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Your search keyword '"MAST, CHRISTOF B."' showing total 31 results
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31 results on '"MAST, CHRISTOF B."'

2. Selection of prebiotic oligonucleotides by cyclic phase separation

Author

Bartolucci, Giacomo, Serrão, Adriana Calaça, Schwintek, Philipp, Kühnlein, Alexandra, Rana, Yash, Janto, Philipp, Hofer, Dorothea, Mast, Christof B., Braun, Dieter, and Weber, Christoph A.

Subjects
Physics - Chemical Physics
Abstract

The emergence of functional oligonucleotides on early Earth required a molecular selection mechanism to screen for specific sequences with prebiotic functions. Cyclic processes such as daily temperature oscillations were ubiquitous in this environment and could trigger oligonucleotide phase separation. Here, we propose sequence selection based on phase separation cycles realized through sedimentation in a system subjected to the feeding of oligonucleotides. Using theory and experiments with DNA, we show sequence-specific enrichment in the sedimented dense phase, in particular of short 22-mer DNA sequences. The underlying mechanism selects for complementarity, as it enriches sequences that tightly interact in the condensed phase through base-pairing. Our mechanism also enables initially weakly biased pools to enhance their sequence bias or to replace the most abundant sequences as the cycles progress. Our findings provide an example of a selection mechanism that may have eased screening for the first auto-catalytic self-replicating oligonucleotides.

Published
2022

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

Author

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

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics, Quantitative Biology - Biomolecules
Abstract

Non-equilibrium conditions must have been crucial for the assembly of the first informational polymers of early life, but supporting their formation and continuous enrichment in a long-lasting environment. Here, we explore how gas bubbles in water subjected to a thermal gradient, a likely scenario within crustal mafic rocks on the early Earth, drive a complex, continuous enrichment of prebiotic molecules. NRA precursors, monomers, active ribozymes, oligonucleotides and lipids are shown to (1) cycle between dry and wet states, enabling the central step of RNA phosphorylation, (2) accumulate at the gas-water interface to drastically increase ribozymatic activity, (3) condense into hydrogels, (4) form pure crystals and (5) encapsulate into protecting vesicle aggregates that subsequently undergo fission. These effects occur within less than 30 min. The findings unite, in one location, the physical conditions that were crucial for the chemical emergence of biopolymers. They suggest that heated microbubbles could have hosted the first cycles of molecular evolution., Comment: 27 pages, 7 Figures

Published
2021
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9. Sequence self-selection by cyclic phase separation

Author

Bartolucci, Giacomo, primary, Calaça Serrão, Adriana, additional, Schwintek, Philipp, additional, Kühnlein, Alexandra, additional, Rana, Yash, additional, Janto, Philipp, additional, Hofer, Dorothea, additional, Mast, Christof B., additional, Braun, Dieter, additional, and Weber, Christoph A., additional

Published
2023
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11. Non-equilibrium conditions inside rock pores drive fission, maintenance and selection of coacervate protocells

Author

Ianeselli, Alan, Tetiker, Damla, Stein, Julian, Kühnlein, Alexandra, Mast, Christof B., Braun, Dieter, and Dora Tang, T.-Y.

Abstract

Key requirements for the first cells on Earth include the ability to compartmentalize and evolve. Compartmentalization spatially localizes biomolecules from a dilute pool and an evolving cell, which, as it grows and divides, permits mixing and propagation of information to daughter cells. Complex coacervate microdroplets are excellent candidates as primordial cells with the ability to partition and concentrate molecules into their core and support primitive and complex biochemical reactions. However, the evolution of coacervate protocells by fusion, growth and fission has not yet been demonstrated. In this work, a primordial environment initiated the evolution of coacervate-based protocells. Gas bubbles inside heated rock pores perturb the coacervate protocell distribution and drive the growth, fusion, division and selection of coacervate microdroplets. Our findings provide a compelling scenario for the evolution of membrane-free coacervate microdroplets on the early Earth, induced by common gas bubbles within heated rock pores.

Published
2024
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13. Selection of the Early Genetic Code by Ultraviolet Light

Author

Kufner, Corinna L., primary, Krebs, Stefan, additional, Fischaleck, Marlis, additional, Philippou-Massier, Julia, additional, Blum, Helmut, additional, Bucher, Dominik B., additional, Braun, Dieter, additional, Zinth, Wolfgang, additional, and Mast, Christof B., additional

Published
2022
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14. RNA Oligomerisation without Added Catalyst from 2′,3′‐Cyclic Nucleotides by Drying at Air‐Water Interfaces**

Author

Dass, Avinash Vicholous, primary, Wunnava, Sreekar, additional, Langlais, Juliette, additional, von der Esch, Beatriz, additional, Krusche, Maik, additional, Ufer, Lennard, additional, Chrisam, Nico, additional, Dubini, Romeo C. A., additional, Gartner, Florian, additional, Angerpointner, Severin, additional, Dirscherl, Christina F., additional, Rovó, Petra, additional, Mast, Christof B., additional, Šponer, Judit E., additional, Ochsenfeld, Christian, additional, Frey, Erwin, additional, and Braun, Dieter, additional

Published
2022
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17. RNA Oligomerisation without Added Catalyst from 2′,3′‐Cyclic Nucleotides by Drying at Air‐Water Interfaces.

Author

Dass, Avinash Vicholous, Wunnava, Sreekar, Langlais, Juliette, von der Esch, Beatriz, Krusche, Maik, Ufer, Lennard, Chrisam, Nico, Dubini, Romeo C. A., Gartner, Florian, Angerpointner, Severin, Dirscherl, Christina F., Rovó, Petra, Mast, Christof B., Šponer, Judit E., Ochsenfeld, Christian, Frey, Erwin, and Braun, Dieter

Subjects
RNA analysis, OLIGOMERIZATION, AIR-water interfaces, CYCLIC nucleotides, DRYING, PREBIOTICS
Abstract

For the emergence of life, the abiotic synthesis of RNA from its monomers is a central step. We found that in alkaline, drying conditions in bulk and at heated air‐water interfaces, 2′,3′‐cyclic nucleotides oligomerised without additional catalyst, forming up to 10‐mers within a day. The oligomerisation proceeded at a pH range of 7–12, at temperatures between 40–80 °C and was marginally enhanced by K+ ions. Among the canonical ribonucleotides, cGMP oligomerised most efficiently. Quantification was performed using HPLC coupled to ESI‐TOF by fitting the isotope distribution to the mass spectra. Our study suggests a oligomerisation mechanism where cGMP aids the incorporation of the relatively unreactive nucleotides C, A and U. The 2′,3′‐cyclic ribonucleotides are byproducts of prebiotic phosphorylation, nucleotide syntheses and RNA hydrolysis, indicating direct recycling pathways. The simple reaction condition offers a plausible entry point for RNA to the evolution of life on early Earth. [ABSTRACT FROM AUTHOR]

Published
2023
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20. Water cycles in a Hadean CO2atmosphere drive the evolution of long DNA

Author

Ianeselli, Alan, Atienza, Miguel, Kudella, Patrick W., Gerland, Ulrich, Mast, Christof B., and Braun, Dieter

Abstract

Dew is a common form of water that deposits from saturated air on colder surfaces. Although presumably common on primordial Earth, its potential involvement in the origin of life in early replication has not been investigated in detail. Here we report that it can drive the first stages of Darwinian evolution for DNA and RNA, first by periodically denaturing their structures at low temperatures and second by promoting the replication of long strands over short, faster replicating ones. Our experiments mimicked a partially water-filled primordial rock pore in the probable CO2atmosphere of Hadean Earth. Under heat flow, water continuously evaporated and recondensed as acidic dew droplets that created the humidity, salt and pH cycles that match many prebiotic replication chemistries. In low-salt and low-pH regimes, the strands melted at 30 K below the bulk melting temperature, whereas longer sequences preferentially accumulated at the droplet interface. Under an enzymatic replication to mimic a sped-up RNA world, long sequences of more than 1,000 nucleotides emerged. The replication was biased by the melting conditions of the dew and the initial short ATGC strands evolved into long AT-rich sequences with repetitive and structured nucleotide composition.

Published
2022
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26. Proton gradients and pH oscillations emerge from heat flow at the microscale.

Author

Keil, Lorenz M. R., Möller, Friederike M., Kieß, Michael, Kudella, Patrick W., and Mast, Christof B.

Abstract

Proton gradients are essential for biological systems. They not only drive the synthesis of ATP, but initiate molecule degradation and recycling inside lysosomes. However, the high mobility and permeability of protons through membranes make pH gradients very hard to sustain in vitro. Here we report that heat flow across a water-filled chamber forms and sustains stable pH gradients. Charged molecules accumulate by convection and thermophoresis better than uncharged species. In a dissociation reaction, this imbalances the reaction equilibrium and creates a difference in pH. In solutions of amino acids, phosphate, or nucleotides, we achieve pH differences of up to 2pH units. The same mechanism cycles biomolecules by convection in the created proton gradient. This implements a feedback between biomolecules and a cyclic variation of the pH. The finding provides a mechanism to create a self-sustained proton gradient to drive biochemical reactions. [ABSTRACT FROM AUTHOR]

Published
2017
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27. Emergence of Life from Trapped Nucleotides? Non-Equilibrium Behavior of Oligonucleotides in Thermal Gradients.

Author

Agerschou, Emil Dandanell, Mast, Christof B., and Braun, Dieter

Subjects
*OLIGONUCLEOTIDES, *NONEQUILIBRIUM thermodynamics, *DNA replication
Abstract

How life emerged is one of the major questions that remains to be answered. Apart from being of interest for completeness of biology, it is also a very interesting study case from the vantage point of physics. Living organisms are inherently non-equilibrium systems. Since non-equilibrium thermodynamics is still a developing field, the emergence of life is a highly interesting study case. Here we present the progress we have made during the last few years, employing experimental biophysics to capture the mechanisms that could eventually lead to the emergence of life. We show how a simple non-equilibrium system, a thermal gradient, gives rise to a range of relevant phenomena, in particular, polymerization, elongation, and replication of DNA molecules as well as demixing of mixed DNA sequences into sequence-pure hydrogels. 1 Introduction 2 Thermophoresis, the Biased Movement of Molecules in Thermal Gradients 3 The Dynamical Behavior of Accumulated Molecules 4 Overcoming Spiegelman’s Monster 5 Sequence Purification and Oscillations by a Gel-Phase Transition in Thermal Gradients 6 Loose Ends 7 Discussion and Conclusion [ABSTRACT FROM AUTHOR]

Published
2017
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