Bottleneck/Challenge: Difficulties in designing RNAs that are stable and robustly fold into desired structures needed for strand displacement within the cell.

Potential Solution: Identification of new RNA-protecting motifs compatible with strand displacement.

Potential Solution: Development and use of RNA-targeting CRISPR nucleases (e.g., dCas13a) for site-specific modification of RNA bases to enhance stability.

Potential Solution: Development of alternative, strand-displacement motifs that are more compatible with the cellular context.

Potential Solution: Further advances of in-cell structure probing techniques to inform design principles for RNA strand displacement regulators.

Potential Solution: Evolutionary optimization using RNA-targeting CRISPR systems to activate mRNAs or regulatory outputs to activate gene expression for selection.

Bottleneck/Challenge: Cellular RNA cascades require large concentration ratios to be effective.

Potential Solution: Design and implement RNA cascades that leverage catalytic interactions.

Potential Solution: Develop design rules to integrate the components of current multi-strand cascades into a single strand.

Bottleneck/Challenge: Cellular RNAs can have high secondary structures that make them challenging to use as inputs for strand displacement cascades.

Potential Solution: Implement RNA signal transducers that modify cellular RNA structures to be compatible.

Bottleneck/Challenge: Filling gaps in RNA parts and their performance. There remains a high level of discrepancy in RNA part performance, particularly across different cell types and in the context of intracellular conditions. For example, dynamic range (On/Off state function) is a critical parameter for gene regulators that determines the stringency of control and their utility for constructing gene networks but varies in different contexts for many existing parts.

Potential Solution: Creation of high-performing RNA parts explicitly characterized for robustness and engineered and tested at magnesium concentrations that are physiologically relevant for intracellular use.

Bottleneck/Challenge: Eukaryotic RNAs are subject to more complex regulation and are subject to additional processing (e.g., nuclear transport, capping, polyadenylation, splicing, microRNA pathways).

Potential Solution: Develop the equivalent of compact and simplified bacterial RNA regulators that distill the complexity of these interactions to function robustly in mammalian systems.

Bottleneck/Challenge: RNA concentrations in eukaryotic cells are lower than those in prokaryotic cells and reduce RNA-RNA interactions.

Potential Solution: Implement RNA strand displacement cascades using RNAs that are confined to the nucleus or that are tagged to remain in the nucleus.

Potential Solution: Make use of catalytic RNA systems as described above.

Bottleneck/Challenge: The most sophisticated strand-displacement architectures require reversible interactions for error correction.

Potential Solution: Leverage existing architectures by implementing strand displacement that allow reversible interactions, or develop a new strand-displacement architecture that is amenable to cellular requirements.

Bottleneck/Challenge: Strand-displacement neural networks require precise control over the relative stoichiometry of strands in the network.

Potential Solution: Develop methods to encode the complete strand-displacement RNA network in a single strand of RNA.

Bottleneck/Challenge: Signal conditioning methods are required in the propagating cascade for proper network function.

Potential Solution: Engineer methods of RNA signal thresholding and amplification required for signal conditioning.

Bottleneck/Challenge: Methods implemented for encoding RNA strand-displacement networks in bacteria may no longer function in mammalian cells.

Potential Solution: Adopt RNA network encoding that is specific to mammalian cells that accommodates differences in RNA processing, polyadenylation, and potential changes in ribozyme activity.

Bottleneck/Challenge: Lower concentrations of RNAs in mammalian cells prevents proper network function.

Potential Solution: Encode the RNA strand-displacement network within a single strand of RNA.

Bottleneck/Challenge: Strand displacement networks need to take as input transcriptomic RNAs that are improperly folded and processed, partially degraded, and interacting with other cellular machinery.

Potential Solution: Design of strand displacement interaction architectures that are robust to errors in inputs.

Potential Solution: Design of error correction computational layers that can process ‘messy’ input signatures.

Bottleneck/Challenge: Strand displacement networks cannot interface with systems that can regulate or alter the cellular state.

Potential Solution: Design of strand displacement output systems that can interact with (i.e., activate and/or repress) a range of native or engineered cellular systems.

Bottleneck/Challenge: Current state-of-the-art RNA-based gene regulators in bacteria utilize RNA structures to control transcription (STARs) and translation (Toeholds, and small RNAs) that are fundamentally different in eukaryotes and do not directly port.

Potential Solution: Understand how initiation, elongation and termination of both transcription and translation can be manipulated through formation of RNA structures and interactions.

Potential Solution: Uncover how natural RNA processing (splicing, polyadenylation, 5’ capping) specific to eukaryotes can be regulated through formation of RNA structures and interactions.

Potential Solution: Investigate orthogonal mechanisms of gene expression and RNA processing in eukaryotic cells, for example, that use machinery from naturally occurring viruses.

Bottleneck/Challenge: We currently have no ability to program RNA modifications inside living cells and natural modification machines lack sequence flexibility.

Potential Solution: Create CRISPR-based systems able to perform guide RNA directed post-transcriptional modification of RNA.

Potential Solution: Investigate natural RNA modification machinery to identify programmable and/or sequence flexible mechanisms.

Bottleneck/Challenge: Design rules of how specific RNA structures and sequences control gene expression and RNA processing in eukaryotes is poorly understood.

Potential Solution: Couple DNA library synthesis with high-throughput screening to rapidly explore sequence-function landscapes of different cellular process.

Examples include using modifications to dynamically control how RNAs interact, control gene expression, and form nanostructures.

Bottleneck/Challenge: While RNA modifications are known to be abundant and diverse, we have almost no idea about their functional consequences. This fundamentally limits our ability to harness modified nucleotides as building blocks or control points.

Potential Solution: Combine in vitro synthesized and modified RNAs with cell-free protein synthesis systems or purified reactions to systematically investigate effects of modifications.

Potential Solution: Apply programmable RNA modification tools in vivo to determine functional consequences of RNA modifications.

Potential Solution: Use next-generation sequencing technologies and statistical analysis to understand how modifications perturb endogenous RNA processing, structure formation, interactions and translation.

Bottleneck/Challenge: It is unknown how RNA modification machinery would tolerate non-natural RNA alphabets.

Potential Solution: Engineer and evolve RNA modification machinery to diversify substrate specificity.

Bottleneck/Challenge: Current non-natural RNA modifications have to be synthesized in vitro, and cannot be produced inside cells.

Potential Solution: Engineer protein enzymes or ribozymes capable of generating non-natural RNA modifications in cells.

Potential Solution: Engineer biosynthetic pathways that can produce substrates of non-natural RNA modification reactions in vivo.