Sound is a pretty simple concept. Stuff
makes noise and you hear it with your ears. You can even be pipetting on your
bench-top while listening to Rihanna if it makes you feel good and energetic. But
sound waves can be used to do lots of amazing things apart from that: some have
practical applications in science an even in our normal day to day life. In
this post I would like to tell you some of the craziest things you didn’t know
you could do with sound and how you could use it on your ongoing research.
What
is sound?
Sound is
made of acoustic waves, which are a type of longitudinal waves that
propagate by means of adiabatic compression and decompression. (Longitudinal
waves are waves that have the same direction of vibration as their direction of
travel). Sound is like
light in some ways: it travels out from a definite source just as light travels
out from the Sun or a light bulb. But there are some very important differences
between light and sound as well. We know light can travel through a vacuum
because sunlight has to race through the vacuum of space to reach us on Earth.
Sound, however, cannot travel through a vacuum: it always has to have something
to travel through (known as a medium), such as air, water, glass or metal. The
first person to discover that sound needs a medium was the brilliant English
scientist Robert Boyle (1627–1691). He carried out a classic experiment: he set
an alarm clock ringing, placed it inside a large glass jar and while the clock
was still ringing, sucked all the air out with a pump. As the air gradually
disappeared, the sound died out because there was nothing left in the jar for
it to travel through.
Surface Acoustic Waves (SAW): the waves that let you use
your cell phone and help you park your car
A surface acoustic wave (SAW) is a type of
mechanical
wave motion which travels
along the surface of a solid material. The
wave was
discovered in 1885 by Lord
Rayleigh and is often named after him.
Rayleigh
showed that SAWs could explain one
component of the seismic signal due to an
earthquake,
a phenomenon not previously understood. These days,
these acoustic
waves are often used in electronic
devices. At first sight it seems odd to use
an acoustic
wave for an electronic application, but acoustic waves
have some
particular properties that make them pretty cool for specialized purposes. Have
you ever noticed that many wrist watches have a quartz crystal used for accurate
frequency generation? Well, this is an acoustic resonator though it uses bulk
acoustic waves rather than surface waves. Surface waves on the other hand have
lots of applications as well, such as touch screens and parking sensors.
A SAW touch screen work by using ultrasonic waves to detect
touch events and the location of the user’s input.
Already in the 1970s German inventor
Rainer Buchmann developed parking sensors,
which are proximity
sensors for road vehicles designed to alert the
driver to obstacles while parking.
The sensors emit acoustic pulses,
with a control unit measuring the return interval of each reflected signal and
calculating object distances. If you happen to have one of this devices as I do
(thanks to my husband who ‘strongly’ recommended it) you would know that the
system in turns warns the driver with acoustic tones, the frequency indicating object distance, with
faster tones indicating closer proximity and a continuous tone indicating a
minimal pre-defined distance.
SAW reaches biochemistry:
acoustic waves moving towards biosensors
SAW also have applications in biochemistry, for example in biosensors.
A biosensor is an analytical device containing an immobilized biological
sensitive material (enzyme, antibody, antigen, organelles, DNA, cells, tissues
or organic molecules) in contact with or integrated within a transducer, which
converts a biological signal into a quantitatively measurable electrical
signal.
SAW-based
sensors are systems in which high frequency acoustic waves travel close to the
surface of a piezoelectric substrate.
Upon interaction with molecules on the sensor
surface, distinct characteristics of the travelling acoustic waves are altered:
· Changes
in total mass on the biosensor result in a shift of the wave's phase.
This phase shift provides information about the on- and off-rates, as well as
the stoichiometry of molecular interactions.
· A
change in flexibility of the molecules alters the wave's amplitude.
This directly reflects changes in the conformation of the molecules, e.g. after
binding to compounds.
Both signal types are detected and quantified
separately and can be used to comprehensively characterize the interaction
mechanism of the molecules on a kinetic and structural level.
Assessment
of protein-small-molecule interactions by acoustic waves
A beautiful example on how SAW can be used to analyze interactions of
a protein and its substrate is that of MBP (1). The E. coli maltose binding protein (MBP) is a monomeric periplasmic protein, that is often used as a
fusion protein to either mediate solubility of its fusion partners or as an
affinity-tag for amylose affinity purification. In its cellular function, MBP
is the corresponding receptor molecule to the bacterial maltose ABC transporter
system. Upon traversing the bacterial outer membrane, by means of a specified
channel protein, maltose is efficiently captured by MBP and delivered to the
inner-membrane ABC transporter system for nutrient uptake. Interestingly,
maltose binding to MBP results in a marked conformational change: in a clamp
like motion, the MBP N- and C-domain close around the associated maltose
molecule.
Using SAW technology, it was able to resolve the structural
transition occurring in MBP upon maltose binding. Accurate dissociation
constants were determined not only by analysis of the mass-binding induced
phase-signal, but also by quantification of the conformational-change induced
amplitude response. So far, highly sensitive fluorescence detection was
required to quantify conformational changes on such a small scale. Now, Surface
Acoustic Wave sensors allow monitoring of intramolecular conformational
transitions with impressive signal to noise ratios for immobilized molecules.
Therefore, SAW presents an ideal tool to investigate mechanisms of protein small-molecule
interactions by separating mass binding and resulting conformational changes.
Conformational changes at
protein-protein interaction followed by SAW biosensor
Simple binding parameters, especially stand-alone Kd values
have repeatedly been shown to characterize protein interactions, but additional
parameters, such as kinetics and the conformational effects on a target protein
due to ligand binding are being investigated particularly in drug discovery
applications.
In general, binding of proteinaceous biomolecules onto the
sensor surface results in both an increase in phase and a decrease in
amplitude. The increase in phase is attributed to the mass loading, while the
decrease in amplitude can be assigned to the additional viscosity of the bound
molecules, as they are not perfectly rigid.
A system previously used for selective measurement of
conformational changes is the signal transduction pathway involving the small GTP-binding
protein Ras and its effector molecules (2). The use of SAW, besides of
retrieving information regarding to binding kinetics, retrieved an interesting
insight of conformational changes of their interplayer proteins. For example,
the recorded amplitude signal, used as a measure of the conformational changes,
showed how salt influenced on protein rigidity and hence on the strength of
binding.
SAW chip-based biosensors for
detecting cancer cells.
Although the title of this post goes in the protein
direction, it is worth noting that SAW has extended applications to any molecule,
cells and even viral particles. A good example is its use on the detection of
cancer cells.
In a beautiful study, a nanostructured chip surface
was fabricated enabling binding via spaced antibodies specifically targeting
surface proteins of cancer cells and detection of extremely low numbers of
circulating tumor cells (CTC) (3). Human cancer cell lines JEG-3 (lymphoblastic
leukemia) and MOLT-17 (placental choriocarcinoma) from cell cultures were
successfully detected using a SAW biosensor which showed significant responses
on less than 10 cells injected in a single run. Thus SAW biosensors are highly
promising tool for medical diagnostics as well.
My final words… ballerinas and conformational changes
If you think about it, proteins can be thought as
ballerinas in the way that they fulfill their functions by changing their
shapes (conformations) flexibly. This nature’s ‘ballerinas’ undergo
conformational changes as part of their interactions with other proteins or
drug molecules or in response to changes in their
environment. As our appreciation of proteins as dynamic, flexible molecules
grows, so does the need for tools to probe the conformational landscape in real
time and in physiological conditions. SAW biosensors appear as an excellent and
highy sensitive tool for analyzing conformational changes.
As you can see, sound goes beyond music
and it has tremendous applications in science. Let’s open our minds and let us
be amazed by new technologies that can offer an inner look into our favourite
molecules.
1.http://www.nanotempertechnologies.com/uploads/media/Application_Note_NT-SE-001_Conformational_Changes_MBP_01.pdf
2. Klumpers, Ulrich Götz, Tanja Kurtz, Christian Herrmann, Thomas M.A. Gronewold, Conformational changes at protein–protein interaction followed online with an SAW biosensor, Sensors and Actuators B: Chemical, Volume 203, November 2014, Pages 904-908.
3. Patrick Bröker, Klaus Lücke, Markus Perpeet, Thomas M.A. Gronewold, A nanostructured SAW chip-based biosensor detecting cancer cells, Sensors and Actuators B: Chemical, Volume 165, Issue 1, April 2012, Pages 1-6.
