How, exactly, do those bonds work? What happens when a pulling force is applied to those bonds? How long before they break? Does a better understanding of all those bonds and their responses to force have implications for fighting disease?
Sanjeevi Sivasankar, an Iowa State assistant professor of physics and astronomy and an associate of the U.S. Department of Energy’s Ames Laboratory, is leading a research team that’s answering those questions as it studies the biomechanics and biophysics of the proteins that bond cells together.
The researchers discovered three types of bonds when they subjected common adhesion proteins (called cadherins) to a pulling force: ideal, catch and slip bonds. The three bonds react differently to that force: ideal bonds aren’t affected, catch bonds last longer and slip bonds don’t last as long.
The findings have just been published by the online Early Edition of the Proceedings of the National Academy of Sciences.
Sivasankar said ideal bonds – the ones that aren’t affected by the pulling force – had not been seen in any previous experiments. The researchers discovered them as they observed catch bonds transitioning to slip bonds.
“Ideal bonds are like a nanoscale shock absorber,” Sivasankar said. “They dampen all the force.”
And the others?
“Catch bonds are like a nanoscale seatbelt,” he said. “They become stronger when pulled. Slip bonds are more conventional; they weaken and break when tugged.”
In addition to Sivasankar, the researchers publishing the discovery are Sabyasachi Rakshit, an Iowa State post-doctoral research associate in physics and astronomy and an Ames Laboratory associate; Kristine Manibog and Omer Shafraz, Iowa State doctoral students in physics and astronomy and Ames Laboratory student associates; and Yunxiang Zhang, a post-doctoral research associate for the University of California, Berkeley’s California Institute for Quantitative Biosciences.
The project was supported by a $308,000 grant from the American Heart Association, a $150,000 Basil O’Connor Award from the March of Dimes Foundation and Sivasankar’s Iowa State startup funds.
The researchers made their discovery by taking single-molecule force measurements with an atomic force microscope. They coated the microscope tip and surface with cadherins, lowered the tip to the surface so bonds could form, pulled the tip back, held it and measured how long the bonds lasted under a range of constant pulling force.
The researchers propose that cell binding “is a dynamic process; cadherins tailor their adhesion in response to changes in the mechanical properties of their surrounding environment,” according to the paper.
When you cut your finger, for example, cells filling the wound might use catch bonds that resist the pulls and forces placed on the wound. As the forces go away with healing, the cells may transition to ideal bonds and then to slip bonds.
Sivasankar said problems with cell adhesion can lead to diseases, including cancers and cardiovascular problems.
And so Sivasankar said the research team is pursuing other studies of cell-to-cell bonds: “This is the beginning of a lot to be discovered about the role of these types of interactions in healthy physiology as well as diseases like cancer.”
Sanjeevi Sivasankar | Source: EurekAlert!
Further information: www.iastate.edu
More articles from Life Sciences:
In Early Earth, Iron Helped RNA Catalyze Electron Transfer
21.05.2013 | Georgia Institute of Technology, Research Communications
Resistance to last-line antibiotic makes bacteria resistant to immune system
21.05.2013 | American Society for Microbiology
University of Würzburg physicists have succeeded in creating a new type of laser.
Its operation principle is completely different from conventional devices, which opens up the possibility of a significantly reduced energy input requirement. The researchers report their work in the current issue of Nature.
It also emits light the waves of which are in phase with one another: the polariton laser, developed ...
Innsbruck physicists led by Rainer Blatt and Peter Zoller experimentally gained a deep insight into the nature of quantum mechanical phase transitions.
They are the first scientists that simulated the competition between two rival dynamical processes at a novel type of transition between two quantum mechanical orders. They have published the results of their work in the journal Nature Physics.
“When water boils, its molecules are released as vapor. We call this ...
Researchers have shown that, by using global positioning systems (GPS) to measure ground deformation caused by a large underwater earthquake, they can provide accurate warning of the resulting tsunami in just a few minutes after the earthquake onset.
For the devastating Japan 2011 event, the team reveals that the analysis of the GPS data and issue of a detailed tsunami alert would have taken no more than three minutes. The results are published on 17 May in Natural Hazards and Earth System Sciences, an open access journal of ...
A new study of glaciers worldwide using observations from two NASA satellites has helped resolve differences in estimates of how fast glaciers are disappearing and contributing to sea level rise.
The new research found glaciers outside of the Greenland and Antarctic ice sheets, repositories of 1 percent of all land ice, lost an average of 571 trillion pounds (259 trillion kilograms) of mass every year during the six-year study period, making the oceans rise 0.03 inches (0.7 mm) per year. ...
About 99% of the world’s land ice is stored in the huge ice sheets of Antarctica and Greenland, while only 1% is contained in glaciers.
However, the meltwater of glaciers contributed almost as much to the rise in sea level in the period 2003 to 2009 as the two ice sheets: about one third. This is one of the results of an international study with the involvement of geographers from the University of Zurich.
21.05.2013 | Studies and Analyses
21.05.2013 | Life Sciences
21.05.2013 | Studies and Analyses
17.05.2013 | Event News
15.05.2013 | Event News
08.05.2013 | Event News