How to make an oscillator
INSIGHT
SYNTHETIC BIOLOGY
How to make an oscillator
A cell-free approach reveals how genetic circuits can produce robust
oscillations of proteins and other components.
BAS JHM ROSIER AND TOM FA DE GREEF
Related research article Niederholtmeyer H,
Sun ZZ, Hori Y, Yeung E, Verpoorte A, Murray
RM, Maerkl SJ. 2015. Rapid cell-free forward
engineering of novel genetic ring oscillators.
eLife 4: e09771. doi: 10.7554/eLife.09771
Image Circuits made of three or five genes
can generate robust oscillations in the fluorescence of bacteria cells.
E
Copyright Rosier and de Greef.
This article is distributed under the
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provided that the original author and
source are credited.
ver since it was discovered that the level
of calcium ions inside a cell can oscillate
(Woods et al., 1986), biologists have
been intrigued by the periodic nature of many
cellular signals. While we are slowly starting to
grasp the many and varied roles that these periodic oscillations play in cellular communication,
an open question remains: how are networks of
genes able to generate sustained oscillations?
Now, in eLife, Sebastian Maerkl and co-workers
– including Henrike Niederholtmeyer and Zachary Sun as joint first authors – report that they
have used a synthetic biology approach to reveal
how simple gene circuits can produce robust
oscillations in cells (Niederholtmeyer et al.,
2015).
Initially, it was argued that periodic oscillations in the level of calcium ions and other cellular components had no role in signaling, but
decades of research has revealed that periodic
signals are better at relaying information than
non-periodic signals (Rapp, 1987; Behar and
Hoffman, 2010; Purvis and Lahav, 2013;
Levine et al., 2013). Both types of signal can
encode information in the size (amplitude) of the
signal, but the frequency and phase of periodic
Rosier and de Greef. eLife 2015;4:e12260. DOI: 10.7554/eLife.12260
signals can also encode information. As a result,
periodic signals may be able to regulate complex cell processes more precisely than nonperiodic signals. Importantly, recent advances in
single-cell analysis and optogenetics have
resulted in numerous in-depth studies that
reveal how critical events, such as the determination of cell fate and multicellular communication, are controlled by periodic signals (the
review by Sonnen and Auleha, 2014 describes
other examples).
Mathematical analysis shows that an essential
element of an oscillating circuit is an inhibitory
feedback loop: if the activity of one gene in such
a feedback loop increases, it activates other
genes in the circuit that ultimately inhibit it
(Rapp, 1987; Novak and Tyson, 2008;
Purcell et al., 2010). This feedback loop needs
to have an in-built time delay to enable the
activities of the genes in the circuit to fluctuate
in regular cycles.
The rise of synthetic biology has made it possible to design and construct synthetic networks
in living cells that perform a specific role. In an
early example of this, researchers at Princeton
reported that they had constructed an oscillatory
gene network in E. coli based on a cyclic network of three genes called the repressilator
(Elowitz and Leibler, 2000; Figure 1). Theory
predicts that the repressilator and other ring
oscillators that have an odd number of genes
(nodes) should be capable of producing sustained oscillations. However, since designing,
building and testing new gene networks in living
cells is a lengthy process, ring oscillators with
more than three nodes have not been reported.
Now Maerkl and co-workers – who are based
at the École Polytechnique Fédérale de Lausanne and the California Institute of Technology
– have made ring architectures containing three,
1 of 3
�Insight
Synthetic biology How to make an oscillator
Figure 1. Synthetic gene networks containing three, four and five genes. The genes in each circuit (top) are
translated into protein products, with each protein product repressing the activity of another gene in the network
(as indicated by the arrows). Theory predicts that cyclic networks of genes display oscillatory behavior when the
number of nodes in the network is odd. Niederholtmeyer et al. found that a circuit consisting of three genes gave
rise to well-defined oscillations with a period of up to 8 hr, and that a circuit containing five genes oscillated with a
period of 19 hours. In contrast, and in line with theoretical predictions, a network consisting of four nodes did not
oscillate: instead it reached a steady state where the activity of all the genes was constant over time.
DOI: 10.7554/eLife.12260.001
four and five genes (Figure 1). They built their
prototype genetic circuits in a cell-free system
by combining microfluidic flow reactors with
extracts
from
E.
coli
bacteria
(Niederholtmeyer et al, 2013; Noireaux et al.,
2003). The major advantage of this approach is
that it significantly decreases the time taken for
each design-build-test cycle because it removes
the need for various laborious tasks, such as
molecular cloning and collecting measurements
from individual cells.
Using this strategy Niederholtmeyer, Sun
et al. were able to confirm the prediction that
oscillators with three or five nodes are able
to generate oscillations, whereas oscillators with
four nodes are not. The period of the five-node
oscillator is about twice as long as the threenode oscillator, indicating that cells can tune the
periodicity of signals by increasing the complexity of their genetic circuits. Next, the researchers
transferred their prototyped designs to living E.
coli cells and showed that the oscillation period
in cells matched the oscillation period in the cellfree systems. This is an important result as it
shows that cell-free systems can be used to
accurately capture the behavior of cells, which
paves the way for researchers to use synthetic
biology approaches in cell-free systems to
explore the complex regulatory mechanisms that
operate inside cells (van Roekel et al., 2015).
The latest work should also greatly speed up the
construction of complex new gene networks in
Rosier and de Greef. eLife 2015;4:e12260. DOI: 10.7554/eLife.12260
bacteria, which could have applications in biofuel production, medical diagnosis and experiments to explore the ways that cells process
information.
Bas JHM Rosier is in the Department of Biomedical
Engineering and Institute for Complex Molecular
Systems, Eindhoven University of Technology,
Eindhoven, The Netherlands
Tom FA de Greef is in the Department of Biomedical
Engineering and Institute for Complex Molecular
Systems, Eindhoven University of Technology,
Eindhoven, The Netherlands
Competing interests: The authors declare that no
competing interests exist.
Published 10 December 2015
References
Behar M, Hoffmann A. 2010. Understanding the
temporal codes of intra-cellular signals. Current
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