Abstract
A subset of hepatocellular carcinoma (HCC) overexpresses the chromosome 19 miRNA cluster (C19MC) and is associated with an undifferentiated phenotype marked by overexpression of cancer testis antigens (CTAs) including anti-apoptotic melanoma-A antigens (MAGEAs). However, the regulation of C19MC miRNA and MAGEA expression in HCCs are not understood. Here we show that, C19MC overexpression is tightly linked to a sub-set of HCCs with transcription-incompetent p53. Using next-generation and Sanger sequencing we found that, p53 in Hep3B cells is impaired by TP53-FXR2 fusion, and that overexpression of the C19MC miRNA-520G in Hep3B cells promotes the expression of MAGEA-3, 6 and 12 mRNAs. Furthermore, overexpression of p53-R175H and p53-R273H mutants promote miR-520G and MAGEA RNA expression and cellular transformation. Moreover, IFN-γ co-operates with miR-520G to promote MAGEA expression. On the other hand, metals such as nickel and zinc promote miR-526B but not miR-520G, to result in the suppression of MAGEA mRNA expression, and evoke cell death through mitochondrial membrane depolarization. Therefore our study demonstrates that a MAGEA-promoting network involving miR-520G, p53-defects and IFN-γ that govern cellular transformation and cell survival pathways, but MAGEA expression and survival are counteracted by nickel and zinc combination.
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Introduction
Chromosome-19 micro-RNA cluster (C19MC) is a large miRNA cluster located at the ‘q’ arm of chromosome 19, band chr19q13.42 within a span of ~ 100kb1. C19MC includes 46 miRNAs and is typically expressed only in the placenta among adult tissues2,3. Overexpression of C19MC miRNAs has been implicated in multiple cancer types such as hepatocellular carcinoma4,5, undifferentiated embryonal sarcoma of the liver6, breast cancer2, embryonal tumors with multilayered rosettes (ETMRs)7, infantile hemangioma8, thyroid adenomas9, testicular germ cell tumors10, and parathyroid tumors11.
Hepatocellular carcinoma (HCC) is one of the deadliest cancer types among human cancers and it accounts for estimated 42,220 new cases, and 30,200 deaths in United States alone in 2018 (for Liver & intrahepatic bile duct)12. The specific functional outcome of C19MC miRNAs in HCC is not fully understood yet, but a report implicates the co-expression of C19MC miRNAs with cancer testis antigens (CTAs)13. However, whether C19MC miRNAs lead to the expression of CTAs is not known. Melanoma antigen-A family genes (MAGEAs) are a subset of CTAs that are often expressed in various cancers13, and play an anti-apoptotic role by counteracting the p53-dependant cell death program14.
Using human hepatocellular carcinoma (LIHC) patient data here we show that, C19MC overexpression is tightly linked to a large set of CTAs including melanoma antigens in patients who harbor transcription incompetent p53. Using a combination of next-generation sequencing and in vitro experiments we further elucidate the role of C19MC miRNAs in regulating MAGEA expression. We identify a novel TP53-FXR2 fusion in Hep3B cells and show that the C19MC miRNA-520G but not miR-519D or miR-526B promotes the expression of MAGEA-3, 6 and 12. Overexpression of p53-R175H or p53-R273H mutant also promotes miR-520G and MAGEA mRNA expression in Hep3B cells. Finally, we identified IFN-γ as a co-operating factor to miR-520G and metals such as nickel and zinc as antagonistic factors of MAGEA mRNA expression to regulate cell death. Thus our study demonstrates a striking co-regulatory network between C19MC miRNAs, MAGEAs, IFN-γ and p53 in HCC and validates the oncogenic role of C19MC in HCC.
Results
C19MC overexpression specifically marks hepatocellular carcinomas with CTA expression, and miR-520G promotes the expression of MAGEAs-3, 6, and 12
To understand the expression pattern of C19MC miRNAs in human hepatocellular carcinoma in the context of CTAs, we re-integrated the Cancer Genome Atlas (TCGA) HCC-iCluster data set15 (miRNA-seq and RNA-seq). We found 54 genes that mainly included CTAs with melanoma antigens (MAGEAs) are expressed specifically in iCluster-3 (Fig. 1a) along with significantly high expression of C19MC miRNAs (Fig. 1b). To understand whether overexpression of C19MC miRNAs indeed regulate the expression of these CTAs, we generated stably transfected Hep3B cell lines overexpressing pMIR control vector, C19MC miRNAs 519D, 520G and 526B and verified the specific expression of miRNAs by quantitative real-time PCR (qRT-PCR) and RNA-seq (Fig. 1c-d). These three miRNAs show minor differences between their mature sequences (Fig. 1e). RNA-seq differential expression analysis of CTAs in these stable cells revealed that, although each miRNAs promoted specific set of CTAs, the read numbers are reliable only for miR-520G regulated MAGEA-3, 6, 12 and CSAG-1 (Fig. 1f). Of note, CSAG-1 gene shares a bivalent enhancer with the MAGEA12 gene (Supplementary Fig. 1) and both genes are upregulated by miR-520G, suggesting the bi-directional transcriptional activation of the enhancer. Therefore, MAGEA-3, 6, and 12 could be the prime promoted targets of miR-520G. We further confirmed the selective upregulation of MAGEA-3, 6 and 12 by miR-520G using RT-PCR along with LIN28B and TP53 (Fig. 1g). We included LIN28B and TP53 as test subjects because LIN28B is enriched in iCluster-3 along with CTAs (Fig. 1a) and is a major miRNA binding protein that intersects with mutant p53 signaling in cancer progression16, whereas p53 is a major mutated gene in HCC iCluster-315. Of note, LIN28B was constitutively transcribed in Hep3B cells but was not influenced by any of the C19MC miRNAs tested (Fig. 1g). However, TP53 mRNA levels were moderately altered by miR-520G and 526B overexpression (Fig. 1g). Taken the iCluster-3 CTA expression data, and RNA-seq plus RT-PCR results on MAGEA expression together, it is conceivable that, C19MC miRNAs correlate with the expression of CTAs in iCluster-3 of HCCs and that individual C19MC miRNAs such as miR-520G promotes the expression of distinct subsets of CTAs such as MAGEA-3, 6, and 12, CSAG1 in the case of miR-520G.
Hepatocellular carcinomas with high C19MC expression are incompetent for p53-dependent transcription: links to zinc and cell death
In HCCs iCluster-3 harbors the highest rate of p53 defects15 and that melanoma-A antigens that are expressed in iCluster-3 are being shown to counteract p53-dependent transcription by targeting p53 to chromatin interaction17 and p53 transactivation to result in therapy resistance14. Therefore we examined whether C19MC expression is correlated to p53 functional status. For this purpose, we classified the TCGA iCluster dataset into p53 transcription competent (p53TC) and p53 transcription incompetent (p53TI) clusters [p53-TCTI dataset] (Fig. 2a) and examined the expression of C19MC in p53-TCTI dataset. We found that, C19MC is significantly overexpressed in p53TI cluster compared to p53TC cluster suggesting the involvement of p53 alteration in C19MC expression or function (Fig. 2b). Similarly, in 28 cancer cell lines that exhibit p53TC and p53TI signature (that includes cells from liver cancer and other cancer types) had relatively similar levels of C19MC miRNA expression, however, the MAGEA-3, MAGEA-6 and MAGEA-12 mRNAs were selectively upregulated in p53TI subset (Supplementary Fig. 2).
As expected, the p53TI cluster had overexpression of pro- and anti-cell death factors such as AFP, MLKL, PRKCD, CASP2, BIRC5, FANCD2, BAK1, PKM2, TRAF5 RHOF or downregulation of pro- and anti-cell death factors such as, CLU, AIFM1, OMA1, BNIP3, BOK, BAD, ENDOG, HTRA1, GADD45A, GADD45B and GADD45G (Fig. 2c). Notably, many of these gene products require, or bind to zinc for their function [examples: AFP, BIRC5/survivin, OMA118,19,20], or their function is antagonized by zinc [Example: BAK121]. Of particular interest, elevated AFP expression is a clinical biomarker for poor prognosis of HCCs22 and is a major zinc binding protein found in human plasma primarily expressed by liver18. AFP mRNA is significantly elevated in the p53TI cluster (Fig. 2d). Therefore we focused on the change in gene expression levels of entire solute carrier family proteins (SLC) which includes zinc transporters and zinc-efflux pumps23. In the p53TI cluster, many of the major zinc transporters (SLC1A2 and SLC10A1) were downregulated, whereas the zinc efflux pumps (SLC30A8 and SLC30A3) were upregulated (Fig. 2e), suggesting that the p53TI tumors do not prefer intracellular accumulation of zinc. RNA-seq data from C19MC miRNA stably overexpressed Hep3B cells revealed that, miR-520G, miR-519D and miR-526B promoted or downregulated distinct sets of SLCs and AFP (Fig. 2f). We further confirmed the upregulation of AFP mRNA by RT-PCR where miR-520G had considerable increase in AFP expression whereas the mRNAs of AFP transcription factors were largely unaffected except minor changes in metal sensing transcription factor MTF-1 (Fig. 2g). Taken together these results indicate that p53 transcriptional incompetence is associated with alterations in mRNAs of zinc regulated cell death factors, zinc transporters/efflux pumps, and that miR-520G mildly promotes AFP expression at RNA level.
Hep3B cells express defective p53 mRNA and harbor TP53-FXR2 fusion as a result of 76 kb focal deletion
Given the fact that C19MC is overexpressed in p53TI HCC tumors, and p53 mutants can utilize zinc for gain-of-wild type-folding24, it becomes necessary to understand the nature of p53 defect in Hep3B cells. Hep3B is known to have defective p5325, but with different details reported on the nature of the defect (homozygous deletion of p5326, intragenic deletion25). Therefore we next examined the nature of TP53 defect in Hep3B cells by exploring the cDNA using three sets of primers spanning from 5’ end to 3’ end through middle piece (M) (Fig. 3a). Only the p53-5’ was amplified (whereas the p53-M band turned out to be a misamplicon from chromosome-2: confirmed by Sanger sequencing) and paired-end sequenced to reveal a single nucleotide deletion, which is capable of shifting the reading frame. However, this nucleotide deletion was detected only in forward but not in reverse sequencing, suggesting that it could be a heterozygous point deletion (Fig. 3a). Because we failed to get amplicons from the middle piece and 3’end of p53 cDNA, we examined the genome aligned RNA-seq reads to see if it is due to deletion. While MCF-7 (a comparator cell line with intact TP53) RNA-seq revealed full-length exon reads for p53, the Hep3B cells had reads only up to the middle of the intron between exons 3 and 4, suggesting a deletion starting from this intronic region (Fig. 3b). Examination of the Hep3B RNA-seq reads upstream of this region (TP53 is on negative strand) revealed that, the reads were lacking between ~ chr17: 7,501,000–7,577,371 [TP53 intron (between exons 3 and 4) to FXR2 intron (between exons 7 and 8); HG19] suggesting a focal 76 kb deletion from chromosome-17 (Fig. 3c). To confirm the deletion, we designed primers spanning from the suspected introns of TP53 and FXR2 and performed PCR using genomic DNA. The PCR resulted in a ~ 425 bp product and a ~ 250 bp product (Fig. 3d). We cut eluted 425 bp product and reamplified the band using same set of primers and made sure that it gives a single band (Fig. 3d). Sequencing of this band using 1 M betaine revealed that the TP53 and FXR2 were indeed fused, with a linker sequence of 12 nucleotides (GenBank accession: MN842296) (Fig. 3e). Taken together, these results demonstrated that Hep3B cells harbor a heterozygous single base pair frameshift capable deletion within the reading frame of TP53 as well as a focal 76 kb deletion resulting in the fusion of the 5’-end of TP53 with 3’-end of FXR2.
Wild-type and mutant p53s promote miR-520G and MAGEA expression
Given the strong clinical association of p53TI tumors with C19MC overexpression and presence of TP53-FXR2 fusion in Hep3B cells, we sought to examine the effect of wild-type and mutant p53s in C19MC miRNA expression in Hep3B cells. DNA binding consensus of p53 usually harbors palindromic DNA binding sites of CDKN1A and GADD45 genes that represent genome-wide and most prominent p53-binding consensuses27,28. The CDKN1A p53 binding sequence has two palindrome boxes within it. P53 CDKN1A palindromic box-1 (p53 CP box-1) has an 8-nucleotide palindrome GCCCGGGC which encompasses the 6-nucleotide palindrome of CCCGGG (Fig. 4a). The p53 CP box-2 has two 6-nucleotide palindromes of ACATGT, of which the second one is extended to a 10-nucleotide palindrome of CAACATGTTG (Fig. 4a). Both CP box-1 and CP box-2 palindromes are abundantly located within C19MC and its flanking regions (Fig. 4a). Similarly during DNA damage response p53 orchestrates transcription of a different set of genes using a GADD45 consensus29. This consensus also has two GADD45 palindromes (GP box) of which ACATGT is similar to CDKN1A consensus. The second GADD45 palindrome is GCATGC and which can be extended to 8-nucleotide palindrome of AGCATGCT (Fig. 4b). While the GP box palindromes are also abundantly located within C19MC and its flanking regions, the 8-nucleotide GP boxes are located only within C19MC (Fig. 4b).
Considering the p53-binding palindromes within C19MC, alterations in zinc efflux pumps in p53-TI clusters, and the role of zinc in p53 folding and DNA binding [especially by the p53-R175H and p53-R273H metastasis promoting mutants30,31,32], we examined whether introduction of wild-type (p53-WT) or p53-R175H and p53-R273H mutants can promote C19MC miRNA transcription. Introduction of p53-WT, p53-R175H, or p53-R273H mutants did not promote considerable cell death by depolarization of mitochondria (Fig. 4c) except rare foci of cellular transformation (discussed below). However, p53-WT, p53-R175H, and p53-R273H all promoted individual C19MC miRNAs, most significantly with p53-WT or p53-R273H promoting miR-520G (Fig. 4d). Furthermore, p53-WT, p53-R175H, and p53-R273H promoted the expression of MAGEA12 and to a lesser extent the expression of MAGEA3 (Fig. 4e). The mRNA level expressions of AFP, or AFP transcription factors FOXM1, SP1, MTF1, or LIN28B did not change by the introduction of p53-WT, p53-R175H, or p53-R273H mutants in Hep3B cells (Fig. 4e). Taken together these results demonstrated that, wild-type and metastasis-promoting mutant p53s promote miR-520G and MAGEA expression.
Nickel and zinc co-operate to drive non-apoptotic cell death associated with loss of MAGEA expression and promotion of miR-526B expression
Zinc plays a prominent role in the function of p53-R175H, p53-R273H mutants and AFP. In the absence of the p53 transcriptional program, the AFP transcription factors Sp1 and MTF1 form transcriptionally active complex33. More intriguingly, Sp1 can switch DNA binding from one DNA element to other depending on the availability of zinc or nickel34 and can promote transcription even if the binding site is CpG methylated35. We found that, C19MC harbors multiple Sp1 binding sites with zinc or nickel binding specificity (Fig. 5a). A dose response in Hep3B cells using ZnCl2 revealed that 250 μM could induce 87.26% (± 3.78 SEM) pyknosis within 24 h (Supplementary Fig. 3). To understand the biology, we chose this dose for zinc as well as for nickel for further experiments. Zinc but not nickel significantly promoted the expression of miR-526B and did not have a considerable increase in miR-519D or miR-520G expression (Fig. 5b). Zinc induced depolarization of mitochondria in 93.0% (± 1.5 SEM) of the cells, whereas nickel induced only in 20.6% (± 1.4 SEM) of the cells (Fig. 5c). Interestingly, zinc and nickel downregulated MAGEA12, whereas zinc or zinc plus nickel combinations downregulated MAGEA3, MAGEA6, AFP, FOXM1, SP1, MTF1, and LIN28B (Fig. 5d) suggesting that, these metals inhibit transcription of these mRNAs. More importantly the zinc plus nickel combination dramatically promoted endogenous p53 (Fig. 5d). Of note, the zinc and nickel combination induced pyknoisis in all stable cells with pMIR, p519D, p520G and p526B and these pyknotic cells did not survive after washing and re-plating in complete growth medium (Fig. 5e) demonstrating the induction of definitive cell death.
We next examined whether Hep3B cells undergo DNA condensation, a characteristic feature of multiple (but not all) cell death modalities. Nickel induced DNA condensation in 22.38% (± 1.2 SEM), zinc induced 74.65% (± 2.1 SEM), and the combination of nickel and zinc induced 99.59% (± 0.1 SEM), of Hep3B cells demonstrating the cell death promotion of zinc by nickel (Fig. 6a). In this experiment we carefully excluded mitotic chromosome condensation from cell death related DNA condensation as shown in Fig. 6b. Although the DNA was condensed during cell death it was not complete DNA condensation as in apoptotic bodies instead, diffused cytoplasmic DNA was also detected in zinc plus nickel combination (Fig. 6b). Therefore, we examined whether these cells undergo DNA fragmentation. Neither nickel nor zinc or their combination induced DNA fragmentation in Hep3B cells demonstrating the progression of non-apoptotic cell death (Fig. 6c).
Mutant p53 (R175H or R273H) transfected Hep3B cells exhibited rare transformed foci with massive accumulation of both depolarized mitochondria, polarized mitochondria and the foci were often but not always surrounded by nuclei (Fig. 6d-e). Similar transformed foci were also observed in miR-520G (Fig. 6f), miR-519D and miR-526B (data not shown) stable cells. However, we did not detect such transformed spheres in p53-WT or pMIR transfected cells. The downregulation of ENDOG, [a nuclease that fragment DNA during apoptosis] and SLC25A4/ANT1 [which trigger proper apoptosis by releasing endonuclease-G through permeability transition pores (PTPs) in mitochondria] in p53TI cluster (Fig. 2c) and in Hep3B miRNA stable cells (Fig. 6g) might explain why the cells did not undergo DNA fragmentation during nickel and zinc combination induced cell death.
Taken together these results demonstrate that, nickel and zinc co-operate to drive mitochondria depolarization-dependent non-apoptotic cell death and a rare type of cellular transformation associated with loss of MAGEA expression and promotion of miR-526B expression.
IFN-γ co-operates but IL-6 antagonizes with miR-520G to regulate MAGEA, FOXM1, MTF1 mRNA expressions
To identify potential regulators of C19MC we subjected mRNAs of 100 ligands (that include cytokines and chemokines from RNA-seq of TCGA LIHC data integrated with miRNA-seq data, classified based on C19MC high and low groups) and 46 C19MC miRNAs for correlation analysis. We found that, while C19MC miRNAs themselves were highly correlated, IFNG mRNA is the candidate that correlated to most of the C19MC miRNAs (Fig. 7a). We tested the effect of IFN-γ in C19MC expression and MAGEAs expression in Hep3B cells along with other cytokines such as IL-6, EGF and bFGF. Recombinant IFN-γ neither promoted C19MC expression (as evaluated by qRT-PCR for miRs-519D, 520G and 526B: data not shown) nor promoted MAGEAs in Hep3B cells (Fig. 7b). However, in miR-520G stable Hep3B cells, IFN-γ promoted the expression of MAGEA-3, 6 and 12 along with FOXM1 and MTF1 mRNAs (Fig. 7c). Interestingly, IL-6 downregulated MAGEA-3, 6, 12, FOXM1, MTF1 and LIN28B mRNAs in miR-520G stable Hep3B cells, but could not do so in Hep3B parental cells (Fig. 7b-c). Furthermore, although mutant p53s and p53-WT promoted MAGEAs (Fig. 4e), these p53s did not promote MAGEAs in miR-520G stable cells (Fig. 7d). Taken together, these data demonstrate that, IFN-γ plays a co-operative role whereas IL-6 plays an antagonistic role with miR-520G in Hep3B cells to regulate MAGEA, FOXM1, MTF1 mRNA expressions.
Discussion
The chromosome 19 microRNA cluster is overexpressed in a subset of hepatocellular carcinoma marked by the expression of cancer testis antigens (CTAs), including MAGEAs13. However, the regulation and function of C19MC miRNAs in HCC are not well known. We for the first time demonstrate that C19MC miRNA-520G promotes the expression of MAGEA-3, 6 and 12 in p53-defective cells and that C19MC miRNAs are overexpressed in p53 transcriptionally incompetent HCC tumors. Defects in p53 transcription can result in impaired apoptosis and enhanced cellular transformation36,37 and MAGEAs are known to inhibit p53 and p21 (a p53 transcriptional target) -induced apoptosis38. Although p53 is known to have defects in Hep3B cells, the exact nature of p53 defect in Hep3B cells was not known. We for the first time identify a novel TP53-FXR2 fusion in Hep3B cells, which can potentially result in defective nuclear translocation and thus transcription39. Therefore, promotion of MAGEA-3, 6 and 12 in p53 defective Hep3B cells by miR-520G overexpression (Fig. 1g) reflects the MAGEA expression pattern of 28 cancer cell line p53TCTI signature (Supplementary Fig. 2). However, further analysis on MAGEA-3, 6 and 12 promoter and enhancers are necessary to understand the transcriptional regulators involved. In the context of CTAs, we have identified the regulation of MYO18B mRNA (another cancer testis antigen) by miR-520G in Hep3B cells40, which further supports the notion that the p53 defective background is associated with CTA expression through C19MC miRNAs. We additionally show that nickel and zinc can differentially regulate C19MC miRNA expression and when combined, the combination abrogates MAGEA expression and promotes definitive non-apoptotic cell death (Fig. 5e). Thus, our study delineates a striking co-regulatory network between C19MC, p53 transcriptional defects, and MAGEAs that is disrupted by metal ions zinc and nickel in HCC.
Cells can initiate blebbishield emergency program to undergo cellular transformation and survival, after the commitment of morphological and biochemical apoptosis 41,42,43,44,45,46,47,48,49,50,51,52,53,54. Mitochondrial depolarization can abrogate survival in the context of the blebbishield emergency program47,52, however, here we for the first time show that mutant p53-induced mitochondrial depolarization leads to cellular transformation with massive accumulation of depolarized mitochondria (Fig. 6d-e). However, cells undergoing pyknosis in response to nickel plus zinc combination could not survive or undergo transformation (Fig. 5e) and could not maintain mRNAs of MAGEAs, AFP, FOXM1, SP1, MTF1 and LIN28B suggesting the expression of C19MC miRNAs in deciding the survival or death of cancer cells that are defective in the p53 transcriptional program. MAGEAs play an anti-apoptotic role by counteracting the p53-dependant cell death program14 and therefore the regulation of MAGEAs at RNA level by C19MC miRNAs is a vital finding that sheds more light on the oncogenic role of C19MC. The overall signaling pathway in the context of C19MC miRNAs, mitochondrial depolarization, DNA fragmentation and cellular transformation is depicted in Fig. 7e.
In summary, we demonstrate an intimate co-regulatory network between C19MC, p53, and MAGEAs in HCC, where C19MC miRNA overexpression and p53 deficiency modulate MAGEA expression, cellular transformation and cell survival pathways.
Materials and methods
The Cancer Genome Atlas (TCGA) and iCluster details
TCGA miRNASeq, and RNASeq, data were from (https://gdac.broadinstitute.org/) and a patient data sub-set was selected from TCGA dataset based on the patient IDs of integrated clusters (iC1 + iC2 + iC3 = 183 samples) which was based on the expression of 528 signature genes (200 + 128 + 200 genes from iC1, iC2 and iC3 respectively) used to generate the prediction model as described previously40 in Figure S3A of reference15. The TCGA IDs and gene list of iClusters were kindly provided by Dr. Lee, Ju-Seog (UT MD Anderson Cancer Center, Houston, TX, USA), Dr. Ronglai Shen (Memorial Sloan Kettering Cancer Center, New York, NY, USA), Dr. David Wheeler (Baylor College of Medicine, Houston, TX, USA) and Dr. Lewis R. Roberts (Mayo Clinic, Rochester, MN, USA). This 183 patient dataset is referred to as HCC-iCluster data set which includes primary tumor samples of HCC patients who did not received any therapy, staged as per American Joint Committee on Cancer (AJCC) guidelines, subjected to pathology quality control using H&E slides as per previously published study55. The results in this study are in part based upon data generated by the TCGA Research Network: https://www.cancer.gov/tcga.
Correlation plots, scripts, color code and statistical significance
Correlation plot to screen mRNAs of ligands that correlate with cumulative C19MC miRNA expression was generated using R package ‘corrplot’ 0.84 (was built under R version 3.4.4) by using the scripts as described previously40 but with minor modifications. Script: > cor(); > mat <—cor(); > corrplot(mat, order = "hclust", addrect = 6, method = "color"); > col1 <—colorRampPalette(c("black", "white", "red")); > corrplot(mat, order = "hclust", addrect = 6, method = "color", col = col1(100)), where addrect = 6 was optional; red = positive correlation; black = negative correlation. LIHC RNA-seq integrated to miRNA-seq data was classified into C19MC high versus low and the 61 high and 61 low samples (please see supplementary methods and supplementary table-3 for C19MC based group characteristics) were log transformed to the base of 10 before generating the matrix table in R. The insignificant correlations were coded white and thus white indicates either correlation value = 0 or insignificant.
Cell lines, DNA fingerprinting, plasmids and stable/transient transfections
Human Hep3B cells (purchased from ATCC # HB-8064), and MCF-7 cells were cultured as described previously40. Briefly, cells were cultured in MEM containing L-Glutamine and Sodium bicarbonate (Sigma #M4655), with 10% FBS (Sigma#F0926), vitamins (Gibco Life Technologies #11120052), sodium pyruvate (Gibco Life Technologies #11360070), non-essential amino acids (Gibco Life Technologies #11140050), and penicillin–streptomycin (Gibco Life Technologies #15140122). DNA was isolated using QIAamp DNA mini kit (Qiagen # 51304) and the DNA were subjected to STR fingerprinting as per institutional/lab standards. The cells were then expanded, and frozen. Fresh vials were used after every 6 months or after ~ 25 passages. The cells in culture were tested for mycoplasma periodically using MycoAlert Kit (Lonza). The cell lines used in this manuscript were maintained from January 2018 to May 2019.
Glycerol stocks of mammalian expression vectors such as pMIR-CMV, pMIR-CMV-519D (CR215546), pMIR-CMV-520G (CR215781), pMIR-CMV-526B (CR215142) were purchased from Vigene Biosciences (Rockville, MD USA). Plasmids were isolated using Qiagen MIDI prep kit (#12143).
Hep3B cells were stably transfected using plasmids and Lipofectamine 2000 (Life Technologies # 11668019) and selected using 4 μg/ml puromycin (Invitrogen # A1113803) for 2 months. The cells were then sorted for GFP positive cells, expanded and frozen. For transient transfections, 1 μg plasmid DNA/10 cm dish were used with lipofectamine for 12–14 h in complete MEM, the media was washed off, and the cells were then collected at the 48 h time point (from the time of addition of DNA + lipofectamine complex to cells).
Quantitative real-time PCRs [qRT-PCRs]
Quantitative RT-PCRs were done as described previously40. Briefly, RNAs were isolated using miRNeasy Mini Kit (Qiagen #217004, Germantown, MD, USA), quantified using Nanodrop, and 250 ng RNAs were subjected to cDNA synthesis using Multiscribe reverse transcriptase with RNAse inhibitor, 10 × buffer, dNTPs, (ABI, Cat # 4366596) and RT TaqMan Primers (RNU6B Control Assay: Assay ID: 001093 (Cat # 4427975), hsa-miR-519d [For 3p]: Assay ID: 002403 (Cat # 4427975), hsa-miR-520 g-3p : Assay ID: 001121 (Cat # 4427975), hsa-miR-526b-3p: Assay ID: 002383 (Cat # 4427975). Then the cDNAs were subjected to real-time PCR reactions using corresponding primers with probes and Taqman master mix in triplicates. Comparative Ct (Δ ΔCt) method was used to calculate the relative expression of miRNAs after normalizing with RNU6B values. The results were then plotted using Graphpad Prism software (v7.04; La Jolla, CA, USA).
RNA-seq and IGV visualization
RNAs were isolated using miRNeasy Mini Kit (Qiagen #217004, Germantown, MD, USA), with an on-column RNAse free DNAse (Qiagen # 79254) digestion as per manufacturer’s protocol. RNA-seq was performed using the NuGen Ovation RNA-seq FFPE System (PN 7150–08) to prepare the libraries and were run on the Illumina NextSeq 500 with a 76-base paired-end read. The adapter reads were detected using BBMerge (v37.88)56 and trimmed using Cutadapt (v1.8.1)57. The adapter sequences were: AGATCGGAAGAGCACACGTCTGAACTCCAGTCA and AGATCGGAAGAGCGTCGTGTAGGGAAAGAGTGT. Trimming was part of the standard Illumina BaseSpace FASTQ Generation app that runs automatically after sequencing run. Processed raw reads were then aligned to human genome (build: hg19) using STAR (v2.5.3a)58. Gene expression was evaluated as read count at gene level with HTSeq (v0.6.1)59 and Gencode gene model v28. Gene expression data were then normalized and differential expression was evaluated using DEseq260. The indexed reads were visualized using IGV v2.4.14 using HG19 genome.
TP53 mutation analysis & Sanger sequencing and identification of TP53 to FXR2 fusion
Mutation analysis
Total RNA was isolated from Hep3B cells as described above, and cDNAs from RNAs were generated using 1.5 M betaine as described in Reverse transcriptase PCRs section (Supplementary methods). The p53 cDNA was amplified using primers mapping to 5’ end (nt. 1–522), middle piece (M: nt. 496–1054), and 3’ end (nt. 961–1546) of coding sequence where the TP53’s 5’ and 3’ end primers overlapping with UTRs. The nucleotide positions were based on the GenBank RNA sequence of NM_000546.5. The primer sequences were included in Supplementary table-2. The PCR products obtained were gel purified using GFX columns (illustra GFX PCR DNA and Gel Band Purification Kit, GE Healthcare # 45001489) and subjected to paired-end Sanger sequencing.
Identification of TP53 to FXR2 fusion in Hep3B cells
Based on RNA-seq IGV reads primers were designed to amplify TP53 to FXR2 focal deletion point. The 53INTR reverse complement primer mapping to TP53 intron (HG19: Chr17: 7,577,480) and the FXINTF sense primer mapping to FXR2 intron (HG19: Chr17: 7,500,880) were used to amplify the fusion sequence of ~ 425 bp using Hep3B genomic DNA or cDNA with 1 M betaine. The primer sequences were included in Supplementary table-2. The resultant product from gDNA was gel excised, GFX purified as described above, and re-amplified to exclude the ~ 250 bp product that resulted in the initial PCR reaction. The 425 bp product was subjected to Sanger sequencing with 1 M betaine. The fusion sequence is submitted to GenBank (Accession: MN842296).
Sp1 (nickel and zinc box), p53 (CDKN1A and GADD45 palindrome box) sequence analysis in C19MC
A 200 kb chromosome 19 sequence (Chr19:54,100,000–54,300,000: HG19) encompassing 96 kb C19MC was mapped for Sp1 binding sites with preference for zinc and nickel as described previously34 and for palindromic sequences within p53 binding consensus of CDKN1A and GADD45 as described previously27,29. The distances between mapped sequences were converted to percentage to create a binding site map corresponding to HG19 co-ordinates.
Statistical analyses
Statistical analyses were performed as described previously2. Briefly, frequency distribution 10–90 percentile type box-whisker plots and statistical analyses were done using Graphpad Prism software (v7.04; La Jolla, CA, USA). In box-whisker plots the outliers are aligned with 75% transparency. For patient group versus group statistical significance analysis (box-whisker plots), unpaired, non-parametric Mann–Whitney test was used. Throughout the study the p-value of 0.05 was considered significant and for frequency distribution box-whisker plots, p-values < 0.001 were considered as robust significance. The ‘n’ for TCGA data analysis were indicated in figures. For wet lab experiments, t-tests were performed using two-tailed distribution, two sample unequal variance. Error bars represent standard error of mean. For statistics on patient clinical characteristics in C19MC high versus low groups, TCGA cBioportal for Cancer Genomics (https://www.cbioportal.org/)61,62 was used. For clinical characteristics that do not have statistics in cBioportal, the TCGA clinical data from GDAC firehose (https://gdac.broadinstitute.org/) was manually curated by integrating C19MC high and low group patients with clinical dataset and the statistical significance was examined using unpaired, non-parametric Mann–Whitney test in Graphpad Prism software.
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Acknowledgements
The authors sincerely thank Moffitt Cancer Center’s molecular genomics and bioinformatics core facilities especially Cen Ling, Zhang Yonghong, Sean J. Yoder, and Jamie K. Teer for technical support for RNA sequencing experiments. Elsa R. Flores is a National Cancer Institute Outstanding Investigator (R35CA197452), Moffitt Distinguished Scholar, and Scholar of the Leukemia and Lymphoma Society, the Rita Allen Foundation, and the V Foundation for Cancer Research. Marco Napoli is a Scholar of the Cancer Prevention Research Institute of Texas-Translational Research in Multidisciplinary Program.
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G.G.J. and A.S.B. conceived the hypothesis, performed data analysis, and drafted the manuscript. G.G.J. designed the study and performed experiments. M.N. and A.D. contributed to real-time PCRs. M.N. contributed to mycoplasma tests. M.T.S, A.S.B. and G.G.J. contributed to patient clinical characteristics details. H.D.A., P.R., and N.M. contributed to reagents. A.S.B. and E.R.F. provided scientific and editorial oversight. All authors read and agree to the contents of the manuscript.
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A.S.B. has advisory board relationship with Bayer and provides consulting work for PierianDx. The remaining authors have no disclosures.
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Supplementary Information
Methods including C19MC-based grouping of HCC patient data & heatmap analysis, p53 transcription competent (TC) and transcription incompetent (TI) HCC sample clustering of TCGA iCluster sub-sets and CCLE cell lines, heatmaps for SLC family and cell death, immunofluorescence analysis & microscopy, mitochondria polarization status analyses, reverse transcriptase PCRs & primer sets, chromatin condensation and DNA fragmentation analyses were included in supplementary materials.
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Jinesh, G.G., Napoli, M., Smallin, M.T. et al. Mutant p53s and chromosome 19 microRNA cluster overexpression regulate cancer testis antigen expression and cellular transformation in hepatocellular carcinoma. Sci Rep 11, 12673 (2021). https://doi.org/10.1038/s41598-021-91924-7
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DOI: https://doi.org/10.1038/s41598-021-91924-7
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