Abstract
Malaria is a predominant infectious disease, with a global footprint, but especially severe in developing countries in the African subcontinent. In recent years, drug-resistant malaria has become an alarming factor, and hence the requirement of new and improved drugs is more crucial than ever before. One of the promising locations for antimalarial drug target is the apicoplast, as this organelle does not occur in humans. The apicoplast is associated with many unique and essential pathways in many Apicomplexan pathogens, including Plasmodium. The use of machine learning methods is now commonly available through open source programs. In the present work, we describe a standard protocol to develop molecular descriptor based predictive models (QSAR models), which can be further utilized for the screening of large chemical libraries. This protocol is used to build models using training data sourced from apicoplast specific bioassays. Multiple model building methods are used including Generalized Linear Models (GLM), Random Forest (RF), C5.0 implementation of a decision tree, Support Vector Machines (SVM), K-Nearest Neighbour and Naive Bayes. Methods to evaluate the accuracy of the model building method are included in the protocol. For the given dataset, the C5.0, SVM and RF perform better than other methods, with comparable accuracy over the test data.
Highlights
Malaria is endemic in many tropical and subtropical regions causing high mortality and morbidity
There were 420 descriptors removed during this process, and 465 descriptors were retained
We removed highly correlated data points which resulted in the exclusion of 292 descriptors after preprocessing-I only 173 descriptors remained
Summary
Malaria is endemic in many tropical and subtropical regions causing high mortality and morbidity. In the last 10-15 years, due to efforts of a global malaria eradication campaign, a significant fall has been observed in malaria infection cases. The majority of death cases have been recorded in Africa (~92 %) and the SouthEast Asia Region (~6%) [1]. Drug-resistant malaria has been emerged in many Asian and African countries in recent years [4]–[7]. This scenario threatens the worldwide efforts for complete eradication of malaria and it is imperative to identify more drug targets as well as potent drugs to regulate the disease before current therapeutic agents lose their clinical relevance. Studies reveal that one of the most promising targets is the apicoplast due to its involvement in many essential biological pathways unique to Plasmodium [8]
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