Protein-free catalysis of DNA hydrolysis and self-integration by a ribozyme.

Group II introns are ancient self-splicing ribozymes and retrotransposons. Though long speculated to have originated before translation, their dependence on intron-encoded proteins for splicing and mobility has cast doubt on this hypothesis. While some group II introns are known to retain part of their catalytic repertoire in the absence of protein cofactors, protein-free complete reverse splicing of a group II intron into a DNA target has never been demonstrated.

Regulating Nucleic Acid Catalysis Using Active Droplets.

Cells use transient membraneless organelles to regulate biological reaction networks. For example, stress granules selectively store mRNA to downregulate protein expression in response to heat or oxidative stress. Models mimicking this active behavior should be established to better understand in vivo regulation involving compartmentalization.

Design of Novel Synthetic RNA Replicons Based on .

Self-replicating RNAs (srRNAs) are synthetic molecules designed to mimic the self-replicating ability of viral RNAs. srRNAs hold significant promise for a range of applications, including enhancing protein expression, reprogramming cells into pluripotent stem cells, and creating cell-free systems for experimental evolution. However, the development of srRNAs for use in bacterial systems remains limited.

Ribozyme activity modulates the physical properties of RNA-peptide coacervates.

Condensed coacervate phases are now understood to be important features of modern cell biology, as well as valuable protocellular models in origin-of-life studies and synthetic biology. In each of these fields, the development of model systems with varied and tuneable material properties is of great importance for replicating properties of life. Here, we develop a ligase ribozyme system capable of concatenating short RNA fragments into long chains.

Design principles and applications of synthetic self-replicating RNAs.

With the advent of ever more sophisticated methods for the in vitro synthesis and the in vivo delivery of RNAs, synthetic mRNAs have gained substantial interest both for medical applications, as well as for biotechnology. However, in most biological systems exogeneous mRNAs possess only a limited half-life, especially in fast dividing cells. In contrast, viral RNAs can extend their lifetime by actively replicating inside their host.

The Long Road to a Synthetic Self-Replicating Central Dogma.

The construction of a biochemical system capable of self-replication is a key objective in bottom-up synthetic biology. Throughout the past two decades, a rapid progression in the design of cell-free systems has provided valuable insight into the requirements for the development of a minimal system capable of self-replication. The main limitations of current systems can be attributed to their macromolecular composition and how the individual macromolecules use the small molecules necessary to drive RNA and protein synthesis.

Ribozyme-mediated RNA synthesis and replication in a model Hadean microenvironment.

Enzyme-catalyzed replication of nucleic acid sequences is a prerequisite for the survival and evolution of biological entities. Before the advent of protein synthesis, genetic information was most likely stored in and replicated by RNA. However, experimental systems for sustained RNA-dependent RNA-replication are difficult to realise, in part due to the high thermodynamic stability of duplex products and the low chemical stability of catalytic RNAs.

In vitro characterisation of the MS2 RNA polymerase complex reveals host factors that modulate emesviral replicase activity.

The RNA phage MS2 is one of the most important model organisms in molecular biology and virology. Despite its comprehensive characterisation, the composition of the RNA replication machinery remained obscure. Here, we characterised host proteins required to reconstitute the functional replicase in vitro.

Generation of RNA with 2', 3'-Cyclic Phosphates by Deoxyribozyme Cleavage in Frozen Solutions.

The generation of terminal 2', 3'-cyclic phosphates on RNA oligomers is an important process in the study of tRNA splicing and repair, ribozyme catalysis, and RNA circularization. Here, we describe a simple method for producing 2', 3'-cyclic phosphate functionalized RNA by the deoxyribozyme-catalyzed cleavage of a short 3'-RNA overhang in frozen solution. This method avoids the nonspecific modification and degradation of RNA and attached functional groups (e.

PCR Methods for the Generation of Catalytic ssDNA.

The ability to produce single-stranded DNA on a preparative scale from low amounts of starting templates is necessary for most research involving deoxyribozymes, but is particularly important for performing in vitro selections. While the production of single-stranded RNA is straightforward by means of in vitro transcription, the enzymatic production of single-stranded DNA (ssDNA) on a preparative scale is often difficult. Nevertheless, several methods for the production of ssDNA have been published over the years.

Charge-density reduction promotes ribozyme activity in RNA-peptide coacervates via RNA fluidization and magnesium partitioning.

It has long been proposed that phase-separated compartments can provide a basis for the formation of cellular precursors in prebiotic environments. However, we know very little about the properties of coacervates formed from simple peptides, their compatibility with ribozymes or their functional significance. Here we assess the conditions under which functional ribozymes form coacervates with simple peptides.

Enhanced Ribozyme-Catalyzed Recombination and Oligonucleotide Assembly in Peptide-RNA Condensates.

The ability of RNA to catalyze RNA ligation is critical to its central role in many prebiotic model scenarios, in particular the copying of information during self-replication. Prebiotically plausible ribozymes formed from short oligonucleotides can catalyze reversible RNA cleavage and ligation reactions, but harsh conditions or unusual scenarios are often required to promote folding and drive the reaction equilibrium towards ligation. Here, we demonstrate that ribozyme activity is greatly enhanced by charge-mediated phase separation with poly-L-lysine, which shifts the reaction equilibrium from cleavage in solution to ligation in peptide-RNA coaggregates and coacervates.

Heat flows in rock cracks naturally optimize salt compositions for ribozymes.

Catalytic nucleic acids, such as ribozymes, are central to a variety of origin-of-life scenarios. Typically, they require elevated magnesium concentrations for folding and activity, but their function can be inhibited by high concentrations of monovalent salts. Here we show that geologically plausible high-sodium, low-magnesium solutions derived from leaching basalt (rock and remelted glass) inhibit ribozyme catalysis, but that this activity can be rescued by selective magnesium up-concentration by heat flow across rock fissures.

Probing self-regeneration of essential protein factors required for in vitro translation activity by serial transfer.

The bottom-up construction of bio-inspired systems capable of self-maintenance and reproduction is a central goal in systems chemistry and synthetic biology. A particular challenge in such systems is the continuous regeneration of key proteins required for macromolecular synthesis. Here, we probe self-maintenance of a reconstituted in vitro translation system challenged by serial transfer of selected key proteins.

Prebiotically Plausible RNA Activation Compatible with Ribozyme-Catalyzed Ligation.

RNA-catalyzed RNA ligation is widely believed to be a key reaction for primordial biology. However, since typical chemical routes towards activating RNA substrates are incompatible with ribozyme catalysis, it remains unclear how prebiotic systems generated and sustained pools of activated building blocks needed to form increasingly larger and complex RNA. Herein, we demonstrate in situ activation of RNA substrates under reaction conditions amenable to catalysis by the hairpin ribozyme.

Active coacervate droplets as a model for membraneless organelles and protocells.

Membraneless organelles like stress granules are active liquid-liquid phase-separated droplets that are involved in many intracellular processes. Their active and dynamic behavior is often regulated by ATP-dependent reactions. However, how exactly membraneless organelles control their dynamic composition remains poorly understood.

Templated Self-Replication in Biomimetic Systems.

A key characteristic of living systems is the storage and replication of information, and as such the development of self-replicating systems capable of heredity is of great importance to the fields of synthetic biology and origin of life research. In this review, the design and implementation of self-replicating systems in the context of bottom-up synthetic biology is discussed, with a particular focus on nucleic acid-based replication including nonenzymatic systems, ribozyme-based systems, and complex in vitro translation coupled RNA and DNA replication. The current state and remaining challenges of the respective fields are discussed, and the potential of individual replicators for synthetic biology applications such as the creation of artificial life capable of Darwinian evolution is also summarized.

In vitro self-replication and multicistronic expression of large synthetic genomes.

The generation of a chemical system capable of replication and evolution is a key objective of synthetic biology. This could be achieved by in vitro reconstitution of a minimal self-sustaining central dogma consisting of DNA replication, transcription and translation. Here, we present an in vitro translation system, which enables self-encoded replication and expression of large DNA genomes under well-defined, cell-free conditions.

Nucleic Acid Catalysis under Potential Prebiotic Conditions.

Catalysis by nucleic acids is indispensable for extant cellular life, and it is widely accepted that nucleic acid enzymes were crucial for the emergence of primitive life 3.5-4 billion years ago. However, geochemical conditions on early Earth must have differed greatly from the constant internal milieus of today's cells.

The difficult case of an RNA-only origin of life.

The RNA world hypothesis is probably the most extensively studied model for the emergence of life on Earth. Despite a large body of evidence supporting the idea that RNA is capable of kick-starting autocatalytic self-replication and thus initiating the emergence of life, seemingly insurmountable weaknesses in the theory have also been highlighted. These problems could be overcome by novel experimental approaches, including out-of-equilibrium environments, and the exploration of an early co-evolution of RNA and other key biomolecules such as peptides and DNA, which might be necessary to mitigate the shortcomings of RNA-only systems.

Special Issue on Bottom-Up Synthetic Biology.

Bottom-up synthetic biology uses both biological and artificial chemical building blocks to create biomimetic systems, including artificial cells. Existing and new technologies such as microfluidics are being developed and applied to the assembly processes. In this special issue, experts present and review the latest progress in this rapidly expanding and diverse field.

Cell-free expression of RNA encoded genes using MS2 replicase.

RNA replicases catalyse transcription and replication of viral RNA genomes. Of particular interest for in vitro studies are phage replicases due to their small number of host factors required for activity and their ability to initiate replication in the absence of any primers. However, the requirements for template recognition by most phage replicases are still only poorly understood.