Revision as of 07:40, 17 October 2018

Parts collection
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Parts collection

Our parts collection has provided an extensive toolbox for researchers to construct their own transmembrane logic gates in mammalian cells.

Parts collection

Our parts collection has provided an extensive toolbox for researchers to construct their own transmembrane logic gates in mammalian cells.

Our parts collection has provided an extensive toolbox for researchers to construct their own transmembrane logic gates in mammalian cells. These parts were made as BioBricks, and are NOT ready for transfecting mammalian cells. Plasmids with these parts in eukaryotic expression backbone are available upon request.

Our parts collection contains all essential components of our ENABLE toolbox, that could also be divided into several sets, enabling others to readily utilize them to improve their existing genetic circuits.

Followed our 3-layer design principle, all ENABLE components have been well characterized, including our SynNotch receptors, Amplifiers and Combiners. In the collection, we have provided 7 versions of SynNotch receptors with (1) different combinations of extracellular domains which can bind to different antigens with different affinities, (2) transmembrane domains with varying cleavage efficiency and (3) intracellular domains executing diverse transcriptional amplifications.

We have provided a set of transcriptional amplifiers including zinc finger-based, TEV protease-based and split intein-based, allowing others to build their own genetic circuits, preferably through transcription (we have test), but not limited to (we have not test). Besides, a set of combiners with different copies of response elements are provided, which makes it easy for others to tune the activation or repression threshold. This feature was experimental confirmed previously(需要对应链接) and mathematically modeled in our 3-layer design again this year. Our modeling process could be used by others to predict their own genetic circuits before any wet-lab experiments.

Each part (sometimes two combined) constitutes one of our ENABLE module, which has its unique function. Yet they consolidate together to create all the 16 transmembrane binary logic gates for mammalian cells.

SynNotch receptors set

We have provided 7 versions of SynNotch receptors. Each of them can transduce signal from out of the cell via a contact-dependent antigen-stimulated cleavage process. When exprssing two SynNotch receptors with two different extracellular domains recognizing two types of antigens, the cell is able to accept dual inputs. The chosen nanobodies(需要对应链接) are highly specific against their antigens, and the chosen intracellular domains are transcriptional orthogonality. For more specific details, please refer to our parts listed below.

BioBrick ID	Protein Name	Recognized Antigen (affinity)	Transmembrane Domain	Intracellular Domain	Sequence Verification
BBa_K2549016	LaG17-mN1c-tTAA	GFP (low)	mouse Notch1 core	tTA advance	016.ab1
BBa_K2549017	LaG17-mN1ce-tTAA	GFP (low)	mouse Notch1 extended core	tTA advance	017.ab1
BBa_K2549018	LaG16-mN1ce-tTAA	GFP (high)	mouse Notch1 extended core	tTA advance	018.ab1
BBa_K2549019	LaG16-2-mN1c-tTAA	GFP (ultrahigh)	mouse Notch1 core	tTA advance	019.ab1
BBa_K2549020	LaG16-2-mN1c-GV2	GFP (ultrahigh)	mouse Notch1 core	Gal4-VP64	020.ab1
BBa_K2549021	αCD19-mN1c-tTAA	CD19	mouse Notch1 core	Gal4-VP64	021.ab1
BBa_K2549022	αCD19-mN1c-GV2	CD19	mouse Notch1 core	Gal4-VP64	022.ab1

Transcriptional amplifiers set

Last year, we have constructed 3 zinc finger-based transcription repressors. This year, we have expanded our zinc finger-based transcription factors library by additional 3 zinc finger-based transcription activators.

Although we prefer to use eight copies of response elements (RE) for a balance between not-too-hard molecular cloning and sufficient signal-to-noise ratio, we have provided 4 promotors with different repeats of response elements, allowing others to explore and tune their own transcriptional amplifiers. Latest modeling(需要对应链接) strongly supports our experimental preference, and others could just BBa_K2549035, e.g.

BioBrick ID	Protein Name	DNA Binding Domain	Transcriptional	Sequence Verification
BBa_K2549023	ZF21.16-VP64	ZF21.16	activation	023.ab1
BBa_K2549024	ZF42.10-VP64	ZF42.10	activation	024.ab1
BBa_K2549025	ZF43.8-VP64	ZF43.8	activation	025.ab1
BBa_K2446039	ZF21.16-KRAB	ZF21.16	repression	039.abl
BBa_K2446040	ZF42.10-KRAB	ZF42.10	repression	040.abl
BBa_K2446041	ZF43.8-KRAB	ZF43.8	repression	041.abl

BioBrick ID	DNA Name	Usage	Sequence Verification
BBa_K2549032	4ZF21.16-minCMV-2ZF43.8	4 copies of RE for ZF21.16 transcriptional activator to bind, and 2 copies of RE for ZF43.8 transcriptional repressor to bind	032.ab1
BBa_K2549033	6ZF21.16-minCMV-2ZF43.8	6 copies of RE for ZF21.16 transcriptional activator to bind, and 2 copies of RE for ZF43.8 transcriptional repressor to bind	033.ab1
BBa_K2549034	8ZF21.16-minCMV-2ZF43.8	8 copies of RE for ZF21.16 transcriptional activator to bind, and 2 copies of RE for ZF43.8 transcriptional repressor to bind	034.ab1
BBa_K2549035	8ZF21.16-minCMV-8ZF43.8	8 copies of RE for ZF21.16 transcriptional activator to bind, and 8 copies of RE for ZF43.8 transcriptional repressor to bind	035.ab1

As is stated above, we have provided three types of transcriptional-based Amplifiers, including zinc finger-based, TEV protease-based and split intein-based. These Amplifiers must be used with our Combiners to execute designed binary logic function.

Amplifiers and Combiners work together to execute binary computation

Zinc finger-based

For simple binary logic function, such as A gate, NOT A gate, OR gate, NOR gate, and NIMPLY gate, placing response elements upstream and downstream of the promoter is sufficient. For more details, please visit our results page.

BioBrick ID	Combiner Name	Usage	Sequence Verification
BBa_K2549026	8*ZF21.16-minCMV	8 copies of RE for ZF21.16 transcriptional activator to bind	026.ab1
BBa_K2549027	8*ZF42.10-minCMV	8 copies of RE for ZF42.10 transcriptional activator to bind	027.ab1
BBa_K2549028	8*ZF43.8-minCMV	8 copies of RE for ZF43.8 transcriptional activator to bind	028.ab1
BBa_K2549029	8*ZF21.16-CMV	8 copies of RE for ZF21.16 transcriptional activator to bind	029.ab1
BBa_K2549030	8*ZF42.10-CMV	8 copies of RE for ZF42.10 transcriptional activator to bind	030.ab1
BBa_K2549031	8*ZF43.8-CMV	8 copies of RE for ZF43.8 transcriptional activator to bind	031.ab1

TEV protease-based

For IMPLY gate, we placed TEV protease-controlled destroyable nuclear localization sequence between zinc finger DNA binding domain (DBD) and transcription factor (TF). In the presence of intracellular TEV protease, the cleavage between DBD-TF would destroy the transcriptional regulation function of DBD-TF. For more details, please visit our results page.

BioBrick ID	Protein Name	Sequence Verification
BBa_K2549039	VP64-dNLS-ZF21.16	039.ab1
BBa_K2549040	KRAB-dNLS-ZF21.16	040.ab1
BBa_K2549041	NLS-TEVp	041.ab1

Split intein-based

We built complex binary logic gates, including XOR gate and XNOR gate, using split intein-based Amplifers, still following our 3-layer design principle. For more details, please visit our results page.

BioBrick ID	Protein Name	Sequence Verification
BBa_K2549036	VP64-ZF21.16N-CfaN	036.ab1
BBa_K2549037	KRAB-ZF21.16N-CfaN	037.ab1
BBa_K2549038	CfaC-ZF21.16C-NLS	038.ab1
BBa_K2549042	NLS-TEVpN-CfaN	042.ab1
BBa_K2549043	CfaC-TEVpC	043.ab1

ENABLE - 16 logic gates for transmembrane signaling

Gate	SynNotch Intracellular Domain	Amplifier	Combiner
TRUE	tTAA + Gal4-VP64	/	CMV-d2EGFP
FALSE	tTAA + Gal4-VP64	/	/
A	tTAA + Gal4-VP64	TRE3GV-ZF21.16-VP64	8*ZF21.16-minCMV-d2EGFP
B	tTAA + Gal4-VP64	4*UAS-ZF21.16-VP64	8*ZF21.16-minCMV-d2EGFP
NOT A	tTAA + Gal4-VP64	TRE3GV-ZF21.16-KRAB	8*ZF21.16-CMV-d2EGFP
NOT B	tTAA + Gal4-VP64	4*UAS-ZF21.16-KRAB	8*ZF21.16-CMV-d2EGFP
OR	tTAA + Gal4-VP64	TRE3GV-ZF21.16-VP64 4*UAS-minCMV-ZF21.16-VP64	8*ZF21.16-minCMV-d2EGFP
NOR	tTAA + Gal4-VP64	TRE3GV-ZF21.16-KRAB 4*UAS-minCMV-ZF21.16-KRAB	8*ZF21.16-CMV-d2EGFP
XOR	tTAA + Gal4-VP64	TRE3GV-VP64-dNLS-ZF21.16-T2A-NLS-TEVpN-CfaN 4*UAS-minCMV-CfaC-TEVpC-T2A-VP64-dNLS-ZF21.16	8*ZF21.16-minCMV-d2EGFP
AND	tTAA + Gal4-VP64	TRE3GV-VP64-ZF21.16N-CfaN 4*UAS-minCMV-CfaC-ZF21.16C-NLS	8*ZF21.16-minCMV-d2EGFP
NAND	tTAA + Gal4-VP64	TRE3GV-KRAB-ZF21.16N-CfaN 4*UAS-minCMV-CfaC-ZF21.16C-NLS	8*ZF21.16-CMV-d2EGFP
A IMPLY B	tTAA + Gal4-VP64	TRE3GV-KRAB-dNLS-ZF21.16 4*UAS-minCMV-NLS-TEVp	8*ZF21.16-CMV-d2EGFP
B IMPLY A	tTAA + Gal4-VP64	4*UAS-minCMV-KRAB-dNLS-ZF21.16 TRE3GV-NLS-TEVp	8*ZF21.16-CMV-d2EGFP
A NIMPLY B	tTAA + Gal4-VP64	TRE3GV-ZF21.16-VP64 4*UAS-minCMV-ZF43.8-KRAB	8ZF21.16-minCMV-8ZF43.8-d2EGFP
B NIMPLY A	tTAA + Gal4-VP64	4*UAS-minCMV-ZF21.16-VP64 TRE3GV-ZF43.8-KRAB	8ZF21.16-minCMV-8ZF43.8-d2EGFP
XNOR	tTAA + Gal4-VP64	TRE3GV-KRAB-dNLS-ZF21.16-T2A-NLS-TEVpN-CfaN 4*UAS-minCMV-CfaC-TEVpC-T2A-KRAB-dNLS-ZF21.16	8*ZF21.16-CMV-d2EGFP

Abstract

Contact-dependent signaling is critical for multicellular biological events, yet customizing contact-dependent signal transduction between cells remains challenging. Here we have developed the ENABLE toolbox, a complete set of transmembrane binary logic gates. Each gate consists of 3 layers: Receptor, Amplifier, and Combiner. We first optimized synthetic Notch receptors to enable cells to respond to different signals across the membrane reliably. These signals, individually amplified intracellularly by transcription, are further combined for computing. Our engineered zinc finger-based transcription factors perform binary computation and output designed products. In summary, we have combined spatially different signals in mammalian cells, and revealed new potentials for biological oscillators, tissue engineering, cancer treatments, bio-computing, etc. ENABLE is a toolbox for constructing contact-dependent signaling networks in mammals. The 3-layer design principle underlying ENABLE empowers any future development of transmembrane logic circuits, thus contributes a foundational advance to Synthetic Biology.

@@ Line 647: / Line 647: @@
                                      <td>tTAA + Gal4-VP64</td>
                                      <td>TRE3GV-<a href="http://parts.igem.org/Part:BBa_K2549036" target="_blank">VP64-ZF21.16N-CfaN</a><br>
-*UAS-minCMV-<a href="http://parts.igem.org/Part::BBa_K254903" target="_blank">CfaC-ZF21.16C-NLS</a></td>
+*UAS-minCMV-<a href="http://parts.igem.org/Part::BBa_K2549038" target="_blank">CfaC-ZF21.16C-NLS</a></td>
                                      <td><a href="http://parts.igem.org/Part:BBa_K2549026" target="_blank">8*ZF21.16-minCMV</a>-d2EGFP </td>
                                  </tr>
@@ Line 654: / Line 654: @@
                                      <td>tTAA + Gal4-VP64</td>
                                      <td>TRE3GV-<a href="http://parts.igem.org/Part:BBa_K2549037" target="_blank">KRAB-ZF21.16N-CfaN</a><br>
-*UAS-minCMV-<a href="http://parts.igem.org/Part::BBa_K254903" target="_blank">CfaC-ZF21.16C-NLS</a></td>
+*UAS-minCMV-<a href="http://parts.igem.org/Part::BBa_K2549038" target="_blank">CfaC-ZF21.16C-NLS</a></td>
                                      <td><a href="http://parts.igem.org/Part:BBa_K2549029" target="_blank">8*ZF21.16-CMV</a>-d2EGFP</td>
                                  </tr>

Difference between revisions of "Team:Fudan/Parts Collection"

Revision as of 07:40, 17 October 2018

Parts collection

Parts collection

SynNotch receptors set

Transcriptional amplifiers set

Amplifiers and Combiners work together to execute binary computation

Zinc finger-based

TEV protease-based

Split intein-based

ENABLE - 16 logic gates for transmembrane signaling

Abstract