CRISPR/Cas9 Genome Editing of the Human Topoisomerase IIα Intron 19 5′ Splice Site Circumvents Etoposide Resistance in Human Leukemia K562 Cells (original) (raw)
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PLOS ONE
DNA Topoisomerase IIα (TOP2α/170) is an enzyme essential for proliferating cells. For rapidly multiplying malignancies, this has made TOP2α/170 an important target for etoposide and other clinically active anticancer drugs. Efficacy of these agents is often limited by chemoresistance related to alterations in TOP2α/170 expression levels. Our laboratory recently demonstrated reduced levels of TOP2α/170 and overexpression of a C-terminal truncated 90-kDa isoform, TOP2α/90, due to intronic polyadenylation (IPA; within intron 19) in an acquired etoposide-resistant K562 clonal cell line, K/VP.5. We previously reported that this isoform heterodimerized with TOP2α/170 and was a determinant of acquired resistance to etoposide. Optimization of the weak TOP2α exon 19/intron 19 5′ splice site in drug-resistant K/VP.5 cells by gene-editing restored TOP2α/170 levels, diminished TOP2α/90 expression, and circumvented drug resistance. Conversely, in the present study, silencing of the exon 19/intro...
Cancers
Intronic polyadenylation (IPA) plays a critical role in malignant transformation, development, progression, and cancer chemoresistance by contributing to transcriptome/proteome alterations. DNA topoisomerase IIα (170 kDa, TOP2α/170) is an established clinical target for anticancer agents whose efficacy is compromised by drug resistance often associated with a reduction of nuclear TOP2α/170 levels. In leukemia cell lines with acquired resistance to TOP2α-targeted drugs and reduced TOP2α/170 expression, variant TOP2α mRNA transcripts have been reported due to IPA that resulted in the translation of C-terminal truncated isoforms with altered nuclear-cytoplasmic distribution or heterodimerization with wild-type TOP2α/170. This review provides an overview of the various mechanisms regulating pre-mRNA processing and alternative polyadenylation, as well as the utilization of CRISPR/Cas9 specific gene editing through homology directed repair (HDR) to decrease IPA when splice sites are intri...
Effects of DNA topoisomerase IIα splice variants on acquired drug resistance
Cancer Drug Resistance, 2020
DNA topoisomerase IIα (170 kDa, TOP2α/170) induces transient DNA double-strand breaks in proliferating cells to resolve DNA topological entanglements during chromosome condensation, replication, and segregation. Therefore, TOP2α/170 is a prominent target for anticancer drugs whose clinical efficacy is often compromised due to chemoresistance. Although many resistance mechanisms have been defined, acquired resistance of human cancer cell lines to TOP2α interfacial inhibitors/poisons is frequently associated with a reduction of Top2α/170 expression levels. Recent studies by our laboratory, in conjunction with earlier findings by other investigators, support the hypothesis that a major mechanism of acquired resistance to TOP2α-targeted drugs is due to alternative RNA processing/splicing. Specifically, several TOP2α mRNA splice variants have been reported which retain introns and are translated into truncated TOP2α isoforms lacking nuclear localization sequences and subsequent dysregulated nuclear-cytoplasmic disposition. In addition, intron retention can lead to truncated isoforms that lack both nuclear localization sequences and the active site tyrosine (Tyr805) necessary for forming enzyme-DNA covalent complexes and inducing DNA damage in the presence of TOP2α-targeted drugs. Ultimately, these truncated TOP2α isoforms result in decreased drug activity against TOP2α in the nucleus and manifest drug resistance. Therefore, the complete characterization of the mechanism(s) regulating the alternative RNA processing of TOP2α pre-mRNA may result in new strategies to circumvent acquired drug resistance. Additionally, novel TOP2α splice variants and truncated TOP2α isoforms may be useful as biomarkers for drug resistance, prognosis, and/or direct future TOP2α-targeted therapies.
Molecular pharmacology, 2018
DNA topoisomerase II (170 kDa, TOP2/170) is essential in proliferating cells by resolving DNA topological entanglements during chromosome condensation, replication, and segregation. We previously characterized a C-terminally truncated isoform (TOP2/90), detectable in human leukemia K562 cells but more abundantly expressed in a clonal subline, K/VP.5, with acquired resistance to the anticancer agent etoposide. TOP2/90 (786 aa) is the translation product of a TOP2 mRNA that retains a processed intron 19. TOP2/90 lacks the active-site tyrosine-805 required to generate double-strand DNA breaks as well as nuclear localization signals present in the TOP2/170 isoform (1531 aa). Here, we found that TOP2/90, like TOP2/170, was detectable in the nucleus and cytoplasm of K562 and K/VP.5 cells. Coimmunoprecipitation of endogenous TOP2/90 and TOP2/170 demonstrated heterodimerization of these isoforms. Forced expression of TOP2/90 in K562 cells suppressed, whereas siRNA-mediated knockdown of TOP2...
The Journal of pharmacology and experimental therapeutics, 2017
DNA topoisomerase IIα (TOP2α) is a prominent target for anticancer drugs whose clinical efficacy is often limited by chemoresistance. Using antibody specific for the N-terminal of TOP2α, immunoassays indicated the existence of two TOP2α isoforms, 170 and 90 kDa, present in K562 leukemia cells and in an acquired etoposide (VP-16)-resistant clone (K/VP.5). TOP2α/90 expression was dramatically increased in etoposide-resistant K/VP.5 compared with parental K562 cells. We hypothesized that TOP2α/90 was the translation product of novel alternatively processed pre-mRNA, confirmed by 3'-rapid amplification of cDNA ends, polymerase chain reaction, and sequencing. TOP2α/90 mRNA includes retained intron 19, which harbors an in-frame stop codon, and two consensus poly(A) sites. The processed transcript is polyadenylated. TOP2α/90 mRNA encodes a 90,076-Da translation product missing the C-terminal 770 amino acids of TOP2α/170, replaced by 25 unique amino acids through translation of the exon...
The interplay between DNA topoisomerase 2α post-translational modifications and drug resistance
Cancer Drug Resistance, 2020
The type 2 DNA topoisomerases (Top2) are conserved enzymes and biomarkers for cell proliferation. The catalytic activities of the human isoform Top2α are essential for the regulation of DNA topology during DNA replication, transcription, and chromosome segregation. Top2α is a prominent target for anti-cancer drugs and is highly regulated by post-translational modifications (PTM). Despite an increasing number of proteomic studies, the extent of PTM in cancer cells and its importance in drug response remains largely uncharacterized. In this review, we highlight the different modifications affecting the human Top2α in healthy and cancer cells, taking advantage of the structure-function information accumulated in the past decades. We also overview the regulation of Top2α by PTM, the level of PTM in cancer cells, and the resistance to therapeutic compounds targeting the Top2 enzyme. Altogether, this review underlines the importance of future studies addressing more systematically the interplay between PTM and Top2 drug resistance.
Oncogene, 2003
Few t(9;11) translocations in DNA topoisomerase II inhibitor-related leukemias have been studied in detail and the DNA damage mechanism remains controversial. We characterized the der(11) and der(9) genomic breakpoint junctions in a case of AML following etoposide and doxorubicin. Etoposide-, etoposide metabolite- and doxorubicin-induced DNA topoisomerase II cleavage was examined in normal homologues of the MLL and AF-9 breakpoint sequences using an in vitro assay. Induction of DNA topoisomerase II cleavage complexes in CEM and K562 cell lines was investigated using an in vivo complex of enzyme assay. The translocation occurred between identical 5'-TATTA-3' sequences in MLL intron 8 and AF-9 intron 5 without the gain or loss of bases. The 5'-TATTA-3' sequences were reciprocally cleaved by DNA topoisomerase II in the presence of etoposide, etoposide catechol or etoposide quinone, creating homologous 4-base 5' overhangs that would anneal to form both breakpoint junctions without any processing. der(11) and der(4) translocation breakpoints in a treatment-related ALL at the same site in MLL are consistent with a damage hotspot. Etoposide and both etoposide metabolites induced DNA topoisomerase II cleavage complexes in the hematopoietic cell lines. These results favor the model in which the chromosomal breakage leading to MLL translocations in DNA topoisomerase II inhibitor-related leukemias is a consequence of DNA topoisomerase II cleavage.
DNA topoisomerase II mutations and resistance to anti-tumor drugs
BioEssays, 1995
Mutations in DNA topoisomerase II are often correlated with drug-resistance in tumor cell lines. Studies of topoisomerase Il-mediated drug-resistance in various model systems, as well as the sequencing of such mutations from drug-resistant tumors, have shed light on the functional domains of topoisomerase II, on how it interacts with inhibitors, and on the different mechanisms by which cells avoid the toxic effects of many clinically important Accepted 4 May 1995 anti-tumor drugs.
Ectopic expression of human topoisomerase IIα fragments and etoposide resistance in mammalian cells
International Journal of Cancer, 2000
Cellular resistance to etoposide has been correlated both with reduced levels and an aberrant cytoplasmic accumulation of the drug's target, topoisomerase II␣ (topo II␣). It is not known, however, whether a cytoplasmic pool of topo II␣ is sufficient to confer drug resistance on cultured mammalian cells. In our study, we have transfected mouse fibroblasts and human 293 cells with truncated forms of human topo II␣ fused to GFP and have examined the transformants for the subcellular localization of topo II␣ and their resistance to etoposide. Transient transfection resulted in high-level expression of all GFP-topo II␣ fusions tested, whereas in stably transfected cells the levels varied significantly. Transfectants expressing a central or a carboxy-terminal topo II␣ domain (aa 428-1504, 639-1028 or 1028-1504) accumulated high levels of the fusion proteins, while only very low amounts of GFP-topo II␣ proteins were observed in cell lines expressing constructs that retain the amino-terminus of the enzyme (aa 1-1214, aa 1-939, aa 1-611). Our results suggest that the topo II␣ amino-terminus affects the stability of truncated forms of the enzyme in mammalian cells, perhaps due to targeted degradation. Assays that screen for cell vitality and DNA synthesis reveal no significant changes in etoposide sensitivity in transfected cells expressing high levels of cytoplasmic or nuclear localized topo II fusion proteins. Retroviral expression of a cytoplasmically anchored domain of human topo II␣ also failed to confer drug resistance. These results suggest that a cytoplasmic pool of topo II␣ is not sufficient to render cultured mammalian cells drug resistant.
Proceedings of the National Academy of Sciences, 2012
Topoisomerase poisons such as the epipodophyllotoxin etoposide are widely used effective cytotoxic anticancer agents. However, they are associated with the development of therapy-related acute myeloid leukemias (t-AMLs), which display characteristic balanced chromosome translocations, most often involving the mixed lineage leukemia (MLL) locus at 11q23. MLL translocation breakpoints in t-AMLs cluster in a DNase I hypersensitive region, which possesses cryptic promoter activity, implicating transcription as well as topoisomerase II activity in the translocation mechanism. We find that 2-3% of MLL alleles undergoing transcription do so in close proximity to one of its recurrent translocation partner genes, AF9 or AF4, consistent with their sharing transcription factories. We show that most etoposide-induced chromosome breaks in the MLL locus and the overall genotoxicity of etoposide are dependent on topoisomerase IIβ, but that topoisomerase IIα and -β occupancy and etoposide-induced DNA cleavage data suggest factors other than local topoisomerase II concentration determine specific clustering of MLL translocation breakpoints in t-AML. We propose a model where DNA double-strand breaks (DSBs) introduced by topoisomerase IIβ into pairs of genes undergoing transcription within a common transcription factory become stabilized by antitopoisomerase II drugs such as etoposide, providing the opportunity for illegitimate end joining and translocation.