The ability to conditionally rewire pathways in human cells holds great therapeutic potential. Transcription activator-like effectors (TALEs) are a class of naturally occurring specific DNA binding proteins that can be used to introduce targeted genome modifications or control gene expression. Here we present TALE hybrids engineered to respond to endogenous signals and capable of controlling transgenes by applying a predetermined and tunable action at the single-cell level. Specifically, we first demonstrate that combinations of TALEs can be used to modulate the expression of stably integrated genes in kidney cells. We then introduce a general purpose two-hybrid approach that can be customized to regulate the function of any TALE either using effector molecules or a heterodimerization reaction. Finally, we demonstrate the successful interface of TALEs to specific endogenous signals, namely hypoxia signaling and microRNAs, essentially closing the loop between cellular information and chromosomal transgene expression.
Gene autorepression is widely present in nature and is also employed in synthetic biology, partly to reduce gene expression noise in cells. Optogenetic systems have recently been developed for controlling gene expression levels in mammalian cells, but most have utilized activator-based proteins, neglecting negative feedback except for in silico control. Here, we engineer optogenetic gene circuits into mammalian cells to achieve noise-reduction for precise gene expression control by genetic, in vitro negative feedback. We build a toolset of these noise-reducing Light-Inducible Tuner (LITer) gene circuits using the TetR repressor fused with a Tet-inhibiting peptide (TIP) or a degradation tag through the light-sensitive LOV2 protein domain. These LITers provide a range of nearly 4-fold gene expression control and up to 5-fold noise reduction from existing optogenetic systems. Moreover, we use the LITer gene circuit architecture to control gene expression of the cancer oncogene KRAS(G12V) and study its downstream effects through phospho-ERK levels and cellular proliferation. Overall, these novel LITer optogenetic platforms should enable precise spatiotemporal perturbations for studying multicellular phenotypes in developmental biology, oncology and other biomedical fields of research.
Decoders
are combinational circuits that convert information from n inputs to a maximum of 2n outputs.
This operation is of major importance in computing systems yet it
is vastly underexplored in synthetic biology. Here, we present a synthetic
gene network architecture that operates as a biological decoder in
human cells, converting 2 inputs to 4 outputs. As a proof-of-principle,
we use small molecules to emulate the two inputs and fluorescent reporters
as the corresponding four outputs. The experiments are performed using
transient transfections in human kidney embryonic cells and the characterization
by fluorescence microscopy and flow cytometry. We show a clear separation
between the ON and OFF mean fluorescent intensity states. Additionally,
we adopt the integrated mean fluorescence intensity for the characterization
of the circuit and show that this metric is more robust to transfection
conditions when compared to the mean fluorescent intensity. To conclude,
we present the first implementation of a genetic decoder. This combinational
system can be valuable toward engineering higher-order circuits as
well as accommodate a multiplexed interface with endogenous cellular
functions.
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