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.

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.

Construction and in vivo assembly of a catalytically proficient and hyperthermostable de novo enzyme.

Although catalytic mechanisms in natural enzymes are well understood, achieving the diverse palette of reaction chemistries in re-engineered native proteins has proved challenging. Wholesale modification of natural enzymes is potentially compromised by their intrinsic complexity, which often obscures the underlying principles governing biocatalytic efficiency. The maquette approach can circumvent this complexity by combining a robust de novo designed chassis with a design process that avoids atomistic mimicry of natural proteins.