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Combinatorial Chemistry &
High Throughput Screening
ISSN: 1386-2073
Combinatorial Chemistry &
High Throughput Screening
Volume 10, Number 8, September 2007
Contents
Chemical Genomics
Guest Editor: Anuj Kumar
Editorial Pp.
617
Yeast Genomics and Drug Target Identification Pp.
618 634
Nikë Bharucha and Anuj Kumar
[Abstract]
Stem Cells and Combinatorial Science Pp.
635-651
Yue Qin Fang, Wan Qing Wong, Yan Wen Yap and Brendan P.Orner
[Abstract]
Chemical Genomic and Proteomic Methods for Determining
Kinase Inhibitor Selectivity Pp. 652-666
Ratika Krishnamurty and Dustin J. Maly
[Abstract]
Chemical Control Over Protein-Protein Interactions: Beyond
Inhibitors Pp. 667-675
Jason E. Gestwicki and Paul S. Marinec
[Abstract]
Functional Genomics and NMR Spectroscopy
Pp. 676-697
Robert Powers
[Abstract]
Functional Nucleic Acids in High Throughput Screening
and Drug Discovery Pp. 698-705
Seergazhi G. Srivatsan and Michael Famulok
[Abstract]
Applications of Protein Microarray Technology
Pp. 706-718
Sheng-Ce Tao, Chien-Sheng Chen and Heng Zhu
[Abstract]
Chemogenomic Data Analysis: Prediction of Small Molecule
Targets and the Advent of Biological Fingerprints
Pp.719-731
Andreas Bender, Daniel W. Young, Jeremy L. Jenkins, Martin
Serrano, Dmitri Mikhailov, Paul A. Clemons and John W. Davies
[Abstract]
Meet the Guest
Editor Pp. 723
Abstracts
[Back to top]
Editorial
The availability of a fully sequenced genome is an enticing
biological resource — sufficiently enticing, in fact,
to spur the establishment of well over 300 eukaryotic genome-sequencing
projects at this time. The investment of labor and resources
in these projects is obviously sizable, and the expected scientific
gain from these projects is equally sizable. In truth, the
realistic advancement in biological knowledge resulting from
a sequenced genome will likely never fulfill the associated
promise; however, genomics has indeed affected a wide array
of disciplines, with an increasing number of studies combining,
in particular, chemistry and genomics.
Over the last few years, researchers in academics and industry
have undertaken many interesting projects interfacing large-scale
genomic methods with synthetic chemical tools — an interface
that is broadly termed “chemical genomics.” Chemical
genomics occurs at the intersection of genomics, bioinformatics,
proteomics, chemoinformatics, structural biology, analytical
chemistry, combinatorial chemistry, and chemical biology.
Thus, new discoveries in these individual fields are, in turn,
driving the development of chemical genomics. Moreover, rapidly
maturing ideas that merge traditionally disparate areas are
providing additional research opportunities, and the development
of new technology is further expanding research avenues. This
emerging field has already been successful in identifying
new drug targets, in providing powerful chemical probes and
in illuminating the mechanism of action of new chemical entities.
Future studies will build upon this scientific foundation.
In this issue of Combinatorial Chemistry & High Throughput
Screening, we present an overview of chemical genomics,
authored by leaders in fields of research relevant to this
discipline. Here, we summarize influential studies using chemical
genomic screens and highlight recent technological developments
with applicability to chemical genomics. This issue brings
together researchers from both academics and industry, with
unique and complementary insight into the current state of
the art (and future potential) in marrying genomic resources
and methodologies to combinatorial chemistry and small molecule
screening.
In particular, model organisms are gaining increasing popularity
in drug-based screening studies; here, Nikë Bharucha
and I provide an overview of chemical genomic studies in yeast
using genome-wide collections of mutants and other genomic
approaches to help identify pathways and proteins targeted
by small-molecule drugs. Recent studies have also utilized
small molecule-based screens to provide insight into specific
biological problems. In this issue, Fang et al. discuss
applications of small molecules in studying various aspects
of stem cell differentiation. Ratika Krishnamurthy and Dustin
Maly review experimental techniques for the determination
of protein kinase inhibitor selectivity and further summarize
important insights gained from these studies.
An exciting slate of technologies applicable on a genomic
scale are now being developed and implemented as tools in
small molecule screening and drug-based discovery; here, we
review several recent technological advances with relevance
to chemical genomics. Specifically, Jason Gestwicki and Paul
Marinec present an overview of bifunctional molecules as tools
in manipulating and probing protein-protein interactions,
potentially on a genomic scale. Robert Powers offers a thorough
review that summarizes applications of nuclear magnetic resonance
energy (NMR) spectroscopy for the large-scale study of protein
and protein-ligand complexes. Seergazhi Srivatsan and Michael
Famulok review the development of functional nucleic acids,
such as aptamers and ribozymes, and their utility in molecular
screening. Tao and Chen in Heng Zhu’s group at Johns
Hopkins provide a current overview of nascent protein microarray
technologies with strong potential implications for future
screens of small molecule-protein interactions. Finally, Bender
et al. address the growing role of informatics in
chemical genomics, both in predicting compound targets and
in integrating and interpreting biological descriptors of
drugs and small molecules.
As evidenced above, the interaction space of genomics and
chemistry is broad, dynamic, and ripe with potential. The
reviews presented here constitute a snapshot picturing the
current state of this field, but in the next few years, we
will likely witness both the expansion and refinement of chemical
genomics. Accordingly, we can anticipate significant benefits
from this vein of research, with strong promise for improved
drug target identification and drug development in the foreseeable
future.
Anuj Kumar
Life Sciences Institute and Department of MCD Biology
University of Michigan
Ann Arbor, MI 48109-2216
USA
E-mail: anujk@umich.edu
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Yeast Genomics and Drug Target Identification
Nikë Bharucha and Anuj Kumar
The budding yeast Saccharomyces cerevisiae is
well recognized as a preferred eukaryote for the development
of genomic technologies and approaches. Accordingly, a sizeable
complement of genomic resources has been developed in yeast,
and this genomic foundation is now informing a wide variety
of disciplines. In particular, yeast genomic methodologies
are gaining an expanding foothold in drug development studies,
most notably as a preliminary tool towards drug target identification.
In this review, we highlight many applications of yeast genomics
in the identification of targeted genes and pathways of small
molecules or therapeutic drugs. The applicability of genome-wide
resources of yeast disruption and deletion mutants for drug-sensitivity/resistance
screening is presented here, along with a summary of microarray
technologies for drug-based transcriptional profiling and
synthetic interaction mapping. Applications of protein-interaction
traps for potential drug target identification are also considered.
Collectively, this overview of yeast genomics emphasizes the
growing intersection between high-throughput model organism
biology and medicinal chemistry — an intersection promising
tangible advances for both academic and pharmaceutical fields
alike.
[Back to top]
Stem Cells and Combinatorial Science
Yue Qin Fang, Wan Qing Wong, Yan Wen Yap and Brendan P. Orner
Stem cell-based technologies have the potential to help
cure a number of cell degenerative diseases. Combinatorial
and high throughput screening techniques could provide tools
to control and manipulate the self-renewal and differentiation
of stem cells. This review chronicles historic and recent
progress in the stem cell field involving both pluripotent
and multipotent cells, and it highlights relevant cellular
signal transduction pathways. This review further describes
screens using libraries of soluble, small-molecule ligands,
and arrays of molecules immobilized onto surfaces while proposing
future trends in similar studies. It is hoped that by reviewing
both the stem cell and the relevant high throughput screening
literature, this paper can act as a resource to the combinatorial
science community.
[Back to top]
Chemical Genomic and Proteomic Methods for Determining
Kinase Inhibitor Selectivity
Ratika Krishnamurty and Dustin J. Maly
The clinical success of the Bcr-Abl tyrosine kinase inhibitor
Gleevec®
and the recent clinical approval of a number of small molecule
drugs that target protein kinases have intensified the search
for novel protein kinase inhibitors. Since most small molecule
kinase inhibitors target the highly conserved ATP-binding
pocket of this enzyme family, the target selectivity of these
molecules is a major concern. Due to the large size of the
human kinome, it is a formidable challenge to determine the
absolute specificity of a given protein kinase inhibitor,
but recent technological developments have made substantial
progress in achieving this goal. This review summarizes some
of the most recent experimental techniques that have been
developed for the determination of protein kinase inhibitor
selectivity. Special emphasis is placed on the results of
these screens and the general insights that they provide into
kinase inhibitor target selectivity.
[Back to top]
Chemical Control Over Protein-Protein Interactions:
Beyond Inhibitors
Jason E. Gestwicki and Paul S. Marinec
Protein-protein interactions have become attractive drug
targets and recent studies suggest that these interfaces may
be amenable to inhibition by small molecules. However, blocking
specific interactions may not be the only way of manipulating
the extensive network of interacting proteins. Recently, several
approaches have emerged for promoting these interactions rather
than inhibiting them. Typically, these strategies employ a
bifunctional ligand to simultaneously bind two targets, forcing
their juxtaposition. Chemically “riveting” specific
protein contacts can reveal important aspects of regulation,
such as the consequences of stable dimerization or the effects
of prolonged dwell time. Moreover, in some cases, entirely
new functions arise when two proteins, which normally do not
interact, are brought into close proximity with one another.
Together with inhibitors, bifunctional molecules are part
of a growing toolbox of chemical probes that can be used to
reversibly and selectively control the interact-ome. Using
these reagents, new insights into the dynamics of protein-protein
interactions and their importance in biology are beginning
to emerge. Future hurdles in this area lie in the development
of robust synthetic platforms for rapidly generating compounds
to meet the challenges of diverse protein-protein interfaces.
[Back to top]
Functional Genomics and NMR Spectroscopy
Robert Powers
The recent success of the human genome project and the
continued accomplishment in obtaining DNA sequences for a
vast array of organisms is providing an unprecedented wealth
of information. Nevertheless, an abundance of the proteome
contains hypothetical proteins or proteins of unknown function,
where high throughput approaches for genome-wide functional
annotation (functional genomics) has evolved as the necessary
next step. Nuclear magnetic resonance spectroscopy is playing
an important role in functional genomics by providing information
on the structure of protein and protein-ligand complexes,
from metabolite fingerprinting and profiling, from the analysis
of the metabolome, and from ligand affinity screens to identify
chemical probes.
[Back to top]
Functional Nucleic Acids in High Throughput Screening and
Drug Discovery
Seergazhi G. Srivatsan and Michael Famulok
In vitro selection can be used to generate functional
nucleic acids such as aptamers and ribozymes that can recognize
a variety of molecules with high affinity and specificity.
Most often these recognition events are associated with structural
alterations that can be converted into detectable signals.
Several signaling aptamers and ribozymes constructed by both
design and selection have been successfully utilized as sensitive
detection reagents. Here we summarize the development of different
types of signaling nucleic acids, and approaches that have
been implemented in the screening format.
[Back to top]
Applications of Protein Microarray Technology
Sheng-Ce Tao, Chien-Sheng Chen and Heng Zhu
Protein microarrays, an emerging class of proteomic technologies,
are quickly becoming essential tools for large-scale and high
throughput biochemistry and molecular biology. Recent progress
has been made in all the key steps of protein microarray fabrication
and application, such as the large-scale cloning of expression-ready
prokaryotic and eukaryotic ORFs, high throughput protein purification,
surface chemistry, protein delivery systems, and detection
methods. Two classes of protein microarrays are currently
available: analytical and functional protein microarrays.
In the case of analytical protein microarrays, well-characterized
molecules with specific activity, such as antibodies, peptide-MHC
complexes, or lectins, are used as immobilized probes. These
arrays have become one of the most powerful multiplexed detection
platforms. Functional protein microarrays are being increasingly
applied to many areas of biological discovery, including drug
target identification/validation and studies of protein interaction,
biochemical activity, and immune responses. Great progress
has been achieved in both classes of protein microarrays in
terms of sensitivity and specificity, and new protein microarray
technologies are continuing to emerge. Finally, protein microarrays
have found novel applications in both scientific research
and clinical diagnostics.
[Back to top]
Chemogenomic Data Analysis: Prediction of Small-Molecule Targets
and the Advent of Biological Fingerprints
Andreas Bender, Daniel W. Young, Jeremy L. Jenkins, Martin
Serrano, Dmitri Mikhailov, Paul A. Clemons and John W. Davies
Chemogenomics comprises a systematic relationship between
targets and ligands that are used as target modulators in
living systems such as cells or organisms. In recent years,
data on small molecule-bioactivity relationships have become
increasingly available, and consequently so have the number
of approaches used to translate bioactivity data into knowledge.
This review will focus on two aspects of chemogenomics. Firstly,
in cases such as cell-based screens, the question of which
target(s) a compound is modulating in order to cause the observed
phenotype is crucial. In silico target prediction
tools can suggest likely biological targets of small molecules
via data mining in target-annotated chemical databases.
This review presents some of the current tools available for
this task and shows some sample applications relevant to a
pharmaceutical industry setting. These applications are the
prediction of false-positives in cell-based reporter gene
assays, the prediction of targets by linking bioassay data
with protein domain annotations, and the direct prediction
of adverse reactions. Secondly, in recent years a shift from
structure-derived chemical descriptors to biological descriptors
has occurred. Here, the effect of a compound on a number of
biological endpoints is used to make predictions about other
properties, such as putative targets, associated adverse reactions,
and pathways modulated by the compound. This review further
summarizes these “performance” descriptors and
their applications, focusing on gene expression profiles and
high-content screening data. The advent of such biological
fingerprints suggests that the field of drug discovery is
currently at a crossroads, where single target bioassay results
are supplanted by multidimensional biological fingerprints
that reflect a new awareness of biological networks and polypharmacology.
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