Trivalent rare earth metal cofactors confer rapid NP-DNA polymerase activity

A Threose Nucleic Acid (TNA) Enzyme Catalyzing Native 3'-5' Ligation of RNA

Threose nucleic acid (TNA) is a synthetic genetic polymer of both prebiotic significance and practical utility. Identification of TNA molecules with enzymatic activities (TNAzymes) not only lends experimental support for TNA as a potential primitive catalyst but also offers intrinsically stable biotechnological and biomedical molecular tools. Here, we report the in vitro selection of TNAzymes capable of catalyzing the native 3'-5' ligation of two RNA oligonucleotides. The Zn2+-dependent TNAzyme facilitates the formation of a canonical phosphoester bond between a terminal 3'-hydroxyl group on one substrate and a 5'-triphosphate on the other. Under optimal conditions (pH 7.3 and 23 °C), the TNAzyme exhibits a catalytic rate constant of 0.39 h-1. Lastly, we demonstrate that the TNAzyme-catalyzed ligation of two RNA fragments could yield a functional RNA product such as a ribozyme. These findings showcase the potential role of TNA as a primordial catalyst during the emergence of the RNA world, as well as its prospective application in RNA synthesis.

Measuring XNA polymerase fidelity in a hydrogel particle format

Growth in the development of engineered polymerases for synthetic biology has led to renewed interest in assays that can measure the fidelity of polymerases that are capable of synthesizing artificial genetic polymers (XNAs). Conventional approaches require purifying the XNA intermediate of a replication cycle (DNA → XNA → DNA) by denaturing polyacrylamide gel electrophoresis, which is a slow, costly, and inefficient process that requires a large-scale transcription reaction and careful extraction of the XNA strand from the gel slice. In an effort to streamline the assay, we developed a purification-free approach in which the XNA transcription and reverse transcription steps occur inside the matrix of a hydrogel-coated magnetic particle. Accordingly, a DNA primer cross-linked throughout the gel matrix is annealed to a template of defined sequence and extended with XNA. Following removal of the DNA template, the XNA product strand is copied back into DNA, recovered, amplified, cloned, and sequenced. Performing the replication cycle in the hydrogel format drastically reduces the time and reaction scales required to measure the fidelity of an XNA polymerase, making it easier to evaluate the properties of a range of candidate XNA polymerases.

Catalytic Metal Ion-Substrate Coordination during Nonenzymatic RNA Primer Extension

Nonenzymatic template-directed RNA copying requires catalysis by divalent metal ions. The primer extension reaction involves the attack of the primer 3'-hydroxyl on the adjacent phosphate of a 5'-5'-imidazolium-bridged dinucleotide substrate. However, the nature of the interaction of the catalytic metal ion with the reaction center remains unclear. To explore the coordination of the catalytic metal ion with the imidazolium-bridged dinucleotide substrate, we examined catalysis by oxophilic and thiophilic metal ions with both diastereomers of phosphorothioate-modified substrates. We show that Mg2+ and Cd2+ exhibit opposite preferences for the two phosphorothioate substrate diastereomers, indicating a stereospecific interaction of the divalent cation with one of the nonbridging phosphorus substituents. High-resolution X-ray crystal structures of the products of primer extension with phosphorothioate substrates reveal the absolute stereochemistry of this interaction and indicate that catalysis by Mg2+ involves inner-sphere coordination with the nonbridging phosphate oxygen in the pro-SP position, while thiophilic cadmium ions interact with sulfur in the same position, as in one of the two phosphorothioate substrates. These results collectively suggest that during nonenzymatic RNA primer extension with a 5'-5'-imidazolium-bridged dinucleotide substrate the interaction of the catalytic Mg2+ ion with the pro-SP oxygen of the reactive phosphate plays a crucial role in the metal-catalyzed SN2(P) reaction.

Bioseparation of rare earth elements and high value-added biomaterials applications

Rare earth elements (REEs) are a group of critical minerals and extensively employed in new material manufacturing. However, separation of lanthanides is difficult because of their similar chemical natures. Current lanthanide leaching and separation methods require hazardous compounds, resulting in severe environmental concerns. Bioprocessing of lanthanides offers an emerging class of tools for REE separation due to mild leaching conditions and highly selective separation scenarios. In the course of biopreparation, engineered microbes not only dissolve REEs from ores but also allow for selective separation of the lanthanides. In this review, we present an overview of recent advances in microbes and proteins used for the biomanufacturing of lanthanides and discuss high value-added applications of REE-derived biomaterials. We begin by introducing the fundamental interactions between natural microbes and REEs. Then we discuss the rational design of chassis microbes for bioleaching and biosorption. We also highlight the investigations on REE binding proteins and their applications in the synthesis of high value-added biomaterials. Finally, future opportunities and challenges for the development of next generation lanthanide-binding biological systems are discussed.