 |
|
Quantum biology — Powerful computer models reveal key biological mechanism
January 17, 2007Troy, N.Y. — Using powerful computers to model the intricate dance of atoms and molecules, researchers at Rensselaer Polytechnic Institute have revealed the mechanism behind an important biological reaction. In collaboration with scientists from the Wadsworth Center of the New York State Department of Health, the team is working to harness the reaction to develop a "nanoswitch" for a variety of applications, from targeted drug delivery to genomics and proteomics to sensors.
The research is part of a burgeoning discipline called "quantum biology," which taps the skyrocketing power of today's high-performance computers to precisely model complex biological processes. The secret is quantum mechanics — the much-touted theory from physics that explains the inherent "weirdness" of the atomic realm.
Reporting in the February 2007 issue of Biophysical Journal, the researchers describe a mechanism to explain how an intein — a type of protein found in single-celled organisms and bacteria — cuts itself out of the host protein and reconnects the two remaining strands. The intein breaks a protein sequence at two points: first the N-terminal, and then the C-terminal. This aspect of the project, which is led by Saroj Nayak, associate professor of physics, applied physics, and astronomy at Rensselaer, focuses on the C-terminal reaction.
Another Rensselaer team previously found that the reaction at the C-terminal speeds up in acidic environments. But to control the reaction and use it as a nanoswitch, a better understanding of the mechanism behind this reaction is needed, according to Philip Shemella, a doctoral student in physics at Rensselaer and corresponding author of the current paper.
"You can use this protein that cuts itself and joins the pieces together in a predictable way," he said. "It already has a function that would be nice to harness for nanotechnology purposes." And because the reaction may be sensitive to light and other environmental stimuli, the process could become more than just a two-way switch between "on" and "off."
The researchers revealed the details of the reaction mechanism by applying the principles of quantum mechanics — a mathematical framework that describes the seemingly strange behavior of the smallest known particles. For example, quantum mechanics predicts that an electron can be in two different places at the same time; or that an imaginary cat can be simultaneously dead and alive, as suggested by one famous thought experiment.
Until recently, scientists could not apply quantum mechanics to biological systems because of the large numbers of atoms involved. But the latest generation of supercomputers, along with the development of efficient mathematical tools to solve quantum mechanical equations, is making these calculations possible, according to Shemella.
"Typically, quantum mechanics has been applied to solid-state problems because the symmetry makes the calculation smaller and easier, but there's really nothing different physically between a carbon atom in a protein and a carbon atom in a nanotube," he said. "Even though a protein is such an asymmetric, complex system, when you really zoom into the quantum mechanical level, they are just atoms. It doesn't matter if strange things are happening; it's still just carbon, nitrogen, hydrogen, and oxygen."
Quantum mechanics allows researchers to do things that can't be done with classical physics, such as modeling the way chemical bonds break and form, or including the effect of proton "tunneling" — allowing protons to move through energy barriers that normal logic would deem impossible.
For this project, the researchers used computing facilities at Rensselaer's Scientific Computation Research Center (SCOREC) and the National Center for Supercomputing Applications at the University of Illinois at Urbana-Champaign. In the future, they hope to take advantage of Rensselaer's new Computational Center for Nanotechnology Innovations — a $100 million partnership between Rensselaer, IBM, and New York state to create one of the world's most powerful university-based supercomputing centers.
The additional computing power will allow them to model complex biological systems with even greater accuracy: "The more atoms you include, the more accurate your system," Shemella said.
Rensselaer Polytechnic Institute
Another Rensselaer team previously found that the reaction at the C-terminal speeds up in acidic environments. But to control the reaction and use it as a nanoswitch, a better understanding of the mechanism behind this reaction is needed, according to Philip Shemella, a doctoral student in physics at Rensselaer and corresponding author of the current paper.
"You can use this protein that cuts itself and joins the pieces together in a predictable way," he said. "It already has a function that would be nice to harness for nanotechnology purposes." And because the reaction may be sensitive to light and other environmental stimuli, the process could become more than just a two-way switch between "on" and "off."
The researchers revealed the details of the reaction mechanism by applying the principles of quantum mechanics — a mathematical framework that describes the seemingly strange behavior of the smallest known particles. For example, quantum mechanics predicts that an electron can be in two different places at the same time; or that an imaginary cat can be simultaneously dead and alive, as suggested by one famous thought experiment.
Until recently, scientists could not apply quantum mechanics to biological systems because of the large numbers of atoms involved. But the latest generation of supercomputers, along with the development of efficient mathematical tools to solve quantum mechanical equations, is making these calculations possible, according to Shemella.
"Typically, quantum mechanics has been applied to solid-state problems because the symmetry makes the calculation smaller and easier, but there's really nothing different physically between a carbon atom in a protein and a carbon atom in a nanotube," he said. "Even though a protein is such an asymmetric, complex system, when you really zoom into the quantum mechanical level, they are just atoms. It doesn't matter if strange things are happening; it's still just carbon, nitrogen, hydrogen, and oxygen."
Quantum mechanics allows researchers to do things that can't be done with classical physics, such as modeling the way chemical bonds break and form, or including the effect of proton "tunneling" — allowing protons to move through energy barriers that normal logic would deem impossible.
For this project, the researchers used computing facilities at Rensselaer's Scientific Computation Research Center (SCOREC) and the National Center for Supercomputing Applications at the University of Illinois at Urbana-Champaign. In the future, they hope to take advantage of Rensselaer's new Computational Center for Nanotechnology Innovations — a $100 million partnership between Rensselaer, IBM, and New York state to create one of the world's most powerful university-based supercomputing centers.
The additional computing power will allow them to model complex biological systems with even greater accuracy: "The more atoms you include, the more accurate your system," Shemella said.
Rensselaer Polytechnic Institute
More Quantum Biology Current Events and Quantum Biology News Articles
 |
Introduction to Quantum Mechanics: in Chemistry, Materials Science, and Biology (Complementary Science) by Sy M. Blinder (Author) This book provides a lucid, up-to-date introduction to the principles of quantum mechanics at the level of undergraduates and first-year graduate students in chemistry, materials science, biology and related fields. It shows how the fundamental concepts of quantum theory arose from classic experiments in physics and chemistry, and presents the quantum-mechanical foundations of modern techniques including molecular spectroscopy, lasers and NMR. Blinder also discusses recent conceptual developments in quantum theory, including Schrödinger's Cat, the Einstein-Podolsky-Rosen experiment, Bell's theorem and quantum computing. * Clearly presents the basics of quantum mechanics and modern developments in the field * Explains... |
 |
Quantum Dots: Applications in Biology (Methods in Molecular Biology) by Charles Z Hotz (Editor), Marcel Bruchez (Editor) Quantum Dots captures many diverse applications enabling utility in biological detection. Organized into five parts, the first two parts cover the use of QDs in imaging fixed and living cells (and tissues). Protocols are included for using QDs in routine (protein and structural cellular labeling), as well as enabling (single receptor trafficking, clinical pathology, correlative microscopy) applications. Part 3 shows early efforts aimed at using QDs in live animals. The final 2 parts demonstrate the versatility of QD technology in existing assay technology. |
 |
BMV Quantum Subliminal CD Learn Biology: Improve Bio Learning Skills (Ultrasonic Academic Performance Series) Program your subconscious mind to learn Biology. Develop your bio skills, study habits, memory and learning for better test scores and peak academic performance. Create life-changing results using state-of-the-art subliminal and brainwave entrainment technology. Tune your brainwaves to specific frequencies by listening to this CD! Program your subconscious mind for positive lasting results, created by a Certified Hypnotherapist and NLP Practitioner (Neuro-Linguistic Programming). Silent affirmations, inaudible hypnotic suggestions and thousands of powerful subliminal messages program your subconscious mind for positive results. The first 3 tracks have an ocean background. The Silent Ultrasonic Track 4 is completely silent with no sound at all! BMV exclusive Quantum Subliminal Matrix... |
 |
Great Scientific Ideas That Changed the World - DVD - The Teaching Company by The Teaching Company Why has science so dramatically altered how we live and how we think about ourselves? With characteristic energy and verve, Professor Steven L. Goldman declares, "One is tempted to speak of scientific discoveries as being the source of science's power to be a driver of social changethat scientists have been discovering new truths about nature, and that the change follows from that. But I argue that it is scientific ideas that are responsible for this change. Ideas are the source of science's powernot discoveries." And what is the greatest scientific idea of all? For Professor Goldman, that is surely the very idea of science, for as he puts it, "The idea of science itself is an idea that had to be invented." In Great Scientific Ideas That Changed the World, you will explore ideas... |
 |
In Search of the Double Helix: Quantum Physics and life by John Gribbin (Author) |
 |
Quantum Evolution: How Physics' Weirdest Theory Explains Life's Biggest Mystery (Norton Paperback) by Johnjoe McFadden (Author) Johnjoe McFadden "enters new and provocative territory in his marriage of physics and biology" (Science News). His simple but staggering theory of quantum evolution shows how quantum mechanics gives living organisms the ability to initiate specific actions, including new mutations. As Paul Davies exclaims, "if these ideas are right, they will transform our understanding of the relationship between physics and biology" and may radically revise the notion of random evolution and the debate over consciousness and free will. |
|
Proceedings of the International Symposium on Atomic, Molecular and Solid-State Theory and Quantum Biology, held in Honor of John H. Van Vleck at Sanibel Island, Florida, January 18-23, 1971. by Per-Olov (ed) Lowdin (Author) | |
|
Mathematical Approach to Fluctuations: Astronomy, Biology and Quantum Dynamics : Proceedings of the Iias Workshop : Kyoto, Japan May 18-21, 1992 by Takeyuki Hida (Editor) Presents the proceedings of a workshop on the mathematical approach to fluctuations. Contributors discuss: correcting the distortion of optical images by a fluctuating atmosphere; some chaotic features of the celestial X-ray sources; and evolution of the genetic code. | |
|
Proceedings of the 10th International Symposium on Quantum Biology & Quantum Pharmacology (Series: International Journal of Quantum Chemistry, Quantum Biology Symposium Number 9) (No. 9) by Lowdin (Author) The meeting of the 22nd Sanibel Symposia, which included the 9th meeting of the Symposium on Quantum Biology and Quantum Pharmacology, was held in Florida on March 1 - 13, 1982. The three days (March 4 - 6) devoted to Quantum Biology and Quantum Pharmacology saw the presentation of 50 papers by 70 participants from 16 nations, including the Americas, Europe and the Far East. These Proceedings comprise the contributions presented in both the invited talks and the poster session. No transcription is kept of the discussion remarks and debates that were engendered by many of the presentations. Consequently, there is no record of those herein represented. It is hoped that these Proceedings will represent adequately the flavor of the meetings and the current status of research in Quantum... | |
|
Solid Clues: Quantum Physics, Molecular Biology, and the Future of Science by Gerald Feinberg (Author) |
| © 2009 BrightSurf.com |