Iron-sulfur clusters are involved in post-translational arginylation.

Eukaryotic arginylation is an essential post-translational modification that modulates protein stability and regulates protein half-life. Arginylation is catalyzed by a family of enzymes known as the arginyl-tRNA transferases (ATE1s), which are conserved across the eukaryotic domain. Despite their conservation and importance, little is known regarding the structure, mechanism, and regulation of ATE1s. In this work, we show that ATE1s bind a previously undiscovered [Fe-S] cluster that is conserved across evolution. We characterize the nature of this [Fe-S] cluster and find that the presence of the [Fe-S] cluster in ATE1 is linked to its arginylation activity, both in vitro and in vivo, and the initiation of the yeast stress response. Importantly, the ATE1 [Fe-S] cluster is oxygen-sensitive, which could be a molecular mechanism of the N-degron pathway to sense oxidative stress. Taken together, our data provide the framework of a cluster-based paradigm of ATE1 regulatory control.

Maturation strategy influences expression levels and cofactor occupancy in Fe-S proteins.

Iron-sulfur clusters are ubiquitous cofactors required for fundamental biological processes. Structural and spectroscopic analysis of Fe-S proteins is often limited by low cluster occupancy in recombinantly produced proteins. In this work, we report a systematic comparison of different maturation strategies for three well-established [4Fe-4S] proteins. Aconitase B, HMBPP reductase (IspH), and quinolinate synthase (NadA) were used as model proteins as they have previously been characterized. The protein production strategies include expression of the gene of interest in BL21(DE3) cells, maturation of the apo protein using chemical or semi-enzymatic reconstitution, co-expression with two different plasmids containing the iron-sulfur cluster (isc) or sulfur formation (suf) operon, a cell strain lacking IscR, the transcriptional regulator of the ISC machinery, and an engineered "SufFeScient" derivative of BL21(DE3). Our results show that co-expression of a Fe-S biogenesis pathway influences the protein yield and the cluster content of the proteins. The presence of the Fe-S cluster is contributing to correct folding and structural stability of the proteins. In vivo maturation reduces the formation of Fe-S aggregates, which occur frequently when performing chemical reconstitution. Furthermore, we show that the in vivo strategies can be extended to the radical SAM protein ThnB, which was previously only maturated by chemical reconstitution. Our results shed light on the differences of in vitro and in vivo Fe-S cluster maturation and points out the pitfalls of chemical reconstitution.

Fluorescence-Based Kinetic Measurements for RNA-Cleaving DNAzymes.

Studying the catalytic behavior of biocatalysts under different conditions including temperature, buffer conditions, and cofactor concentrations is an important tool to understand their reaction mechanism. We describe two protocols that allow for the investigation of the catalysis of RNA-cleaving DNAzymes. The techniques include the use of FRET-labeled RNA substrates for studying the RNA-cleavage reaction in real-time under high throughput as well as RNA substrates labeled with a fluorescein molecule at the 5' end for gel-based assays. Both methods allow for an accurate determination of rate constants given a reaction model.

Stability and Activity of the 10-23 DNAzyme Under Molecular Crowding Conditions.

DNAzymes are biocatalysts that have been selected in vitro and their function inside cells (in vivo) is extremely low. Thus, almost all studies have been carried out in diluted solutions (in vitro). The cellular presence of molecules such as amino acids, polypeptides, alcohols, and sugars introduces forces that modify the kinetics and thermodynamics of DNAzyme-mediated catalysis. The crowded intracellular environment referred to as molecular crowding can be mimicked by adding high concentrations of natural or synthetic macromolecules to the reaction conditions. Here, we investigate the activity of the 10-23 DNAzyme and the stability of the DNAzyme:RNA complex under molecular crowding conditions. Therefore, we use a Förster resonance energy transfer (FRET)-based activity assay in combination with denaturing urea polyacrylamide gel electrophoresis and circular dichroism (CD) spectroscopy.

Obtaining Crystals of Nucleic Acids in Complex with the Protein U1A Using the Soaking Method.

X-ray crystallography is one of the most prominent techniques for determining high-resolution structures of nucleic acids. The major challenges are to obtain well-diffracting single crystals and to solve the phase problem. The absence of structural information impedes the elucidation of the molecular details of biological processes. A particularly intriguing example is the RNA-cleavage catalyzed by the 10-23 deoxyribozyme (DNAzyme). This DNAzyme consists of a catalytic core that is flanked by two substrate binding arms, which can be designed to bind any RNA of interest. Structure elucidation of the 10-23 DNAzyme in a biologically relevant conformation faces three major challenges: (1) stabilization of the RNA substrate to capture the DNA:RNA complex in the pre-catalytic conformation, (2) prevention of the formation of an artificial duplex conformation due to a self-complementary sequence in the catalytic core of the DNAzyme, and (3) the crystallization of nucleic acids with their uniform surfaces. Here, we provide a protocol for an innovative strategy facilitating the crystallization of protein:nucleic acid complexes using a soaking approach and discuss on how to apply this protocol for the structure elucidation of the 10-23 DNAzyme. For this purpose, we describe the purification procedure of an optimized variant of the RNA-binding protein U1A, the crystallization of this specific U1A variant, the soaking process with its specific RNA hairpin loop, and finally suggest a strategy for applying this procedure on the 10-23 DNAzyme in complex with its specific RNA target.

Time-resolved structural analysis of an RNA-cleaving DNA catalyst.

The 10-23 DNAzyme is one of the most prominent catalytically active DNA sequences1,2. Its ability to cleave a wide range of RNA targets with high selectivity entails a substantial therapeutic and biotechnological potential2. However, the high expectations have not yet been met, a fact that coincides with the lack of high-resolution and time-resolved information about its mode of action3. Here we provide high-resolution NMR characterization of all apparent states of the prototypic 10-23 DNAzyme and present a comprehensive survey of the kinetics and dynamics of its catalytic function. The determined structure and identified metal-ion-binding sites of the precatalytic DNAzyme-RNA complex reveal that the basis of the DNA-mediated catalysis is an interplay among three factors: an unexpected, yet exciting molecular architecture; distinct conformational plasticity; and dynamic modulation by metal ions. We further identify previously hidden rate-limiting transient intermediate states in the DNA-mediated catalytic process via real-time NMR measurements. Using a rationally selected single-atom replacement, we could considerably enhance the performance of the DNAzyme, demonstrating that the acquired knowledge of the molecular structure, its plasticity and the occurrence of long-lived intermediate states constitutes a valuable starting point for the rational design of next-generation DNAzymes.

The Asp1 pyrophosphatase from S. pombe hosts a [2Fe-2S]2+ cluster in vivo.

The Schizosaccharomyces pombe Asp1 protein is a bifunctional kinase/pyrophosphatase that belongs to the highly conserved eukaryotic diphosphoinositol pentakisphosphate kinase PPIP5K/Vip1 family. The N-terminal Asp1 kinase domain generates specific high-energy inositol pyrophosphate (IPP) molecules, which are hydrolyzed by the C-terminal Asp1 pyrophosphatase domain (Asp1365-920). Thus, Asp1 activities regulate the intracellular level of a specific class of IPP molecules, which control a wide number of biological processes ranging from cell morphogenesis to chromosome transmission. Recently, it was shown that chemical reconstitution of Asp1371-920 leads to the formation of a [2Fe-2S] cluster; however, the biological relevance of the cofactor remained under debate. In this study, we provide evidence for the presence of the Fe-S cluster in Asp1365-920 inside the cell. However, we show that the Fe-S cluster does not influence Asp1 pyrophosphatase activity in vitro or in vivo. Characterization of the as-isolated protein by electronic absorption spectroscopy, mass spectrometry, and X-ray absorption spectroscopy is consistent with the presence of a [2Fe-2S]2+ cluster in the enzyme. Furthermore, we have identified the cysteine ligands of the cluster. Overall, our work reveals that Asp1 contains an Fe-S cluster in vivo that is not involved in its pyrophosphatase activity.

Molecular Features and Metal Ions That Influence 10-23 DNAzyme Activity.

Deoxyribozymes (DNAzymes) with RNA hydrolysis activity have a tremendous potential as gene suppression agents for therapeutic applications. The most extensively studied representative is the 10-23 DNAzyme consisting of a catalytic loop and two substrate binding arms that can be designed to bind and cleave the RNA sequence of interest. The RNA substrate is cleaved between central purine and pyrimidine nucleotides. The activity of this DNAzyme in vitro is considerably higher than in vivo, which was suggested to be related to its divalent cation dependency. Understanding the mechanism of DNAzyme catalysis is hindered by the absence of structural information. Numerous biological studies, however, provide comprehensive insights into the role of particular deoxynucleotides and functional groups in DNAzymes. Here we provide an overview of the thermodynamic properties, the impact of nucleobase modifications within the catalytic loop, and the role of different metal ions in catalysis. We point out features that will be helpful in developing novel strategies for structure determination and to understand the mechanism of the 10-23 DNAzyme. Consideration of these features will enable to develop improved strategies for structure determination and to understand the mechanism of the 10-23 DNAzyme. These insights provide the basis for improving activity in cells and pave the way for developing DNAzyme applications.

Expanding crystallization tools for nucleic acid complexes using U1A protein variants.

The major bottlenecks in structure elucidation of nucleic acids are crystallization and phasing. Co-crystallization with proteins is a straight forward approach to overcome these challenges. The human RNA-binding protein U1A has previously been established as crystallization module, however, the absence of UV-active residues and the predetermined architecture in the asymmetric unit constitute clear limitations of the U1A system. Here, we report three crystal structures of tryptophan-containing U1A variants, which expand the crystallization toolbox for nucleic acids. Analysis of the structures complemented by SAXS, NMR spectroscopy, and optical spectroscopy allow for insights into the potential of the U1A variants to serve as crystallization modules for nucleic acids. In addition, we report a fast and efficient protocol for crystallization of RNA by soaking and present a fluorescence-based approach for detecting RNA-binding in crystallo. Our results provide a new tool set for the crystallization of RNA and RNA:DNA complexes.

Influence of monovalent metal ions on metal binding and catalytic activity of the 10-23 DNAzyme.

Deoxyribozymes (DNAzymes) are single-stranded DNA molecules that catalyze a broad range of chemical reactions. The 10-23 DNAzyme catalyzes the cleavage of RNA strands and can be designed to cleave essentially any target RNA, which makes it particularly interesting for therapeutic and biosensing applications. The activity of this DNAzyme in vitro is considerably higher than in cells, which was suggested to be a result of the low intracellular concentration of bioavailable divalent cations. While the interaction of the 10-23 DNAzyme with divalent metal ions was studied extensively, the influence of monovalent metal ions on its activity remains poorly understood. Here, we characterize the influence of monovalent and divalent cations on the 10-23 DNAzyme utilizing functional and biophysical techniques. Our results show that Na+ and K+ affect the binding of divalent metal ions to the DNAzyme:RNA complex and considerably modulate the reaction rates of RNA cleavage. We observe an opposite effect of high levels of Na+ and K+ concentrations on Mg2+- and Mn2+-induced reactions, revealing a different interplay of these metals in catalysis. Based on these findings, we propose a model for the interaction of metal ions with the DNAzyme:RNA complex.