Current
Computer-Aided Drug Design
ISSN: 1573-4099
Current Computer-Aided
Drug Design
Volume 4, Number 2, June 2008
Contents
On the Paradigm Shift Towards Multitarget Selective
Drug Designb Pp. 76-90
Nigus Dessalew and Workalemahu Mikre
[Abstract]
Predictive QSAR Models for Polyspecific Drug Targets:
The Importance of Feature Selection Pp. 91-110
M.A. Demel, Andres G.K. Janecek, Khac-Minh Thai,
Gerhard F. Ecker and Wilfried N. Gansterer
[Abstract]
Enzyme-Substrate Binding Interaction Energies
and Their Application to the Cytochrome P450 Systemb
Pp. 111-122
David F.V. Lewis, Yuko Ito and Peter
S. Goldfarb
[Abstract]
Exploring the Odorant Binding Site of a G-Protein-Coupled
Olfactory Receptorb Pp. 123-131
Sayako Katada, Takatsugu Hirokawa and
Kazushige Touhara
[Abstract]
Variable Selection in QSAR Models for Drug Design
Pp. 132-142
Irina G. Tsygankova
[Abstract]
How to Efficiently Include Receptor Flexibility
During Computational Docking Pp. 143-153
Andreas May, Florian Sieker and Martin
Zacharias
[Abstract]
Abstracts
[Back to top]
On the Paradigm Shift Towards Multitarget Selective
Drug Design
Nigus Dessalew and Workalemahu Mikre
Modern drug discovery has contributed much to the progress
of medicine and well being of societies during the past century.
Generally, a disease relevant macromolecule is studied first
in vitro, in cells and in whole organisms, and evaluated
as a potential drug target for a specific therapeutic intervention.
Medicinal chemistry projects then commence by the search and
identification of a binding partner for the single macromolecular
target. This one-drug one-target design strategy is what has
been in use for several decades and is widely pursued both
in the academia and in the pharmaceutical industry. However,
many debilitating disorders such as cancers, cardiovascular
diseases, dementias, depression, to name few, basically result
from multiple molecular abnormalities, not from a single defect.
Moreover, systems biology has revealed that human cells and
tissues are composed of complex, networked systems with redundant,
convergent and divergent signaling pathways. And hence, it
is increasingly being recognized that a balanced modulation
of the several but relevant and inter connected targets can
provide a superior therapeutic and side effect profile of
drugs compared to the more conventional one-drug one-target
one-disease practice. Although the currently available drugs
are inherently multiple acting, the design of multi-target
selective drugs is just a recent trend and is beginning to
be appreciated by the scientific community. The success of
this promising drug-design paradigm will depend on advances
in the identification of the correct and relevant multiple
targets and their binding partners. This manuscript reviews
the emerging concepts of attacking multiple targets through
a deliberate design of agents which could bind with a selected
number of several proteins relevant in a given disease. The
current knowledge and tools for the rational design of a multitarget
selective ligand is reviewed and the challenges, limitations
and outlook of such novel ligand design strategy is presented.
[Back to top]
Predictive QSAR Models for Polyspecific Drug Targets:
The Importance of Feature Selection
M.A. Demel, Andres G.K. Janecek, Khac-Minh Thai,
Gerhard F. Ecker and Wilfried N. Gansterer
Since the advent of QSAR (quantitative structure activity
relationship) modeling quantitative representations of molecular
structures are encoded in terms of information-preserving
descriptor values. Nowadays, a nearly infinite variety of
potential descriptors is available and descriptor selection
is no longer a task which can be done manually. There is an
increasing need for automation in order to reduce the dimensionality
of the descriptor space. Classical feature selection (FS)
and dimensionality reduction (DR) methods like principal component
analysis, which relies on the selection of those descriptors
that contribute most to the variance of a data set, often
fail in providing the best classification result. More sophisticated
methods like genetic algorithms, self-organizing-maps and
stepwise linear discriminant analysis have proven to be useful
techniques in the process of selecting descriptors with a
significant discriminative power.
The topic FS and DR becomes even more important when predictive
models are approached which should describe the QSAR of highly
promiscuous target proteins. The ABC-transporter family, the
cardiac hERG-potassium channel, and the hepatic cytochrom-P450-family
are classical representatives of such poly-specific proteins.
In this case the interaction pattern is a rather complex one
and thus the selection of the most predictive descriptors
needs advanced methods. This review surveys FS and DR methods
that have recently been successfully applied to classify ligands
of poly-specific target proteins.
[Back to top]
Enzyme-Substrate Binding Interaction Energies and
Their Application to the Cytochrome P450 System
David F.V. Lewis, Yuko Ito and Peter
S. Goldfarb
The various contributions to binding energies for cytochrome
P450 enzyme-substrate interactions are discussed in the light
of intermolecular forces of attraction in biological systems.
These energies include: electrostatic, van der Waals, hydrogen
bond, π-π
stacking and desolvation processes. These individual components
can be used to estimate the binding energies of P450 substrates,
and the example of camphor in CYP101 is employed to demonstrate
the particular merits of these approaches. The various methods
of calculating desolvation energies are demonstrated for camphor
binding to CYP101, together with estimation of the hydrogen
bond energy associated with this process as they are thought
to be the major contributions. The binding of warfarin to
CYP2C9 is also discussed and evaluated in the light of the
estimations for camphor binding to CYP101, thus indicating
a degree of comparison between examples of bacterial and human
P450-substrate interactions. The various force fields (Amber,
Tripos and AutoDock) employed in energy calculations are also
compared, together with typical values for the several individual
components to the overall binding energy.
[Back to top]
Exploring the Odorant Binding Site of a G-Protein-Coupled
Olfactory Receptor
Sayako Katada, Takatsugu Hirokawa and Kazushige
Touhara
The olfactory system has sophisticated molecular mechanisms
for recognizing and discriminating an enormous number of odorants.
The detection of odorants in mammals is mediated by several
hundreds of olfactory receptors (ORs), which comprise the
largest superfamily of G-protein-coupled receptors (GPCRs)
in the genome. Because GPCRs are major targets for therapeutic
application, ample experimental data and computer modeling
studies are available on some GPCRs. However, even though
ORs represent approximately one half of all GPCRs, few structural
and functional studies have been carried out for ORs. Here,
we review recent studies on mechanisms underlying the molecular
recognition of a large number of odorants by ORs. A combination
of computational and experimental approaches has revealed
the odorant-binding site of ORs. Point mutations in the odorant
binding site based on the mode of odorant binding resulted
in predicted changes in ligand specificity and antagonist
activity, demonstrating the validity of the binding site model
and indicating that it may be applied to the design of useful
ligands for ORs. Understanding the molecular basis for the
discriminative power of the olfactory system will also provide
insight into how to design agonists or antagonists of GPCRs.
[Back to top]
Variable Selection in QSAR Models for Drug Design
Irina G. Tsygankova
QSAR modeling, a powerful method for the computer-aided
drug design, demands appropriate choice of molecular structure
description. At present thousands descriptors of molecular
structure are suggested in QSAR and QSPR approaches. The selection
of a subset of the most relevant molecular descriptors, used
as variables, is important step in model development. In this
short review recently reported algorithms for variable subset
selection procedure are considered. The scoring functions
and some other useful guidelines are discussed.
[Back to top]
How to Efficiently Include Receptor Flexibility During
Computational Docking
Andreas May, Florian Sieker and
Martin Zacharias
Target-based drug design uses available 3D structural
information of receptor molecules to either dock putative
ligand molecules to receptor binding sites or to de-novo design
new ligands. In many cases accurate prediction of putative
binding geometries requires the appropriate inclusion of conformational
flexibility of both the ligand as well as the receptor structure.
The problem of appropriate treatment of conformational flexibility
during docking is also tightly connected to the improvement
of scoring a docked ligand-receptor complex. Highly accurate
scoring of a ligand placement is only possible if the complex
geometry has been predicted with high precision. Considerable
progress has already been achieved in modeling the conformational
flexibility of small organic ligands during docking. Although
of similar importance, receptor flexibility has not been tackled
satisfactorily despite the steady increase in computational
power. Especially during virtual screening of large drug-like
compound libraries the target structure often is still kept
rigid. However, many protein structures undergo local structural
changes (side chain or loop motions) as well as global changes
in the backbone geometry upon complex formation. In recent
years, several promising approaches to efficiently tackle
receptor flexibility have been introduced ranging from conformational
ensemble methods to explicit inclusion of the most relevant
receptor degrees of freedom. Possible applications and future
directions on improving flexible docking approaches will be
discussed.
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