Histone acetylation: a key determinant of acquired cisplatin resistance in cancer.

Cisplatin is an alkylating class of chemotherapeutic drugs used to treat cancer patients. However, cisplatin fails in long-term treatment, and drug resistance is the primary reason for tumor recurrence. Hence, understanding the mechanism of acquirement of chemoresistance is essential for developing novel combination therapeutic approaches. In this study, in vitro cisplatin-resistant cancer cell line models were developed. Gene ontology and GSEA of differentially expressed genes between parental and resistant cells suggest that PI3K-AKT signaling, central carbon metabolism, and epigenetic-associated phenomenon alter in cisplatin-resistant cells. Further, the data showed that increased glucose transport, alteration in the activity of histone-modifying enzymes, and acetyl-CoA levels in resistant cells paralleled an increase in global histone acetylation. Enrichment of histone acetylation on effectors of PI3K-AKT and glycolysis pathway provides evidence of epigenetic regulation of the key molecules in drug resistance. Moreover, cisplatin treatment to resistant cells showed no significant changes in histone acetylation marks since drug treatment alters cell epigenome. In continuation, targeting PI3K-AKT signaling and glycolysis leads to alteration in histone acetylation levels and re-sensitization of resistant cells to chemo-drug. The data provide evidence of histone acetylation's importance in regulating pathways and cisplatin-resistant cells' cell survival. Our study paves the way for new approaches for developing personalized therapies in affecting metabolic pathways and epigenetic changes to achieve better outcomes for targeting drug-resistant cells.

An increase in polyadenylation of histone isoforms, Hist1h2ah and Hist2h3c2, is governed by 3'-UTR in de-differentiated and undifferentiated hepatocyte.

Replication-dependent histones have a stem-loop structure at the 3' end of messenger RNA (mRNA) and are stabilized by stem-loop binding protein (SLBP). Moreover, loss of SLBP and imbalance in the level of ARE (adenylate-uridylate-rich elements)-binding proteins, HuR, and BRF1 are associated with the polyadenylation of canonical histone mRNAs under different physiological conditions. Previous studies from the lab have shown increased protein levels of H2A1H and H3.2 in N-nitrosodiethylamine (NDEA)-induced hepatocellular carcinoma (HCC). In this study, we report that increase in the polyadenylation of histone mRNA contributes to increased levels of H2A1H and H3.2 in NDEA-induced HCC. The persistent exposure to carcinogen with polyadenylation of histone mRNA increases the total histone pool resulting in aneuploidy. The embryonic liver has also shown increased polyadenylated histone isoforms, Hist1h2ah and Hist2h3c2, primarily contributing to their increased protein levels. The increase in polyadenylation of histone mRNA in HCC and e15 are in coherence with the decrease in SLBP and BRF1 with an increase in HuR. Our studies in neoplastic CL38 cell line showed that direct stress on the cells induces downregulation of SLBP with enhanced histone isoform polyadenylation. Moreover, the polyadenylation is related to increase in activated MAP kinases, p38, ERK, and JNK in HCC liver tumor tissues and CL38 cells treated with arsenic. Our data suggest that SLBP degrades under stress, destabilizing the stem-loop, elongating histone isoforms mRNA with 3' polyadenylated tail with increase of HuR and decrease of BRF1. Overall, our results indicate that SLBP may play an essential part in cell proliferation, at least in persistent exposure to stress, by mediating the stabilization of histone isoforms throughout the cell cycle.

Comparison of circulating DNA in malignant neoplasia from diverse locations: Investigating a diagnostic role.

CONTEXT: Circulating free DNA (cfDNA) analysis has emerged as novel noninvasive diagnostic biomarker in several solid tumors. Raised levels have been reported in several malignancies and may correlate with clinicopathological and treatment response. The current study was designed to assess the diagnostics of cfDNA in different tumor types of malignancies correlating with tumor (T), nodes (N), and metastases (M) stage. DESIGN: Serum samples were collected from treatment naïve cases with histologically diagnosed tumors including 23 brain tumors, 48 breasts, 50 gallbladder carcinoma (GBC), 13 lungs, 68 oral squamous cell carcinoma (OSCC), and 25 normal controls. CfDNA was quantified with real-time polymerase chain reaction (PCR), Invasive ductal carcinoma (IDC) using beta-globin gene amplification. Cut off values for diagnostics were calculated using receiver operating curve analysis. RESULTS: Contrary to other cfDNA studies where it was postulated that cfDNA would not cross the blood-brain barrier and reach the systemic circulation, we found detectable cfDNA in glioma with median (Q1-Q3) of 349.22 ng/ml (19.87-1276.58). Median cfDNA concentration in breast, gallbladder, lung, oral and normal controls was 328.72 (128.38-624.44), 778.50 (589.88-1864.35), 348.73 (194.67-483.61), 386.27 (47.88-959.67), and 74.12 (49.66-120.00), respectively. Grades I and II glioma had significantly lower levels compared to Grades III and IV (P = 0.0001). Significant difference in median cfDNA values in IDC and GBC was observed with increasing tumor grades, stage, T stage, nodal stage and metastasis and with stage of OSCC cases. CONCLUSION: CfDNA levels showed good diagnostic discrimination in glioma, GBC, breast, lung carcinoma, and OSCC. Significant increase in titers was evident with increase in cancer stage from I to IV in breast, GBC and OSCC.

RPS13, a potential universal reference gene for normalisation of gene expression in multiple human normal and cancer tissue samples.

BACKGROUND: Reference genes are considered stable genes and are used for normalizing the gene expression profile across different cell types; as well as, in normal and diseased samples. However, these gene associates with different biological processes, and hence expression vary in different pathological conditions. Therefore, in the present study, eight different reference genes were used and compared to identify common reference gene usable for an array of different cell types and human cancers. METHODS AND RESULTS: The expression stability of the eight reference genes across eleven normal and cancerous tissues was confirmed through real time-qPCR. Ribosomal protein S13 (RPS13) was found to be a common and stable reference gene across intra- and inter-comparison between various normal and tumor tissue types. Further, TCGA data analysis across and between normal and tumor tissue types also showed minimum deviation in expression of RPS13 gene out of eight routinely used reference genes. CONCLUSION: RPS13 is the common stable reference gene in normalization for gene expression based analysis in cancer research.

Tumor-specific overexpression of histone gene, H3C14 in gastric cancer is mediated through EGFR-FOXC1 axis.

Incorporation of different H3 histone isoforms/variants have been reported to differentially regulate gene expression via alteration in chromatin organization during diverse cellular processes. However, the differential expression of highly conserved histone H3.2 genes, H3C14 and H3C13 in human cancer has not been delineated. In this study, we investigated the expression of H3.2 genes in primary human gastric, brain, breast, colon, liver, and head and neck cancer tissues and tumor cell lines. The data showed overexpression of H3.2 transcripts in tumor samples and cell lines with respect to normal counterparts. Furthermore, TCGA data of individual and TCGA PANCAN cohort also showed significant up-regulation of H3.2 genes. Further, overexpressed H3C14 gene coding for H3.2 protein was regulated by FOXC1 transcription factor and G4-cassette in gastric cancer cell lines. Elevated expression of FOXC1 protein and transcripts were also observed in human gastric cancer samples and cell lines. Further, FOXC1 protein was predominantly localized in the nuclei of neoplastic gastric cells compared to normal counterpart. In continuation, studies with EGF induction, FOXC1 knockdown, and ChIP-qPCR for the first time identified a novel axis, EGFR-FOXC1-H3C14 for regulation of H3C14 gene overexpression in gastric cancer. Therefore, the changes the epigenomic landscape due to incorporation of differential expression H3 variant contributes to change in gene expression pattern and thereby contributing to pathogenesis of cancer.

Circulating free DNA as a marker of response to chemoradiation in locally advanced head and neck squamous cell carcinoma.

CONTEXT: Liquid biopsy has moved from bench to bedside as a non-invasive biomarker for early diagnosis and monitoring treatment response. OBJECTIVE: This study investigated the role of circulating free DNA (cfDNA) as a diagnostic marker in locally advanced head and neck squamous cell carcinoma (HNSCC) and in monitoring response to chemoradiation therapy. MATERIALS AND METHODS: Serum was collected from treatment naïve, histopathologically diagnosed tumors in 24 HNSCC cases and 16 normal controls. CfDNA levels were quantified using ß globin gene amplification. RESULTS: The cfDNA level was significantly elevated in HNSCC (992.67 ± 657.43 ng/mL) as compared to healthy controls (60.65 ± 30.42 ng/mL, P = <0.001). The levels of cfDNA did not significantly correlate with TNM stage, lymph node involvement and grade. In responders, percentage decrease in cfDNA levels was 9.57% and 29.66%, whereas in nonresponders percentage increase was 13.28% and 24.52% at the end of three months of follow-up. CONCLUSION: Our study adds to the evidence that cfDNA levels are significantly higher in HNSCC cases and provides some evidence that levels increase with tumor progression. CfDNA may be a promising prospective non-invasive marker to predict response in patients undergoing chemo-radiotherapy.

Histone H2A isoforms: Potential implications in epigenome plasticity and diseases in eukaryotes.

Epigenetic mechanisms including the post-translational modifications of histones, incorporation of histone variants and DNA methylation have been suggested to play an important role in genome plasticity by allowing the cellular environment to define gene expression and the phenotype of an organism. Studies over the past decade have elucidated how these epigenetic mechanisms are significant in orchestrating various biological processes and contribute to different pathophysiological states. However, the role of histone isoforms and their impact on different phenotypes and physiological processes associated with diseases are not fully clear. This review is focussed on the recent advances in our understanding of the complexity of eukaryotic H2A isoforms and their roles in defining nucleosome organization. We elaborate on their potential roles in genomic complexity and regulation of gene expression, and thereby on their overall contribution towards cellular phenotype and development of diseases.

Establishing a correlation between RIN and A260/280 along with the multivariate evaluation of factors affecting the quality of RNA in cryopreserved cancer bio-specimen.

Biomarkers are biological characteristic to measure and evaluate normal and pathological states. To define expression-based molecular biomarkers, high-quality tissue samples are a prerequisite for the preparation of standard RNA. It is already known that RIN number defines the RNA quality, however its relation with A260/280 ratio and Ct value is not defined clearly; therefore, understanding an association will provide a reliable method for describing RNA quality. Multiple cryopreserved human tumor tissue types from ACTREC Biorepository and TMH-INTTR were analyzed for the effect of storage time on RNA quality. The RNA from tumor samples were isolated and analyzed by RIN, A260/280 ratio, and Ct value to establish inter-relationships. Around 50% samples had a RIN of ≥ 6.9 and A260/280 ≤ 2.04; 27% had a RIN ≥ 5 and A260/280 ≤ 2.08, and remaining 23% displayed RIN < 5 and A260/280 > 2.08. However, the RNA quality has no association with the storage period of tissue samples. Moreover, all samples which had A260/280 ≤ 2.08 showed acceptable Ct values of 17-24. The data clearly suggests that the A260/280 ratio is able to predict RNA quality. To the best of our knowledge, this is the first Indian report analyzing the labile nucleic acid-RNA quality from different cancer tissue types cryopreserved for diverse time periods. In conclusion, RIN and A260/280 ratio can help in predicting the quality of RNA independently; however, both together provide better assurance for further downstream processing.

Cationic cholesterol derivative efficiently delivers the genes: in silico and in vitro studies.

The aims of the research work were to synthesize ethyl(cholesteryl carbamoyl)-L-arginate (ECCA), an arginine-conjugated cholesterol derivative, and to evaluate its application as a gene delivery vector. The interactions of ECCA with DNA duplex were studied using molecular dynamics (MD) simulations. It was found that the guanidine group of ECCA could interact with the phosphate group of DNA through ionic interactions as well as hydrogen bonds. The structure of DNA was stable throughout the simulation time. Liposomes were formulated using ECCA and soya phosphatidylcholine (SPC) by a thin-film hydration method. They had the particle size of ~ 150 nm and the zeta potential of + 51 mV. To ensure the efficient binding of DNA to the liposomes, the ratio of DNA to ECCA was optimized using gel retardation assay. Further, serum stability, haemolysis and cytotoxicity studies were carried out to determine the stability and safety of the lipoplexes. Circular dichroism spectroscopy was used to determine the interaction of DNA and cationic liposomes. Cellular uptake pathway was determined by studying the uptake of coumarin-loaded lipoplexes at 4 °C and in the presence of uptake inhibitors, i.e. genistein, chlorpromazine and methyl-ß-cyclodextrin. Transfection studies were carried out to evaluate the transfection efficacy of the ECCA-loaded lipoplexes. The binding of DNA and lipoplexes was found to be stable in the presence of serum, and no degradation of DNA was observed. The lipoplexes showed low haemolysis and cytotoxicity. The uptake of coumarin-loaded liposomes was decreased up to ~ 20% in the presence of clathrin- and caveola-mediated uptake inhibitors, indicating a role of both the pathways in the uptake of the inhibitors. Satisfactory transfection efficiency was obtained compared to Lipofectamine®. Thus, cationic cholesterol derivative is a useful tool for gene delivery vector.