The programming of cellular networks to achieve new biological functions depends on the development of genetic tools that link the presence of a molecular signal to gene-regulatory activity. Recently, a set of engineered RNA controllers was described that enabled predictable tuning of gene expression in the yeast Saccharomyces cerevisiae through directed cleavage of transcripts by an RNase III enzyme, Rnt1p. Here, we describe a strategy for building a new class of RNA sensing-actuation devices based on direct integration of RNA aptamers into a region of the Rnt1p hairpin that modulates Rnt1p cleavage rates. We demonstrate that ligand binding to the integrated aptamer domain is associated with a structural change sufficient to inhibit Rnt1p processing. Three tuning strategies based on the incorporation of different functional modules into the Rnt1p switch platform were demonstrated to optimize switch dynamics and ligand responsiveness. We further demonstrated that these tuning modules can be implemented combinatorially in a predictable manner to further improve the regulatory response properties of the switch. The modularity and tunability of the Rnt1p switch platform will allow for rapid optimization and tailoring of this gene control device, thus providing a useful tool for the design of complex genetic networks in yeast

Andrew H. Babiskin

Andrianantoandro

Babiskin

Basu

Bayer

Beisel

Buskirk

Caponigro

Chen

Christina D. Smolke

Culler

Desai

Elowitz

Gardner

Gietz

Grate

Isaacs

Koch

Lamontagne

Sambrook

Sharma

Sinha

Suess

Thompson

Weigand

Zimmermann

Nucleic Acids Research

English

PubMed

Crossref

Engineering ligand-responsive RNA controllers in yeast through the assembly of RNase III tuning modules

Babiskin, Andrew H.

Smolke, Christina D.

Caltech Authors - Main

1 
 
Babiskin AH and Smolke CD 
 
SUPPLEMENTARY INFORMATION 
Supplementary Figure 1 Plasmid map of pCS321, the Rnt1p hairpin characterization 
plasmid. 
Supplementary Figure 2 Sequences illustrating the placement of the TCT-4 aptamer 
within R31L-3B4Inv at multiple locations. 
Supplementary Figure 3 The dose response curves of RS, RS-B03, RS-B05, and RS-B06 
indicate that these synthetic BSB modules increase baseline 
expression relative to the original Rnt1p switch (RS). 
Supplementary Table 1 Oligonucleotide template sequences for all switches built in this 
study. 
Supplementary Table 2 The theoretical fold-change and dynamic range of all Rnt1p 
switches examined in this study as determined from experimentally 
measured baseline expression at 0 mM theophylline (b) and the 
theoretical maximal output (M) calculated by fitting the dose 
response data to the binding model. 
Supplementary Table 3 The previously reported gene-regulatory activity of the synthetic 
BSB modules selected for use in this study in the context of the 
Rnt1p hairpin genetic control element (A02). 
 
2 
 
 
 
 
Supplementary Figure S1. Plasmid map of pCS321, the Rnt1p hairpin characterization plasmid. 
  
pCS321
6.5 kbp
URA3
ADH1t yEGFP
AmpR
XhoI AvrII
CEN6/ARSH4
PGAL1
3 
 
 
 
 
Supplementary Figure S2. Sequences illustrating the placement of the TCT-4 aptamer within R31L-3B4Inv at multiple locations. 
RS2 and RS3 resulted in nonfunctional switches that were unresponsive to theophylline (data not shown), while RS was functional 
and utilized as the base Rnt1p switch design in this study. Gray lettering is used to indicate the nucleotides in RS2 and RS3 that differ 
from RS. 
  
RS2
A C
G U
GC
UA
AU
CG
UG
GC
UA
AU
GC
GU
AU
CG
G   A
A     U
C   A
GC
GC
UA
5’   3’
GC
U
C
C
CG
UA
AU
GC
RS3
A C
G U
GC
UA
AU
CG
UG
GC
UA
AU
GC
GU
CG
CG
G   A
A     U
C   A
GC
GC
UA
5’   3’
GC
U
C
C
CG
UA
AU
GC
RS
A C
G U
GC
UA
AU
CG
UG
GC
UA
AU
GC
GU
CG
CG
G   A
A     U
C   A
GC
GC
UA
5’   3’
GC
U
C
C
CG
UA
AU
GC
GC
AUCG
4 
 
 
 
 
Supplementary Figure S3. The dose response curves of RS, RS-B03, RS-B05, and RS-B06 indicate that these synthetic BSB 
modules increase baseline expression relative to the original Rnt1p switch (RS). These switches exhibit a reduced fold-change relative 
to that exhibited by RS. Data are reported as indicated in Figure 1C. The model parameters for the curve fit are provided in Table I. 
 
no insert
RS
RS-B03
RS-B05
RS-B06
40%
60%
80%
100%
0.01 0.1 1 10
N
o
rm
a
liz
e
d
 p
ro
te
in
 l
e
v
e
ls
 (
%
)
[theophylline] (mM)
5 
 
Supplementary Table 1. Oligonucleotide template sequences for all switches built in this study. The sequences of the indicated 
primers are provided in the Materials and Methods section. 
switch forward primer reverse primer template 
SR SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTCATGAGTC
CATGGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SRN SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTCATGCATC
CATGGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SRnt SRnt_fwd SR_rev 
AAACAAACTTGATGCCATTGGCAGCCGGATGTCATGAGTC
CATGGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-theo2 SR-theo2_fwd SR-theo2_rev 
AAACAAACTTGGCCCTTGGCAGCCGGATGTCATGAGTCCA
TGGCATCTGGATACCAGCCGTAAAAAGAAAAATAAA 
SR-theo3 SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCACGATGTCATGAGTC
CATGGCATCGTGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-B03 SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTTGAAAGTC
TTCAGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-B05 SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTTGTAAGTC
TACGGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-B06 SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTAATGAGTC
CATTGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-B07 SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTTGTGAGTC
CACAGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-B12 SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTAGTGAGTC
CACTGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SRx2 SRx2_fwd SRx2_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTCATGAGTC
CATGGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SRx3 SRx3_fwd SRx3_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTCATGAGTC
CATGGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-B07x2 SRx2_fwd SRx2_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTTGTGAGTC
CACAGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-B12x2 SRx2_fwd SRx2_rev 
AAACAAACTTGATGCCCTTGGCAGCCGGATGTAGTGAGTC
CACTGCATCTGGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-theo3-B07 SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCACGATGTTGTGAGTC
CACAGCATCGTGATACCAGCATCGTAAAAAGAAAAATAAA 
SR-theo3-B12 SR_fwd SR_rev 
AAACAAACTTGATGCCCTTGGCAGCACGATGTAGTGAGTC
CACTGCATCGTGATACCAGCATCGTAAAAAGAAAAATAAA 
 
6 
 
Supplementary Table 2. The theoretical fold-change and dynamic range of all Rnt1p switches examined in this study as determined 
from experimentally measured baseline expression at 0 mM theophylline (b) and the theoretical maximal output (M) calculated by 
fitting the dose response data to the binding model. 
switch b=Y(0mM) M 
theorectical 
fold-change 
theorectical 
dynamic range 
SR 47% ± 2% 97% ± 1% 2.07 ± 0.08 50% ± 2% 
SR-theo2 52% ± 2% 94% ± 3% 1.79 ± 0.08 41% ± 3% 
SR-theo3 42% ± 2% 101% ± 1% 2.40 ± 0.11 59% ± 2% 
SR-B03 79% ± 4% 105% ± 1% 1.33 ± 0.07 26% ± 4% 
SR-B05 51% ± 1% 104% ± 2% 2.04 ± 0.06 53% ± 2% 
SR-B06 56% ± 5% 108% ± 3% 1.94 ± 0.17 52% ± 6% 
SR-B07 44% ± 2% 112% ± 4% 2.56 ± 0.12 68% ± 4% 
SR-B12 44% ± 2% 101% ± 2% 2.26 ± 0.11 56% ± 3% 
SRx2 20% ± 1% 92% ± 0% 4.54 ± 0.16 71% ± 1% 
SRx3 10% ± 0% 74% ± 1% 7.18 ± 0.32 64% ± 1% 
SR-B07x2 16% ± 1% 89% ± 2% 5.42 ± 0.33 72% ± 2% 
SR-B12x2 22% ± 0% 81% ± 2% 3.69 ± 0.10 59% ± 2% 
SR-theo3-B07 37% ± 2% 103% ± 2% 2.79 ± 0.15 66% ± 3% 
SR-theo3-B12 36% ± 1% 95% ± 2% 2.61 ± 0.11 59% ± 2% 
 
  
7 
 
Supplementary Table 3. The previously reported gene-regulatory activity of the synthetic BSB modules selected for use in this study 
in the context of the Rnt1p hairpin genetic control element (A02). The data is taken from previous work (A Babiskin and C Smolke, in 
preparation [b]). 
substrate Normalized protein levels (%) Normalized transcript levels (%) 
A02-B00 28% ± 1% 43% ± 8% 
A02-B03 50% ± 2% 53% ± 5% 
A02-B05 25% ± 0% 39% ± 3% 
A02-B06 27% ± 2% 57% ± 2% 
A02-B07 37% ± 3% 51% ± 3% 
A02-B12 27% ± 2% 47% ± 5% 
 
 


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