Researchers at the University of Pennsylvania School of Medicine are the first to observe and measure the internal motion inside proteins, or its “dark energy.” This research, appearing in the current issue of Nature, has revealed how the internal motion of proteins affects their function and overturns the standard view of protein structure-function relationships, suggesting why rational drug design has been so difficult.
“The situation is akin to the discussion in astrophysics in which theoreticians predict that there is dark matter, or energy, that no one has yet seen,” says senior author A. Joshua Wand, PhD, Benjamin Rush Professor of Biochemistry. “Biological theoreticians have been kicking around the idea that proteins have energy represented by internal motion, but no one can see it. We figured out how to see it and have begun to quantify the so-called ‘dark energy’ of proteins.”
Proteins are malleable in shape and internal structure, which enables them to twist and turn to bind with other proteins. “The motions that we are looking at are very small, but very fast, on the time scale of billions of movements per second,” explains Wand. “Proteins just twitch and shake.” The internal motion represents a type of energy called entropy.
Current models of protein structure and function used in research and drug design often do not account for their non-static nature. “The traditional model is almost a composite of all the different conformations a protein could take,” says Wand.
The researchers measured a protein called calmodulin and its interactions with six other proteins when bound to a protein partner one at a time. These binding partners included proteins important in smooth muscle contraction and a variety of brain functions.
Using nuclear magnetic resonance spectroscopy, the investigators were able to look at the changes in the internal motion of calmodulin itself in each of the six different protein binding situations. They found a direct correlation between a change in calmodulin’s entropy – a component of its stored energy – and the total entropy change leading to the formation of the calmodulin-protein complex.
Finding out the contribution from individual proteins versus the entropy, or movement, of the entire protein complex has been more difficult and has been overcome in this study. From this individual contribution they deduced that changes in the entropy of the protein are indeed important to the process of calmodulin binding its partners.
“Before these unexpected results, most researchers in our field would have predicted that entropy’s contribution to protein-protein interactions would be zero or negligible,” says Wand. “But now it’s clearly an important component of the total energy in protein binding.”
Because of this new information, the researchers suggest that the entropy component may explain why drug design fails more often than it works. Currently, drugs are designed generally based on the precise structures of their biological targets, active regions on proteins that are intended to inhibit key molecules. However, the number of designed molecules actually binding to their targets is low for many engineered molecules. “We think that this is because the design is based on a model of a static protein, not the moving, hyper protein that is constantly changing shape,” say Wand. “We need to figure out how this new information fits in and perhaps drug design could be significantly improved.”
Future directions include understanding whether the principles revealed by this study are universal and impact the thousands of protein-protein interactions that underlie biology and disease. As Wand explains, “Protein-protein interactions are central to ‘signalling’, which is often the molecular origin of diseases. Cancer, diabetes, and asthma are three important examples. We are currently looking at the role of protein entropy in the control of critical signaling events in all three.”
Artist rendering of calmodulin molecule depicting protein "dark energy."
Image Credit: Mary Leonard and Michael Marlow, UP School of Medicine.
Proteins' Internal Motion, Implications For Drug Design Science Daily Releases
New proteomics research promises to revolutionize biomedical discovery
Protein Pulling: Learning How Proteins Fold By Pulling Them Apart
_________________________________________________________
_________________________________________________________
18 comments:
I must say I like your cotrasting blogs Quasar ... one where the Universe is large and immeasurable and this one where the universe is so tiny it's immeasurable. Cool.
So protein's twist and shake? There they knew how to dance all along!
lol Aggie,
and that's why dancing is so good for the body, everybody.
So Chubby Checker was, like, that era's version of a fitness instructor and nobody knew it back then?!!
So this explains why how the interaction of proteins and their structure work together in the body.
Thus also explains why some drugs work and others don't as described, interesting.
Never knew this until now.
Later. :)
verrry interesting!!!!!!
So.
Do proteins have a pack mentality?
Like a hunter gatherer...
Maybe not dark energy but primitive in nature?
Is their malleability like the muscles they feed?
And with a similar 'memory'?
Muscle is meant to move so why shouldn't protien want to groove right along with it???
Do drugs bind better with a common type of protien design?
Maybe a more basic design???
Can't imagine one size fits all here???
BTW Came from Aggies Blog..hope that's ok:):)
The more we try to understand the more we are brought face to face with the magnificence of this body that we unfortunately do not worship as much we should.
My body is my temple seems so much more significant when you read what an amazing creation of god we truly are!
This is really interesting Quasar!
I need to learn how to dance!
hugs!
lol rachel,
fitness & aerobics are almost timeless, from the moment we are born, and we start moving to the beat, and reaching for the stars
Alas mavin,
and what is clear is that just as different sounds, lights, smells and thoughts influence the brain's chemical process in different ways
So do drugs and pharaceuticals.
After all when we prescribe drugs, we are simply trying to find the easy solution to stimulating or suppressing the information and chemistry to the brain
Hi Bert,
I've seen you at Aggies, nice of you to look in.
one size definitely does not fit all, it all depends who or what we are trying to reach (and where).
Most proteins probably have a pack mentality, but will respond individually to their environment.
The 'dark energy' alludes more to the exotic cosmic unknown, which has yet to be 'clearly' identified.
lol Random,
Your Body is indeed a Temple.
But we are all a little guilty of not taking care of our body & mind.
The recklessness of youth, the feeling of indestructibility, the feeling of immortality - the over indulgence, and the wanting to experience it all
Often leave us with hangovers or acjes & pains the next day
lol Katie, I thought you were
A Master of the Dance
with just a fleeting glance
temptress spins into a trance
ah to dance, still my favorite form of meditation :)
I agree with aggie...I like how your blogs are about the infinite...whether without or within. Awesome job, awesome photos, great variety of topics.
the link with the picture on aggies Blog....The center of the wave..I mean RIP CURL!!!!!!
Awsome...send some my way from time to time please!
Beautiful to get lost in a picture like that :)
Hi Serenity,
nice to see you back out and about on the blogosphere.
So how are things with you, any lick with the pain management, and have you been down to your local Brahma Humaris Centre
Hi Bert, love that smile
I promise I'll catch a wave and send it your way, or capture some other picture just for you, and send it to brighten up your day
cool!!!!
Q 9!!!! Your just so.....neat!
Love to read your wit during my days of raising wildlife :)
Post a Comment