Overview
Background
We use computer based modelling techniques to understand and predict the the structural and dynamic properties of (bio)molecules including proteins and lipid aggregates.
Born in 1961, I obtained a BSc (Hon 1) at the University of Sydney in 1982. I obtained my PhD in 1986 from the John Curtin School of Medical Research, Australian National University (ANU), on the "Binding Responses Associated with Self-Interacting Ligands: Studies on the Self-Association and Receptor binding of Insulin”. After holding postdoctoral positions at the ANU, University of Groningen, The Netherlands and the Federal Institute of Technology (ETH), Zurich, Switzerland I was appointed Professor of Biophysical Chemistry (Molecular Simulation) University of Groningen, in 1998. In 1998 I also received the Swiss Ruzicka Prize for research in Chemistry for work on simulating peptide folding. In 2004 I was awarded an ARC Federation Fellowship and in February 2005 an honorary chair (Bijzonder Hoogleraar) at the University of Groningen, The Netherlands. I have given over 90 invited lectures at conferences and academic Institutions around the world as well as at a range of summer and winter schools on advanced simulation techniques.
In my research I have performed pioneering simulations of a variety of important biological phenomena, including some of the first atomic simulations of protein unfolding and the first simulations of reversible peptide folding in a realistic environment. In recent years my group performed some of the first atomic and near atomic simulations of the spontaneous aggregation of surfactant and lipid systems into micelles, bilayers and vesicles. These have enabled us, amongst other things, to elucidate the mechanism by which pores are induced within biological membranes in unprecedented detail. Over the last decade I have been intimately involved in the development of the GROMOS force field which is specifically tuned for protein and peptide folding simulations and as well as the development of models for a range of solvents including methanol and trifluoroethanol. I have also been responsible for the development of methodology for the calculations of the thermodynamic properties of biomolecular systems such as free energies of binding and hydration, as well as estimating entropic effects from simulations. Most recently, I have been responsible for the development of novel approaches to promote structure formation in protein folding simulations that can be used for the refinement of protein structures generated by ab initio or by homology methods. Finally, I am associated with two, internationally recognised, (bio)molecular simulation packages the GROningen Molecular Simulation library (GROMOS) and the GROningen Machine for Chemical Simulations (GROMACS).
Availability
- Professor Alan Mark is:
- Available for supervision
- Media expert
Fields of research
Qualifications
- Bachelor (Honours) of Science (Advanced), University of Sydney
- Doctor of Philosophy, Australian National University
Works
Search Professor Alan Mark’s works on UQ eSpace
2001
Journal Article
Free energy barrier estimation of unfolding the alpha-helical surfactant-associated polypeptide C
Zangi, R., Kovacs, H., van Gunsteren, W. F., Johansson, J. and Mark, A. E. (2001). Free energy barrier estimation of unfolding the alpha-helical surfactant-associated polypeptide C. Proteins-structure Function And Genetics, 43 (4), 395-402. doi: 10.1002/prot.1052
2001
Journal Article
Investigation of the mechanism of domain closure in citrate synthase by molecular dynamics simulation
Roccatano, D., Mark, A. E. and Hayward, S. (2001). Investigation of the mechanism of domain closure in citrate synthase by molecular dynamics simulation. Journal of Molecular Biology, 310 (5), 1039-1053. doi: 10.1006/jmbi.2001.4808
2001
Journal Article
Essential dynamics of reversible peptide folding: Memory-free conformational dynamics governed by internal hydrogen bonds
de Groot, B. L., Daura, X., Mark, A. E. and Grubmuller, H. (2001). Essential dynamics of reversible peptide folding: Memory-free conformational dynamics governed by internal hydrogen bonds. Journal of Molecular Biology, 309 (1), 299-313. doi: 10.1006/jmbi.2001.4655
2001
Journal Article
Simulation of the spontaneous aggregation of phospholipids into bilayers
Marrink, S. J., Lindahl, E., Edholm, O. and Mark, A. E. (2001). Simulation of the spontaneous aggregation of phospholipids into bilayers. Journal of The American Chemical Society, 123 (35), 8638-8639. doi: 10.1021/ja0159618
2000
Journal Article
A new 2,2,2-triflouroethanol model for molecular dynamics simulations
Fioroni, Marco, Burger, Klaus, Mark, Alan E. and Roccatano, Danilo (2000). A new 2,2,2-triflouroethanol model for molecular dynamics simulations. The Journal of Physical Chemistry Part B: Condensed Matter, Materials, Surfaces, Interfaces and Biophysical, 104 (51), 12347-12354. doi: 10.1021/jp002115v
2000
Journal Article
Molecular dynamics simulation of the kinetics of spontaneous micelle formation
Marrink, S. J., Tieleman, D. P. and Mark, A. E. (2000). Molecular dynamics simulation of the kinetics of spontaneous micelle formation. Journal of Physical Chemistry B, 104 (51), 12165-12173. doi: 10.1021/jp001898h
2000
Journal Article
Absolute entropies from molecular dynamics simulation trajectories
Schafer, Heiko, Mark, Alan E. and van Gunsteren, Wilfred F. (2000). Absolute entropies from molecular dynamics simulation trajectories. Journal of Chemical Physics, 113 (18), 7809-7817. doi: 10.1063/1.1309534
2000
Journal Article
The effect of force-field parameters on properties of liquids: Parameterization of a simple three site model for methanol
Walser, Regula, Mark, Alan E., van Gunsteren, Wilfred F., Lauterbach, Monika and Wipff, Georges (2000). The effect of force-field parameters on properties of liquids: Parameterization of a simple three site model for methanol. Journal of Chemical Physics, 112 (23), 10450-10459. doi: 10.1063/1.481680
2000
Journal Article
On the temperature and pressure dependence of a range of properties of a type of water model commonly used in high-temperence protein unfolding simulations
Walser, Regula, Mark, Alan E. and van Gunsteren, Wilfred F. (2000). On the temperature and pressure dependence of a range of properties of a type of water model commonly used in high-temperence protein unfolding simulations. Biophysical Journal, 78 (6), 2752-2760. doi: 10.1016/S0006-3495(00)76820-2
2000
Journal Article
The GROMOS96 benchmarks for molecular simulation
Bonvin, Alexandre M. J. J., Mark, Alan E. and van Gunsteren, Wilfred F. (2000). The GROMOS96 benchmarks for molecular simulation. Computer Physics Communications, 128 (3), 550-557. doi: 10.1016/S0010-4655(99)00540-8
1999
Journal Article
Peptide folding simulations: No solvent required?
Daura, X., van Gunsteren, W. F. and Mark, A. E. (1999). Peptide folding simulations: No solvent required?. Computer Physics Communications, 123 (1-3), 97-102. doi: 10.1016/S0010-4655(99)00261-1
1999
Journal Article
Estimating relative free energies from a single ensemble: Hydration free energies
Schäfer, Heiko, Van Gunsteren, Wilfred F. and Mark, Alan E. (1999). Estimating relative free energies from a single ensemble: Hydration free energies. Journal of Computational Chemistry, 20 (15), 1604-1617. doi: 10.1002/(SICI)1096-987X(19991130)20:153.0.CO;2-A
1999
Journal Article
The effect of motional averaging on the calculation of NMR-derived structural properties
Daura, Xavier, Antes, Iris, van Gunsteren, Wilfred F, Thiel, Walter and Mark, Alan E. (1999). The effect of motional averaging on the calculation of NMR-derived structural properties. Proteins: Structure, Function, and Bioinformatics, 36 (4), 542-555. doi: 10.1002/(SICI)1097-0134(19990901)36:43.0.CO;2-M
1999
Journal Article
The GROMOS biomolecular simulation program package
Scott, Walter R. P., Hunenberger, Philippe H., Tironi, Ilario G., Mark, Alan E., Billeter, Salomon R., Fennen, Jens, Torda, Andrew E., Huber, Thomas, Kruger, Peter and van Gunsteren, Wilfred F. (1999). The GROMOS biomolecular simulation program package. Journal of Physical Chemistry A, 103 (19), 3596-3607. doi: 10.1021/jp984217f
1999
Journal Article
On the validity of Stokes’ law at the molecular level
Walser, Regula, Mark, Alan E. and van Gunsteren, Wilfred F. (1999). On the validity of Stokes’ law at the molecular level. Chemical Physics Letters, 303 (5-6), 583-586. doi: 10.1016/S0009-2614(99)00266-3
1999
Journal Article
Folding-unfolding thermodynamics of a beta-heptapeptide form equilibrium simulations
Daura, X., van Gunsteren, W. F. and Mark, A. E. (1999). Folding-unfolding thermodynamics of a beta-heptapeptide form equilibrium simulations. Proteins: Structure, Function, and Genetics, 34 (3), 269-280. doi: 10.1002/(SICI)1097-0134(19990215)34:3
1999
Journal Article
Peptide Folding: When simulation meets experiment
Daura, Xavier, Gadermann, Karl, Jaun, Bernhard, Seebach, Dieter, van Gunsteren, Wilfred F. and Mark, Alan E. (1999). Peptide Folding: When simulation meets experiment. Angewandte Chemie, 38 (1-2), 236-240. doi: 10.1002/(SICI)1521-3773(19990115)38:1/23.0.CO;2-M
1998
Journal Article
On using time-averaging restraints in molecular dynamics simulation
Scott, Walter R. P., Mark, Alan E. and van Gunsteren, W.F. (1998). On using time-averaging restraints in molecular dynamics simulation. Journal of Biomolecular NMR, 12 (4), 501-508. doi: 10.1023/A:1008306732538
1998
Journal Article
Reversible peptide folding in solution by molecular dynamics simulation
Daura, Xavier, Jaun, Bernhard, Seebach, Dieter, van Gunsteren, Wilfred F. and Mark, Alan E. (1998). Reversible peptide folding in solution by molecular dynamics simulation. Journal of Molecular Biology, 280 (5), 925-932. doi: 10.1006/jmbi.1998.1885
1998
Journal Article
Molecular dynamics simulations of peptide fragments from hen lysozyme: Insight into non-native protein conformations
Smith, Lorna J., Mark, Alan E., Dobson, Christopher M. and van Gunsteren, Wilfred (1998). Molecular dynamics simulations of peptide fragments from hen lysozyme: Insight into non-native protein conformations. Journal of Molecular Biology, 280 (4), 703-719. doi: 10.1006/jmbi.1998.1892
Funding
Current funding
Past funding
Supervision
Availability
- Professor Alan Mark is:
- Available for supervision
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Available projects
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Understanding the mechanism of action of antimicrobial peptides
Cytolytic antimicrobial peptides form an integral part of the innate immune system of many vertebrates including man. These antimicrobial peptides act by binding to and disrupting bacterial cell membrane. They are highly specific and increasingly recognized as a potential source of novel antibiotic agents. A major limitation in the further development of AMPs in a therapeutic setting is that the mechanism by which these peptides discriminate between different classes of membranes is still poorly understood. The aim of this project is to use computer simulation techniques elucidate the mechanism of action of cytolytic peptides at an atomic level. Specifically to study their binding to the outer membrane of specific pathogenic bacteria and determine the key structural and physico-chemical properties that allows them to distinguish between the pathogenic intruder and host cells.
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Force fields for drug-like molecules
A critical consideration when modelling biomolecular systems is the description of the interactions. The aim of this project is to develop and validate an automated force field topology builder (ATB; http://compbio.biosci.uq.edu.au/atb/). The ATB provides force field descriptions for drug-like molecules for use in studying the ligand-macromolecule interactions with applications in drug design and X-ray refinement.
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From model systems to true biological membranes
Lipid molecules are fundamental components of biological membranes. Not only do they play a role in the compartmentalization of cells and organelles but, also participate in fundamental processes such as cell division and intracellular trafficking. The aim of this project is to develop detailed models representing the membranes of specific cell types.
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The mechanism of activation of cytokine receptors:
The activation of cell surface receptors such as the growth hormone receptor and the epidermal growth factor receptor is a critical step in cell regulation. Molecular dynamics simulation techniques will be used to characterize the conformational changes within the extracellular and transmembrane domains that accompany the binding of the cytokine (growth hormone1 or epidermal growth factor) to its receptor thereby shedding light on the mechanism of action of cytokine receptors in general.
Supervision history
Current supervision
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Doctor Philosophy
Development of novel computational algorithms for biotechnological applications including molecular simulation and drug design
Principal Advisor
-
Doctor Philosophy
Enhanced force fields for computational drug design and materials research.
Principal Advisor
Other advisors: Professor Paul Burn
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Doctor Philosophy
Investigation of pH-dependent bacterial transporters
Principal Advisor
Other advisors: Professor Debra Bernhardt
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Doctor Philosophy
Developing transferable force fields to simulate biological membranes
Principal Advisor
-
Doctor Philosophy
Validation of predicted solution processed organic semiconductor properties
Associate Advisor
Other advisors: Associate Professor Paul Shaw, Professor Paul Burn
Completed supervision
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2024
Doctor Philosophy
Developing transferable force fields to simulate biological membranes
Principal Advisor
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2024
Doctor Philosophy
Investigating the mechanisms of growth and morphology of organic thin films
Principal Advisor
Other advisors: Professor Paul Burn
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2023
Doctor Philosophy
Understanding Protein Mediated Membrane Fusion
Principal Advisor
Other advisors: Professor Brett Collins
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2022
Doctor Philosophy
Modelling Glycogen Structure and Metabolism
Principal Advisor
Other advisors: Professor Bob Gilbert
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2022
Doctor Philosophy
Understanding How Antimicrobial Peptides Interact with Membranes
Principal Advisor
Other advisors: Professor Mikael Boden
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2021
Doctor Philosophy
Computational approaches to determine the relevant chemical species in drug design
Principal Advisor
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2019
Doctor Philosophy
Improving Automated Force Field Parametrisation for Molecular Simulation: A Graph Approach
Principal Advisor
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2018
Doctor Philosophy
Improving the Accuracy of Molecular Dynamics Simulations: Parameterisation of Interaction Potentials for Small Molecules
Principal Advisor
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2017
Doctor Philosophy
Signals in Motion: Determining How Signal Transduction is Mechanically Coupled Through Type-I Cytokine Receptors
Principal Advisor
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2016
Doctor Philosophy
Development and validation of the force field parameters for drug-like molecules and their applications in structure-based drug design
Principal Advisor
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2015
Doctor Philosophy
Understanding multidrug resistance: Molecular Dynamics studies of ligand recognition by P-glycoprotein
Principal Advisor
Other advisors: Professor Megan O'Mara
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2013
Doctor Philosophy
Targeting the membrane: molecular dynamics studies of protein-membrane interactions.
Principal Advisor
Other advisors: Professor Megan O'Mara
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2013
Doctor Philosophy
The application of free energy calculations and molecular dynamics simulations to drug design
Principal Advisor
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2011
Doctor Philosophy
Effect of external conditions on membrane-protein interactions
Principal Advisor
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2009
Master Philosophy
Molecular Dynamics on a Grand Scale: Towards large-scale atomistic simulations of self-assembling biomolecular systems
Principal Advisor
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2017
Doctor Philosophy
Conservative interpretation of small-angle X-ray scattering data from biological macromolecules.
Associate Advisor
Other advisors: Professor Bostjan Kobe
Media
Enquiries
Contact Professor Alan Mark directly for media enquiries about:
- Atomic force fields
- Computational drug design
- Computer simulation - molecular
- Drug design
- Free energy calculations
- GROMACS - GROningen MAchine for Chemical Simulations
- GROMOS - force field for molecular dynamics simulation
- Molecular dynamics
- Molecules and computation
- Protein folding
- Protein structure
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