Heated gas bubbles enrich, crystallize, dry, phosphorylate and encapsulate prebiotic molecules

Morasch, Matthias; Liu, Jonathan; Dirscherl, Christina F.; Ianeselli, Alan; Kühnlein, Alexandra; Vay, Kristian Le; Schwintek, Philipp; Islam, Suhail A.; Corpinot, Mérina K.; Scheu, Bettina; Dingwell, Donald B.; Schwille, Petra; Mutschler, Hannes; Powner, Matthew W.; Mast, Christof B.; Braun, Dieter

doi:10.1038/s41557-019-0299-5

Cited by 88 publications

(132 citation statements)

References 53 publications

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“…To the best of our knowledge, we demonstrate for the first time that the division of GUVs can be regulated by metabolic activity. Our results prompt to ask whether similar mechanisms may have sustained cell division at the onset of live [26,27]. Similarly, remnants thereof may still play a role in cell biology today, e.g.…”

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confidence: 80%

Protein-free division of giant unilamellar vesicles controlled by enzymatic activity

Dreher

Spatz

Göpfrich

2019

Preprint

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Cell division is one of the hallmarks of life. Success in the bottom-up assembly of synthetic cells will, no doubt, depend on strategies for the controlled autonomous division of protocellular compartments. Here, we describe the protein-free division of giant unilamellar lipid vesicles (GUVs) based on the combination of two physical principles -phase separation and osmosis. We visualize the division process with confocal fluorescence microscopy and derive a conceptual model based on the vesicle geometry. The model successfully predicts the shape transformations over time as well as the time point of the final pinching of the daughter vesicles. Remarkably, we show that two fundamentally distinct yet highly abundant processes -water evaporation and metabolic activity -can both regulate the autonomous division of GUVs. Our work may hint towards mechanisms that governed the division of protocells and adds to the strategic toolbox of bottom-up synthetic biology with its vision of bringing matter to life."Omni cellulae es cellulae." From the point of view of modern science, Raspail's realization from 1825 [1], popularized by Virchow [2], may state the obvious: Every living cell found on Earth today originates from a preexisting living cell. Bottom-up synthetic biology, however, is challenging this paradigm with the vision to create a synthetic cell from scratch [3,4]. Success unquestionably entails that the synthetic cells must have the capacity to produce offspring, making the implementation of synthetic cell division an exciting goal [5,6,7,8]. Over the course of evolution, living cells have developed a sophisticated machinery to divide their compartments in a highly regulated manner. The reconstitution of a minimal set of components from the procaryotic divisome seems to be a promising route towards synthetic cell division. FtsZ [9,6], ESCRT [10,11] and Min proteins [12] led to shape transformations in lipid vesicles, including budding [11] and the formation of tight constrictions [6]. However, reproducible minimal cell division based on common biological mechanisms has not yet been achieved. These challenges leave room for creative approaches, seeking solutions beyond the mimicry of today's biological cells. One exciting strategy is to assemble a division machinery de novo, by designing active, not necessarily protein-based nanomachines. DNA origami structures have been used to shape and remodel lipid vesicles [13,14,15], although active force-generating contractile motors remain a distant goal. A shortcut towards synthetic cell division is the mechanical division of liposomes, which was achieved with microfluidic splitters [16]. While this is not autonomous, it may jump start exciting new directions by circumventing a longstanding challenge. The exploitation of physico-chemical mechanisms, on the other hand, could lead to autonomous division. Noteworthy theoretical and experimental work describes the shape transformations of single-component [17,18,19] as well as phase-separated liposomes [20,21], determined by th...

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confidence: 80%

Protein-free division of giant unilamellar vesicles controlled by enzymatic activity

Dreher

Spatz

Göpfrich

2019

Preprint

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“…The resulting environment up-concentrates av ariety of components including RNA precursors and oligonucleotides, enabling a compelling variety of prebiotically important processes including precursor crystallization and phosphorylation. [207] Furthermore, the same environments ubstantially improves ribozyme catalysis ande ncapsulation within lipid vesicles.T he improved ribozyme catalysis is primarily the result of local high magnesium and RNA concentrationsa tt he air-water interface, but dehydration may also be significant.…”

Section: The Potential Of Wet-dry Cyclesmentioning

confidence: 99%

“…Wet‐dry cycles can also be produced by the application of thermal gradients at an air–water interface (Figure ). The resulting environment up‐concentrates a variety of components including RNA precursors and oligonucleotides, enabling a compelling variety of prebiotically important processes including precursor crystallization and phosphorylation . Furthermore, the same environment substantially improves ribozyme catalysis and encapsulation within lipid vesicles.…”

Section: Activity Enhancement By Freezing Evaporation and Presence Omentioning

confidence: 99%

“… Schematic of a heated rock pore. Thermal gradients at an air–water interface can result in an environment which up‐concentrates a variety of components including ribozymes and ions . The improved ribozyme catalysis is most likely the result of local high magnesium and RNA concentrations at the interface.…”

Section: Activity Enhancement By Freezing Evaporation and Presence Omentioning

confidence: 99%

“…Thermal gradients at an airwater interface can result in an environmentwhich up-concentrates av ariety of components including ribozymes and ions. [207] The improved ribozyme catalysis is most likely the result of local high magnesiuma nd RNA concentrationsatt he interface. However,d irect dehydrationo ft he RNA at the temporallyd ried interfaceo nt he warm side (red) may also contribute to activity.…”

Section: Ultraviolet Lightmentioning

confidence: 99%

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Nucleic Acid Catalysis under Potential Prebiotic Conditions

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Song

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Chemistry An Asian Journal

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Catalysis by nucleic acids is indispensable for extant cellular life, and it is widely accepted that nucleic acid enzymes were crucial fort he emergence of primitive life 3.5-4b illion years ago. However,g eochemicalc onditions on early Earth must have differed greatlyf rom the constant internal milieus of today's cells. In order to explore plausible scenarios for early molecular evolution, it is therefore essential to understand how different physicochemical parame-ters, such as temperature,p H, and ionic composition, influence nucleic acidc atalysis and to explore to what extent nucleic acid enzymes can adapt to non-physiological conditions. In this article, we give an overview of the research on catalysis of nucleic acids, in particularc atalytic RNAs (ribozymes) and DNAs( deoxyribozymes), under extreme and/or unusualc onditions that may relate to prebiotic environments.[a] Dr.

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Heated gas bubbles enrich, crystallize, dry, phosphorylate and encapsulate prebiotic molecules

Cited by 88 publications

References 53 publications

Protein-free division of giant unilamellar vesicles controlled by enzymatic activity

Protein-free division of giant unilamellar vesicles controlled by enzymatic activity

Nucleic Acid Catalysis under Potential Prebiotic Conditions

A Survey of the Battlefield for the Origin of Life

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