Abstract
In the search for new pharmaceutical leads, especially with DNA-binding molecules or genome editing methods, the issue of side and off-target effects have always been thorny in nature. A particular case is the investigation into the off-target effects of N-methylpyrrole-N-methylimidazole polyamides, a naturally inspired class of DNA binders with strong affinity to the minor-groove and sequence specificity, but at < 20 bases, their relatively short motifs also insinuate the possibility of non-unique genomic binding. Binding at non-intended loci potentially lead to the rise of off-target effects, issues that very few approaches are able to address to-date. We here report an analytical method to infer off-target binding, via expression profiling, based on probing the relative impact to various biochemical pathways; we also proposed an accompanying side effect prediction engine for the systematic screening of candidate polyamides. This method marks the first attempt in PI polyamide research to identify elements in biochemical pathways that are sensitive to the treatment of a candidate polyamide as an approach to infer possible off-target effects. Expression changes were then considered to assess possible outward phenotypic changes, manifested as side effects, should the same PI polyamide candidate be administered clinically. We validated some of these effects with a series of animal experiments, and found agreeable corroboration in certain side effects, such as changes in aspartate transaminase levels in ICR and nude mice post-administration.
Highlights
We utilized PI polyamides 1–3 (Fig 1A) targeting KRAS G12D/V mutations, PIK3CA E545K mutation and a third candidate which sought to suppress MYCN amplification as its mode of action [28, 29] to determine whether the newly formed hypothesis sufficiently addressed the question of determining the extent of off-target effects at the pathway level; polyamide 4, an additional unbiotinylated version of polyamide 1, was used for a follow-up validation experiment in vivo
All three polyamides were functionalized with indole-seco-CBI, an alkylating moiety; while polyamide 1 had an additional biotinyl moiety as it was originally developed for next-generation sequencing (NGS) applications, we previously [16] found no discernible differences compared to the nonbiotinylated counterpart in microarray studies
Polyamide 2, for instance, was estimated to have a larger number of off-target genes in SiHA, a cervical cancer cell line expressing wild-type PIK3CA; while this polyamide was capable of disrupting mutant PIK3CA preferentially, the cytotoxicity was still in the nanomolar range, the high number of off-target genes would provide an explanation for this observation
Summary
Estimation of off-target and side effects for pyrrole-imidazole polyamides of Science (JP17H03602 to H.N. and JP17K15047 to J.L.) as well as Japan Agency for Medical Research and Development (AMED, JP17cm0106510, JP17ck0106263 and JP17ck0106356 to H.N., 15656919 to A.T. and JP18ck0106422 to H.N. and J.L.). Additional support was provided in part by Takeda Science Foundation (A.T.), Princess Takamatsu Cancer Research Fund (H.N.) and Grant-in-Aid for Scientific Research on Innovative Areas via the Platform for Supporting Cohort Study and Biospecimen Analysis (H.N. and J.L.) from the Ministry of Education, Culture, Sports, Science and Technology of Japan. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript
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