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A Multidimensional Strategy to Detect Polypharmacological Targets in the Absence of Structural and Sequence Homology

  • Jacob D. Durrant ,

    jdurrant@ucsd.edu

    Affiliation Biomedical Sciences Program, University of California San Diego, La Jolla, California, United States of America

  • Rommie E. Amaro,

    Affiliation Department of Chemistry & Biochemistry, NSF Center for Theoretical Biological Physics, National Biomedical Computation Resource, University of California San Diego, La Jolla, California, United States of America

  • Lei Xie,

    Affiliation San Diego Supercomputer Center and Department of Pharmacology, University of California San Diego, La Jolla, California, United States of America

  • Michael D. Urbaniak,

    Affiliation Division of Biological Chemistry and Drug Discovery, College of Life Sciences, University of Dundee, Dundee, United Kingdom

  • Michael A. J. Ferguson,

    Affiliation Division of Biological Chemistry and Drug Discovery, College of Life Sciences, University of Dundee, Dundee, United Kingdom

  • Antti Haapalainen,

    Affiliation Biocenter Oulu and Department of Biochemistry, University of Oulu, Oulu, Finland

  • Zhijun Chen,

    Affiliation Biocenter Oulu and Department of Biochemistry, University of Oulu, Oulu, Finland

  • Anne Marie Di Guilmi,

    Affiliation Institut de Biologie Structurale CEA; CNRS UMR 5075; Université Joseph Fourier, Partnership for Structural Biology, Grenoble, France

  • Frank Wunder,

    Affiliation Lead Discovery Wuppertal, Bayer Schering Pharma AG, Wuppertal, Germany

  • Philip E. Bourne,

    Affiliation Skaggs School of Pharmacy and Pharmaceutical Sciences, University of California San Diego, La Jolla, California, United States of America

  • J. Andrew McCammon

    Affiliations Department of Chemistry & Biochemistry, NSF Center for Theoretical Biological Physics, National Biomedical Computation Resource, University of California San Diego, La Jolla, California, United States of America, Skaggs School of Pharmacy and Pharmaceutical Sciences, University of California San Diego, La Jolla, California, United States of America, Howard Hughes Medical Institute, University of California San Diego, La Jolla, California, United States of America

Abstract

Conventional drug design embraces the “one gene, one drug, one disease” philosophy. Polypharmacology, which focuses on multi-target drugs, has emerged as a new paradigm in drug discovery. The rational design of drugs that act via polypharmacological mechanisms can produce compounds that exhibit increased therapeutic potency and against which resistance is less likely to develop. Additionally, identifying multiple protein targets is also critical for side-effect prediction. One third of potential therapeutic compounds fail in clinical trials or are later removed from the market due to unacceptable side effects often caused by off-target binding. In the current work, we introduce a multidimensional strategy for the identification of secondary targets of known small-molecule inhibitors in the absence of global structural and sequence homology with the primary target protein. To demonstrate the utility of the strategy, we identify several targets of 4,5-dihydroxy-3-(1-naphthyldiazenyl)-2,7-naphthalenedisulfonic acid, a known micromolar inhibitor of Trypanosoma brucei RNA editing ligase 1. As it is capable of identifying potential secondary targets, the strategy described here may play a useful role in future efforts to reduce drug side effects and/or to increase polypharmacology.

Author Summary

Proteins play a critical role in human disease; bacteria, viruses, and parasites have unique proteins that can interfere with human health, and dysfunctional human proteins can likewise lead to illness. In order to find cures, scientists often try to identify small molecules (drugs) that can inhibit disease-causing proteins. The goal is to identify a molecule that can fit snugly into the pockets and grooves, or “active sites,” on the protein's surface. Unfortunately, drugs that inhibit a single disease-causing protein are problematic. A single protein can evolve to evade drug action. Additionally, when only one protein is targeted, drug potency is often diminished. Single drugs that simultaneously target multiple disease-causing proteins are much more effective. On the other hand, if scientists are not careful, the drugs they design might inhibit essential human proteins in addition to inhibiting their intended targets, leading to unexpected side effects. In our current work, we have developed a computer-based procedure that can be used to identify proteins with similar active sites. Once unexpected protein targets have been identified, scientists can modify drugs under development in order to increase the simultaneous inhibition of multiple disease-causing proteins while avoiding potential side effects by decreasing the inhibition of useful human proteins.

Introduction

Researchers have traditionally focused in silico efforts on designing inhibitors of specific protein targets, giving less attention to the computational identification of unpredicted secondary targets. This tendency is surprising given the frequency with which secondary receptors are responsible for both detrimental and beneficial pharmacological effects. The cost of developing a novel therapeutic ranges from $500 million to $2 billion dollars [1]. Millions of dollars are typically invested to advance a compound through clinical trials, but one third of these compounds fail or are later removed from the market due to unacceptable, medically harmful side effects [2] often caused by binding to off-target receptors. The detrimental effects caused by drug binding to unknown secondary targets can be financially and clinically devastating.

In other cases, compound binding to multiple therapeutic targets (polypharmacology) is beneficial. Conventional drug discovery embraces the “one gene, one drug, one disease” philosophy; however, drugs that target only one protein are susceptible to resistance, as a single amino-acid mutation in the target active site often substantially reduces compound binding affinity. Resistance to multi-target drugs, on the other hand, requires simultaneous mutations in multiple protein targets. Furthermore, drugs with polypharmacological mechanisms often have greater therapeutic potency. Some serotonergic drugs, for example, bind both 5-HT G-protein coupled receptors as well as the 5-HT3A ion channel to achieve their therapeutic benefits, despite the fact that these two target proteins are not related by sequence or structure [3].

Identifying secondary targets in neglected tropical diseases, diseases for which drug development is neither profitable nor prevalent, allows researchers and doctors to retool approved drugs as novel treatments for the otherwise abandoned infections of the developing world. For instance, eflornithine, initially developed as an anti-cancer compound, was found to be a potent inhibitor of Trypanosoma brucei ornithine decarboxylase and is now a critical therapeutic in the fight against human African trypanosomiasis [4]. Examples like these motivate the need to develop new tools and algorithms to predict potential protein targets of candidate compounds.

A barrier to the development of these tools is the frequent absence of apparent evolutionary relationships among the multiple protein targets of a given compound, requiring that any potential method be capable of identifying target receptors independently of global sequence or structural homology. One approach is chemo-centric [5]; similar ligands are more likely to have similar properties and therefore often bind proteins with similar active sites. A number of studies have successfully identified secondary receptors by comparing their known small-molecule ligands [3], [6][8], leading to probabilistic models that can in some cases successfully predict polypharmacology. Despite these successes, however, chemo-centric approaches have their limitations. Chemically similar small molecules do not always inhibit proteins with similar active sites; indeed, even small changes in the chemical structures of some small-molecule inhibitors can drastically alter binding affinity [3] and the broad profile of binding to pharmacological targets.

A second approach is protein-centric. As the evolutionary relationships between secondary targets are not always apparent [3], receptor active-site geometries and pharmacophores must be compared directly, independently of global sequence or structural homology. Geometric constraints have been used extensively to identify binding sites and to assess binding-site similarity [9][16]. Of these methods, the sequence order independent profile-profile alignment (SOIPPA) algorithm is largely insensitive to both conformational changes in protein structure as well as the uncertainty inherent in homology models and low-resolution structures [17].

In the current work, we present a novel multidimensional strategy to identify the multiple protein receptors of a given compound that incorporates three levels of information: sequence-based homology clustering, the SOIPPA algorithm in conjunction with a geometric-potential metric [17][19], and in silico ligand docking. To demonstrate the utility of the strategy, we identify several human and pathogen secondary targets of compound 1 (NSC-45208), 4,5-dihydroxy-3-(1-naphthyldiazenyl)-2,7-naphthalenedisulfonic acid, a recently discovered micromolar inhibitor of T. brucei RNA editing ligase 1 (TbREL1) [20]. TbREL1 is a confirmed drug target in T. brucei, the causative agent of human African trypanosomiasis, a disease for which drug development has been largely neglected [21].

Results

Predicted Secondary Targets

Sequence homology clustering was used to identify 12,646 protein-chain clusters from among the 110,000 protein chains present in the Protein Data Bank (PDB) as of late 2007 (Figure 1A, B). A representative protein chain was chosen from each cluster, creating a smaller set of chains called the PDB30 (Figure 1C). The SOIPPA algorithm in conjunction with a geometric-potential metric [17][19] revealed that the active sites of 12,428 of the representative PDB30 protein chains (98.3%) were dissimilar to that of TbREL1 (p>0.05), the known target. After discarding these dissimilar protein chains, 218 representative PDB30 chains remained (Figure 1D). The remaining PDB30 proteins and the clusters they represented were merged into a single list containing 2,897 chains, a list enriched with possible secondary targets (Figure 1E). By considering only proteins from human or known human-pathogen species and eliminating PDBs with formatting errors, the number of chains was reduced from 2,897 to 645 (22.3%). This new list of protein chains was called the PDBr (PDBreduced).

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Figure 1. The strategy workflow.

Circles and squares represent protein chains. Homologous chains share the same color. From each group of homologous chains, one is selected as representative and is shown as a square. (A) As the PDB has approximately 110,000 protein chains, identifying secondary targets directly is computationally intractable. (B) To reduce the number of chains, all chains are grouped by sequence homology into 12,646 clusters, and (C) a single representative chain is selected from each cluster. The set of all representative chains is called the PDB30. (D) SOIPPA is used to eliminate all protein chains in the PDB30 with active sites that are dissimilar to that of the primary target, TbREL1. Only 218 chains remain. (E) A new set of 645 protein-chain structures called the PDBr is created by taking the union of all those clusters whose representative PDB30 protein chains have active sites that are not dissimilar to that of TbREL1. (F) Redundant chains are ignored; compound 1 is docked into the remaining 87 protein chains. Chains are ranked by their corresponding docking scores.

https://doi.org/10.1371/journal.pcbi.1000648.g001

Compound 1, a known inhibitor of the primary target, TbREL1, was docked into each of the 645 potential secondary targets of the PDBr with AutoDock 4.0 (Figure 1F). After docking, both protein chains of unknown function and chains belonging to proteins with duplicate names were deleted without regard for species. This pruning produced a list of 87 non-redundant predicted secondary targets. The docked pose of 1 into each of these 87 predicted secondary targets was analyzed to confirm binding to a pocket of known biochemical or pharmacological activity. In two instances, SITE data was included in the published PDB file, allowing us to identify one active-site and one off-site docking. In 25 instances, the docked ligand bound at the same location as a co-crystallized ligand, typically superimposed on top of it. Homology modeling revealed that an additional nine docked ligands bound at active sites of known biochemical or pharmacological activity, while 34 bound at alternate sites on the receptor. Though these alternate sites may be involved in allosteric regulation of protein function, we chose not to pursue them further. In all, the list of 87 protein chains contained 35 chains whose known active sites contained docked ligands, 35 chains whose alternate sites contained docked ligands, and 17 chains that could not be classified (Text S1).

Experimental Validation of Predicted Secondary Targets

The predicted secondary targets that gave the best docking scores, H. sapiens mitochondrial 2-enoyl thioester reductase (HsETR1), T. brucei UDP-galactose 4′ epimerase (TbGalE), H. sapiens phosphodiesterase 9A (HsPDE9A2), and Streptococcus pneumoniae teichoic acid phosphorylcholine esterase (SpPce), were subsequently tested experimentally.

Compound 1 inhibited HsETR1 with a measured IC50 of approximately 33.5 µM and a Hill slope of 1.06. Neither the FATCAT algorithm nor CLUSTALW2 judged HsETR1 to be significantly homologous in sequence or structure to the primary target, TbREL1 (p = 0.754; identity = 4%). In contrast, the SOIPPA algorithm judged the active sites of these two proteins to be significantly similar (p<1×10−5) (Table 1). HsETR1 aggregates were not detected, as measured by both spectrometry and centrifugation. A mixture of compound 1 and HsETR1 was run through a gel filtration column, thereby removing any unbound ligand. Spectroscopic analysis subsequently demonstrated that 1 was not covalently bound to HsETR1.

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Table 1. Selected predicted secondary targets of compound 1 in humans.

https://doi.org/10.1371/journal.pcbi.1000648.t001

Compound 1 inhibited TbGalE with a measured IC50 of 0.7±0.2 µM and a Hill slope of 1.13+/−0.36. Again, the FATCAT algorithm did not judge the structure of TbGalE to be significantly similar to that of the primary target, TbREL1 (p = 0.627), and the CLUSTALW2 algorithm did not identify significant sequence homology (identity = 1%) (Table 2). TbGalE inhibition was unaffected by the presence of detergent, and activity could be restored by dialysis of the protein, demonstrating that the TbGalE inhibition was not due to aggregation of the compound or chemical modification of the protein.

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Table 2. Selected predicted secondary targets of compound 1 in pathogens.

https://doi.org/10.1371/journal.pcbi.1000648.t002

Two of the predicted secondary targets, HsPDE9A2 and SpPce, were uninhibited by 1 at 200 µM and 10 mM, respectively. AutoDock predicted that 1 would bind HsPDE9A2 and SpPce with −18.19 and −28.00 kcal/mol, respectively (Tables 1 and 2).

Discussion

In this work, we attempt to further the study of polypharmacological and side-effect prediction by presenting a multidimensional strategy for identifying secondary targets of known enzyme inhibitors in the absence of global structure and sequence homology. To demonstrate the utility of the strategy, we identify secondary targets of 1, a recently discovered inhibitor of TbREL1 [20] from T. brucei, the causative agent of African sleeping sickness. TbREL1 plays a critical role in the editing of trypanosomatid mitochondrial RNA transcripts and is required for the survival of both the T. brucei insect and bloodstream forms [22],[23]. Additionally, TbREL1 is a particularly attractive drug target because there are no known close human homologs [20].

Compound 1 was chosen to illustrate how the current strategy can be applied early in the drug-discovery process. The compound inhibits a known drug target, satisfies Lipinski's rule of five, and is structurally similar to surinam, a drug currently approved for the treatment of human African trypanosomiasis. In this sense, 1 is drug like. Compound 1 has not yet been optimized to bind TbREL1 in the nanomolar regime, however, and does contain some undesirable functional groups, and so is still very much under development. By incorporating the identification of secondary targets early in the drug-design process, we hope to eventually make modifications to compound 1 that will increase the binding affinity to the primary target while decreasing binding to undesirable secondary targets.

Human Secondary Targets

Of the 35 predicted secondary targets of compound 1 identified, twelve were human proteins. Potential side effects of 1 can be predicted by considering the physiological role of these targets. For instance, a number of the predicted secondary human targets regulate metabolism, including the experimentally confirmed secondary target HsETR1. Neither FATCAT nor CLUSTALW2 judged HsETR1to be homologous to the primary target, TbREL1 (Table 1). The current strategy, which is not dependent on sequence or global structural homology, was able to identify this secondary target where identification by homology would have failed. HsETR1 is thought to be essential for fatty acid synthesis (FAS) type II [24]. In the process of optimizing 1 to make it more druglike, modifications that reduce binding to human HsETR1 may diminish unforeseen side effects. Interestingly, AutoDock predicted that 1 partially occupies a co-factor (NADPH) binding site, suggesting that the compound may function as a competitive inhibitor for NADPH (Figure S1A).

H. sapiens UDP-galactose 4-epimerase (HsGalE), a second protein involved in human metabolism, was also identified as a potential secondary target. Though HsGalE shares little homology with the primary target, TbREL1 (FATCAT p-value: 0.610; CLUSTALW2 identity: 2%), it is highly homologous with TbGalE (FATPAT p-value: 0.00; CLUSTALW2 identity: 37%; Figure S2A), which we show to be a secondary target of 1 (IC50: 0.7±0.2 µM). Mutations in the HsGalE gene cause type 3 galactosemia in humans. As toxic levels of galactose build up in patients' blood, vomiting, hepatomegaly, jaundice, renal failure, and cataracts typically follow [25]. Chronic administration of 1 is thus ill advised, though short-term treatment may be acceptable if patients avoid dairy and other sources of galactose.

In addition to metabolism, a number of the predicted human secondary targets are involved in polynucleotide synthesis, repair, and replication. H. sapiens DNA ligase I (HsLigI), a protein that belongs to the same enzyme superfamily as TbREL1, is one notable example. HsLigI catalyzes the ultimate, essential step in DNA replication, repair, and recombination [26]. Studies have demonstrated that HsLigI is defective in at least one representative lymphoid cell line of Bloom's syndrome origin [27], and a mouse model with a mutant HsLigI allele exhibits an increased incidence of spontaneous cancer [28].

Though not tested explicitly, additional evidence does suggest that 1 binds HsLigI. First, 1 is known to inhibit H. sapiens DNA ligase IIIβ (HsLigIIIβ; IC50: 27.49±6.40 µM) [20], a HsLigI homolog (Table 3). Second, the FATCAT algorithm [29] judged the structure of HsLigI to be significantly similar to that of the primary target, TbREL1, and the SOIPPA algorithm judged the active sites of these two proteins to be similar (Table 1). Finally, the AutoDock-predicted binding energy of 1 to HsLigI was −9.70 kcal/mol (Table 1).

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Table 3. Global sequence and structural homology between HsLigI, residues 535 to 751, and three other selected DNA ligases.

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Secondary Targets in Bacterial and Parasitic Pathogens

Of the 35 predicted secondary targets identified, 23 belonged to bacterial and parasitic species. Among these predicted pathogenic secondary targets, enzymatic assays demonstrated that 1 inhibits TbGalE [30] (Table 2) with high nanomolar affinity. Interestingly, the FATCAT algorithm did not judge the structure of TbGalE to be significantly similar to that of the primary target, TbREL1 (Table 2), nor did CLUSTALW2 suggest sequence homology (identity = 1%). Thus, had we attempted to identify secondary targets by protein sequence or structural homology alone, TbGalE would not have been detected. This result again illustrates the power of the current strategy.

Like TbREL1, TbGalE is essential for T. brucei survival [31]. Thus, 1 inhibits two essential T. brucei enzymes, an example of potential polypharmacology. In the process of optimizing 1 to make it more druglike, modifications that increase binding to both TbREL1 and TbGalE would likely improve drug efficacy and decrease the chances of resistance through mutation. Interestingly, AutoDock again predicted that 1 would bind partially in the TbGalE NAD+ pocket, suggesting that the compound may be a competitive inhibitor for NAD+ rather than UDP-galactose (Figure S1B).

Though not tested explicitly, another predicted secondary target in pathogens, Salmonella enterica dTDP-D-glucose 4,6 dehydratase (SeRmlB), shares sequence and structural homology with TbGalE and may also bind 1 (Table 2, Figure S2A). The FATCAT algorithm judged SeRmlB to be significantly structurally similar to TbGalE (p value = 0.00), and CLUSTALW2 identified some sequence homology (identity = 21%). Additionally, AutoDock predicted that SeRmlB would bind 1 with relatively high affinity (Table 2).

SeRmlB is the second enzyme in the dTDP-L-rhamnose biosynthetic pathway; L-rhamnose is part of the LPS endotoxin (the O antigen) in many serotypes and serovars of Gram-negative bacteria. As L-rhamnose is common in the cell walls and envelopes of some pathogenic bacteria but absent in humans, SeRmlB is thought to be a potential drug target [32]. These findings support the hypothesis that compounds similar to 1 may have anti-bacterial properties.

Aside from inhibiting an essential protein in the bacterial dTDP-L-rhamnose biosynthetic pathway, the current strategy also identified two bacterial DNA ligases as potential secondary targets. Enterococcus faecalis v583 NAD-dependent DNA ligase (Ef ligase) and Mycobacterium tuberculosis DNA ligase (Mt ligase) are structurally homologous to HsLigI (Table 3, Figure S2B). Human DNA ligases require ATP as a co-factor, but bacterial ligases require NAD+ [33]. Because of this important biochemical difference, bacterial ligases are thought to be good drug targets.

Method Limitations

A limitation of the current method is the prediction of false positives. Two of the predicted secondary targets, SpPce and HsPDE9A2, were uninhibited by 1. Closer inspection of the docking results revealed electrostatic energy components of −30.89 kcal/mol and −12.29 kcal/mol, respectively. In both cases, the partial charges of several active-site metal cations had been manually set to the corresponding formal charge. Subsequent analysis of the docked poses revealed that for both receptors, one of the sulfonate groups of 1 was juxtaposed against these highly charged metal cations (Figure S3). Clearly, a more careful treatment of the electrostatic interactions that accounts for electron polarization is warranted when docking into active sites that include metal ions.

An additional limitation of the current method is its dependence on sequence-homology clustering. Because of computational limitations, the number of potential secondary targets analyzed with SOIPPA had to be reduced; consequently, rather than analyzing all protein chains in the PDB, representative chains were selected from clusters of homologous proteins based on the supposition that sequence-homologous proteins would likely have similar active sites. This supposition, however, is hardly a universal truth. Through convergent evolution, two proteins with very different primary sequences may have evolved to bind similar ligands, and so may have similar active sites despite a lack of sequence homology.

Fortunately, recent advances in the SOIPPA algorithm now make sequence-homology clustering unnecessary. The version of SOIPPA used in the current study estimated the statistical significance of each active-site comparison using a non-parametric statistics method that required at least several hundred additional comparisons to derive a background distribution. Recently, an extreme-value distribution model has been developed to compute the statistical significance of SOIPPA scores [34]; this model improves the speed of the algorithm by at least two orders of multitude, so that each active-site comparison can be performed in mere seconds. Ligand binding-site similarity searches can now be performed on a genome-wide scale without the need for sequence-homology clustering [34],[35]. The new statistical model has been implemented in SMAP v2.0, available at http://funsite.sdsc.edu.

The manual verification of predicted compound binding to active sites of known biochemical or pharmacological activity also presented a limiting challenge. This step was very time consuming; had multiple compounds been tested, manual verification of all docked poses may have been impossible. To automate the process, active-site binding can be confirmed in many cases based on the proximity of the docked ligand to known catalytic residues annotated in the Catalytic Site Atlas [36] or to active-site residues specified in the site records of the PDB. Additionally, the SOIPPA implementation in SMAP v2.0, not available until recently, suggests an initial ligand binding pose for each predicted secondary target. Docked poses could be compared to this initial suggestion using an automated script and rejected in the absence of proximity.

Accounting for Possible Promiscuous Binding

As experimental validation has confirmed that 1 inhibits multiple protein targets, the possibility of nonspecific, promiscuous binding must be eliminated. Previous work has demonstrated that compound 1 inhibition of several ATP-dependent proteins depends on the degree of homology with the primary target, TbREL1, suggesting that binding occurs via a specific rather than promiscuous mechanism [20]. Additionally, the lack of SpPce or HsPDE9A2 inhibition further suggests that indiscriminant inhibition is unlikely.

Promiscuous inhibition can occur when a compound forms colloidal aggregates that inhibit indiscriminately. In one recent study, 95% of the inhibitors identified in a high-throughput screen were subsequently found to inhibit via a nonspecific aggregation-based mechanism [37]. In theory, the chances of aggregation are reduced in the case of 1 because of its negative charge; individual molecules should repel each other, preventing aggregation. To confirm this theory, Amaro et. al assayed 1 against TbREL1 in the presence of a non-ionic detergent as well as an additional protein (BSA) known to prevent aggregation. The presence of the detergent and the separate test with BSA did not significantly influence TbREL1 inhibition, demonstrating that 1 does not aggregate [20].

The current work likewise suggests no aggregation. The presence of detergent had no effect on TbGalE inhibition. Additionally, no HsETR1 aggregation was observed, as measured by both spectrometry and centrifugation (see the Text S1). The Hill slopes corresponding to the inhibition of HsETR1 and TbGalE were 1.06 and 1.13, respectively. As these slopes are approximately equal to one, the inhibition of these two proteins likely occurs via ligand binding to a single site, as predicted. One recent study suggested that aggregation-based inhibition typically produces Hill slopes that are much steeper, with average values of about 2.2 [37].

Promiscuous inhibition can also occur when compounds chemically modify the proteins they inhibit. Several experiments were performed in order to rule out chemical modification. To test for chemical modification of TbGalE, TbGalE was incubated with 1, and subsequent dialysis was used to remove any unbound ligand. TbGalE activity was unaffected following dialysis, as compared to treatment with DMSO alone. Had 1 been covalently linked to TbGalE, the compound would not have been washed away, and the enzyme would have shown little activity.

To test for chemical modification of HsETR1, a mixture of compound 1 and HsETR1 was run through a gel filtration column, which likewise removed any unbound ligand. The absorption spectrum of the fraction containing HsETR1 was subsequently analyzed and did not demonstrate the peaks characteristic of 1 at 530 nm and 320 nm, likewise demonstrating that 1 was not covalently bound to HsETR1.

A Cursory Chemo-Centric Analysis

A number of the predicted secondary targets identified belong to the same or similar biochemical pathways (i.e. metabolic pathways; DNA synthesis, repair, and replication pathways; and DNA ligase pathways) (Table 1). This result is encouraging, as proteins of the same pathway often act on similar substrates and so have similar active sites. A cursory chemo-centric look at the native substrates of the identified secondary targets in many instances corroborates our findings. For instance, the human proteins HsLigI, 3-methyl-adenine DNA glycosylase, and thymidylate synthase, all involved in DNA synthesis, repair, and replication, were identified as potential target receptors. HsLigI is a TbREL1 homolog (Table 1) that ligates DNA in a way analogous to TbREL1 dsRNA ligation. In contrast, 3-methyl-adenine DNA glycosylase is not a TbREL1 homolog (Table 1), but an examination of its structure nevertheless reveals that it also binds DNA. One of the nucleotides of the bound DNA, an alkylated base generated endogenously by lipid peroxidation, protrudes into a deep binding pocket in a way analogous to TbREL1-ATP binding [38]. Thymidylate synthase, another predicted secondary target involved in nucleotide synthesis, does not bind double-stranded nucleic acid, but rather binds deoxyuridine monophosphate, a compound with a nucleotide-ribose-phosphate substructure like that of ATP, a known substrate of the primary target, TbREL1.

Notably, two experimentally validated secondary targets contain NAD+ or NADPH co-factors, and in both cases 1 is predicted to bind at least partially in one of the co-factor binding pockets. Similar to ATP, NAD+ and NADPH both contain adenine-ribose-biphosphate substructures. Of the 23 proteins listed in Tables 1 and 2, eight contain NAD+-like co-factors. We expect that there are even more true positives among the predicted secondary targets; to this end, we provide the entire list of predicted targets in Text S1.

Traditionally, researchers have devoted their computational efforts to designing inhibitors of specific protein targets while paying less attention to the in silico prediction of secondary targets. Because adverse side effects are often discovered late in the drug-development process, often after the investment of many millions of dollars, we recommend using the current strategy to help bad drugs “fail early,” or, better yet, to guide the drug-discovery process towards more selective inhibitors. Additionally, the current methodology can help medicinal chemists overcome the conventional “one gene, one drug, one disease” paradigm. The rational design of drugs that act via polypharmacological mechanisms can produce compounds that exhibit increased therapeutic potency and against which resistance is less likely to develop.

Materials and Methods

Compound Purity

Compound 1 was provided by the NCI/DTP Open Chemical Repository (http://dtp.cancer.gov). Compound identity was confirmed by high-resolution mass spectrometry, and no impurities were detected by 1H-NMR.

Computational Methodology

The computational strategy presented here utilizes three distinct components in order to identify secondary pharmacological targets.

1. Homology Clustering: Creating a Non-Redundant PDB Representation

Identifying potential secondary targets from among the 110,000 protein chains deposited in the RCSB PDB [39] as of late 2007 was judged computationally intractable. In order to reduce the number of protein chains, redundancies in the RCSB PDB were eliminated by clustering all protein chains by sequence using the NCBI blastclust program, with a sequence identity threshold of 30% and an overlap threshold of 0.9 (Figure 1A, B). A representative protein chain was then chosen at random from each cluster, thus creating a smaller set of chains called the PDB30 (Figure 1C).

2. SOIPPA: Identifying Active Sites Similar to that of the Primary Target

In order to eliminate those members of the PDB30 whose active-site alpha-carbon configurations were different enough from that of the primary target, TbREL1, so as to likely preclude NSC4520 binding, we used the SOIPPA algorithm in conjunction with a geometric potential [17][19], which computes general binding-site similarity based on shape (alpha-carbon tessellation), physical properties, and the evolutionary profiles of the active-site residues, without regard for specific side-chain positions or global sequence or structure (Figure 1D). Using SOIPPA and the geometric potential, we eliminated all protein chains in the PDB30 with active sites that were dissimilar to that of the primary target, TbREL1 (p-value>0.05) (Figure 1D). The p-value was calculated from a non-parametric density function generated from 980 PDB chains with unique SCOP folds [18]. To derive the background distribution, a Gaussian function was placed at each observation. The mean of the Gaussian of the observed binding-site similarity score and its variance were fixed. The final probability density function was the sum of all these Gaussian functions. The optimal bandwidth was estimated from the data by using a least square cross-validation approach [40].

Each representative protein chain corresponded to a PDB cluster containing multiple homologous chains. A new set of protein-chain structures called the PDBr (PDBreduced) was created by taking the union of all those clusters whose representative PDB30 protein chains had active sites that were not dissimilar to that of TbREL1 (p-value<0.05) (Figure 1E). By considering only proteins from human or known human-pathogen species, the number of chains was significantly reduced. An additional protein, 1GJJ, was eliminated because of apparent PDB formatting errors. 1S31 was retained despite having a malformed GLU residue (561) to which Gasteiger partial charges could not be assigned.

3. In silico Docking

AutoDock 4.0 [41] was used to dock 1 into the protein chains of the PDBr (Figure 1F). In previous work, AutoDock was validated against TbREL1 [20]. To define the distinct docking grid associated with each protein chain, SOIPPA was used to identify the most probable active site, and the grid box was set to the smallest possible X-Y-Z cube encompassing all the atoms of the SOIPPA-reported alignable alpha carbons. Additional details regarding receptor and ligand preparation and grid and docking parameters can be found in Text S1.

All dockings were sorted by the predicted binding energy of their most-populated AutoDock clusters. After eliminating protein chains of unknown function from the list, the data was grouped according to species and protein, revealing significant redundancy in the PDBr. We selected the ligand-protein pair from each group with the best AutoDock score, producing a list of non-redundant ligand-protein pairs, one corresponding to each protein/species group (Text S1).

For each of these ligand-protein pairs, we used one of several methods to determine if AutoDock placed 1 in an active site of known biochemical or pharmacological activity. First, SITE data included in the published PDB file identified several active sites. Second, co-crystallized ligands bound in native active sites were examined. Finally, homology modeling was used to determine the locations of active sites for the remaining protein chains, when possible. A protein chain was considered to be a “hit” if 1 had a high predicted energy of binding and if 1 was predicted to bind in an identified active site of known biochemical or pharmacological activity. A description of the assays used to experimentally validate several of the predicted secondary targets is included in Text S1.

Supporting Information

Text S1.

Text S1 contains details about the computational methods employed and the assays used to confirm theoretical results. It also contains expanded versions of Tables 1 and 2.

https://doi.org/10.1371/journal.pcbi.1000648.s001

(0.23 MB DOC)

Figure S1.

Possible binding of compound 1 in NAD+ and NADPH pockets. In the case of two experimentally validated secondary targets, AutoDock predicted that 1 would bind in a NAD+ or NADPH pocket, suggesting that 1 may be a competitive inhibitor for these co-factors. (a) HsETR1. The crystal structure (PDB: 1ZSY) contained no NAD+ co-factor, so a related structure (PDB: 1GUF) with co-crystallized NDP (NADPH dihydro-nicotinamide-adenine-dinucleotide phosphate) was aligned to the 1ZSY structure using MultiSeq. The aligned NDP is shown in red. The predicted binding pose of 1 is shown in green. (b) TbGalE. The co-crystallized NAD+ co-factor is shown in red. The predicted binding pose of 1 is shown in green.

https://doi.org/10.1371/journal.pcbi.1000648.s002

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Figure S2.

Unvalidated but likely secondary targets of compound 1. (a) The current strategy correctly identified TbGalE as a secondary target of 1. Additionally, HsGalE and SeRmlB, both TbGalE homologs, are also predicted to be off-target receptors. SeRmlB and TbGalE were aligned to HsGalE using MultiSeq to demonstrate structural similarity. Blue: TbGalE; Red: SeRmlB; Green: HsGalE. (b) The current strategy identified a number of DNA ligases as predicted secondary targets of 1. Three of these DNA ligases are homologous with HsLigIIIβ, an experimentally validated secondary target. The structures of the three predicted secondary targets were aligned using MultiSeq to demonstrate structural similarity. Portions of some ligands were removed to simplify visualization. The active site is shown with selected protein residues to demonstrate active-site similarity. Blue: HsLigI; Red: Ef ligase; Green: Mt ligase.

https://doi.org/10.1371/journal.pcbi.1000648.s003

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Figure S3.

False-positive predictions. Compound 1 is shown in licorice, docked into each protein crystal structure. Magnesium and zinc are shown in green and grey, respectively. In both cases, one of the sulfonate groups of 1 is juxtaposed against multiple metal cations, leading to an exaggerated estimate of the electrostatic energy. (a) SpPce was predicted to bind 1 with −28.00 kcal/mol. (b) HsPDE9A2 was predicted to bind 1 with −18.19 kcal/mol.

https://doi.org/10.1371/journal.pcbi.1000648.s004

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Acknowledgments

Resources provided by the National Center for Supercomputing Applications, the San Diego Supercomputer Center, the W.M. Keck Foundation, the National Biomedical Computation Resource, and the Center for Theoretical Biological Physics are gratefully acknowledged. Compound 1 was provided by the NCI/DTP Open Chemical Repository (http://dtp.cancer.gov). We also would also like to thank Professor Rik K. Wierenga and Professor J. Kalervo Hiltunen.

Author Contributions

Conceived and designed the experiments: JDD REA LX MDU MAJF AH AMDG FW. Performed the experiments: JDD LX MDU AH ZC AMDG FW. Analyzed the data: JDD LX MDU AH ZC AMDG FW. Contributed reagents/materials/analysis tools: JDD LX MDU MAJF AH ZC AMDG FW PEB JAM. Wrote the paper: JDD REA LX MDU AH AMDG FW.

References

  1. 1. Adams CP, Brantner VV (2006) Estimating the cost of new drug development: is it really 802 million dollars? Health Aff (Millwood) 25: 420–428.
  2. 2. Kennedy T (1997) Managing the drug discovery/development interface. Drug discovery today 2: 436–444.
  3. 3. Keiser MJ, Roth BL, Armbruster BN, Ernsberger P, Irwin JJ, et al. (2007) Relating protein pharmacology by ligand chemistry. Nat Biotechnol 25: 197–206.
  4. 4. Croft SL (2005) Public-private partnership: from there to here. Trans R Soc Trop Med Hyg 99: Suppl 1S9–14.
  5. 5. Schreiber SL (2005) Small molecules: the missing link in the central dogma. Nat Chem Biol 1: 64–66.
  6. 6. Paolini GV, Shapland RH, van Hoorn WP, Mason JS, Hopkins AL (2006) Global mapping of pharmacological space. Nat Biotechnol 24: 805–815.
  7. 7. Vieth M, Higgs RE, Robertson DH, Shapiro M, Gragg EA, et al. (2004) Kinomics-structural biology and chemogenomics of kinase inhibitors and targets. Biochim Biophys Acta 1697: 243–257.
  8. 8. Izrailev S, Farnum MA (2004) Enzyme classification by ligand binding. Proteins 57: 711–724.
  9. 9. Coleman RG, Sharp KA (2006) Travel depth, a new shape descriptor for macromolecules: application to ligand binding. J Mol Biol 362: 441–458.
  10. 10. Nayal M, Honig B (2006) On the nature of cavities on protein surfaces: application to the identification of drug-binding sites. Proteins 63: 892–906.
  11. 11. Coleman RG, Burr MA, Souvaine DL, Cheng AC (2005) An intuitive approach to measuring protein surface curvature. Proteins 61: 1068–1074.
  12. 12. Agarwal PK, Edelsbrunner H, Harer J, Wang Y (2004) Extreme elevation on a 2-manifold.. Symp Comp Geo 20: 357–365.
  13. 13. Hendrix DK, Kuntz ID (1998) Surface solid angle-based site points for molecular docking. Pac Symp Biocomput 317–326.
  14. 14. Liang J, Edelsbrunner H, Woodward C (1998) Anatomy of protein pockets and cavities: measurement of binding site geometry and implications for ligand design. Protein Sci 7: 1884–1897.
  15. 15. Norel R, Wolfson HJ, Nussinov R (1999) Small molecule recognition: solid angles surface representation and molecular shape complementarity. Comb Chem High Throughput Screen 2: 223–237.
  16. 16. Watson JD, Laskowski RA, Thornton JM (2005) Predicting protein function from sequence and structural data. Curr Opin Struct Biol 15: 275–284.
  17. 17. Xie L, Bourne P (2007) A robust and efficient algorithm for the shape description of protein structures and its application in predicting ligand binding sites. BMC Bioinformatics 8: S9.
  18. 18. Xie L, Bourne PE (2008) Detecting evolutionary relationships across existing fold space, using sequence order-independent profile-profile alignments. Proc Natl Acad Sci U S A 105: 5441–5446.
  19. 19. Xie L, Wang J, Bourne PE (2007) In silico elucidation of the molecular mechanism defining the adverse effect of selective estrogen receptor modulators. PLoS Comput Biol 3: e217.
  20. 20. Amaro RE, Schnaufer A, Interthal H, Hol W, Stuart KD, et al. (2008) Discovery of drug-like inhibitors of an essential RNA-editing ligase in Trypanosoma brucei. Proceedings of the National Academy of Sciences 105: 17278–17283.
  21. 21. Remme JH, Blas E, Chitsulo L, Desjeux PM, Engers HD, et al. (2002) Strategic emphases for tropical diseases research: a TDR perspective. Trends in parasitology 18: 421–426.
  22. 22. Schnaufer A, Panigrahi AK, Panicucci B, Igo RP Jr, Salavati R, et al. (2001) An RNA Ligase Essential for RNA Editing and Survival of the Bloodstream Form of Trypanosoma brucei. Science 291: 2159–2162.
  23. 23. Rusche LN, Huang CE, Piller KJ, Hemann M, Wirtz E, et al. (2001) The two RNA ligases of the Trypanosoma brucei RNA editing complex: cloning the essential band IV gene and identifying the band V gene. Molecular and cellular biology 21: 979–989.
  24. 24. Miinalainen IJ, Chen ZJ, Torkko JM, Pirila PL, Sormunen RT, et al. (2003) Characterization of 2-enoyl thioester reductase from mammals. An ortholog of YBR026p/MRF1'p of the yeast mitochondrial fatty acid synthesis type II. J Biol Chem 278: 20154–20161.
  25. 25. Rake J, Visser G, Smit G (2006) Disorders of Carbohydrate and Glycogen Metabolism. Physician's Guide to the Treatment and Follow-Up of Metabolic Diseases. pp. 161–180.
  26. 26. Pascal JM, O'Brien PJ, Tomkinson AE, Ellenberger T (2004) Human DNA ligase I completely encircles and partially unwinds nicked DNA. Nature 432: 473–478.
  27. 27. Willis AE, Lindahl T (1987) DNA ligase I deficiency in Bloom's syndrome. Nature 325: 355–357.
  28. 28. Harrison C, Ketchen AM, Redhead NJ, O'Sullivan MJ, Melton DW (2002) Replication failure, genome instability, and increased cancer susceptibility in mice with a point mutation in the DNA ligase I gene. Cancer Res 62: 4065–4074.
  29. 29. Ye Y, Godzik A (2003) Flexible structure alignment by chaining aligned fragment pairs allowing twists. Bioinformatics (Oxford, England) 19: Suppl 2ii246.
  30. 30. Shaw MP, Bond CS, Roper JR, Gourley DG, Ferguson MA, et al. (2003) High-resolution crystal structure of Trypanosoma brucei UDP-galactose 4′-epimerase: a potential target for structure-based development of novel trypanocides. Mol Biochem Parasitol 126: 173–180.
  31. 31. Roper JR, Guther ML, Milne KG, Ferguson MA (2002) Galactose metabolism is essential for the African sleeping sickness parasite Trypanosoma brucei. Proceedings of the National Academy of Sciences of the United States of America 99: 5884–5889.
  32. 32. Allard ST, Giraud MF, Whitfield C, Graninger M, Messner P, et al. (2001) The crystal structure of dTDP-D-Glucose 4,6-dehydratase (RmlB) from Salmonella enterica serovar Typhimurium, the second enzyme in the dTDP-l-rhamnose pathway. J Mol Biol 307: 283–295.
  33. 33. Gajiwala KS, Pinko C (2004) Structural rearrangement accompanying NAD+ synthesis within a bacterial DNA ligase crystal. Structure 12: 1449–1459.
  34. 34. Xie L, Bourne PE (2009) A unified statistical model to support local sequence order independent similarity searching for ligand-binding sites and its application to genome-based drug discovery. Bioinformatics 25: i305–312.
  35. 35. Xie L, Li J, Bourne PE (2009) Drug discovery using chemical systems biology: identification of the protein-ligand binding network to explain the side effects of CETP inhibitors. PLoS Comput Biol 5: e1000387.
  36. 36. Porter CT, Bartlett GJ, Thornton JM (2004) The Catalytic Site Atlas: a resource of catalytic sites and residues identified in enzymes using structural data. Nucleic Acids Res 32: D129–133.
  37. 37. Feng BY, Simeonov A, Jadhav A, Babaoglu K, Inglese J, et al. (2007) A high-throughput screen for aggregation-based inhibition in a large compound library. J Med Chem 50: 2385–2390.
  38. 38. Lau AY, Wyatt MD, Glassner BJ, Samson LD, Ellenberger T (2000) Molecular basis for discriminating between normal and damaged bases by the human alkyladenine glycosylase, AAG. Proc Natl Acad Sci U S A 97: 13573–13578.
  39. 39. Berman HM, Westbrook J, Feng Z, Gilliland G, Bhat TN, et al. (2000) The Protein Data Bank. Nucleic Acids Research 28: 235–242.
  40. 40. Silverman BW (1986) Density Estimation for Statistics and Data Analysis. Chapman & Hall/CRC.
  41. 41. Morris GM, Goodsell DS, Halliday RS, Huey R, Hart WE, et al. (1998) Automated docking using a Lamarckian genetic algorithm and an empirical binding free energy function. Journal of Computational Chemistry 19: 1639–1662.