An engineered small RNA-mediated genetic switch based on a ribozyme expression platform

An important requirement for achieving many goals of synthetic biology is the availability of a large repertoire of reprogrammable genetic switches and appropriate transmitter molecules. In addition to engineering genetic switches, the interconnection of individual switches becomes increasingly important for the construction of more complex genetic networks. In particular, RNA-based switches of gene expression have become a powerful tool to post-transcriptionally program genetic circuits. RNAs used for regulatory purposes have the advantage to transmit, sense, process and execute information. We have recently used the hammerhead ribozyme to control translation initiation in a small molecule-dependent fashion. In addition, riboregulators have been constructed in which a small RNA acts as transmitter molecule to control translation of a target mRNA. In this study, we combine both concepts and redesign the hammerhead ribozyme to sense small trans-acting RNAs (taRNAs) as input molecules resulting in repression of translation initiation in Escherichia coli. Importantly, our ribozyme-based expression platform is compatible with previously reported artificial taRNAs, which were reported to act as inducers of gene expression. In addition, we provide several insights into key requirements of riboregulatory systems, including the influences of varying transcriptional induction of the taRNA and mRNA transcripts, 5′-processing of taRNAs, as well as altering the secondary structure of the taRNA. In conclusion, we introduce an RNA-responsive ribozyme-based expression system to the field of artificial riboregulators that can serve as reprogrammable platform for engineering higher-order genetic circuits

Editorial. Les fabriques des "géographies" – making academic geographies in Europe

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Highly motif- and organism-dependent effects of naturally occurring hammerhead ribozyme sequences on gene expression

<p>Recent bioinformatics studies have demonstrated a wide-spread occurrence of the hammerhead ribozyme (HHR) and similar small endonucleolytic RNA motifs in all domains of life. It is becoming increasingly evident that such ribozyme motifs participate in important genetic processes in diverse organisms. Although the HHR motif has been studied for more than three decades, only little is known about the consequences of ribozyme activity on gene expression. In the present study we analysed eight different naturally occurring HHR sequences in diverse genetic and organismal contexts. We investigated the influence of active ribozymes incorporated into mRNAs in mammalian, yeast and bacterial expression systems. The experiments show an unexpectedly high degree of organism-specific variability of ribozyme-mediated effects on gene expression. The presented findings demonstrate that ribozyme cleavage profoundly affect gene expression. However, the extent of this effect varies and depends strongly on the respective genetic context. The fast-cleaving type 3 HHRs [CChMVd(-) and sLTSV(-)] generally tended to cause the strongest effects on intracellular gene expression. The presented results are important in order to address potential functions of naturally occurring ribozymes in RNA processing and post-transcriptional regulation of gene expression. Additionally, our results are of interest for biotechnology and synthetic biology approaches that aim at the utilisation of self-cleaving ribozymes as widely applicable tools for controlling genetic processes.</p

Post-transcriptional Boolean computation by combining aptazymes controlling mRNA translation initiation and tRNA activation

In cellular systems environmental and metabolic signals are integrated for the conditional control of gene expression. On the other hand, artificial manipulation of gene expression is of high interest for metabolic and genetic engineering. Especially the reprogramming of gene expression patterns to orchestrate cellular responses in a predictable fashion is considered to be of great importance. Here we introduce a highly modular RNA-based system for performing Boolean logic computation at a post-transcriptional level in Escherichia coli. We have previously shown that artificial riboswitches can be constructed by utilizing ligand-dependent Hammerhead ribozymes (aptazymes). Employing RNA self-cleavage as the expression platform-mechanism of an artificial riboswitch has the advantage that it can be applied to control several classes of RNAs such as mRNAs, tRNAs, and rRNAs. Due to the highly modular and orthogonal nature of these switches it is possible to combine aptazyme regulation of activating a suppressor tRNA with the regulation of mRNA translation initiation. The different RNA classes can be controlled individually by using distinct aptamers for individual RNA switches. Boolean logic devices are assembled by combining such switches in order to act on the expression of a single mRNA. In order to demonstrate the high modularity, a series of two-input Boolean logic operators were constructed. For this purpose, we expanded our aptazyme toolbox with switches comprising novel behaviours with respect to the small molecule triggers thiamine pyrophosphate (TPP) and theophylline. Then, individual switches were combined to yield AND, NOR, and ANDNOT gates. This study demonstrates that post-transcriptional aptazyme-based switches represent versatile tools for engineering advanced genetic devices and circuits without the need for regulatory protein cofactors

Riboswitch-mediated Attenuation of Transgene Cytotoxicity Increases Adeno-associated Virus Vector Yields in HEK-293 Cells

Cytotoxicity of transgenes carried by adeno-associated virus (AAV) vectors might be desired, for instance, in oncolytic virotherapy or occur unexpectedly in exploratory research when studying sparsely characterized genes. To date, most AAV-based studies use constitutively active promoters (e.g., the CMV promoter) to drive transgene expression, which often hampers efficient AAV production due to cytotoxic, antiproliferative, or unknown transgene effects interfering with producer cell performance. Therefore, we explored artificial riboswitches as novel tools to control transgene expression during AAV production in mammalian cells. Our results demonstrate that the guanine-responsive GuaM8HDV aptazyme efficiently attenuates transgene expression and associated detrimental effects, thereby boosting AAV vector yields up to 23-fold after a single addition of guanine. Importantly, riboswitch-harboring vectors preserved their ability to express functional transgene at high levels in the absence of ligand, as demonstrated in a mouse model of AAV-TGFβ1-induced pulmonary fibrosis. Thus, our study provides the first application-ready biotechnological system-based on aptazymes, which should enable high viral vector yields largely independent of the transgene used. Moreover, the RNA-intrinsic, small-molecule regulatable mode of action of riboswitches provides key advantages over conventional transcription factor-based regulatory systems. Therefore, such riboswitch vectors might be ultimately applied to temporally control therapeutic transgene expression in vivo.publishe

Ribozyme-Based Aminoglycoside Switches of Gene Expression Engineered by Genetic Selection in <i>S. cerevisiae</i>

Systems for conditional gene expression are powerful tools in basic research as well as in biotechnology. For future applications, it is of great importance to engineer orthogonal genetic switches that function reliably in diverse contexts. RNA-based switches have the advantage that effector molecules interact immediately with regulatory modules inserted into the target RNAs, getting rid of the need of transcription factors usually mediating genetic control. Artificial riboswitches are characterized by their simplicity and small size accompanied by a high degree of modularity. We have recently reported a series of hammerhead ribozyme-based artificial riboswitches that allow for post-transcriptional regulation of gene expression via switching mRNA, tRNA, or rRNA functions. A more widespread application was so far hampered by moderate switching performances and a limited set of effector molecules available. Here, we report the re-engineering of hammerhead ribozymes in order to respond efficiently to aminoglycoside antibiotics. We first established an <i>in vivo</i> selection protocol in <i>Saccharomyces cerevisiae</i> that enabled us to search large sequence spaces for optimized switches. We then envisioned and characterized a novel strategy of attaching the aptamer to the ribozyme catalytic core, increasing the design options for rendering the ribozyme ligand-dependent. These innovations enabled the development of neomycin-dependent RNA modules that switch gene expression up to 25-fold. The presented aminoglycoside-responsive riboswitches belong to the best-performing RNA-based genetic regulators reported so far. The developed <i>in vivo</i> selection protocol should allow for sampling of large sequence spaces for engineering of further optimized riboswitches

Uropathogenic E. coli Exploit CEA to Promote Colonization of the Urogenital Tract Mucosa

Attachment to the host mucosa is a key step in bacterial pathogenesis. On the apical surface of epithelial cells, members of the human carcinoembryonic antigen (CEA) family are abundant glycoproteins involved in cell-cell adhesion and modulation of cell signaling. Interestingly, several gram-negative bacterial pathogens target these receptors by specialized adhesins. The prototype of a CEACAM-binding pathogen, Neisseria gonorrhoeae, utilizes colony opacity associated (Opa) proteins to engage CEA, as well as the CEA-related cell adhesion molecules CEACAM1 and CEACAM6 on human epithelial cells. By heterologous expression of neisserial Opa proteins in non-pathogenic E. coli we find that the Opa protein-CEA interaction is sufficient to alter gene expression, to increase integrin activity and to promote matrix adhesion of infected cervical carcinoma cells and immortalized vaginal epithelial cells in vitro. These CEA-triggered events translate in suppression of exfoliation and improved colonization of the urogenital tract by Opa protein-expressing E. coli in CEA-transgenic compared to wildtype mice. Interestingly, uropathogenic E. coli expressing an unrelated CEACAM-binding protein of the Afa/Dr adhesin family recapitulate the in vitro and in vivo phenotype. In contrast, an isogenic strain lacking the CEACAM-binding adhesin shows reduced colonization and does not suppress epithelial exfoliation. These results demonstrate that engagement of human CEACAMs by distinct bacterial adhesins is sufficient to blunt exfoliation and to promote host infection. Our findings provide novel insight into mucosal colonization by a common UPEC pathotype and help to explain why human CEACAMs are a preferred epithelial target structure for diverse gram-negative bacteria to establish a foothold on the human mucosa.publishe

The interaction of <i>E</i>. <i>coli</i> Opa_CEA with CEA facilitates mucosal colonization and leads to CD105 expression in epithelial cells.

<p><i>(A)</i> Wild-type (●) or CEAtg (▼) female mice were infected with the indicated bacterial strains and 24 h later, bacteria were re-isolated. Each data point in the graph reflects the number of bacteria re-isolated from an individual animal (n = 10; except for CEAtg animals infected with <i>E</i>. <i>coli</i> Opa_CEA, where n = 15). Data were compiled from four independent experiments. The median for each experimental group of animals is indicated by a line; groups were compared by Mann-Whitney U-test and highly significant differences (p<0.001) are indicated by ***. <i>(B)</i> Individual re-isolated bacterial colonies from the genital tract of CEAtg mice infected with either <i>E</i>. <i>coli</i> or <i>E</i>. <i>coli</i> Opa_CEA were plated on LB-ampicillin agar plates (post infection). Five isolates for each strain were analysed by Western blotting with an antibody against Opa protein. As a control, lysates of the <i>E</i>. <i>coli</i> or <i>E</i>. <i>coli</i> Opa_CEA used for infection (input) were also analysed. <i>(C)</i> Genital tracts from CEAtg mice infected for 24 hours with <i>E</i>. <i>coli</i> or <i>E</i>. <i>coli</i> Opa_CEA were excised, and cryosections were co-stained with antibodies against <i>E</i>. <i>coli</i> (green) and against CEA (red). Cell nuclei were stained with Hoechst dye (blue). Arrowheads indicate host-associated <i>E</i>. <i>coli</i>. Pictures are representative for three independent biological replicates. <i>(D)</i> Cryosections as in (C) were co-stained with antibodies against <i>E</i>. <i>coli</i> (green) and a rat monoclonal antibody against murine CD105 (red). Cell nuclei were visualized by Hoechst (blue). CD105 expression on the mucosal surface of CEAtg mice infected with <i>E</i>. <i>coli</i> Opa_CEA is highlighted by small arrows. Pictures are representative for three independent biological replicates.</p