Synthetic riboswitches mediating ligand-dependent RNA cleavage or splicing-modulation represent elegant tools to control gene expression in various applications, including nextgeneration gene therapy. However, due to the limited understanding of context-dependent structure-function relationships, the identification of functional riboswitches requires largescale-screening of aptamer-effector-domain designs, which is hampered by the lack of suitable cellular high-throughput methods. Here we describe a fast and broadly applicable method to functionally screen complex riboswitch libraries (~1.8 × 10 4 constructs) by cDNAamplicon-sequencing in transiently transfected and stimulated human cells. The selfbarcoding nature of each construct enables quantification of differential mRNA levels without additional pre-selection or cDNA-manipulation steps. We apply this method to engineer tetracycline-and guanine-responsive ON-and OFF-switches based on hammerhead, hepatitis-delta-virus and Twister ribozymes as well as U1-snRNP polyadenylation-dependent RNA devices. In summary, our method enables fast and efficient high-throughput riboswitch identification, thereby overcoming a major hurdle in the development cascade for therapeutically applicable gene switches.
Artificial riboswitches based on ribozymes serve as versatile tools for ligand-dependent gene expression regulation. Advantages of these so-called aptazymes are their modular architecture and the comparably little coding space they require. A variety of aptamer-ribozyme combinations were constructed in the past 20 years and the resulting aptazymes were applied in diverse contexts in prokaryotic and eukaryotic systems. Most in vivo functional aptazymes are OFF-switches, while ON-switches are more advantageous regarding potential applications in e.g. gene therapy vectors. We developed new ON-switching aptazymes in the model organism Escherichia coli and in mammalian cell culture using the intensely studied guanine-sensing xpt aptamer. Utilizing a high-throughput screening based on fluorescence-activated cell sorting in bacteria we identified up to 9.2-fold ON-switches and OFF-switches with a dynamic range up to 32.7-fold. For constructing ON-switches in HeLa cells, we used a rational design approach based on existing tetracycline-sensitive ON-switches. We discovered that communication modules responding to tetracycline are also functional in the context of guanine aptazymes, demonstrating a high degree of modularity. Here, guanine-responsive ON-switches with a four-fold dynamic range were designed. Summarizing, we introduce a series of novel guanine-dependent ribozyme switches operative in bacteria and human cell culture that significantly broaden the existing toolbox.
Small aptamer-based regulatory devices can be designed to control
a range of RNA-dependent cellular processes and emerged as promising
tools for fine-tuning gene expression in synthetic biology. Here,
we design a conceptually new riboswitch device that allows for the
conditional regulation of polyadenylation. By making use of ligand-induced
sequence occlusion, the system efficiently controls the accessibility
of the eukaryotic polyadenylation signal. Undesirable 3′-extended
read-through products are counteracted by the downstream insertion
of a microRNA target site. We demonstrate the modularity of the system
with regard to sensor aptamers and polyadenylation signals used and
combine the newly designed riboswitch with well-known aptazymes to
yield superior composite systems. In addition, we show that the switches
can be used to control alternative polyadenylation. The presented
genetic switches require very little coding space and can be easily
optimized by rational adjustments of the thermodynamic stability.
The polyadenylation riboswitch extends the repertoire of RNA-based
regulators and opens new possibilities for the generation of complex
synthetic circuits.
RNA-based gene control mechanisms pose an elegant and straightforward way to switch on, off, or fine-tune transgene expression without the need for expressing regulatory proteins. A small molecule effector binds directly to a ligand-binding aptamer RNA structure and thereby modulates expression of an associated target gene. We established genetic switches based on regulation of self-cleaving ribozymes and polyadenylation that allow for control of transgene expression in bacteria, yeast, human cell lines and Caenorhabditis elegans in a robust and dose-dependent manner.
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