membrane enclosing an RNA-based self-replicating genetic system and a primitive metabolism without protein enzymes. Thus, protocell evolution must have relied on simple physicochemical self-organization processes within and across such vesicular structures. We investigate freeze-thaw (FT) cycling as a potential environmental driver for the necessary content exchange between vesicles. To this end, we developed a conceptually simple yet statistically powerful high-throughput procedure based on nucleic acid-containing giant unilamellar vesicles (GUVs) as model protocells. GUVs are formed by emulsion transfer in glass bottom microtiter plates and hence can be manipulated and monitored by fluorescence microscopy without additional pipetting and sample handling steps. This new protocol greatly minimizes artefacts, such as unintended GUV rupture or fusion by shear forces. Using DNA-encapsulating phospholipid GUVs fabricated by this method, we quantified the extent of content mixing between GUVs under different FT conditions. We found evidence of nucleic acid exchange in all detected vesicles if fast freezing of GUVs at −80 °C is followed by slow thawing at room temperature. In contrast, slow freezing and fast thawing both adversely affected content mixing. Surprisingly, and in contrast to previous reports for FT-induced content mixing, we found that the content is not exchanged through vesicle fusion and fission, but that vesicles largely maintain their membrane identity and even large molecules are exchanged via diffusion across the membranes. Our approach supports efficient screening of prebiotically plausible molecules and environmental conditions, to yield universal mechanistic insights into how cellular life may have emerged.
Highlights
Defining living matter is difficult [1]
Generating heterogeneous giant unilamellar vesicles (GUVs) populations by emulsion transfer in microtiter plates To study the effect of FT-cycling on vesicle content mixing, we first developed a method to simultaneously generate GUVs of differing content via emulsion transfer in microtiter plates, greatly improving experimental throughput and parallelizing the screening for optimal conditions
We found that mixing of contents in our POPC-GUV model system proceeded to varying degrees in conditions A–C
Summary
Defining living matter is difficult [1]. Yet, all living species are capable of decreasing internal entropy and increasing functional complexity at the expense of substances or free energy absorbed from the environment. In order for cellular life to develop this characteristic complexity, even primitive protocells must have compartmentalized their molecular components to separate themselves from each other and the environment, allowing them to maintain and regulate biochemical processes (i.e., develop a metabolism), effectively couple their cellular phenotype to their genotype and prevent takeover by parasitic mutants. This compartment boundary consists of lipid membranes in all known living entities. Given the intricate nature of these complex biological processes, it remains a mystery how the first precursors of our modern cells, doubtlessly much more primitive entities before the advent of proteins, could have exchanged material—itself a prerequisite for the emergence of life
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