Tunable self-cleaving ribozymes for modulating gene expression in eukaryotic systems.

Advancements in the field of synthetic biology have been possible due to the development of genetic tools that are able to regulate gene expression. However, the current toolbox of gene regulatory tools for eukaryotic systems have been outpaced by those developed for simple, single-celled systems. Here, we engineered a set of gene regulatory tools by combining self-cleaving ribozymes with various upstream competing sequences that were designed to disrupt ribozyme self-cleavage. As a proof-of-concept, we were able to modulate GFP expression in mammalian cells, and then showed the feasibility of these tools in Drosophila embryos. For each system, the fold-reduction of gene expression was influenced by the location of the self-cleaving ribozyme/upstream competing sequence (i.e. 5' vs. 3' untranslated region) and the competing sequence used. Together, this work provides a set of genetic tools that can be used to tune gene expression across various eukaryotic systems.

The Role of Reverse Transcriptase in the Origin of Life.

It has been suggested that RNA polymerase ribozyme displaying reverse transcriptase and integrase activities has played a vital role in the origin of life on Earth. Here, we present a hypothesis that formation of universal ancestral units of all living organisms - retroelements - in the evolution was mediated by reverse transcriptase. The propensity of retroelements to mutations and their insertion capacity have formed a basis for the origin of complex DNA structures - primary genomes - that have given rise to archaea, eukaryotes, bacteria, and viruses. Conserved properties of retroelements have been preserved throughout the evolution; their modifications have facilitated the emergence of mechanisms for the interactions between proteins and nucleic acids. Life has evolved due to insertional mutagenesis and competition of autonomously replicating polynucleotides that allowed to preserve structures with adaptive properties. We hypothesize that natural selection of mechanisms for the defense against insertions based on the ribonuclease activity of reverse transcriptase ribozyme has led to the emergence of all universal enzymatic systems for the processing of RNA molecules. These systems have been and still remain the key sources of structural and functional transformations of genomes in the course of evolution. The data presented in this review suggest that the process of translation, which unifies the nucleic acid and protein worlds, has developed as a modification of the defense mechanisms against insertions. Polypeptides formed by this defense system have potentiated the activity of ribozymes in the composition of ribonucleoproteins (RNPs) and even functionally replaced them as more efficient catalysts of biological reactions. Here, we analyze the mechanisms of retroelement involvement in the structural and regulatory transformations of eukaryotic genomes supposedly reflecting the adaptive principles that had originated during the beginning of life on Earth. Simultaneously with the evolution of existing proteins, retroelements have served as sources of new ribozymes, such as long non-coding RNAs. These ribozymes can function in complexes with proteins in the composition of RNPs, as well as display independent catalytic and translational activities; their genes have a potential for the transformation into protein-coding genes. Hence, the conserved principles of RNA, DNA, and proteins interregulation formed at the time of life origin on Earth have been used throughout the evolution.

Massively parallel RNA device engineering in mammalian cells with RNA-Seq.

Synthetic RNA-based genetic devices dynamically control a wide range of gene-regulatory processes across diverse cell types. However, the limited throughput of quantitative assays in mammalian cells has hindered fast iteration and interrogation of sequence space needed to identify new RNA devices. Here we report developing a quantitative, rapid and high-throughput mammalian cell-based RNA-Seq assay to efficiently engineer RNA devices. We identify new ribozyme-based RNA devices that respond to theophylline, hypoxanthine, cyclic-di-GMP, and folinic acid from libraries of ~22,700 sequences in total. The small molecule responsive devices exhibit low basal expression and high activation ratios, significantly expanding our toolset of highly functional ribozyme switches. The large datasets obtained further provide conserved sequence and structure motifs that may be used for rationally guided design. The RNA-Seq approach offers a generally applicable strategy for developing broad classes of RNA devices, thereby advancing the engineering of genetic devices for mammalian systems.

In search of a primitive signaling code.

Cells must have preceded by simpler chemical systems (protocells) that had the capacity of a spontaneous self-assembly process and the ability to confine chemical reaction networks together with a form of information. The presence of lipid molecules in the early Earth conditions is sufficient to ensure the occurrence of spontaneous self-assembly processes, not defined by genetic information, but related to their chemical amphiphilic nature. Ribozymes are plausible molecules for early life, being the first small polynucleotides made up of random oligomers or formed by non-enzymatic template copying. Compartmentalization represents a strategy for the evolution of ribozymes; the attachment of ribozymes to surfaces, such as formed by lipid micellar aggregates may be particular relevant if the surface itself catalyzes RNA polymerization.It is conceivable that the transition from pre-biotic molecular aggregates to cellular life required the coevolution of the RNA world, capable of synthesizing specific, instead of statistical proteins, and of the Lipid world, with a transition from micellar aggregates to semipermeable vesicles. Small molecules available in the prebiotic inventory might promote RNA stability and the evolution of hydrophobic micellar aggregates into membrane-delimited vesicles. The transition from ribozymes catalyzing the assembly of statistical polypeptides to the synthesis of proteins, required the appearance of the genetic code; the transition from hydrophobic platforms favoring the stability of ribozymes and of nascent polypeptides to the selective transport of reagents through a membrane, required the appearance of the signal transduction code.A further integration between the RNA and Lipid worlds can be advanced, taking into account the emerging roles of phospholipid aggregates not only in ensuring stability to ribozymes by compartmentalization, but also in a crucial step of evolution through natural selection mechanisms, based on signal transduction pathways that convert environmental changes into biochemical responses that could vary according to the context. Here I present evidences on the presence of traces of the evolution of a signal transduction system in extant cells, which utilize a phosphoinositide signaling system located both at nucleoplasmic level as well as at the plasma membrane, based on the very same molecules but responding to different rules. The model herewith proposed is based on the following assumptions on the biomolecules of extant organisms: i) amphiphils can be converted into structured aggregates by hydrophobic forces thus giving rise to functional platforms for the interaction of other biomolecules and to their compartmentalization; ii) fundamental biochemical pathways, including protein synthesis, can be sustained by natural ribozymes of ancient origin; iii) ribozymes and nucleotide-derived coenzymes could have existed long before protein enzymes emerged; iv) signaling molecules, both derived from phospholipids and from RNAs could have guided the evolution of complex metabolic processes before the emergence of proteins.

Optimal molecular crowding accelerates group II intron folding and maximizes catalysis.

Unlike in vivo conditions, group II intron ribozymes are known to require high magnesium(II) concentrations ([Mg2+]) and high temperatures (42 °C) for folding and catalysis in vitro. A possible explanation for this difference is the highly crowded cellular environment, which can be mimicked in vitro by macromolecular crowding agents. Here, we combined bulk activity assays and single-molecule Förster Resonance Energy Transfer (smFRET) to study the influence of polyethylene glycol (PEG) on catalysis and folding of the ribozyme. Our activity studies reveal that PEG reduces the [Mg2+] required, and we found an "optimum" [PEG] that yields maximum activity. smFRET experiments show that the most compact state population, the putative active state, increases with increasing [PEG]. Dynamic transitions between folded states also increase. Therefore, this study shows that optimal molecular crowding concentrations help the ribozyme not only to reach the native fold but also to increase its in vitro activity to approach that in physiological conditions.

Oligomerization of a Bimolecular Ribozyme Modestly Rescues its Structural Defects that Disturb Interdomain Assembly to Form the Catalytic Site.

The emergence of cellular compartmentalization was a crucial step in the hypothetical RNA world and its evolution because it would not only prevent the extinction of RNA self-replication systems due to dispersion/diffusion of their components but also facilitate ribozyme reactions by molecular crowding effects. Here, we proposed and examined self-assembly of RNA components as a primitive cellular-like environment, which may have the ability to mimic cellular compartmentalization and crowding effects. We engineered a bimolecular group I ribozyme to form a one-dimensional (1D)-ribozyme assembly. In the 1D assembly form, severe mutations that inactivated the parent bimolecular ribozyme were modestly rescued resulting in weak catalytic ability.

Cotranscriptional 3'-End Processing of T7 RNA Polymerase Transcripts by a Smaller HDV Ribozyme.

In vitro run-off transcription by T7 RNA polymerase generates heterogeneous 3'-ends because the enzyme tends to add untemplated adenylates. To generate homogeneous 3'-termini, HDV ribozymes have been used widely. Their sequences are added to the 3'-terminus such that co-transcriptional self-cleavage generates homogeneous 3'-ends. A shorter HDV sequence that cleaves itself efficiently would be advantageous. Here we show that a recently discovered, small HDV ribozyme is a good alternative to the previously used HDV ribozyme. The new HDV ribozyme is more efficient in some sequence contexts, and less efficient in other sequence contexts than the previously used HDV ribozyme. The smaller size makes the new HDV ribozyme a good alternative for transcript 3'-end processing.

[Structure and function of c-di-GMP riboswitches].

Cyclic diguanosine monophosphate (c-di-GMP) is a ubiquitous nucleotide second messenger present in a wide variety of bacteria. It regulates many important bacterial physiological functions such as biofilm formation, motility, adhesion, virulence and extracellular polysaccharide synthesis. It binds with many different proteins or RNA receptors, one of which is called riboswitch that is usually located at the 5'-untranslational region (5'-UTR) in some mRNA. Riboswitch usually comprises a specific ligand-binding (sensor) domain (named aptamer domain, AD), as well as a variable domain, termed expression platform (EP), to regulate expression of downstream coding sequences. When a specific metabolite concentration exceeds its threshold level, it will bind to its cognate riboswitch receptor to induce a conformational change of 5'-UTR, leading to modulation of downstream gene expression. Two classes of c-di-GMP-binding riboswitches (c-di-GMP-Ⅰ and c-di-GMP-Ⅱ) have been discovered that bind with this second messenger with high affinity to regulate diverse downstream genes, underscoring the importance of this unique RNA receptor in this pathway. Class Ⅰ c-di-GMP riboswitches are present in a wide variety of bacteria, and are most common in the phyla Firmicutes and Proteobacteria, while class Ⅱ c-di-GMP riboswitches typically function as allosteric ribozymes, binding to c-di-GMP to induce folding changes at atypical splicing site junctions to modulate downstream gene expression. This review introduces the discovery, classification, function, and also the affected downstream genes of c-di-GMP riboswitches.

The Hammerhead Ribozyme: A Long History for a Short RNA.

Small nucleolytic ribozymes are a family of naturally occurring RNA motifs that catalyse a self-transesterification reaction in a highly sequence-specific manner. The hammerhead ribozyme was the first reported and the most extensively studied member of this family. However, and despite intense biochemical and structural research for three decades since its discovery, the history of this model ribozyme seems to be far from finished. The hammerhead ribozyme has been regarded as a biological oddity typical of small circular RNA pathogens of plants. More recently, numerous and new variations of this ribozyme have been found to inhabit the genomes of organisms from all life kingdoms, although their precise biological functions are not yet well understood.

Dead element replicating: degenerate R2 element replication and rDNA genomic turnover in the Bacillus rossius stick insect (Insecta: Phasmida).

R2 is an extensively investigated non-LTR retrotransposon that specifically inserts into the 28S rRNA gene sequences of a wide range of metazoans, disrupting its functionality. During R2 integration, first strand synthesis can be incomplete so that 5' end deleted copies are occasionally inserted. While active R2 copies repopulate the locus by retrotransposing, the non-functional truncated elements should frequently be eliminated by molecular drive processes leading to the concerted evolution of the rDNA array(s). Although, multiple R2 lineages have been discovered in the genome of many animals, the rDNA of the stick insect Bacillus rossius exhibits a peculiar situation: it harbors both a canonical, functional R2 element (R2Brfun) as well as a full-length but degenerate element (R2Brdeg). An intensive sequencing survey in the present study reveals that all truncated variants in stick insects are present in multiple copies suggesting they were duplicated by unequal recombination. Sequencing results also demonstrate that all R2Brdeg copies are full-length, i. e. they have no associated 5' end deletions, and functional assays indicate they have lost the active ribozyme necessary for R2 RNA maturation. Although it cannot be completely ruled out, it seems unlikely that the degenerate elements replicate via reverse transcription, exploiting the R2Brfun element enzymatic machinery, but rather via genomic amplification of inserted 28S by unequal recombination. That inactive copies (both R2Brdeg or 5'-truncated elements) are not eliminated in a short term in stick insects contrasts with findings for the Drosophila R2, suggesting a widely different management of rDNA loci and a lower efficiency of the molecular drive while achieving the concerted evolution.

Looking at LncRNAs with the ribozyme toolkit.

A diverse population of large RNA molecules controls every aspect of cellular function, and yet we know very little about their molecular structures. However, robust technologies developed for visualizing ribozymes and riboswitches, together with new approaches for mapping RNA inside cells, provide the foundation for visualizing the structures of long noncoding RNAs, mRNAs, and viral RNAs, thereby facilitating new mechanistic insights.

Inhibition by polyamines of the hammerhead ribozyme from a Chrysanthemum chlorotic mottle viroid.

BACKGROUND: Viroids are the smallest pathogens known to date. They infect plants and cause considerable economic losses. The members of the Avsunviroidae family are known for their capability to form hammerhead ribozymes (HHR) that catalyze self-cleavage during their rolling circle replication. METHODS: In vitro inhibition assays, based on the self-cleavage kinetics of the hammerhead ribozyme from a Chrysanthemum chlorotic mottle viroid (CChMVd-HHR) were performed in the presence of various putative inhibitors. RESULTS: Aminated compounds appear to be inhibitors of the self-cleavage activity of the CChMVd HHR. Surprisingly the spermine, a known activator of the autocatalytic activity of another hammerhead ribozyme in the presence or absence of divalent cations, is a potent inhibitor of the CChMVd-HHR with Ki of 17±5µM. Ruthenium hexamine and TMPyP4 are also efficient inhibitors with Ki of 32±5µM and IC50 of 177±5nM, respectively. CONCLUSIONS: This study shows that polyamines are inhibitors of the CChMVd-HHR self-cleavage activity, with an efficiency that increases with the number of their amino groups. GENERAL SIGNIFICANCE: This fundamental investigation is of interest in understanding the catalytic activity of HHR as it is now known that HHR are present in the three domains of life including in the human genome. In addition these results emphasize again the remarkable plasticity and adaptability of ribozymes, a property which might have played a role in the early developments of life and must be also of significance nowadays for the multiple functions played by non-coding RNAs.

Molecular crowding favors reactivity of a human ribozyme under physiological ionic conditions.

In an effort to relate RNA folding to function under cellular-like conditions, we monitored the self-cleavage reaction of the human hepatitis delta virus-like CPEB3 ribozyme in the background of physiological ionic concentrations and various crowding and cosolute agents. We found that at physiological free Mg(2+) concentrations (∼0.1-0.5 mM), both crowders and cosolutes stimulate the rate of self-cleavage, up to ∼6-fold, but that in 10 mM Mg(2+) (conditions widely used for in vitro ribozyme studies) these same additives have virtually no effect on the self-cleavage rate. We further observe a dependence of the self-cleavage rate on crowder size, wherein the level of rate stimulation is diminished for crowders larger than the size of the unfolded RNA. Monitoring effects of crowding and cosolute agents on rates in biological amounts of urea revealed additive-promoted increases at both low and high Mg(2+) concentrations, with a maximal stimulation of more than 10-fold and a rescue of the rate to its urea-free values. Small-angle X-ray scattering experiments reveal a structural basis for this stimulation in that higher-molecular weight crowding agents favor a more compact form of the ribozyme in 0.5 mM Mg(2+) that is essentially equivalent to the form under standard ribozyme conditions of 10 mM Mg(2+) without a crowder. This finding suggests that at least a portion of the rate enhancement arises from favoring the native RNA tertiary structure. We conclude that cellular-like crowding supports ribozyme reactivity by favoring a compact form of the ribozyme, but only under physiological ionic and cosolute conditions.

Interleukin-1ß-induced barrier dysfunction is signaled through PKC-θ in human brain microvascular endothelium.

Blood-brain barrier dysfunction is a serious consequence of inflammatory brain diseases, cerebral infections, and trauma. The proinflammatory cytokine interleukin (IL)-1ß is central to neuroinflammation and contributes to brain microvascular leakage and edema formation. Although it is well known that IL-1ß exposure directly induces hyperpermeability in brain microvascular endothelium, the molecular mechanisms mediating this response are not completely understood. In the present study, we found that exposure of the human brain microvascular endothelium to IL-1ß triggered activation of novel PKC isoforms δ, µ, and θ, followed by decreased transendothelial electrical resistance (TER). The IL-1ß-induced decrease in TER was prevented by small hairpin RNA silencing of PKC-θ or by treatment with the isoform-selective PKC inhibitor Gö6976 but not by PKC inhibitors that are selective for all PKC isoforms other than PKC-θ. Decreased TER coincided with increased phosphorylation of regulatory myosin light chain and with increased proapoptotic signaling indicated by decreased uptake of mitotracker red in response to IL-1ß treatment. However, neither of these observed effects were prevented by Gö6976 treatment, indicating lack of causality with respect to decreased TER. Instead, our data indicated that the mechanism of decreased TER involves PKC-θ-dependent phosphorylation of the tight junction protein zona occludens (ZO)-1. Because IL-1ß is a central inflammatory mediator, our interpretation is that inhibition of PKC-θ or inhibition of ZO-1 phosphorylation could be viable strategies for preventing blood-brain barrier dysfunction under a variety of neuroinflammatory conditions.

Engineering of ribozyme-based riboswitches for mammalian cells.

Artificial RNA riboswitches--apart from protein-based gene regulation systems, which have been known about for a long time--have become increasingly important in biotechnology and synthetic biology. Aptamer-controlled hammerhead ribozymes (so-called aptazymes) have been shown to be a versatile platform for the engineering of novel gene regulators. Since aptazymes are cis-acting elements that are located in the untranslated regions of a gene of interest, their application does not need any further protein co-factor. This presents the opportunity to simplify complex gene networks while simultaneously expanding the repertoire of available parts. Nevertheless, the generation of novel aptazymes requires a functional aptamer-ribozyme connection, which can be difficult to engineer. This article describes a novel approach for using fluorescence activated cell sorting (FACS) in order to identify functional aptazymes in bacteria and their subsequent transfer into mammalian cells.

The biochemical roots of the RNA world: from zymonucleic acid to ribozymes.

The history of the ideas that led to the RNA World hypothesis is reviewed. As the understanding of the properties of RNA molecules progressed, the evolutionary interpretation of their genetic properties and widespread distribution in intracellular environments, as well as the catalytic properties of nucleotide coenzymes and the participation of RNA monomers in metabolic pathways, led to several independent proposals of protein-free primordial life forms. Current ideas on the RNA World are part of a long and storied scientific perspective in which these different hypotheses were developed. However, the lack of continuity between them may be explained in part by the absence of an evolutionary framework that characterized the early development of molecular biology, as well as by the demise of certain areas of research like coenzyme chemistry.

Prospects for riboswitch discovery and analysis.

An expanding number of metabolite-binding riboswitch classes are being discovered in the noncoding portions of bacterial genomes. Findings over the last decade indicate that bacteria commonly use these RNA genetic elements as regulators of metabolic pathways and as mediators of changes in cell physiology. Some riboswitches are surprisingly complex, and they rival protein factors in their structural and functional sophistication. Each new riboswitch discovery expands our knowledge of the biochemical capabilities of RNA, and some give rise to new questions that require additional study to be addressed. Some of the greatest prospects for riboswitch research and some of the more interesting mysteries are discussed in this review.

The structural basis of RNA-catalyzed RNA polymerization.

Early life presumably required polymerase ribozymes capable of replicating RNA. Known polymerase ribozymes best approximating such replicases use as their catalytic engine an RNA-ligase ribozyme originally selected from random RNA sequences. Here we report 3.15-Å crystal structures of this ligase trapped in catalytically viable preligation states, with the 3'-hydroxyl nucleophile positioned for in-line attack on the 5'-triphosphate. Guided by metal- and solvent-mediated interactions, the 5'-triphosphate hooks into the major groove of the adjoining RNA duplex in an unanticipated conformation. Two phosphates and the nucleophile jointly coordinate an active-site metal ion. Atomic mutagenesis experiments demonstrate that active-site nucleobase and hydroxyl groups also participate directly in catalysis, collectively playing a role that in proteinaceous polymerases is performed by a second metal ion. Thus artificial ribozymes can use complex catalytic strategies that differ markedly from those of analogous biological enzymes.