Current
Topics in Medicinal Chemistry
ISSN: 1568-0266
Current Topics
in Medicinal Chemistry
Volume 6, Number 15, 2006
Contents
Predicting Drug Metabolism In Silico
Guest Editors: Drs. Michael Sorich and Paul Smith
Editorial Pp. 1567-1568
Quantitative Structure Activity Relationships in Drug Metabolism
Pp. 1569-1578
Kamaldeep K. Chohan, Stuart W. Paine and Nigel J. Waters
[Abstract]
Machine Learning Techniques for In Silico
Modeling of Drug Metabolism Pp. 1579-1591
Thomas Fox and Jan M. Kriegl
[Abstract]
Application of Support Vector Machines to In
Silico Prediction of Cytochrome P450 Enzyme Substrates
and Inhibitors Pp. 1593-1607
C.W. Yap, Y. Xue, Z.R. Li and Y.Z. Chen
[Abstract]
Computational Models for Predicting Interactions
with Cytochrome P450 Enzyme Pp. 1609-1618
Rieko Arimoto
[Abstract]
Insights into Drug Metabolism from Modelling Studies
of Cytochrome P450-Drug Interactions Pp. 1619-1626
Jean-Didier Maréchal and Michael J. Sutcliffe
[Abstract]
Predicting Drug Metabolism Induction In Silico
Pp. 1627-1640
Daniela Schuster, Theodora M. Steindl and Thierry Langer
[Abstract]
Structure and Mechanism of Arylamine N
Acetyltransferases Pp. 1641-1654
I.M. Westwood, A. Kawamura, E. Fullam, A.J. Russell, S.G.
Davies and E. Sim
[Abstract]
Abstracts
[Back to top]
Editorial
In silico (computational) simulation of
chemical-biological interactions underpins efforts to remedy
the escalating average cost and timeframe required to develop
a marketable pharmaceutical. Chemicals with poor drug metabolism
properties in humans are unfavourable for medicinal use, typically
presenting problems with bioavailability, half life, inter-individual
variability, and drug-drug interactions. As a result, it is
increasingly seen as prudent to screen chemicals for these
properties as early as possible in the drug discovery and
development process. In silico methods are generally
orders of magnitude faster and less expensive than the best
in vitro methods, enabling screening of drug metabolism
properties on much larger numbers of chemicals and much earlier
in the drug discovery pipeline. Existing in silico
screens span a range of different metabolic properties for
an array of different phase I and phase II enzymes. The Cytochrome
P450 (CYP) family of phase I enzymes plays the greatest role
in drug metabolism in humans and consequently the majority
of research has focused on this enzyme. Nevertheless, Phase
2 enzymes are increasingly recognized as important and research
in this area is growing. One of the most common goals of in
silico screens is the prediction of the ability of a
chemical to inhibit a drug metabolizing enzyme. Other important
metabolic properties studied include regioselectivity of metabolism,
the ability of a chemical to be metabolised, metabolic stability,
and induction of drug metabolising enzymes. A variety of in
silico methodologies have been applied to predict these
properties, including two- and three-dimensional quantitative
structure activity relationships (2D- and 3D-QSAR), pharmacophore
modelling, quantum chemistry, protein modelling, and docking
simulations. The major current challenges of in silico
screens include validation, accuracy and interpretability.
In this issue of Current Topics in Medicinal Chemistry,
titled ‘Predicting drug metabolism in silico’,
the current major issues, directions, techniques, and applications
of this area are reviewed in detail. Although each review
has a different focus, there is sufficient overlap to appreciate
the variety of perspectives existing in the field today.
Chohan, Paine and Waters begin the issue with an in-depth
review of the contemporary 2D QSAR, 3D QSAR, and pharmacophore
approaches that have been applied to gain insight into the
molecular features influencing binding and metabolism by the
major human phase 1 and phase 2 drug metabolising enzymes.
Fox and Kriegl follow on by reviewing a variety of machine
learning techniques that commonly underlie recent global QSAR
studies on drug metabolism properties. The application and
recent progress of these methods for the prediction of drug
metabolism properties are considered in detail. This leads
into a more specific review by Yap, Xue, Li and Chen on the
use of support vector machines (SVM) - one of the most popular
and powerful machine learning methods of the moment - for
the prediction of CYP substrates and inhibitors. The discussion
of SVM methodology, performance, difficulties and future prospects
are a must-read for any researcher considering using machine
learning methods for the prediction of drug metabolism.
Arimoto details the key findings of recent pharmacophore,
QSAR and structure-based modeling undertaken to understand
and predict metabolic properties of the major human CYP isoforms;
CYP1A2, 2A6, 2C9, 2D6 and 3A4. Subsequently, Maréchal
and Sutcliffe review the structure-based modeling of human
CYPs, focusing particularly on CYP2D6. The recent crystallization
of a number of mammalian and human CYPs has been a significant
step forward in using structure-based methods to understand
the active site of CYPs and predict chemical binding and metabolism.
The use of in silico methods for the prediction of
drug metabolism induction is reviewed in detail by Schuster,
Steindl and Langer. Such models are complementary to those
described in other reviews in this issue. In this review there
is a focus on the modelling methods used, their applicability,
limitations and recent applications.
Westwood, Kawamura, Fullan, Russell and Sim conclude the issue
with a review on ligand- and structure-based modelling of
N-acetyltransferases for the prediction of chemical
binding and metabolism. N-acetyltransferase is an
important phase 2 drug metabolising enzyme family and the
variety and depth of research described herein indicates the
potential for future work on the in silico prediction
of drug metabolism by phase 2 enzymes.
Dr. Michael Sorich
Sansom Institute
School of Pharmacy and Medical Sciences
University of South Australia
Adelaide, SA 5000
Australia
Dr. Paul Smith
The Australian Wine Research Institute
Glen Osmond, Adelaide, SA 5064
Australia
[Back to top]
Quantitative Structure Activity Relationships in Drug Metabolism
Kamaldeep K. Chohan, Stuart W. Paine and Nigel J. Waters
This review of 61 references delineates contemporary computation
quantitative structure activity relationship (QSAR) approaches
that have been used to elucidate the molecular features that
influence the binding and metabolism of a compound by the
major phase 1 and phase 2 metabolising enzymes; Cytochrome
P450 (CYP) and UDP-glucuronosyltransferase (UGT), respectively.
Contemporary studies are applying 2D and 3D QSAR, pharmacophore
approaches and nonlinear techniques (for example: recursive
partitioning, neural networks and support vector machines)
to model drug metabolism. Furthermore, this review highlights
some of the challenges and opportunities for future research;
the need to develop ‘global’ models for CYP and
UGT metabolism and to extend QSAR for other important metabolising
enzymes.
[Back to top]
Machine Learning Techniques for In Silico
Modeling of Drug Metabolism
Thomas Fox and Jan M. Kriegl
The computational assessment of drug metabolism has gained
considerable interest in pharmaceutical research. Amongst
others, machine learning techniques have been employed to
model relationships between the chemical structure of a compound
and its metabolic fate. Examples for these techniques, which
were originally developed in fields far from drug discovery,
are artificial neural networks or support vector machines.
This paper summarizes the application of various machine learning
techniques to predict the interaction between organic molecules
and metabolic enzymes. More complex endpoints such as metabolic
stability or in vivo clearance will also be addressed.
It is shown that the prediction of metabolic endpoints with
machine learning techniques has made considerable progress
over the past few years. Depending on the procedure used,
either classification or quantitative prediction is possible
for even large and diverse compound sets. Together with the
expanding experimental data basis, these in silico
methods have become valuable tools in the drug discovery and
development process.
[Back to top]
Application of Support Vector Machines to In Silico
Prediction of Cytochrome P450 Enzyme Substrates and Inhibitors
C.W. Yap, Y. Xue, Z.R. Li and Y.Z. Chen
Cytochrome P450 enzymes are responsible for phase I metabolism
of the majority of drugs and xenobiotics. Identification of
the substrates and inhibitors of these enzymes is important
for the analysis of drug metabolism, prediction of drug-drug
interactions and drug toxicity, and the design of drugs that
modulate cytochrome P450 mediated metabolism. The substrates
and inhibitors of these enzymes are structurally diverse.
It is thus desirable to explore methods capable of predicting
compounds of diverse structures without over-fitting. Support
vector machine is an attractive method with these qualities,
which has been employed for predicting the substrates and
inhibitors of several cytochrome P450 isoenzymes as well as
compounds of various other pharmacodynamic, pharmacokinetic,
and toxicological properties. This article introduces the
methodology, evaluates the performance, and discusses the
underlying difficulties and future prospects of the application
of support vector machines to in silico prediction
of cytochrome P450 substrates and inhibitors.
[Back to top]
Computational Models for Predicting Interactions with
Cytochrome P450 Enzyme
Rieko Arimoto
Cytochrome p450 (CYP) enzymes are predominantly involved in
Phase 1 metabolism of xenobiotics. As only 6 isoenzymes are
responsible for ~90 % of known oxidative drug metabolism,
a number of frequently prescribed drugs share the CYP-mediated
metabolic pathways. Competing for a single enzyme by the co-administered
therapeutic agents can substantially alter the plasma concentration
and clearance of the agents. Furthermore, many drugs are known
to inhibit certain p450 enzymes which they are not substrates
for. Because some drug-drug interactions could cause serious
adverse events leading to a costly failure of drug development,
early detection of potential drug-drug interactions is highly
desirable. The ultimate goal is to be able to predict the
CYP specificity and the interactions for a novel compound
from its chemical structure. Current computational modeling
approaches, such as two-dimensional and three-dimensional
quantitative structure-activity relationship (QSAR), pharmacophore
mapping and machine learning methods have resulted in statistically
valid predictions. Homology models have been often combined
with 3D-QSAR models to impose additional steric restrictions
and/or to identify the interaction site on the proteins. This
article summarizes the available models, methods, and key
findings for CYP1A2, 2A6, 2C9, 2D6 and 3A4 isoenzymes.
[Back to top]
Insights into Drug Metabolism from Modelling Studies
of Cytochrome P450-Drug Interactions
Jean-Didier Maréchal and Michael J. Sutcliffe
The cytochromes P450 (CYPs) comprise a vast superfamily of
enzymes found in virtually all life forms. In mammals, xenobiotic
metabolising CYPs provide crucial protection from the harmful
effects of exposure to a wide variety of chemicals, including
environmental toxins and therapeutic drugs. Elucidating the
structural features of CYPs that contribute to their metabolism
of structurally diverse substrates impacts on the rational
design of improved therapeutic drugs and specific inhibitors.
Models capable of predicting the possible involvement of CYPs
in the metabolism of drugs or drug candidates are thus important
tools in drug discovery and development. Ideally, functional
information would be obtained from crystal structures of all
the CYPs of interest. Initially only crystal structures of
distantly related bacterial CYPs were available – comparative
modelling techniques were used to bridge the gap and produce
structural models of human CYPs, and thereby obtain some useful
functional information. A significant step forward in the
reliability of these models came six years ago with the first
crystal structure of a mammalian CYP, rabbit CYP2C5, followed
by the structures of five human enzymes, CYP2A6, CYP2C8, CYP2C9,
CYP2D6 and CYP3A4, and a second rabbit enzyme, CYP2B4. The
evolution of a CYP2D6 model, leading to the validation of
the model as an in silico tool for predicting binding
and metabolism, is presented as a case study.
[Back to top]
Predicting Drug Metabolism Induction In Silico
Daniela Schuster, Theodora M. Steindl and Thierry Langer
The inducibility of drug-metabolizing enzymes and transporters
by numerous xenobiotics has become a vital issue to be considered
in the drug development process. Activation of so-called orphan
nuclear receptors has been identified to result in increased
expression of these detoxifying systems and consequently altered
drug levels in the human body. In order to anticipate such
mechanisms already in early stages of drug design and to avoid
dangerous drug-drug interactions, reliable in silico simulation
tools are highly desirable. This review aims to give an introduction
into induction of drug metabolism and transport and focuses
on computer-assisted molecular modeling prediction techniques,
on their applicability and limitations, on recent case studies,
and on success stories.
[Back to top]
Structure and Mechanism of Arylamine N Acetyltransferases
I.M. Westwood, A. Kawamura, E. Fullam, A.J. Russell, S.G.
Davies and E. Sim
Arylamine N-acetyltransferases (NATs) are
a family of phase II drug-metabolising enzymes which are important
in the biotransformation of various aromatic and heterocyclic
amines and hydroxylamines, arylhydrazines and arylhydrazides.
NATs are present in a wide range of eukaryotes and prokaryotes.
Humans have two functional NAT isoforms, both of which are
highly polymorphic. The pharmacogenetics of NATs is an area
which has been extensively studied. The determination of the
X-ray crystal structure of NAT from Salmonella typhimurium
led to the identification of the catalytically essential triad
of residues: Cys-His-Asp, which is present in all functional
NAT enzymes. Recent co-crystallisation data and in silico
docking studies of NAT from Mycobacterium smegmatis
with substrates and inhibitors have aided the identification
of important contact residues within the active site. The
X-ray crystal structures of four prokaryotic NAT proteins
have now been determined, and these have been used to generate
structural models of eukaryotic NATs, providing valuable insight
into their active-site architecture. In addition to aiding
crystallographic experiments, recent progress in the production
of recombinant prokaryotic and eukaryotic NATs has allowed
comparative studies of the kinetics and activity profiles
of these enzymes.In this review we present an overview of
recent structural and activity studies on NAT enzymes, and
we outline how in silico methods may be used to predict
NAT protein-ligand interactions based on the current knowledge.
|
