Logic operations in biological systems have been tested with several approaches
Singh2014
. Our project
relies on the reconstitution of split protein promoted by coiled coil (CC) dimerization. The
interaction between CC peptides can be finely tuned
Woolfson2005, Gradisar2011, Negron2014
, thereby CCs offers a flexible and
versatile platform in terms of designing logic operation in vivo. With the purpose of
understanding the relation that underlies the interaction between coiled coil peptides and
therefore using them in logic gates, we designed the following model (
5.4.1.
). Our system is based on constructs that have been characterized in mammalian cells in the
context of logic function
design. Two orthogonal CC segment, A and b, fused together in on chain can bind each
other and form a stable CC pair. This complex exists in combination with the peptide B, which
can also bind the peptide A and has a different affinity from the peptide b. The linker that
connects A and b can be cleaved by a generic protease (e.g. TEV), this irreversible reaction
shift the equilibrium towards a state in which all of the three peptides are free in solution
and therefore compete for binding. In our experiments, a similar system as the generic coils A
and B was fused to the split reporter
firefly luciferase.
The relationship between the signal before and after cleavage by proteases is represented by the
difference [AB] - [AB-b]. In order to understand the optimal combination of dissociation
constant required to obtain a good signal we solved two systems of equations set up considering
the two state of the reaction scheme (“Before cleavage and “After cleavage”) as separate phases
of the reaction and additionally, considering cleavage as an irreversible and complete
reaction.
Given values for total concentrations and Kd (from 10-9 to 10-3 M) the
equations, for the
reaction constants \eqref{1.1-2} - \eqref{2.1-2} and for mass conservation \eqref{1.3-4} -
\eqref{2.3-5}, were solved for the
species at equilibrium.
Before cleavage
\begin{equation}
\ce{Axb + B <=>[Kd_x] A-b + B <=>[Kd_B] AB-b}
\end{equation}
\begin{align}
Kd_x &= \frac{[A-b]}{[Axb]} \label{1.1-2}\\
Kd_B &= \frac{[A-b] * [B]}{[AB - b]} \\
c_B &= [B] + [AB-b]\\
c_A-b &= [A-b]+[Axb]+[AB-b] \label{2.1-2}
\end{align}
After cleavage
\begin{equation}
\ce{Ab + B <=>[Kd_b] A + b + B <=>[Kd_B] AB + b}
\end{equation}
\begin{align}
Kd_b &= \frac{[A] * [b]}{[Ab]} \label{1.3-4}\\
Kd_B &= \frac{[A] * [B]}{[AB]} \\
c_A &= [A]+[AB]+[Ab]\\
c_B &= [B] +[AB]\\
c_b &= [b] + [Ab] \label{2.3-5}
\end{align}
>external text
The two systems are connected by the relation between the dissociation constants $Kd_b$ and $Kd_x$,
\begin{equation}
Kd_x = Kd_b * 4 * 10^{-3} M^{-1}
\end{equation}
This relation approximates the higher affinity between the coils A and b when they are covalently
linked by a short peptide (as in the system “Before cleavage”)
Moran1999, Zhou2004
.
The results have been plotted varying the Kd for the interaction of A with both B and b, against
the difference [AB] - [AB-b], where [AB] is considered the signal after cleavage and [AB-b] the
signal before cleavage (leakage). The system revealed that in order to obtain a high difference
between signal and leakage a high affinity of the coil B for the coil A (low $Kd_B$) is
required,
while on the other hand an excessive destabilization of the autoinhibitory coil b (high $Kd_b$)
would prevent the signal to be visible (
5.4.2.
).
This relationship suggested to try using a different version of the coiled coils available in the
toolset already used by the Slovenian iGEM 2009
teamGradisar2011
.In order to
obtain a detectable signal for logic operation in
vivo we decided
to use an inhibitory coiled coil, which would be displaced by the second coiled coil with higher
affinity, only once is cleaved off its partner ($ Kd_B \gt Kd_b $). In doing so we selected
P3 as
B and
P3mS as b, these two coiled coil peptides present only few substitutions and the higher
solubility of P3mS (b), which presents Gln and Ser instead of Ala in b and c position of the
heptads, would favour the dissociation. We also tried differently destabilized versions of P3
and it turned out that, as in the forehead described model, an excessive destabilization
(obtained by substituting a and d positions with Ala) leads to a small difference of the signal
before and after cleavage. Using a slightly destabilized coiled coil (P3mS-2A), which presents
only 2 alanines in the second heptad, the signal after cleavage reached its maximum of 16 folds.
(MISSING Link to Figure 4.12.9.)