Living
computers: RNA circuits transform cells into nanodevices
Date: July 26, 2017
Source: Arizona State University
Summary: Scientists have demonstrated how living cells can be induced to carry
out computations in the manner of tiny robots or computers.
FULL STORY
Ribonucleic acid (RNA) is used to create logic circuits capable of
performing various computations. In new experiments, Green and his colleagues
have incorporated RNA logic gates into living bacterial cells, which act like
tiny computers.
Credit: Graphic by Jason Drees for the Biodesign Institute
The interdisciplinary nexus of biology and engineering, known as
synthetic biology, is growing at a rapid pace, opening new vistas that could
scarcely be imagined a short time ago.
In new research, Alex Green, a professor at ASU's Biodesign Institute,
demonstrates how living cells can be induced to carry out computations in the
manner of tiny robots or computers.
The results of the new study have significant implications for
intelligent drug design and smart drug delivery, green energy production,
low-cost diagnostic technologies and even the development of futuristic
nanomachines capable of hunting down cancer cells or switching off aberrant
genes.
"We're using very predictable and programmable RNA-RNA interactions
to define what these circuits can do," says Green. "That means we can
use computer software to design RNA sequences that behave the way we want them
to in a cell. It makes the design process a lot faster."
The study appears in the advance online edition of the journal Nature.
Designer RNA
The approach described uses circuits composed of ribonucleic acid or
RNA. These circuit designs, which resemble conventional electronic circuits,
self-assemble in bacterial cells, allowing them to sense incoming messages and
respond to them by producing a particular computational output, (in this case,
a protein).
In the new study, specialized circuits known as logic gates were
designed in the lab, then incorporated into living cells. The tiny circuit
switches are tripped when messages (in the form of RNA fragments) attach
themselves to their complementary RNA sequences in the cellular circuit,
activating the logic gate and producing a desired output.
The RNA switches can be combined in various ways to produce more complex
logic gates capable of evaluating and responding to multiple inputs, just as a
simple computer may take several variables and perform sequential operations
like addition and subtraction in order to reach a final result.
The new study dramatically improves the ease with which cellular computing
may be carried out. The RNA-only approach to producing cellular nanodevices is
a significant advance, as earlier efforts required the use of complex
intermediaries, like proteins. Now, the necessary ribocomputing parts can be
readily designed on computer. The simple base-pairing properties of RNA's four
nucleotide letters (A, C, G and U) ensure the predictable self-assembly and
functioning of these parts within a living cell.
Green's work in this area began at the Wyss Institute at Harvard, where
he helped develop the central component used in the cellular circuits, known as
an RNA toehold switch. The work was carried out while Green was a post-doc
working with nanotechnology expert Peng Yin, along with the synthetic
biologists James Collins and Pamela Silver, who are all co-authors on the new
paper. "The first experiments were in 2012," Green says.
"Basically, the toehold switches performed so well that we wanted to find
a way to best exploit them for cellular applications."
After arriving at ASU, Green's first grad student Duo Ma worked on
experiments at the Biodesign Institute, while another postdoc, Jongmin Kim
continued similar work at the Wyss Institute. Both are also co-authors of the
new study.
Nature's Pentium chip
The possibility of using DNA and RNA, the molecules of life, to perform
computer-like computations was first demonstrated in 1994 by Leonard Adleman of
the University of Southern California. Since then, rapid progress has advanced
the field considerably, and recently, such molecular computing has been
accomplished within living cells. (Bacterial cells are usually employed for
this purpose as they are simpler and easier to manipulate.)
The technique described in the new paper takes advantage of the fact
that RNA, unlike DNA, is single stranded when it is produced in cells. This
allows researchers to design RNA circuits that can be activated when a
complementary RNA strand binds with an exposed RNA sequence in the designed
circuit. This binding of complementary strands is regular and predictable, with
A nucleotides always pairing with U and C always pairing with G.
With all the processing elements of the circuit made using RNA, which
can take on an astronomical number of potential sequences, the real power of
the newly described method lies in its ability to perform many operations at
the same time. This capacity for parallel processing permits faster and more
sophisticated computation while making efficient use of the limited resources
of the cell.
Logical results
In the new study, logic gates known as AND, OR and NOT were designed. An
AND gate produces an output in the cell only when two RNA messages A AND B are
present. An OR gate responds to either A OR B, while a NOT gate will block
output if a given RNA input is present. Combining these gates can produce
complex logic capable of responding to multiple inputs.
Using RNA toehold switches, the researchers produced the first
ribocomputing devices capable of four-input AND, six-input OR and a 12-input
device able to carry out a complex combination of AND, OR and NOT logic known
as disjunctive normal form expression. When the logic gate encounters the
correct RNA binding sequences leading to activation, a toehold switch opens and
the process of translation to protein takes place. All of these circuit-sensing
and output functions can be integrated in the same molecule, making the systems
compact and easier to implement in a cell.
The research represents the next phase of ongoing work using the highly
versatile RNA toehold switches. In earlier work, Green and his colleagues
demonstrated that an inexpensive, paper-based array of RNA toehold switches
could act as a highly accurate platform for diagnosing the Zika virus.
Detection of viral RNA by the array activated the toehold switches, triggering
production of a protein, which registered as a color change on the array.
The basic principle of using RNA-based devices to regulate protein
production can be applied to virtually any RNA input, ushering in a new
generation of accurate, low-cost diagnostics for a broad range of diseases. The
cell-free approach is particularly well suited for emerging threats and during
disease outbreaks in the developing world, where medical resources and
personnel may be limited.
The computer within
According to Green, the next stage of research will focus on the use of
the RNA toehold technology to produce so-called neural networks within living
cells -- circuits capable of analyzing a range of excitatory and inhibitory
inputs, averaging them and producing an output once a particular threshold of
activity is reached, much the way a neuron averages incoming signals from other
neurons. Ultimately, researchers hope to induce cells to communicate with one
another via programmable molecular signals, forming a truly interactive, brain-like
network.
"Because we're using RNA, a universal molecule of life, we know
these interactions can also work in other cells, so our method provides a
general strategy that could be ported to other organisms," Green says,
alluding to a future in which human cells become fully programmable entities
with extensive biological capabilities.
The accompanying video demonstrates
the basic principles of the RNA toehold switch.
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