Abstract
Drug development for rare and intractable diseases has been challenging for decades due to the low prevalence and insufficient information on these diseases. Drug repositioning is increasingly being used as a promising option in drug development. We aimed to analyze the trend of drug repositioning and inter-disease drug repositionability among rare and intractable diseases. We created a list of rare and intractable diseases based on the designated diseases in Japan. Drug information extracted from clinical trial data were integrated with information of drug target genes, which represent the mechanism of drug action. We obtained 753 drugs and 551 drug target genes from 8307 clinical trials for 189 diseases or disease groups. Trend analysis of drug sharing between a disease pair revealed that 1676 drug repositioning events occurred in 4401 disease pairs. A score, Rgene, was invented to investigate the proportion of drug target genes shared between a disease pair. Annual changes of Rgene corresponded to the trend of drug repositioning and predicted drug repositioning events occurring within a year or two. Drug target gene-based analyses well visualized the drug repositioning landscape. This approach facilitates drug development for rare and intractable diseases.
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Introduction
Rare and intractable diseases are mostly severe and cause a lifetime suffering1. There are approximately 7000 rare diseases and more than 300 million people are affected worldwide2,3. Because of their low prevalence and complex pathology, they are often difficult to diagnose and treat. A paradigm shift and systematic approach to drug discovery is the key for treatment of rare and intractable diseases.
Recently, drug development in rare and intractable diseases has attracted the attention of pharmaceutical companies. New modalities, such as antibodies and anti-sense oligonucleotides, are being developed as an effective approach to these diseases. Another solution is drug repositioning4,5. Drug repositioning, also called drug repurposing, introduces existing drugs in the treatment of new diseases, where their use has not been previously tested. By utilizing drugs already approved as safe in previous clinical trials, drug repositioning can accelerate drug discovery also in rare and intractable diseases.
The trend of drug discovery and repositioning in rare and intractable diseases has been unclear. The main reason for this is the lack of comprehensive information for the diseases. Apart from the small number of patients, the variable classification, challenging diagnosis, and the use of inconsistent disease names make the integration of information particularly difficult. Investigation of information is crucial also for accelerating drug repositioning in rare and intractable diseases.
When repositioning a drug developed for a specific disease, it is important to find a target disease that has a common mechanism of action for the particular drug6,7,8. We considered that drug target genes are able to provide key information for the mechanism. Each drug has a set of target genes (or target gene products), with which the drug interacts to modify their actions. Sharing the target genes of a drug between a disease pair may suggest that this disease pair also shares a common mechanism of drug action. Therefore, a disease pair sharing drug target genes could be a good candidate for drug repositioning.
In this study, we collected drug information from four major clinical trial registries, and assigned information of target genes to these drugs. We targeted 333 rare and intractable diseases, which consists of 787 main and sub-categorized diseases in total. We hypothesized that a proportion of the number of shared genes to that of total genes for each disease in the pair could be the key for drug repositionability. Through the inter-disease analysis based on drug target genes, we invented a score of drug repositionability that is useful for drug development in rare and intractable diseases.
Results
Trend of drug development for rare and intractable diseases
To visualize the inter-disease landscape of drug repositioning in rare and intractable diseases, we extracted information on drug development from clinical trial registries. Comprehensive information on drug development is available from clinical trial registries, since it is mandatory to register all clinical trials in at least one registry worldwide. Then, we investigated genes or gene products that are targeted by the drugs. These target genes, which can represent the mechanism of drug action, were used for mining the drug repositionability in this study.
In order to search clinical trials, we constructed an original list of rare and intractable diseases based on the intractable diseases designated in Japan (Supplementary Table 1). This disease list included synonyms and consisted of 787 rare and intractable diseases in a two-level categorized format (333 first-level diseases and 454 second-level diseases). Since the number of drugs for rare and intractable diseases is mostly small, we performed the following analyses based on the 333 first-level diseases, by merging all search results for the second-level diseases to their parent (first-level) diseases. The disease list covered 15 disease fields, such as neuromuscular diseases, metabolic diseases, cutaneous connective tissue diseases, etc.9. We also constructed a reference drug list that included drug names, synonyms, and product names registered in DrugBank10. This drug list consisted of 13,339 drugs (DrugBank accession numbers) and was used for searching clinical trials.
First, by searching 412,555 clinical trials from the four largest registries in the world (JPRN11, ClinicalTrials.gov12, EU-CTR13, and ChiCTR14) through WHO International Clinical Trials Registry Platform15, 15,194 trials were identified to target rare and intractable diseases and contain drug information (Fig. 1A). In these trials, 1666 drugs were tested for 226 diseases in total. Second, we extracted clinical trials in which at least one drug had target gene information based on KEGG16. As a result, we selected 8307 clinical trials that tested 753 drugs which targeted 551 genes (Supplementary Table 2) for 189 rare and intractable diseases (Fig. 1A, Supplementary Table 3). Out of the 8307 clinical trials, 3241 trials (39.0%) were Phase 3 or 4 trials (Supplementary Fig. 1). We used these 8307 trials as a data set for the analysis, since the target gene information is a key to investigate inter-disease relationship that might underlie drug repositioning.
Drug repositioning in rare and intractable diseases
In the extracted clinical trials, 442 out of 753 drugs were tested for two or more diseases (Supplementary Fig. 2), suggesting that these drugs had been tested as repositioned drugs among rare and intractable diseases. Since drug repositioning is a process of finding another target disease, we examined the trend of drug repositioning from the viewpoint of a disease pair. Drug repositioning in a disease pair was defined as a drug donor (provider) and a drug recipient (acceptor), that is, a drug which is developed for one disease (drug donor) is repositioned for another disease (drug recipient, Fig. 1B). When repositioned, the drug becomes shared between the disease pair.
We defined a drug repositioning event as an annual change of drug sets tested in clinical trials between a disease pair. Clinical trials purposing drug repositioning were selected based on two criteria; (i) a drug was newly tested for a disease in the trial, and (ii) this drug had been already tested for other rare and intractable diseases in other trials. During the past 20 years, the number of clinical trials identified as drug repositioning trials continuously increased to 1676 trials in November 2019 (Fig. 1C). The unique number of disease pairs for drug repositioning also increased to 4401 pairs during the same period (Fig. 1D). As a whole, drug repositioning was actively occurring in rare and intractable diseases.
Invention of drug target gene-based score for the analysis of drug repositioning landscape
We investigated the drug repositionability among rare and intractable diseases based on drug target genes. Drug target genes can represent the inter-disease proximity more clearly than drugs, as denoting similar mechanisms of drug actions that lead to drug repositionability between diseases. We connected drugs found in the clinical trials to their target genes, then we examined whether the drug target genes for each disease became shared between diseases (Fig. 2A). Some drugs target more than one gene, while some genes are targeted by more than one drug.
To investigate the drug target gene-based proximity of a pair of diseases, we invented a score, Rgene (Relationship between diseases based on drug target gene sharing). Rgene is calculated for each disease pair by multiplying the proportions of the number of shared genes to the number of total genes for each disease, and the unique number of total genes for both diseases (Fig. 2B). A larger Rgene indicates a higher similarity in the mechanisms of drug actions between the disease pair. The distribution of Rgene was examined in 6808 disease pairs (Fig. 2C). This distribution ranged between 0.03 and 107.78, and was extremely biased; Rgene of 2466 disease pairs (36.2%) was less than 1, while only 814 pairs (12.0%) were higher than 10, and 220 pairs (3.2%) were higher than 20. Higher Rgene was limited to a small number of disease pairs.
The top 10 Rgene disease pairs are listed in Table 1. The diseases in this list were composed of a specific subset of diseases and disease fields. Neuromuscular diseases (Multiple sclerosis, amyotrophic lateral sclerosis, and Parkinson’s disease) and digestive diseases (Crohn’s disease and ulcerative colitis) appeared multiple times in the either side of disease pairs. Some disease pairs were paired by diseases from different disease fields as seen in the pair of Multiple sclerosis (neuromuscular diseases) and Crohn’s disease (digestive diseases).
This trend of biases was also observed in the following disease network analysis. We visualized the drug repositionability network by merging the top 100 Rgene disease pairs as a network (Fig. 2D). This network consisted of 33 diseases (Supplementary Table 5), since some diseases appeared more than once in the pairs as shown in Table 1. As expected, these diseases had multiple partners in the network. For example, multiple sclerosis (ID: 13) and Crohn’s disease (ID: 96) not only paired together, but also paired with many other diseases. The disease network based on drug target genes is expected to reveal a drug repositionability landscape as a wide variety of inter-disease relationships in rare and intractable diseases.
R gene reflects and predicts drug repositioning events
We investigated how Rgene represents drug repositioning events over the past 20 years. We calculated annual changes in Rgene and the number of repositioned drugs in each disease pair. Here, we selected multiple sclerosis (MS) and Crohn’s disease (CD) in Table 1, for instance. Between MS and CD, Rgene increased gradually during the period with three characteristic surges seen from 2007 to 2008, 2010 to 2011, and 2014 to 2016 (Fig. 3A). We found that these surges of Rgene coincided with actual drug repositioning events between MS and CD. In 2007–2008 when the first surge of Rgene was observed, two drugs (cholecalciferol and glatiramer) were repositioned from MS to CD. In the following 2008–2009, additionally, four drugs were repositioned (tacrolimus and dexamethasone from MS to CD; zoledronic acid and prednisolone from CD to MS). As described above, we found the tendency that Rgene surges coincided with, or preceded to, the actual drug repositioning events.
We investigated whether this tendency holds true in other disease pairs. For this purpose, we standardized the variations of Rgene and the number of repositioned drugs during the period. For each disease pair, annual changes in Rgene and the number of drugs were converted to ΔRgene and ΔDrug, respectively, based on their standard deviations throughout the period (see Methods for details). As a result, ΔRgene clearly visualizes three surges in Rgene in the MS–CD pair, which are followed by rapid increases of ΔDrug within 2 years (Fig. 3B). This tendency is comprehensively observed in other disease pairs in Table 1: Amyotrophic lateral sclerosis (ALS)–MS, Parkinson’s disease (PD)–MS, and ALS–PD (Supplementary Figs. 3 and 4). Through these observations of ΔRgene and ΔDrug, we found that drug repositioning events surge periodically like a wave, and that ΔRgene can suitably represent this drug repositioning wave.
The surge of Rgene is likely to precede drug repositioning events actively occurring. We investigated this hypothesis using the top 100 Rgene disease pairs (Supplementary Table 4). We divided the top 100 disease pairs into 10 groups with 10 pairs each, consecutively by the order. We merged ΔRgene and ΔDrug of the 10 disease pairs in each group. We defined positive values (> 0) of ΔRgene as surges and those of ΔDrug as active repositioning events. Then, by logistic regression analysis, we examined the association of ΔRgene and ΔDrug in each group during the period. As a result, the surges of Rgene predicted active drug repositioning events occurring within 2 years, in all 10 groups with high odds ratio (3.89–13.34; Fig. 3C). Odds ratio was also high for those within a year (3.61–14.25) and within 3 years (2.01–19.14; Supplementary Fig. 5A–C).
Additionally, we examined the overall odds ratio of the top 100 disease pairs merged in one group. We found that, also in this case, the odds ratio for the predictability within 2 years was high (5.73), and it was also high for those within a year (6.52) and within 3 years (4.75; Supplementary Fig. 5D). Furthermore, we obtained similar results when we performed another analysis limiting data to Phase 3 and 4 clinical trials only (Supplementary Fig. 6).
These logistic regression analyses were performed as a sensitivity analysis to examine the predictability of drug repositioning events by Rgene. The results confirmed that the surge of Rgene can predict active drug repositioning events, regardless of what disease pairs they are. Given this, the utility of Rgene in the prediction of drug repositioning events was validated.
Discussion
In this study, we visualized the drug repositioning landscape in rare and intractable diseases. This landscape is rapidly expanding annually with a wide variety of inter-disease combinations. We invented a score, Rgene, to investigate drug target gene-based proximity of a pair of diseases. Rgene represented the trend and potential of drug repositioning, and was useful in identifying the drug repositioning-active diseases. Rgene also potentiated the prediction of drug repositioning events. These findings illustrate the characteristics of drug repositioning trend and facilitate drug development in rare and intractable diseases.
Drug repositioning occurred frequently among rare and intractable diseases. In total, drug repositioning was identified between 4401 disease pairs in 1676 clinical trials. This large number of disease pairs is specific to the nature of rare and intractable diseases. The number of diseases is large, whereas the number of patients is small and the information available is limited. The diagnosis is often difficult, the pathogenic mechanism is unclear, and thus, available drugs are limited. The nature of rare and intractable diseases often interferes with novel drug developments, whereas drug repositioning may have compensated for the lack of drug developments. To cover broad ranges of diseases, drug repositioning has been attempted vigorously. On the other hand, the number of drug repositioning events were highly biased to a small number of disease pairs. The diseases frequently appeared in the disease pairs included such diseases as multiple sclerosis and Crohn’s disease. Most drug repositioning events were observed among these diseases which are large in number of patients. Less information of drug repositioning was available for most of rare and intractable diseases.
The degree of drug repositionability between a disease pair was further clarified using Rgene. Rgene is a score for disease pairs sharing drug target genes which represent a common mechanism of drug action underling drug repositionability. In many cases, drugs were developed to target genes or gene products by inhibiting their disease-related activities as enzymes or receptors, to produce pharmacological effect17,18. Thus, if a disease pair shares more drug target genes, this disease pair is likely to share similar mechanisms of drug action. Although researchers in the world have vigorously applied drug repositioning in rare and intractable diseases, the lack of robust and sufficient information often hinders the identification of a suitable disease pair for drug repositioning. In rare and intractable diseases whose information is limited, investigation of drug target genes is crucial to access the mechanism of drug action. The repositionable disease pair is likely to share more target genes, denoting the closer drug target gene-based proximity of this pair. Rgene in a disease pair becomes high when the gene-based proximity becomes closer.
Besides its function to identify drug repositioning-active disease pairs, Rgene also elucidates the annual trends of drug repositioning among diseases. The number of repositioned drugs and Rgene increased during the observational period, indicating the accumulation of the number of drugs and drug target genes between a disease pair (MS–CD, Fig. 3A). In the trend analysis, we observed two waves of the annual changes of the number of repositioned drugs (ΔDrug) and ΔRgene (Fig. 3B). ΔRgene surges periodically, and these surges often preceded actual drug repositioning events (ΔDrug). The predictability of Rgene for the drug repositioning events was confirmed by logistic regression analyses throughout the top 100 drug repositioning-active disease pairs (Fig. 3C). Rgene predicted the potential of drug repositioning in the near future. Since Rgene is based on the sharedness of drug target genes between a disease pair and ΔRgene surges before ΔDrug, a drug that targets the same gene was likely to be repositioned after the discovery of a new gene target of the drug.
Rgene provides a systematic approach to identify a target disease for repositioning, whereas Rgene has the potential for further improvement. Incorporation of information such as genetic variation and clinical phenotypes into Rgene may better represent the mechanism of drug action for targeting repositioning diseases. Modality and side effects of drugs are also important information that need to be incorporated for the information of drug repositioning. By accumulating testing data, cutoff values for Rgene in various cases can be determined to investigate the drug repositionability. Furthermore, since various drug combinations were tested in some clinical trials, Rgene will be applicable for the studies of pharmacodynamic drug interaction.
In many rare and intractable diseases, information on drug repositioning is still lacking. Development of the efficient methods to explore repositionable drugs in these diseases is still a challenge. Once the information of clinical trials and drug target genes are available, Rgene approach is efficient for this purpose. Rgene approach is also useful in other diseases, such as common diseases. Likewise, Rgene also provides the clue for new drug candidates not tested for rare and intractable diseases yet. Further drug repositioning is expected in the disease pairs which were identified by Rgene but had no repositioned drugs between them. Rgene approach is getting more effective these days, since target gene information is expanding. We expect that the invention of a score such as Rgene can broaden the drug repositioning landscape in rare and intractable diseases.
In conclusion, we visualized drug repositioning landscape in rare and intractable diseases. Drug target gene-based approach using Rgene provides both inter-disease and longitudinal perspectives as a whole landscape of drug repositioning, which is useful in drug development in rare and intractable diseases.
Methods
Data sources
Clinical trial data were obtained from four registries (JPRN11, ClinicalTrials.gov12, EU-CTR13, and ChiCTR14) through the website of the WHO International Clinical Trials Registry Platform15. Clinical trial data of the four registries were extracted from all clinical trial data in XML format and downloaded by searching WHO ICTRP with “Recruitment status: ALL" option. Drug data were downloaded from DrugBank10 (drugbank_all_full_database.xml.zip, version 5.1.4). Data on drug target genes were downloaded from KEGG16. In this study, data construction and analyses were conducted using our in-house Perl programs19 and other tools described later.
Disease list
A list of rare and intractable diseases used in this study was initially created based on the 333 designated intractable diseases of the Ministry of Health, Labour and Welfare (MHLW) in Japan20. They included all fields of rare and intractable diseases covering 15 disease fields9. The list was manually constructed by translating Japanese disease names into English and assigning them synonyms and abbreviations. In addition, this list included second-level diseases (sub-categorized diseases), referenced in the MHLW documents. For example, lysosomal storage disease in the first level contains a subset of second-level diseases, such as Gaucher disease and Farber disease. In total, a list of 787 rare and intractable diseases consisting of a two-level categorized format (333 first-level diseases and 454 second-level diseases) was constructed (Supplementary Table 1).
Data construction
Data construction was conducted as described in our previously reported method21 with some technical improvements for comprehensiveness. First, clinical trials with drug information were selected from the trials of the four registries. Two types of searches were conducted targeting the "Intervention" section of each trial data. (1) Searching for drug candidate descriptions by utilizing specific tags (e.g., "Drug:" for ClinicalTrials.gov) and (2) searching for drug names, synonyms, etc. based on DrugBank. Second, clinical trials for the rare and intractable diseases were selected by searching for the 787 disease names in "Public title", "Scientific title," and "Condition" sections of each trial data. These searches were conducted with detailed search options covering plural/singular forms, special characters (ä, ç, è, etc.), and word substitutions. For instance, for a disease name including “disease,” additional searches by substituting it with “disorder” or “syndrome” were also conducted. Some trials tested multiple diseases and/or multiple drugs, and some trials tested the same disease-drug combination.
Finally, from the clinical trials selected above, drugs were extracted and integrated to their target genes, referring to KEGG. First, drug data was connected between DrugBank and KEGG by referring links that appeared in each database and by searching drug names bi-directionally. Then, the extracted drugs were connected to their corresponding target genes using KEGG. If a drug had target gene information, the trial in which the drug was tested was selected to construct the data (Fig. 1A).
Drug repositioning detection
Detection of drug repositioning was conducted among 333 first-level diseases. Drugs were assigned to each disease based on clinical trial data. Then, for each disease pair (A, B), the numbers of shared drugs (A and B), and unshared drugs (A only or B only) were counted. Each disease pair sharing at least one drug target gene was determined as a repositionable disease pair to be analyzed. Based on the “Date of first enrolment” section of clinical trial data, we constructed annual data of a set of clinical trials enrolled in and before each year from 2000 to 2019 (~ Nov. 2019). For example, the annual data of 2008 contain the clinical trials enrolled both in 2008 and before 2008. For each annual data, the numbers of shared and unshared drugs were counted per disease pair. Then, for each disease pair, differences in the number of drugs between every two consecutive years were counted.
Drug repositioning was defined as follows: in a disease pair (A, B), if an unshared drug in disease A becomes newly shared in the next year, then this is a drug repositioning event where the drug was repositioned from disease A (donor) to disease B (acceptor; Fig. 1B). For each disease pair (A, B), annual changes in the number of repositioned drugs were defined as ΔDrug. The number of repositioned drugs for both “A to B” and “B to A” repositioning was counted. ΔDrug standardization was conducted as follows: (ΔDrug_i–av) / SD, where ΔDrug_i, av, and SD are ΔDrug for each year, an average of ΔDrug, and standard deviation, respectively, for each disease pair with SD > 0.
R gene calculation
The numbers of drug target genes were counted as well for each disease pair by converting drugs to their target genes (Fig. 2A). Based on the numbers of shared and unshared genes, Rgene was calculated for each disease pair using the formula shown in Fig. 2B. The disease pairs for which Rgene > 0 were expanded to a disease network. A circular network shown in Fig. 2D was depicted by Cytoscape v3.8.2 (Degree Sorted Circle Layout)22. ΔRgene and its standardization was conducted in the same way as ΔDrug.
Odds ratio for ΔR gene and ΔDrug
Logistic regression analyses were conducted to calculate the odds ratio and confidence intervals for the association between ΔRgene and ΔDrug. They were conducted for disease pairs in which ΔRgene was calculated in two or more years, and when at least one drug repositioning event occurred during the period. Before calculation, ΔRgene and ΔDrug were converted to 1 (if > 0) or 0 (if ≤ 0), and additionally two sets of ΔDrug were prepared: ΔDrug+1 = 1 if ΔDrug = 1 in the same year or next year, and ΔDrug+2 = 1 if ΔDrug = 1 in the same year or within the next two years. Odds ratio was calculated for (1) ΔRgene and ΔDrug, (2) ΔRgene and ΔDrug+1, and (3) ΔRgene and ΔDrug+2. Odds ratios were calculated for each set of 10 disease pairs in the top 100 Rgene disease pairs, from the top to the last. The analyses were conducted by logistic.display in the epiDisplay library of R version 4.0.323.
Data availability
The datasets used and/or analyzed during the current study are available from the supplementary information files and the database (DDrare: Database of Drug Development for Rare Diseases: https://ddrare.nibiohn.go.jp/index_e.html).
References
Melnikova, I. Rare diseases and orphan drugs. Nat. Rev. Drug Discov. 11, 267–268 (2012).
Nguengang, W. et al. Estimating cumulative point prevalence of rare diseases: analysis of the Orphanet database. Eur. J. Hum. Genet. 28, 165–173 (2020).
RARE List. Global genes (accessed November 2020). https://globalgenes.org/rarelist/.
Brown, A. S. & Patel, C. J. A standard database for drug repositioning. Sci. Data 4, 170029 (2017).
Shameer, K. et al. Systematic analyses of drugs and disease indications in RepurposeDB reveal pharmacological, biological and epidemiological factors influencing drug repositioning. Brief. Bioinform. 19, 656–678 (2018).
Goh, K. I. et al. The human disease network. Proc. Natl. Acad. Sci. U.S.A. 104, 8685–8690 (2007).
Rodriguez-Esteban, R. A drug-centric view of drug development: How drugs spread from disease to disease. PLoS Comput. Biol. 12, e1004852 (2016).
Fang, H. et al. A genetics-led approach defines the drug target landscape of 30 immune-related traits. Nat. Genet. 51, 1082–1091 (2019).
Japan Intractable Diseases Information Center (accessed November 2019) (in Japanese). https://www.nanbyou.or.jp/entry/5347.
Wishart, D. S. et al. DrugBank: A comprehensive resource for in silico drug discovery and exploration. Nucleic Acids Res. 34, D668–D672 (2006).
Japan Primary Registries Network (JPRN) (accessed November 2019). http://www.who.int/ictrp/network/jprn2/en/.
ClinicalTrials.gov (accessed November 2019). https://www.clinicaltrials.gov.
The European Union Clinical Trials Register (EUCTR) (accessed November 2019). https://www.clinicaltrialsregister.eu/ctr-search/search.
Chinese Clinical Trial Register (ChiCTR) (accessed November 2019). http://www.chictr.org.cn/enIndex.aspx.
International Clinical Trials Registry Platform (ICTRP) World Health Organization (accessed November 2019). https://apps.who.int/trialsearch/Default.aspx.
Kanehisa, M. & Goto, S. KEGG: Kyoto encyclopedia of genes and genomes. Nucleic Acids Res. 28, 27–30 (2000).
Spratto, G. R. & Woods, A. L. Delmar Nurse’s Drug Handbook (Cengage Learning, 2010). ISBN: 978-1-4390-5616-5.
Grant, R. L., Combs, A. B. & Acosta, D. Experimental models for the investigation of toxicological mechanisms. In Comprehensive Toxicology 2nd edn (ed. McQueen, C. A.) 204 (Elsevier, 2010). ISBN: 978-0-08-046884-6.
Wall, L. et al. The Perl Programming Language (Prentice Hall, London, 1994).
Intractable diseases designated by the Ministry of Health, Labour and Welfare in Japan (accessed November 2019) (in Japanese). https://www.mhlw.go.jp/stf/seisakunitsuite/bunya/0000084783.html.
Sakate, R., Fukagawa, A., Takagaki, Y., Okura, H. & Matsuyama, A. Trends of clinical trials for drug development in rare diseases. Curr. Clin. Pharmacol. 13, 199–208 (2018).
Shannon, P. et al. Cytoscape: A software environment for integrated models of biomolecular interaction networks. Genome Res. 13, 2498–2504 (2003).
R Core Team. R: A language and environment for statistical computing. R Foundation for Statistical Computing, Vienna, Austria (accessed December 2020). https://www.R-project.org/ (2020).
Acknowledgements
We thank Akiko Fukagawa for supporting the original data construction, Makoto Hirata for technical advice for programming, and Emiko Fujisawa for administrative work. Data construction and analyses were supported by a grant from the Japan Society for the Promotion of Science (JSPS, Grant Number 20K12056).
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Conceptualization: R.S. and T.K.; Design: R.S. and T.K.; Acquisition and construction of data: R.S.; Analysis of data: R.S. and T.K.; Interpretation of data: R.S. and T.K.; Supervision: T.K.; Writing manuscript: R.S. and T.K. All authors read and approved the final manuscript.
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Sakate, R., Kimura, T. Drug target gene-based analyses of drug repositionability in rare and intractable diseases. Sci Rep 11, 12338 (2021). https://doi.org/10.1038/s41598-021-91428-4
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DOI: https://doi.org/10.1038/s41598-021-91428-4
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