dynamic mutually inhibitory switch
Construct PatternSuch portability enabled convenient construction of dynamic mutually inhibitory switches, where genes tagged by SRTS and OPRTS could regulate each other.
CFBacMamMusHumTxRep
Ev 28Rep 9Pr 71
Toolkit Items
Browse the toolkit beneath workflows. The mechanism branch runs mechanism -> architecture -> component, while the technique branch runs from high-level approaches down to concrete methods.
4 items matching 1 filter
Mechanism Branch
Layer 1
Mechanisms
▾Top-level concepts: biophysical action modes such as heterodimerization, photocleavage, or RNA binding.
Layer 1
Mechanisms
Layer 2
Architectures
▾Arrangements that realize or deploy mechanisms, including switches, construct patterns, and delivery strategies.
Layer 2
Architectures
Layer 3
Components
▾Low-level parts and sequence-defined elements used inside architectures, including protein domains and RNA elements.
Layer 3
Components
Technique Branch
Layer 1
Approaches
▾High-level engineering practices such as computational design, directed evolution, sequence verification, and functional assay.
Layer 1
Approaches
Layer 2
Methods
▾Concrete methods used to design, build, verify, or characterize engineered systems.
Layer 2
Methods
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mutual inhibition
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selective lethal system for enriching high-fluorescent mutants
Construct Patterna selective lethal system was further constructed to enrich high-fluorescent mutants, resulting in up to 11.32-fold enhancement in mean fluorescence intensity
CFBacMamMusHumTxRep
Ev 28Rep 9Pr 71
SRTS-OPRTS
RNA ElementSince 2025mutual inhibitionorthogonal cognate rna pairingpost-transcriptional rna-mediated regulationComputational Design
we reconstructed artificial TA pairs termed SRTS-OPRTS. A platform for generating orthogonal SRTS-OPRTS pairs with cross-species application ... was developed
CFBacMamMusHumTxRep
Ev 28Rep 9Pr 71
switched differential equations
Computational MethodSince 2020mutual inhibitionnegative feedbackoscillatory dynamical systems modelingstate switchingComputational Design
Switched differential equations were developed as a computational framework to model oscillatory behavior of circadian clock cells in the Madeira cockroach. The model was used to interpret RNAi perturbation phenotypes and to support a hypothesis of coupled morning and evening oscillators linked by mutual inhibition.
CFBacMamMusHumTxRep
Ev 28Rep 9Pr 71
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