Coupling chemical mutagenesis to next generation sequencing for the identification of drug resistance mutations in Leishmania

Current genome-wide screens allow system-wide study of drug resistance but detecting small nucleotide variants (SNVs) is challenging. Here, we use chemical mutagenesis, drug selection and next generation sequencing to characterize miltefosine and paromomycin resistant clones of the parasite Leishman...

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Bibliographic Details
Published in:Nature communications 2019-12, Vol.10 (1), p.5627-14, Article 5627
Main Authors: Bhattacharya, Arijit, Leprohon, Philippe, Bigot, Sophia, Padmanabhan, Prasad Kottayil, Mukherjee, Angana, Roy, Gaétan, Gingras, Hélène, Mestdagh, Anais, Papadopoulou, Barbara, Ouellette, Marc
Format: Article
Language:English
Subjects:
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631/326/417/2551
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Cloning
CRISPR
Drug resistance
Drug Resistance - genetics
Gene sequencing
Genes
Genetic modification
Genome editing
Genomes
High-Throughput Nucleotide Sequencing - methods
Humanities and Social Sciences
Kinases
Leishmania
Leishmania - genetics
Lipid metabolism
Lipids
Miltefosine
multidisciplinary
Mutagenesis
Mutation
Mutation - genetics
Next-generation sequencing
Nucleotides
Organic chemistry
Parasites
Paromomycin
Paromomycin - pharmacology
Phosphorylation - drug effects
Phosphorylcholine - analogs & derivatives
Phosphorylcholine - pharmacology
Protein kinase
Protein kinase C
Science
Science (multidisciplinary)
Translation
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Description
Summary:Current genome-wide screens allow system-wide study of drug resistance but detecting small nucleotide variants (SNVs) is challenging. Here, we use chemical mutagenesis, drug selection and next generation sequencing to characterize miltefosine and paromomycin resistant clones of the parasite Leishmania . We highlight several genes involved in drug resistance by sequencing the genomes of 41 resistant clones and by concentrating on recurrent SNVs. We associate genes linked to lipid metabolism or to ribosome/translation functions with miltefosine or paromomycin resistance, respectively. We prove by allelic replacement and CRISPR-Cas9 gene-editing that the essential protein kinase CDPK1 is crucial for paromomycin resistance. We have linked CDPK1 in translation by functional interactome analysis, and provide evidence that CDPK1 contributes to antimonial resistance in the parasite. This screen is powerful in exploring networks of drug resistance in an organism with diploid to mosaic aneuploid genome, hence widening the scope of its applicability. Here, Bhattacharya et al. chemically mutagenize Leishmania and identify genes associated with resistance to miltefosine and paromomycin by next generation sequencing. The study shows that a protein kinase (CDPK1) can mediate resistance to paromomycin by affecting translation.
ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-019-13344-6