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Spectroscopy and computational modeling workshops announced

The Membrane Protein Structural Dynamics Consortium (MPSDC) is hosting two workshops on computational modeling and simulation, and spectroscopy methods. These will take place at the University of Chicago campus prior to the conference. Both of these workshops are designed for young investigators to learn some of the cutting edge tools and methodologies that are frequently used in contemporary membrane proteins research.



Computational Modeling Workshop and Mini-Symposium

May 6th – 7th 2014

 


Spectroscopy Workshop

May 7th 2014

Final program for Frontiers in Membrane Protein Dynamics 2014 released

The final program for Frontiers in Membrane Protein Structural Dynamics 2014 has been made available and posted to the website. To see the program, please click here.

Reminder: One more week to register early for Frontiers in Membrane Protein Structural Dynamics 2014

Frontiers in Membrane Protein Structural Dynamics

May 7th, 8th, and 9th, 2014*
Chicago Hilton Hotel, Chicago IL

This meeting is being hosted by the Membrane Protein Structural Dynamics Consortium (MPSDC), an NIH/NIGMS Glue Grant funded consortium which focuses on elucidating the relationship between structure, dynamics and function in a variety of membrane proteins.

The early registration deadline is on April 7th. After this date, registration is still possible but the fee schedule will increase significantly!

Register  Program

* The MPSDC will also host a NAMD mini-course on May 6th, plus satellite computational and spectroscopy workshops on May 7th. These will take place on the campus of the University of Chicago. More information will be released soon.

ABC Transporter paper by Tajkhorshid laboratory recommended on F1000Prime

One of our long-term projects on Structural Dynamics of ABC Transporters integrates computational, biochemical and spectroscopic approaches to understand the structural dynamics of the ATP binding cassette (ABC) transporters, which are associated with a number of human pathologies and play critical roles in the removal of cytotoxic agents.

Among the MPSDC participants in this project is Dr. Emad Tajkhorshid, whose contribution is applying molecular dynamics (MD) simulations integrating experimental constraints to develop structural models for key conformational states and characterize their inter-conversion during the transport cycle.

Tajkhorshid, together with postdoctoral researcher Mahmoud Moradi, recently published a paper on conformational transitions of ATP exporters which was recommended on the F1000Prime or “Faculty of 1000″ website. F1000 is a team of 5,000 Faculty Members – senior scientists and leading experts in all areas of biology and medicine — plus their associates who provide recommendations of important scientific articles, rating them and providing short explanations for their selections.

The publication by Moradi and Tajkhorshid, titled “Mechanistic picture for conformational transition of a membrane transporter at atomic resolution“, was published on November 19, 2013 in PNAS vol. 110, no. 47. The paper describes a nonequilibrium approach which they developed to characterize the conformational transition of MsbA, a member of the ATP-binding cassette exporter family, which is involved in transport of diverse substrates across the membrane. The F1000Prime recommendation, written by Qian Cui, tagged the publication as Good for Teaching, as having an Interesting Hypothesis, and for Technical Advance. Read the F1000 recommendation »

Dancing Proteins: Cell Membrane Transporter Motion May Revolutionize Drug Therapies (video)

The Beckman Institute at the University of Illinois at Urbana-Champaign produced the following video. In the video, Dr. Tajkhorshid describes how his laboratory has successfully simulated the molecular dance moves that a multidrug resistance membrane transporter undertakes as it pumps compounds out of a cell. This is the first time researchers have been able to simulate the motion of a complex membrane transporter in its native environment in full atomic detail and gives drug developers vital new targets to help combat drug-resistant cancers and other diseases.

Other plaudits

The popular NIH Biomedical Beat blog, which covers research news from NIGMS, featured the video on their website. As per the blog page, “In this video, Emad Tajkhorshid of the University of Illinois at Urbana-Champaign explains the molecular dance of ABC transporters, a family of molecular machines that utilize ATP to move substances across the cell membrane. Tajkhorshid and his team recently used computational methods to map the movements between two known structural models of MsbA, a bacterial version of a transporter in human cells that helps to export anti-cancer drugs. They then described the individual steps of the molecular motions during the transport cycle. Understanding the process at such a detailed level could suggest new targets for treating a range of diseases, including some drug-resistant cancers that often make more transporter proteins to kick out medications meant to kill them.”

Additionally, Tajkhorshid and Moradi were also featured in the University of Illinois News Bureau, in an article titled “Difficult dance steps: Team learns how membrane transporter moves.” The article helpfully describes the nature of the research and points to its innovation.


Photo taken from the University of Illinois News Bureau website. Photo by L. Brian Stauffer.

According to the article, “the new findings, reported in the Proceedings of the National Academy of Sciences, will help scientists figure out how other transporters work. The work also offers new insights into multi-drug-resistant (MDR) cancers, some of which use these transporters to export cancer-killing drugs.” Previously, it has been difficult to research large, membrane-bound proteins like MsbA because they are not easy to crystallize, and each crystal structure reflects only one of the many conformations of these shape-shifting proteins. This study marks “the first time that we are characterizing a very complex structural transition at atomic-level resolution for a large protein,” Dr. Tajkhorshid is quoted as saying.

Emad Tajkhorshid is Professor of Biochemistry, Biophysics, and Pharmacology and an affiliate of the Beckman Institute for Advanced Science and Technology at the University of Illinois at Urbana-Champaign.

CLC Channel/Transporter Family Project team combines computational and experimental methodologies in PNAS publication

The Conformational Dynamics in the CLC Channel/Transporter Family Project of the Membrane Protein Structural Dynamics Consortium (MPSDC) has published its first publication titled “Water access points and hydration pathways in CLC H+/Cl- transporters” in Proceedings of the National Academy of Sciences of the United States of America (PNAS). This Consortium Project is spearheaded by Principal Investigator Merritt Maduke. The laboratories of Marc Baldus, Emad Tajkhorshid, and Hassane Mchaourab are also collaborators in the Project’s ongoing research.

Water access points and hydration pathways in CLC H+/Cl- transporters

Figure 3. Entryways of water into the central hydrophobic region. (Han et al. 2013)

Abstract: CLC transporters catalyze transmembrane exchange of chloride for protons. Although a putative pathway for Cl has been established, the pathway of H+ translocation remains obscure. Through a highly concerted computational and experimental approach, we characterize microscopic details essential to understanding H+-translocation. An extended (0.4 µs) equilibrium molecular dynamics simulation of membrane-embedded, dimeric ClC-ec1, a CLC from Escherichia coli, reveals transient but frequent hydration of the central hydrophobic region by water molecules from the intracellular bulk phase via the interface between the two subunits. We characterize a portal region lined by E202, E203, and A404 as the main gateway for hydration. Supporting this mechanism, site-specific mutagenesis experiments show that ClC-ec1 ion transport rates decrease as the size of the portal residue at position 404 is increased. Beyond the portal, water wires form spontaneously and repeatedly to span the 15-Å hydrophobic region between the two known H+ transport sites [E148 (Gluex) and E203 (Gluin)]. Our finding that the formation of these water wires requires the presence of Cl explains the previously mystifying fact that Cl occupancy correlates with the ability to transport protons. To further validate the idea that these water wires are central to the H+ transport mechanism, we identified I109 as the residue that exhibits the greatest conformational coupling to water wire formation and experimentally tested the effects of mutating this residue. The results, by providing a detailed microscopic view of the dynamics of water wire formation and confirming the involvement of specific protein residues, offer a mechanism for the coupled transport of H+ and Cl ions in CLC transporters.

The results were published in Proceedings of the National Academy of Sciences of the United States of America, and are currently made available as an e-publication ahead of print. The citation is as follows:

Wei Han, Ricky C. Cheng, Merritt C. Maduke, and Emad Tajkhorshid.
Water access points and hydration pathways in CLC H+/Cl− transporters
PNAS 2013; published ahead of print December 30, 2013, doi:10.1073/pnas.1317890111

 
Learn more about this publication »

Significance

CLC transporters are biologically essential proteins that catalyze the transmembrane exchange of chloride for protons. The permeation pathway for chloride through the transporters has been well characterized. In this publication, Han et al. study the more elusive permeation pathway for protons. Through computational modeling, they show that water molecules can permeate deep inside the protein and form continuous wires. To test the hypothesis that these water wires mediate proton transport, they mutated residues predicted to impede water wire This research article reports results from the tightly coordinated efforts of a computational and an experimental lab brought together by the Consortium. The study addresses a critical question about the CLC transporter mechanism: how does H+ traverse the hydrophobic expanse of the CLC protein?formation and experimentally evaluated the effects of the mutations. The results from their concerted computational and experimental approach strongly support the role of water in proton transport by CLCs and provide a valuable framework for investigating their overall transport mechanism.

In a commentary piece published by PNAS this month, Mounir Tarek (National Center of Scientific Research at the University of Lorraine, France) describes the significance of this paper for future research of chloride channels, and highlights the fruitful combination of simulation and experimentation: “In PNAS, Han et al. used molecular dynamics (MD) simulations of the CLC-ecl, a CLC exchanger from Escherichia coli to specifically address this issue. The predictions of their calculations were tested by additional experiments, providing a robust description of the molecular prerequisites to proton transport in CLC-ecl and a framework for refining models of the Cl-/H+-coupled transport in CLCs.”

Indeed, this research article reports results from the tightly coordinated efforts of a computational and an experimental lab brought together by the Consortium. The study addresses a critical question about the CLC transporter mechanism: how does H+ traverse the hydrophobic expanse of the CLC protein? The MD simulations performed reveal water dynamics, water-wire formation, and side-chain conformational change not observed in any of the static crystal structures. The functional analyses validated predictions of the simulations and confirm the importance of water dynamics in the transport mechanism. The simulations further reveal that Cl- binding is critical for water-wire formation, thus providing a satisfying explanation for the puzzling experimental observation that Cl- occupancy correlates with the ability of CLCs to transport H+. These studies provide a crucial framework for understanding how H+ and Cl- binding and translocation steps are coordinated in the CLC transporters to control stoichiometric transport.

About the project

The CLC family of chloride channels and transporters is necessary for proper neuronal, cardiovascular, and epithelial function. One of the important aspects of this family of transport proteins is that minute changes in their amino acid sequence can result in a shift in their operation mode from a channel to a transporter. Studying the structural dynamics of CLCs can therefore provide fundamental information on the nature of structural and dynamical differences between passive channels and active transporters.

The Conformational Dynamics in the CLC Channel/Transporter Family project addresses the multiple structural conformations that underlie the dual function of ClC- proteins as both channels and coupled transporters. Using a combination of NMR (solution and solid-state) and molecular dynamics simulations, the multiple conformations that support closely-coupled, stoichiometric ion transport will be accessed by binding and unbinding its two ligands, (Cl- and H+). Additional efforts are made made to use conformation-specific ligands to “lock” CLC proteins in order to study these conformations by crystallography, EPR, and NMR.

Learn more about the project »

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