New tool gives researchers a glimpse of biomolecules in motion

January 14, 2009

The ability of biomolecules to flex and bend is important for the performance of many functions within living cells. However, researchers interested in how biomolecules such as amino acids and proteins function have long had to make inferences from a series of X-ray-like "still pictures" of pure crystalline samples. Now, using a new technique based on terahertz (THz) spectroscopy, scientists at the National Institute of Standards and Technology (NIST) have recently taken the first step toward revealing the hidden machinations of biomolecules in water.*

With wavelengths that range from 1 millimeter to 25 micrometers, terahertz radiation falls between the infrared and microwave spectral regions. Researchers can determine how molecules are moving by passing terahertz radiation through a sample and measuring which wavelengths are absorbed. Unfortunately, room temperature water, the medium in which biological molecules typically are studied, absorbs nearly all of the terahertz radiation, limiting the utility of terahertz spectroscopy for probing biomolecular function.

To avoid the water problem, the NIST team needed to find a way to provide a simple but realistic environment for the biomolecules that contained the least amount of water possible. NIST researcher Ted Heilweil, National Research Council postdoctoral fellow Catherine Cooksey and NIST Summer Undergraduate Research Fellow Ben Greer from Carnegie Mellon University found their solution in the form of nanoscale droplets made of soap-like molecules called micelles.

Using the micelles as tiny test tubes, the team filled the hollow molecules with a small sample of water and the amino acid L-proline, a protein building block. Measurements validated their hypothesis that the micelles would provide an aqueous environment that allows the amino acid to flex and bend while limiting the absorption of the terahertz radiation by water. The terahertz measurements on this simple biomolecule compared well with expectations from other studies, further validating the technique.

According to Heilweil, this study is an important first step toward using terahertz radiation for studying biomolecules. More ambitious measurements on larger molecules such as small peptides, proteins, and DNA fragments will be more challenging, but he says it may be possible in the near future.

"If we can get larger molecules in [the micelles], we can get a much better idea of how living molecules function," Heilweil said. "This will let us see the basic, most fundamental building blocks of life as they move, which is very exciting."

National Institute of Standards and Technology (NIST)

---

---

	Biomolecular Crystallography: Principles, Practice, and Application to Structural Biology by Bernhard Rupp (Author) Synthesizing over thirty years of advances into a comprehensive textbook, Biomolecular Crystallography describes the fundamentals, practices, and applications of protein crystallography.  Deftly illustrated in full-color by the author, the text describes mathematical and physical concepts in accessible and accurate language. It distills key concepts for understanding the practice and analysis of protein crystal structures and contains examples of biologically-relevant molecules, complexes, and drug target structures. Biomolecular Crystallography will be a valuable resource for advanced undergraduate and graduate students and practitioners in structural biology, crystallography, and structural bioinformatics.
	Statistical Physics of Biomolecules: An Introduction by Daniel M. Zuckerman (Author) From the hydrophobic effect to protein-ligand binding, statistical physics is relevant in almost all areas of molecular biophysics and biochemistry, making it essential for modern students of molecular behavior. But traditional presentations of this material are often difficult to penetrate. Statistical Physics of Biomolecules: An Introduction brings "down to earth" some of the most intimidating but important theories of molecular biophysics. With an accessible writing style, the book unifies statistical, dynamic, and thermodynamic descriptions of molecular behavior using probability ideas as a common basis. Numerous examples illustrate how the twin perspectives of dynamics and equilibrium deepen our understanding of essential ideas such as entropy, free energy, and the meaning of rate...
	Templated xerogels as platforms for biomolecule-less biomolecule sensors [An article from: Analytica Chimica Acta] by Z. Tao (Author), E.C. Tehan (Author), R.M. Bukowski (Author), Y. Tang (Author), Shugha (Author) This digital document is a journal article from Analytica Chimica Acta, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: We report on a new sensor strategy that we have termed protein imprinted xerogels with integrated emission sites (PIXIES). The PIXIES platform is completely self-contained, and it achieves analyte recognition without a biorecognition element (e.g., antibody). The PIXIES relies upon sol-gel-derived xerogels, molecular imprinting, and the selective installation of a luminescent reporter molecule directly within the molecularly imprint site. In operation the templated xerogel selectively recognizes the target...
	Encapsulation of biomolecules for bioanalytical purposes: Preparation of diclofenac antibody-doped nanometer-sized silica particles by reverse micelle ... [An article from: Analytica Chimica Acta] by F. Tsagkogeorgas (Author), M. Ochsenkuhn-Petropoulou (Author), Niess (Author) This digital document is a journal article from Analytica Chimica Acta, published by Elsevier in 2006. The article is delivered in HTML format and is available in your Amazon.com Media Library immediately after purchase. You can view it with any web browser. Description: In recent years, the sol-gel technique has attracted increasing interest as a unique approach to immobilize biomolecules for bioanalytical applications as well as biochemical and biophysical studies. For this purpose, crushed biomolecule-doped sol-gel glass monoliths have been widely used. In the present work, for the first time, the encapsulation of anti-diclofenac antibodies in silica nanoparticles was carried out by a combination of reverse micelle and sol-gel technique. Cyclohexane was used for the...
	Mass Spectrometry in Structural Biology and Biophysics: Architecture, Dynamics, and Interaction of Biomolecules (Wiley - Interscience Series on Mass Spectrometry) by Igor A. Kaltashov (Author), Stephen J. Eyles (Author), Dominic M. Desiderio (Series Editor), Nico M. Nibbering (Series Editor) The definitive guide to mass spectrometry techniques in biology and biophysicsThe use of mass spectrometry (MS) to study the architecture and dynamics of proteins is increasingly common within the biophysical community, and Mass Spectrometry in Structural Biology and Biophysics: Architecture, Dynamics, and Interaction of Biomolecules, Second Edition provides readers with detailed, systematic coverage of the current state of the art.Offering an unrivalled overview of modern MS-based armamentarium that can be used to solve the most challenging problems in biophysics, structural biology, and biopharmaceuticals, the book is a practical guide to understanding the role of MS techniques in biophysical research. Designed to meet the needs of both academic and industrial researchers, it makes mass...
	Energy Landscapes: Applications to Clusters, Biomolecules and Glasses (Cambridge Molecular Science) by David Wales (Author) Many research groups are now attempting to understand how the properties of systems ranging from small molecules to proteins and glasses are determined by the energy landscape. This book provides a self-contained account of energy landscape theory and how it is applied in studies of clusters, biomolecules and glasses. Beautifully illustrated in full color, the volume is geared to graduate students as well as professionals.
	Low-Energy Electron Scattering from Molecules, Biomolecules and Surfaces by Petr Carsky (Editor), Roman Curik (Editor) Since the turn of the 21st century, the field of electron molecule collisions has undergone a renaissance. The importance of such collisions in applications from radiation chemistry to astrochemistry has flowered, and their role in industrial processes such as plasma technology and lighting are vital to the advancement of next generation devices. Furthermore, the development of the scanning tunneling microscope highlights the role of such collisions in the condensed phase, in surface processing, and in the development of nanotechnology. Low-Energy Electron Scattering from Molecules, Biomolecules and Surfaces highlights recent progress in the theory and experiment of electron-molecule collisions, providing a detailed review of the current state of knowledge of electron molecule...
	Rosalind Franklin: Photographing Biomolecules (Trailblazers in Science and Technology) by Lisa Yount (Author) Growing up in the interwar period in London, Rosalind Franklin was determined to become a scientist, defying her father's wishes. After World War II, Franklin worked at the French government's central chemical research laboratory, where she learned X-ray crystallography. This technique relies on a beam of X-rays that passes through a crystal and strikes photographic film, letting a trained reader to see a three-dimensional arrangement of atoms. Her training in this field led to opportunities to photograph DNA, which allowed researchers to study in depth this complex molecule and to come to conclusions about its structure, including scientists James Watson and Francis Crick. Though Franklin proposed several conclusions similar to Watson and Crick's, Franklin was not sufficiently credited...
	Chemistry of Biomolecules by S. P. Bhutani (Author) Biomolecules are molecules that are involved in the maintenance and metabolic processes of all living organisms. Ideal for graduate students and researchers, Chemistry of Biomolecules offers extensive coverage of important biomolecules from an organic chemistry point of view. The esteemed author discusses carbohydrates, amino acids, peptides, proteins, enzymes, pyrimidines, purines, nucleic acids, terpenoids, and lipids. He describes the various topics in simple, lucid language and explains the mechanisms of the reactions wherever required.
	Solvation Effects on Molecules and Biomolecules: Computational Methods and Applications (Challenges and Advances in Computational Chemistry and Physics) by Sylvio Canuto (Editor) This volume is an interdisciplinary treatise on the theoretical approach to solvation problems. It describes the essential details of the theoretical methods and places them into the context of modern applications, and hence is of broad interest to theoreticians and experimentalists. The assembly of these modern methods and applications into one volume is a unique contribution to date and gives a broad and ample description of the field in its present stage of development.