Artificial cells
that encapsulate DNA-programmable protein expression
machinery are emerging as an attractive platform for studying fundamental
cellular properties and applications in synthetic biology. However,
interfacing these artificial cells with the complex and dynamic chemical
environment remains a major and urgent challenge. We demonstrate that
the repertoire of molecules that artificial cells respond to can be
expanded by synthetic RNA-based gene switches, or riboswitches. We
isolated an RNA aptamer that binds histamine with high affinity and
specificity and used it to design robust riboswitches that activate
protein expression in the presence of histamine. Finally, the riboswitches
were incorporated in artificial cells to achieve controlled release
of an encapsulated small molecule and to implement a self-destructive
kill-switch. Synthetic riboswitches should serve as modular and versatile
interfaces to link artificial cell phenotypes with the complex chemical
environment.
Recent discoveries of new classes of self‐cleaving ribozymes in diverse organisms have triggered renewed interest in the chemistry and biology of ribozymes. Functional analysis and engineering of ribozymes often involve performing biochemical assays on multiple ribozyme mutants. However, because each ribozyme mutant must be individually prepared and assayed, the number and variety of mutants that can be studied are severely limited. All of the single and double mutants of a twister ribozyme (a total of 10 296 mutants) were generated and assayed for their self‐cleaving activity by exploiting deep sequencing to count the numbers of cleaved and uncleaved sequences for every mutant. Interestingly, we found that the ribozyme is highly robust against mutations such that 71 % and 30 % of all single and double mutants, respectively, retain detectable activity under the assay conditions. It was also observed that the structural elements that comprise the ribozyme exhibit distinct sensitivity to mutations.
Self-cleaving ribozymes are found in all domains of life and are believed to play important roles in biology. Additionally, self-cleaving ribozymes have been the subject of extensive engineering efforts for applications in synthetic biology. These studies often involve laborious assays of multiple individual variants that are either designed rationally or discovered through selection or screening. However, these assays provide only a limited view of the large sequence space relevant to the ribozyme function. Here, we report a strategy that allows quantitative characterization of greater than 1000 ribozyme variants in a single experiment. We generated a library of predefined ribozyme variants that were converted to DNA and analyzed by high-throughput sequencing. By counting the number of cleaved and uncleaved reads of every variant in the library, we obtained a complete activity profile of the ribozyme pool which was used to both analyze and engineer allosteric ribozymes.
Chemically regulated self-cleaving ribozymes, or aptazymes, are emerging as a promising class of genetic devices that allow dynamic control of gene expression in synthetic biology. However, further expansion of the limited repertoire of ribozymes and aptamers, and development of new strategies to couple the RNA elements to engineer functional aptazymes are highly desirable for synthetic biology applications. Here, we report aptazymes based on the recently identified self-cleaving pistol ribozyme class using a guanine aptamer as the molecular sensing element. Two aptazyme architectures were studied by constructing and assaying 17 728 mutants by deep sequencing. Although one of the architectures did not yield functional aptazymes, a novel aptazyme design in which the aptamer and the ribozyme were placed in tandem yielded a number of guanine-inhibited ribozymes. Detailed analysis of the extensive sequence-function data suggests a mechanism that involves a competition between two mutually exclusive RNA structures reminiscent of natural bacterial riboswitches.
We introduced a positive feedback loop into a LacI-dependent gene expression system in lipid vesicles, producing a cell-like system that senses and responds to an external signal with a high signal-to-noise ratio. This fully reconstituted system will be a useful tool in future applications in in vitro synthetic biology.
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