Next Article in Journal
Childhood Cancer Incidence and Survival in South Australia and the Northern Territory, 1990–2017, with Emphasis on Indigenous Peoples
Previous Article in Journal
Distinct Capabilities in NAD Metabolism Mediate Resistance to NAMPT Inhibition in Glioblastoma
Previous Article in Special Issue
Hitting the Sweet Spot: How Glucose Metabolism Is Orchestrated in Space and Time by Phosphofructokinase-1
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Cancers
Volume 16
Issue 11
10.3390/cancers16112055
cancers-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Restricting Colorectal Cancer Cell Metabolism with Metformin: An Integrated Transcriptomics Study

by
Ayla Orang
1,
Shashikanth Marri
1,
Ross A. McKinnon
1,
Janni Petersen
1,2 and
Michael Z. Michael
1,3,4,*
1
Flinders Health and Medical Research Institute, Flinders University, Bedford Park, SA 5042, Australia
2
Nutrition and Metabolism, South Australia Health and Medical Research Institute, Adelaide, SA 5000, Australia
3
Department of Gastroenterology and Hepatology, Flinders Medical Centre, Bedford Park, SA 5042, Australia
4
Flinders Centre for Innovation in Cancer, Flinders Medical Centre, Bedford Park, SA 5042, Australia
*
Author to whom correspondence should be addressed.
Cancers 2024, 16(11), 2055; https://doi.org/10.3390/cancers16112055
Submission received: 5 April 2024 / Revised: 13 May 2024 / Accepted: 18 May 2024 / Published: 29 May 2024
(This article belongs to the Special Issue Targeting Metabolic Vulnerabilities in Cancer)
Browse Figures
Versions Notes

Abstract

:

Simple Summary

Metformin, a primary treatment for type 2 diabetes, is known to reduce colorectal cancer (CRC) risk. This study explores the molecular mechanisms behind metformin’s anti-tumour effects in CRC cells. The research identifies specific microRNAs (miRNAs) influenced by metformin, revealing their role in regulating genes associated with cell proliferation and key signalling pathways. The findings provide valuable insights into how metformin disrupts CRC cell growth through post-transcriptional control, impacting both metabolism and cell proliferation.

Abstract

Background: Metformin is a first-line therapy for type 2 diabetes as it disrupts cellular metabolism. Despite the association between metformin and lower cancer incidence, the anti-tumour activity of the drug in colorectal cancer (CRC) is incompletely understood. This study identifies underlying molecular mechanisms by which metformin slows colorectal cancer cell proliferation by investigating metformin-associated microRNA (miRNA) and target gene pairs implicated in signalling pathways. Methods: The present study analysed changes in miRNAs and the coding transcriptome in CRC cells treated with a sublethal dose of metformin, followed by the contextual validation of potential miRNA–target gene pairs. Results: Analyses of small RNA and transcriptome sequencing data revealed 104 miRNAs and 1221 mRNAs to be differentially expressed in CRC cells treated with metformin for 72 h. Interaction networks between differentially expressed miRNAs and putative target mRNAs were identified. Differentially expressed genes were mainly implicated in metabolism and signalling processes, such as the PI3K-Akt and MAPK/ERK pathways. Further validation of potential miRNA–target mRNA pairs revealed that metformin induced miR-2110 and miR-132-3p to target PIK3R3 and, consequently, regulate CRC cell proliferation, cell cycle progression and the PI3K-Akt signalling pathway. Metformin also induced miR-222-3p and miR-589-3p, which directly target STMN1 to inhibit CRC cell proliferation and cell cycle progression. Conclusions: This study identified novel changes in the coding transcriptome and small non-coding RNAs associated with metformin treatment of CRC cells. Integration of these datasets highlighted underlying mechanisms by which metformin impedes cell proliferation in CRC. Importantly, it identified the post-transcriptional regulation of specific genes that impact both metabolism and cell proliferation.

Graphical Abstract

1. Introduction

Metformin has proven anti-cancer properties in cell lines as it reprogrammes the metabolism of cancer cells. The potential mechanisms of action are mainly associated with activation of AMPK, inhibition of the mTOR pathway, regulating inflammatory responses and promoting cell death in cancer stem cells [1,2,3,4,5]. The inhibitory effects of metformin on colorectal cancer (CRC) have previously been reported at the pre-clinical level, as reduced spontaneous intestinal polyp growth in ApcMin/+mice [6] or sensitisation of CRC cells to other chemotherapeutic agents, which has led to clinical trials evaluating the combinatorial effect of metformin with standard chemotherapeutics [7].
Combination of chemotherapeutics with metformin shows additive responses, which highlights the pleiotropic nature of this drug through simultaneously targeting numerous pathways affecting both tumourigenesis and tumour progression [8,9,10]. Therefore, the molecular mechanisms and crosstalk between signalling pathways that contribute to the anti-cancer effects of metformin remain elusive. Phosphatidylinositol-3-kinase (PI3K)/AKT signalling is an important intracellular pathway and considered a master regulator for cancer [11]. The MAPK/ERK pathway also plays an important role in complex cellular programmes including proliferation, differentiation, development, transformation and apoptosis and has been shown to play a key role in the transduction of extracellular signals to elicit cellular responses [12].
Growing evidence confirms that several miRNA changes are associated with the anti-proliferative activity of metformin. Accordingly, metformin treatment altered miRNA expression in hepatocellular carcinoma, pancreatic cancer, oesophageal squamous cancer, gastric cancer, lung cancer and prostate cancer [13,14,15,16,17].
In general, specific alterations in miRNA expression are likely to result in functional changes in the expression of other genes. Hence, the implications of the interplay between metformin-regulated miRNAs and their target genes, within relevant metabolic and signalling pathways, require further investigation. Given this rationale, an integrated-systems biology approach is necessary to understand the transcriptional and post-transcriptional responses to metabolic disruption in colorectal cancer.
This study provides a comprehensive snapshot of the changes associated with metformin treatment of HCT116 cells, using small RNA sequencing and transcriptome analyses, and characterises metformin response pathways in a systematic manner across different CRC cell lines. It identifies specific miRNA–target transcript interactions that contribute to the metformin response in colorectal cancer cells.

2. Materials and Methods

2.1. Cell Lines and Reagents

Colorectal cancer cell lines (HCT116, DLD1, RKO, HT29, Caco2 and SW480) were obtained from the American Type Culture Collection and cultivated in Dulbecco Modified Eagle Medium (DMEM) supplemented with 10% Fetal Bovine Serum (FBS). STMN1 siRNA and miRNA mimics (as well as matched negative control siRNA and mimics) were synthesised by Shanghai GenePharma (Shanghai, China), while the PIK3R3 siRNA was purchased from Qiagen (PIK3R3_8 FlexiTube siRNA and #SI03650325 negative control; Valencia, CA, USA). The sequences for these reagents are presented in Supplementary Table S7. Metformin was purchased from Sigma-Aldrich (St. Louis, MO, USA).

2.2. Transcriptome and Small RNA Sequencing

To perform Next-Generation Sequencing, the quality of RNA samples was confirmed using an Agilent 2100 Bioanalyzer system (Agilent Technologies, Santa Clara, CA, USA). Following RNA preparation, the generation of libraries, including adapter ligation and PCR amplification, then sequencing were performed at the Flinders Genomics Facility (South Australian Genomics Centre, Adelaide, Australia) using TruSeq Stranded Total RNA and small RNA Sample Preparation Kits (Illumina Inc., San Diego, CA, USA) for RNA and small RNA sequencing, respectively. Ribosomal RNA (rRNA) depletion was performed for RNA sequencing prior to library preparation. The paired-end 100 bp sequencing was performed using the Illumina NextSeq sequencing platform (Illumina Inc., San Diego, CA, USA), and approximately 30–40 and 10–20 million reads were generated per sample for total RNA and small RNA sequencing, respectively.
The QIAseq Targeted RNA Panel (human apoptosis and cell death pathway finder RHS-002Z) from Qiagen (Hilden, Germany) served as a supplementary approach for assessing gene expression. RNA was extracted from HCT116 cells (n = 2) subjected to either no treatment (0 mM) or metformin treatment (2.5 mM) over 72 h, as described earlier. Following the manufacturer’s protocol (Qiagen), samples were processed and sequenced using the Illumina MiSeq platform, resulting in approximately 19.5 million reads.
Following quality control, RNA-seq data were trimmed for adaptor sequences using the FASTX-toolkit followed by quality analysis of the reads using FASTQ and assembly, mapping and alignment of reads to the Ensembl human genome (Grch38.p5_v24) or miRbase 20.1 using STAR [18] and SAMtool [19]. Aligned reads were then converted to raw counts using HTseq [20], and differential expression analysis was performed using DESeq2 [21]. The differentially expressed miRNAs and mRNAs were refined using the following criteria: raw counts ≥ 50, adjusted p value ≤ 0.05 and −1 ≥ log2 fold change ≥ 1.

2.3. microRNA Target Analysis

To predict miRNA targets and collate previously validated targets, seven online resources were used. miRTarBase (release 7.0) [22] and miRecord (release 2013) [23] contain validated miRNA targets, and those targets that were validated with strong evidence (reporter assays) were selected. To collect the predicted targets, TargetScan (release 7.1) [24], miRmap (release 1.1) [25], miRDB (release 6.0) [26], DIANA-microT-CDS (release 5.0) [27] and miRanda (release 3.3a) [28] were used. In TargetScan, targets with a context score smaller or equal to −0.15 were retained. In DIANA-microT-CDS, targets with miTG scores greater or equal to 0.85 were selected. Predicted targets from miRDB with a score greater or equal to 80 were also kept. For miRanda and miRmap, cut-off thresholds of miRSV score ≤ −1.2 and miRmap score ≥ 90 were applied, respectively. Finally, differentially expressed miRNA–target mRNA pairs were extracted only if there was an anti-correlation between metformin-induced miRNA and mRNA levels (if miRNA was downregulated, the mRNA should be upregulated and vice versa) and the pairs were common to at least two databases.

2.4. Network Construction and Analysis

Protein–protein interaction (PPI) networks were constructed using the NetworkAnalyst online tool (Release 3.0) and extracted as a zero-ordered network from IMEx Interaction using curated comprehensive datasets through InnateDB [29]. The PPI network was visualised, and the expression values were incorporated into the network using Cytoscape software (version 3.4.0) [30]. The PPI network was then analysed by NetworkAnalyzer, a plug-in of Cytoscape, and the topological properties of the network were assessed [31].

2.5. Pathway and Gene Ontology Analysis and Subnetwork Construction

ClueGo (version 2.3.3), a Cytoscape plug-in, was used to extract the non-redundant KEGG (version 305) pathways and gene ontology (GO) terms (Biological Processes, Molecular Functions and Cellular Compartments) in functionally organised networks representing the connection between the pathways or GO terms based on the similarity of their linked genes [32]. At least 3 genes per term and 4 percent attribution in the term were considered. The terms were grouped based on the kappa scores, which is a robust measurement of the correlation occurring by chance. For network connectivity, the kappa score was set at 0.04. GO term fusion was applied, and the cut-off for the term p value was 0.05. For GO analysis, “experimental evidence” was selected.

2.6. Reverse Transcription Polymerase Chain Reaction

Total RNA was extracted with TRIzol RNA Isolation Reagent (Thermo Fisher Scientific, Waltham, MA, USA) using the standard method. To remove any genomic DNA contamination, the RQ1 RNase free DNase kit (Promega, Madison, WI, USA) was used, and the DNase I enzyme was then deactivated by adding 2.5 µL DNase deactivation slurry from the Ambion DNA-free™ Kit (Invitrogen, Waltham, MA, USA). cDNA was made from 1 µg total DNase-treated RNA with M-MLV Reverse Transcription kit (Promega) and Random Hexamer primers (Invitrogen) according to the manufacturer’s recommended conditions. Real-time RT-PCR reactions were subsequently performed in triplicate using Power SYBR green quantitative real-time RT-PCR master mix (Invitrogen, Life Technologies, Waltham, MA, USA) in a Qiagen Rotorgene Q real-time PCR cycler (Qiagen). Relative expression levels were calculated from Ct values using Qgene [24]. Results were normalised relative to the β-actin (ACTNB) expression levels. The PCR primer sequences are listed in Supplementary Table S7.
For miRNA expression analysis, TaqMan miRNA assays (Applied Biosystems, Life Technologies, Waltham, MA, USA) were used (Supplementary Table S7). cDNA was synthesised from 20 ng total RNA using miRNA-specific primers according to the TaqMan miRNA Assay protocol. Real-time PCR was then carried out according to the TaqMan protocol using 1 µL of reverse transcription product, 1× TaqMan Universal PCR Master Mix No AmpErase UNG (Applied Biosystems), miRNA-specific primer and probe assay mix. Results were normalised relative to endogenous miR-16 expression.

2.7. Western Blot Analyses

Total extracts were prepared in radioimmunoprecipitation assay buffer (RIPA buffer) containing protease and phosphatase inhibitors (Merck, Darmstadt, Germany). Protein concentration was determined using EZQ® Protein Quantitation Kit (BioRad, Hercules, CA, USA). Samples were then boiled for 3 min at 98 °C, separated in SDS-PAGE gel electrophoresis and transferred to a LF-PVDF membrane (BioRad) using Trans-blot Turbo System (BioRad). The membrane was blocked in TBS with 5% skim milk for an hour and incubated overnight at 4 °C with primary antibodies including α-Actinin (Cell Signaling Technology, Danvers, MA, USA, 1:1000), PIK3R3 (Cell Signaling Technology, 1:1000), STMN1 (Abcam, Cambridge, UK, 1:10,000), p70 S6K (Cell Signaling Technology, 1:1000) and Phospho-p70 S6K (Thr389-Cell Signaling Technology, 1:500) followed by incubation for 1 h with anti-rabbit HRP-conjugated secondary antibody at a dilution of 1:20,000. ECL assay was used to visualise bands using ChemiDoc™ Imaging Systems (BioRad) and analysed using AlphaEaseFC™ software (Alpha Innotech, San Leandro, CA, USA, http://genetictechnologiesinc.com/alpha/alpha_ease_fc.htm (accessed on 17 May 2024)).

2.8. Cell Viability Assays

Crystal violet solution was made by dissolving 100 mg crystal violet (Sigma-Aldrich) in 500 mL 10% buffered formalin (Orion Labs, San Francisco, CA, USA). To perform the assay for cells grown in 96-well plates, the plate was washed with 1× PBS. A 50 µL amount of 1× crystal violet solution was added to each well and incubated at room temperature for 10 min. The plate was then washed, the crystal-violet-stained DNA was solubilised in 100 µL 1% SDS solution and the absorbance at 570 nm was measured using an EnSight Multimode Plate Reader (Perkin Elmer, Shelton, CT, USA).

2.9. Flow Cytometry Analyses

To define the cell cycle distribution, flow cytometric analyses were performed. In brief, cells grown in 6-well plates were harvested by trypsinisation and fixed with 80% ethanol. Cells were stained for total DNA content with a solution containing 50 µg/mL propidium iodide and 200 µg/mL RNase I and 0.1% Triton X-100 in PBS for 30 min. Cell cycle distribution was then assayed with a CytoFLEX flow cytometer (Beckman Coulter Life Sciences, Brea, CA, USA) and the data analysed using FCS Express (De Novo Software, Pasadena, CA, USA, https://denovosoftware.com/ (accessed on 17 May 2024)).

2.10. miRNA Target Validation

miScript Target Protectors (Qiagen) were used to validate predicted miRNA::mRNA target pairs and binding regions (Supplementary Table S7). Target protectors are nuclease-resistant, single-stranded oligonucleotides that competitively hybridise with miRNA binding sites on the 3′UTR of the predicted targets while having no effect on other targets of the same miRNA [33]. The Qiagen online algorithm was used to design target protectors. In 24-well plates, HCT116 cells were co-transfected with miRNA mimics (20 nM) and also with the corresponding target protector/s (500 nM) designed for the specific transcript binding sites, or with a negative control target protector (Qiagen: MTP0079571, MTP0079585, MTP0079592, MTP0079578, MTP0079599 and MTP0000002), for 72 h followed by RT-PCR or crystal violet assays.

3. Results

3.1. Metformin Treatment of Colorectal Cancer Cells Induces Integrated miRNA::mRNA Responses

To investigate the altered miRNA and transcriptome profiles resulting from metformin treatment at a sublethal dose (2.5 mM) in HCT116 colorectal cancer cells, small RNA-seq and total RNA-seq were performed. The 2.5 mM metformin concentration was chosen as it reproducibly slows HCT116 proliferation by ~20% over 72 h, without inducing apoptosis [34]. This concentration is also physiologically relevant in the gut epithelium [35]. Differential expression analysis identified 104 miRNAs, with 63 and 41 miRNAs being upregulated or downregulated, respectively (Figure 1 and Supplementary Table S1). Also, 1221 differentially expressed (DE) protein-coding genes were identified, with a total of 554 upregulated and 667 downregulated genes (Figure 1(Aii) and Supplementary Table S2). The data reliability was confirmed by comparing the common differentially expressed genes between the total RNA-seq (TruSeq Stranded Total RNA) and QIAseq Targeted RNA Panel, and the strong positive correlation (r = 0.86) showed the reproducibility and reliability of the total RNA-seq results (Figure S1, Supplementary Table S3).
To construct an integrative network including DE miRNAs and genes, miRNA target gene prediction was performed as detailed in Section 2. The validated and predicted protein-coding gene targets of 104 DE miRNAs were then collected. Relatively strict thresholds were selected in an attempt to reduce the number of false-positive targets. The potential DE miRNA–gene pairs identified showed anti-correlations in their expression changes and were common to two or more prediction databases. To ensure the robustness of protein-coding gene identification, the genes with fewer than six reads per million in either metformin-treated or untreated RNA sequencing data were excluded. A total of 1060 DE genes were thus assigned for the following analyses. In total, 167 miRNA::mRNA pairs were identified, with only 10% of predictions having been experimentally validated (Table S4). Using protein–protein interactions together with miRNA–gene interactions (predicted or validated), a miRNA-based network was then assembled (Figure 1B). The integrated miRNA-based network compromised 365 nodes (47 miRNAs, 317 mRNAs) and 728 edges (169 miRNA–gene interactions and 559 protein–protein interactions). Overall, this network demonstrates the complex changes in miRNA–gene and gene–gene interactions. Since DE miRNAs potentially target multiple and highly connected genes within the integrated network, these miRNAs together with putative/validated target genes represent complex metformin-mediated biochemical pathway changes in HCT116 cells.

3.2. Metformin-Associated Differentially Expressed miRNAs and Genes Are Enriched in PI3K-Akt and MAPK/ERK Signalling

To examine which biological pathways were altered in HCT116 cells treated with 2.5 mM metformin, the biochemical pathways were extracted from the Kyoto Encyclopedia of Genes and Genomes (KEGG) collection, the DE genes with at least one interaction were extracted from the integrative network (Figure 1B) and the ClueGO Cytoscape plug-in was used for further analyses. KEGG pathway analysis revealed 20 statistically enriched pathways organised into eight groups based on kappa score (Figure 2A). “PI3K-Akt signalling pathway” had the lowest p value of all GO groups and was the parent term within this group (p = 1.0 × 10−8). In addition, “MAPK/ERK signalling pathway” had the lowest term p value (p = 7.4 × 10−7), with 25 DE genes involved in this pathway (Table S4).
The involvement of miRNAs in the PI3K-Akt and MAPK/ERK signalling pathways was investigated by identifying potential miRNA::target gene pairs within the two cascades (Table S6). After applying a further stringent selection criterion by filtering out miRNAs with fewer than 12 reads per million and retaining those miRNA::gene pairs if downregulated, miRNAs were described as oncogenic miRNAs, and their putative upregulated target genes had a tumour suppressor role in cancer; vice versa, six (four predicted and two validated) and four (three predicted and one validated) miRNA::mRNA pairs remained in the PI3K-Akt or MAPK/ERK signalling pathways, respectively, as shown in Table S6. RT-PCR validation of the expression changes in miRNAs and genes associated with 2.5 mM metformin treatment was then performed in an independent experiment (Figure 2B). These results collectively represent the multi-functional responses to metformin in altering miRNA profiles of CRC cells to fine-tune associated gene interactions and consequent signalling pathways.

3.3. Metformin-Induced miRNAs Directly Target Key PI3K-Akt and MAPK/ERK Signalling Components

To validate direct or indirect targeting of genes by selected miRNAs within PI3K-Akt and MAPK/ERK signalling pathways, HCT116 cells were transfected with corresponding synthetic miRNA mimics, and the putative target transcript levels were assessed by RT-PCR. Among the selected miRNA::mRNA pairs in the PI3K-Akt pathway, exogenous introduction of miR-132-3p or miR-2110 activity resulted in a significant reduction in PIK3R3 gene expression of more than 60% (p = 0.0073 and 0.0006, respectively), as shown in Figure 3A. Also, THBS1 gene expression was downregulated as a result of miR-590-3p mimic transfection (p = 0.0029, Figure S2A), while there was no change in expression levels for the predicted targets MYB, EFNA4 and CDKN1A associated with the transfection of miR-132-3p, miR-149-3p and miR-345-5p mimics, respectively (Figure S3). In addition, among four putative/validated miRNA::mRNA pairs within the MAPK/ERK signalling pathway, miR-222-3p and miR-589-3p transfection both resulted in STMN1 gene expression downregulated by 56% and 73%, respectively (Figure 3A), while there was no significant change in expression of MECOM and GADD45A in cells transfected with miR-92a-1-5p and miR-374a-5p, respectively (Figure S3). The miR-590-3p::THBS1A pair was excluded from following investigations as increasing miR-590-3p activity in HCT116 cells did not significantly affect cell proliferation (Figure S2).
To further explore miR-2110 and miR-132-3p targeting PIK3R3 as well as miR-222-3p and miR-589-3p targeting STMN1, the protein levels of the corresponding targets were assessed in cells transfected with miRNA mimics. PIK3R3 and STMN1 immunoblots showed a prominent decrease in the normalised band intensity of the putative/validated target genes in cells transfected with the corresponding miRNAs compared to the cells transfected with scrambled negative control (NC) mimics and normalised to α-actinin band intensity. Accordingly, cells transfected with miR-2110 or miR-132-3p mimics, or a specific PIK3R3 siRNA, showed an at least 50% reduction in PIK3R3 protein levels (Figure 3(Bi)). Additionally, as shown in Figure 3(Bii), transfection of HCT116 cells with miR-222-3p and miR-589-3p precursors led to a 30% and 60% reduction in normalised STMN1 protein band intensity, respectively, and diminished expression of STMN1 at protein levels observed with transfection of STMN1 siRNA. These results therefore confirm the direct targeting of PIK3R3 by miR-132-3p, as described in [36]. They also suggest a role for miR-2110 in the regulation of PIK3R3 as well as both miR-222-3p and miR-589-3p in the regulation of STMN1 in HCT116 cells.
PIK3R3 is a validated target of miR-132-3p [28], and, as listed in Table S6, it is identified as a novel target of miR-2110 by TargetScan and miRmap prediction algorithms. Based on the target predictions, the 3′-UTR of PIK3R3 mRNA contains three potential binding sites for miR-2110 (Figure 3C). Similarly, miR-222-3p and miR-589-3p were predicted to have binding sites on the 3′UTR of STMN1 mRNA by microT-CDS, miRanda and TargetScan algorithms (Table S6). To confirm the direct binding of miR-2110 to the PIK3R3 3′UTR as well as miR-222-3p and miR-589-3p to predicted sites in the STMN1 3′UTR, miScript Target Protectors were designed to obstruct miRNA interaction with the specific transcript binding sites [37]. HCT116 cells were co-transfected with miR-2110 mimics and a combination of three target protectors, each designed to individual binding sites in the PIK3R3 3′UTR, as well as control transfections with negative control (NC) mimics and/or a negative control (NC) target protector. miR-2110 mimics alone and miR-2110 mimics with NC target protectors resulted in a 62% and 45% reduction in PIK3R3 transcript levels, respectively (p = 0.0035 and 0.0111, respectively), as shown in Figure 3C. Introduction of the NC target protector did not protect PIK3R3 from miR-2110 binding and regulation (p = 0.4423), as shown in Figure 3C. PIK3R3 RT-PCR showed an increase in cells co-transfected with miR-2110 mimics and PIK3R3 3′UTR target protectors compared with the cells co-transfected with miR-2110 mimics and NC target protectors, as well as with the cells transfected with miR-2110 mimics alone (0.5- and 1.2-fold increase, respectively), as shown in Figure 3C. In addition, HCT116 cells were co-transfected with miR-589 or miR-222-3p mimics and the corresponding STMN1 3′UTR target protectors as well as negative control treatments with NC mimics and/or NC target protectors. miR-222-3p and miR-589-3p mimics alone resulted in a 46% and 70% reduction in STMN1 gene expression, respectively (p = 0.025 and 0.0012, Figure 3C), while NC target protectors had little to no effect on the miRNA-associated STMN1 downregulation (p = 0.102). Co-transfection of miR-222-3p with the corresponding STMN1 site target protector almost completely negated the silencing effect of the miRNA mimic, and miR-589-3p co-transfection with its corresponding STMN1 target protector restored STMN1 expression by 58% compared with mimics combined with the NC target protector and a 124% increase compared with the mimics alone (Figure 3C). Together, these results confirm the prevention of miRNA binding to the corresponding specific binding sites in the 3′UTRs of PIK3R3 or STMN1 mRNAs by specific target protectors. They also support the findings that PIK3R3 and STMN1 transcripts are direct targets of miR-2110 or miR-222-3p and miR-589-3p-mediated repression, respectively.

3.4. Metformin-Associated miRNAs That Target PI3K-Akt and MAPK/ERK Signalling Pathways Also Suppress Colorectal Cancer Cell Proliferation and Induce Cell Cycle Arrest

To investigate the roles of validated miRNA–gene pairs (miR-132-3p and miR-2110 targeting PIK3R3, miR-222-3p and miR-589-3p targeting STMN1) in cellular processes, such as cell proliferation and cell cycle progression, in different CRC cell models, miRNA mimics were transfected into a panel of CRC cell lines, then viability assayed using crystal violet assay. In addition, the percentage of HCT116 cells at each cell cycle stage was assessed by flow cytometry. HCT116, RKO, DLD1, HT29 and Caco2 cell transfections with miR-132-3p, miR-2210, miR-222-3p or miR-589-3p mimics resulted in decreased cell proliferation. Among these lines, HCT116, RKO and HT29 showed the lowest cell viability, an up to 45% decrease, with each of the overexpressed miRNAs compared with DLD1, Caco2 and SW480 cells (Figure 4A). To confirm that target genes PIK3R3 and STMN1 are important in CRC, the role of PIK3R3 and STMN1 genes in regulating cell proliferation of CRC cell lines was examined. Crystal violet assays showed that RNA interference with PIK3R3 and SMTN1 siRNAs significantly decreased growth, up to a 35% and 65% reduction, respectively, compared with a negative control siRNA transfection at 72 h post-transfection in all six different colorectal cell lines (Figure 4B). The consistent decrease in CRC cell proliferation following STMN1 and PIK3R3 knockdown confirms their pro-proliferative roles across CRC cell lines.
To investigate the biological relevance of the specific interactions between PIK3R3 or STMN1 and their corresponding miRNAs, cell proliferation was examined following the co-transfection of HCT116 cells with PIK3R3 or STMN1 target protectors and miRNA mimics. As shown in Figure 4C, cell viability measurements using crystal violet assays demonstrated that the restoration of PIK3R3 or STMN1 mRNA levels by target protectors, where specific miRNA binding is prevented, increases the viability of HCT116 cells compared with the cells transfected with miRNA mimics alone. The viability increases detected were 40% with miR-2110 target protectors, 15% with miR-222-3p target protectors and 30% with miR-589-3p target protectors. Collectively, these results indicate that PIK3R3 or STMN1 silencing by the validated miRNAs contributes to the anti-proliferative effect of these miRNAs in CRC cell lines. They confirm the tumour suppressor roles of the selected miRNAs as inhibitors of cell proliferation.
To further confirm the cellular changes associated with PIK3R3 targeting by miR-2110 and miR-132-3p within the PI3K/Akt pathway, and since the suppression of PI3K/Akt/mTOR signalling is considered a common cellular response to metformin treatment [38,39], the phosphorylation of p70 S6 kinase was assessed as a downstream effector of this pathway [40]. As shown in Figure 4D, transfection of HCT116 cells with miR-132-3p or miR-2110 mimics, as well as PIK3R3 RNA interference, resulted in a prominent reduction in p70 S6 kinase phosphorylation (Thr389) compared to the negative control. While PIK3R3 siRNA transfection resulted in a slight reduction in total p70 S6K protein levels, miR-2110 and miR-132-3p transfection had no significant effect on p70 S6K levels (Figure 4D).
Cell cycle analysis was performed to examine whether changes in cell cycle control contribute to the reduced cell proliferation that is induced by miRNA-suppressed PIK3R3 or STMN1 activity. Metformin treatment resulted in an increased proportion of cells in G1 phase compared to vehicle-treated HCT116 cells, which indicates partial G1 cell cycle arrest (Figure 4E). Likewise, transfection with STMN1 or PIK3R3 siRNAs, miR-222-3p or miR-589-3p mimics enhanced the percentage of cells in G1 phase compared to vehicle-treated cells (Figure 4E). These data suggest that metformin can partially delay cell cycle progression, mainly at the G1 phase, by inducing these miRNAs and thereby inhibiting their target genes, PIK3R3 and STMN1.

4. Discussion

Metformin was shown to alter the expression of 1221 mRNAs and 104 miRNAs in HCT116 cells. Aberrant expression of mRNAs and miRNAs contributes to tumour progression in the gastrointestinal tract, while expression profiles also differ along the gut [41,42,43,44]. While many oncogenic miRNA levels decreased in colorectal cell lines in response to metformin, other miRNAs were shown to increase with metformin treatment. Udhane et al. performed a detailed transcriptome analysis of metformin-associated changes and identified 14 DE genes that are involved in intracellular metabolic processes in polycystic ovaries (PCO) [45].
Metformin reaches serum concentrations of approximately 40 µM in diabetic patients [46]. However, it undergoes substantial accumulation within the human intestinal lining, where concentrations are markedly higher. Studies examining metformin levels extracted from cleansed intestinal biopsies of diabetic individuals have revealed concentrations up to 300 times greater than those found in the plasma [35,47]. Consequently, the elevated levels of metformin within the intestine suggest potential differences from its effects elsewhere in the body.
Our study of the genome-wide impact of metformin exposure, with unique KEGG pathway signatures, confirmed that components of PI3K-Akt-related pathways are major molecular targets in HCT116 cells. Further validation of the potential miRNA–target gene pairs affected by metformin treatment and involved in the PI3K-Akt pathway identified PIK3R3 as a putative target of miR-2110 and miR-132-3p and one of the key regulators of the pathway. miR-2110 and miR-132-3p were significantly upregulated in metformin-treated HCT116 cells. While several studies have highlighted a key onco-suppressive role for miR-132-3p, to date, there is little research on the role of miR-2110 in cancers. Regardless, miR-2110 has been shown to be rectal cancer specific and to be associated with tumour development [48,49]. It is a neurite-inducing miRNA, shown to exert a pro-differentiation and tumour-suppressive role in neuroblastoma [50]. Similarly, Zhao et al. showed the anti-cancer effect of miR-2110: inducing neuroblastoma cell differentiation and reducing cell survival through targeting Tsukushi (TSKU) [51]. Another study on neuroblastoma showed a similar effect of miR-2110 and the inverse expression of miR-2110 with MYCN mRNA levels [52]. Ectopic expression of miR-132-3p was shown to significantly inhibit CRC cell proliferation and invasion, and to be correlated with increased sensitivity to preoperative chemoradiotherapy [53,54,55]. Zheng et al. also showed the inhibitory effect of miR-132-3p on CRC cell invasion and metastasis through direct targeting of ZEB2 [56]. Downregulation of this miRNA by DNA hypermethylation has also been associated with CRC invasion and poor prognosis in colorectal cancer [54,57]. miR-132-3p suppression of CRC cell proliferation, migration and invasion, and induced apoptosis, has also been accredited with targeting transcripts Derlin-1 and CREB5 [58,59]. As shown in this study, metabolic disruption of HCT116 cells with 2.5 mM metformin resulted in a significant increase in miR-132-3p and miR-2110 expression levels, and a significant reduction in PIK3R3 expression.
The PI3K intracellular signalling pathway plays a critical role in cell apoptosis, cell cycle progression, proliferation and protein synthesis. Its role in regulating glucose uptake and metabolism is equally definitive. PI3K dysregulation was reported in several human cancers, and drugs targeting this pathway are currently in clinical trials [60]. An overactivated PI3K-Akt pathway, caused by gene mutations and/or amplifications, is commonly associated with tumourigenesis. Activation of PI3K leads to the induction of downstream effectors such as AKT and mTOR [61].
Liu et al. confirmed direct PIK3R3 targeting by miR-132-3p in hepatocellular carcinoma. They also showed that the expression levels of PIK3R3 were significantly downregulated in liver cancer tissues and cell lines compared to normal counterparts and were inversely correlated with tumour differentiation, cancer stage and lymph node metastasis. Investigating the molecular target of miR-132-3p, this study confirmed that suppressing cell proliferation, migration, invasion and inhibition of the Akt/mTOR signalling pathway could be attributed to PIK3R3 silencing by this miRNA [36].
In our study, we confirmed that enhanced activity of miR-2110 and miR-132-3p resulted in a significant reduction in the proliferation of all six cell lines tested, representing various classifications of CRC. This was accompanied by decreased PIK3R3 mRNA and protein levels, as well as decreased mTOR signal activation in HCT116 cells, as detected by suppressed p70 S6K phosphorylation. The functional roles of PIK3R3 in CRC, to sustain cell proliferation (and presumably tumour growth), and the mTOR pathway were both disrupted following PIK3R3 knockdown, possibly reflecting the consequences of reduced PIK3R3 levels following metformin treatment. The current study also confirmed PIK3R3 as a direct target of miR-2110 using target protector assays, verifying direct interaction between miR-2110 and the PIK3R3 3′-UTR. Furthermore, the biological function of this targeting, in this case, CRC cell proliferation, was also confirmed.
Through further investigation of likely metformin-associated roles in CRC cells, informed by KEGG pathway analysis, this study revealed that MAPK/ERK signalling had the highest term significance among 20 terms identified to be relevant. Following further validation experiments, miR-222-3p/miR-589-3p::STMN1 pairs were highlighted as a putative MAPK effector that may contribute to the metformin response.
The MAPK/ERK pathway regulates different cellular characteristics such as gene expression, cell cycle, metabolism, motility, cell survival, apoptosis and differentiation [62]. Both pro- and anti-oncogenic functions have been attributed to miR-222-3p in different cancers, suggesting a context-dependent and bimodal role for this miRNA [63,64,65]. While upregulation of miR-222-3p was reported in some cancers including glioblastoma, non-small-cell lung cancer, lymphoma, Kaposi sarcoma and hepatocellular cancer, in some cases, miR-222-3p was downregulated compared with non-cancer specimens and cells [66,67,68,69]. Functioning as an oncogenic miRNA, miR-222-3p was shown to target p27Kip1 and p57 to diminish CDK inhibition. It also induced EMT by noncanonically upregulating ZEB2 expression [70,71,72]. In contrast, miR-222-3p overexpression in malignant glioblastoma cells increased the cell population in the S phase and induced apoptosis [73]. Fuse et al. reported a reduced level of miR-222-3p in clinical specimens of prostate cancer compared with non-cancer tissues and a tumour-suppressive function for this miRNA in suppressing cell proliferation, migration and invasion [74]. In lung cancer cell lines, growth suppression was also shown through intra-S phase arrest and induced apoptosis [75]. Similarly, phorbol myristate acetate (PMA)-induced overexpression of miR-222-3p in acute myeloid leukemia (AML) resulted in cell cycle arrest and partial differentiation [76].
Whilst some research has been reported for miR-589-5p, there is still little understanding of its function in cancers. Cesarini et al. reported A-to-I editing within the miR-589-3p seed sequence, exclusively in normal brain, but a significant decrease in editing in glioblastoma cell lines and tissue. They also showed suppressed cell proliferation, migration and invasion once miR-589-3p editing was induced in glioblastoma cells [77]. Also, miR-589-3p was shown to promote lumbar disc degeneration (LDD) by playing a pro-apoptotic role in lipopolysaccharide (LPS)-stimulated nucleus pulposus (NP) cells [78].
STMN1 encodes stathmin1/oncoprotein-18, which is a cytosolic protein that regulates microtubule dynamics during mitotic spindle formation [79,80]. STMN1 is highly expressed in different types of cancers such as colorectal, gallbladder, breast cancer, hepatocellular carcinoma, sarcoma, lung and prostate adenocarcinomas [81,82,83,84,85,86,87,88]. STMN1 expression is correlated with the clinical outcome of patients with breast cancer, glioma and hepatocellular carcinoma [89,90,91]. STMN1 is associated with MAPK/ERK signalling and thus can be involved in cell cycle progression [92]. Its involvement in the development of various cancers has been reported [93,94,95]. STMN1 silencing resulted in inhibited cell growth, induced apoptosis and delayed G2/M phase transition in gallbladder cancer cells by regulating the activity of p38 MAPK kinase and p53/p21 signal pathways [81]. MAPK activity suppresses miR-193b, derepressing STMN1 in pancreatic cancer cells and thereby enabling proliferation [96]. STMN1 was shown to suppress mesenchymal cell motility and correlate with the metastatic phenotype in human sarcomas in vivo [97]. In colorectal cancer, STMN1 expression is also correlated with elevated cell proliferation and poorer patient prognosis in metastatic disease [94]. As a downstream effector of PI3K/Akt signalling, STMN1 activity contributes to metabolism-related carcinogenesis and is a likely target for therapeutic intervention.
As shown in this study, the expression of both miR-222-3p and miR-589-3p was dramatically increased by metformin treatment in HCT116 cells, and there was a significant reduction in STMN1 gene expression in treated cells compared with in the control group. Furthermore, the exogenous expression of miR-222-3p and miR-589-3p also reduced CRC cell proliferation and STMN1 expression at both the mRNA and protein levels. Target protector assays confirmed the direct binding and post-transcriptional suppression of STMN1 expression by these miRNAs. The biological consequences of STMN1 targeting by miR-222-3p and miR-589-3p were also confirmed, as direct STMN1::miRNA binding was required to significantly suppress CRC cell proliferation.
Cell cycle arrest is often associated with anti-cancer drug activity. Consistent with previous reports, the current study confirmed the role of metformin in suppressing CRC cell proliferation by increasing the proportion of cells in G1 phase. As shown in this study, elevating miR-132-3p and miR-2110 activities, and also miR-589-3p and miR-222-3p activities, resulted in a delayed cell cycle at the G1 phase, which is partly due to direct transcript binding and downregulation of PIK3R3 or STMN1 expression, respectively. These miRNAs that are prevalent in various cancers emerge here as central players influenced by metabolic regulation. While our study sheds light on their role in CRC, the broader implications of the metabolic regulation of these miRNAs in other tumour types remain to be fully explored. Further investigation into how metabolic disruption impacts other tumours may unveil novel therapeutic avenues for diverse cancer types.
While our initial transcriptomic analysis was centred on a specific CRC cell line that represents tumours with microsatellite instability, it is noteworthy that the findings were validated across various CRC cell lines with differing genotypes. Such replication across different cellular contexts not only enhances the robustness and reliability of our results but also underscores the generalisability of the identified mechanisms.
A notable limitation of our study is that the experiments were conducted using a high-glucose medium. While this medium is commonly used for cell culture, it does not fully represent the physiological nutrient environment encountered by cells in vivo. Therefore, to better mimic the conditions encountered by tumours in situ, it would be valuable to replicate our experiments using media that more closely resemble physiological nutrient levels.
Altogether, these results combined with previous studies conclude that metformin exerts its anti-cancer properties in part through inducing miRNAs such as miR-2110, miR-132-3p, miR-222-3p and miR-589-3p to directly target genes including PIK3R3 and STMN1, and thereby regulates signalling pathways such as PI3K-Akt and MAPK/ERK.
While the roles of PIK3R3 and STMN1 and their regulation are well described, this study uncovers a novel mode of regulation of these genes at the post-transcriptional level. These findings highlight the potential for developing RNA therapeutics. Moving forward, further investigations are warranted to elucidate the clinical implications and therapeutic opportunities stemming from these discoveries, paving the way for targeted interventions in CRC management.

5. Conclusions

In summary, this study highlights a mechanism by which metformin regulates signalling pathways, including PI3K-Akt and MAPK/ERK, through direct miRNA inhibition of genes encoding pathway components and effectors. In particular, metformin upregulated miR-2110 and miR-132-3p to directly target PIK3R3 and, consequently, modulate the PI3K-mTOR pathway and suppress CRC cell proliferation and cell cycle progression. Similarly, STMN1 was targeted by upregulated miR-222-3p and miR-589-3p, and its knockdown resulted in cell growth suppression and a delayed cell cycle.
These findings provide new insights into the molecular mechanisms of metformin activity that are responsible for reduced proliferation in CRC cells. With the emergence of RNA therapeutics, future studies are required to explore the clinical utility of these findings.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/cancers16112055/s1, Figure S1: Pairwise correlation between the differentially expressed genes obtained from total RNA sequencing and targeted RNA panel sequencing. Figure S2: THBS1 gene expression changes associated with exogenous overexpression of miR-590-3p were assessed by real-time RT-PCR and compared with NC mimic. Figure S3: Gene expression changes associated with exogenous overexpression of selected miRNA were assessed by real-time RT-PCR and compared with NC mimic. Figure S4: Original Western Blots. Table S1: Differentially expressed miRNAs associated with 2.5 mM metformin treatment of HCT116 cells and compared with control medium. Table S2: Differentially expressed protein-coding genes associated with 2.5 mM metformin treatment of HCT116 cells and compared with control medium. Table S3: Differentially expressed protein-coding genes from the QIAseq Targeted RNA Panel (human apoptosis and cell death pathway finder RHS-002Z) associated with 2.5 mM metformin treatment of HCT116 cells and compared with control medium. Table S4: Predicted and validated miRNA–mRNA targets showing anti-correlation in expression changes associated with 2.5 mM metformin treatment of CRC cells. Table S5: Enriched KEGG pathways overrepresented with metformin treatment of HCT116. Table S6: miRNA–target gene pairs identified within PI3K-Akt and MAPK pathway. Table S7: Supplementary material and methods.

Author Contributions

A.O. was involved in conceptualisation, project administration, data generation and manuscript writing. R.A.M. was involved in funding acquisition, resources and manuscript review. M.Z.M. and J.P. were involved in conceptualisation, project supervision, resources, manuscript editing and funding acquisition. S.M. was involved in bioinformatic analyses of the data. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by Tour de Cure (Australia) and Flinders Foundation funding. A.O. was supported by the Australian Research Training Program. J.P. was supported by a National Health and Medical Research Council (NHMRC) Ideas grant (GNT2012373) and the Australian Research Council (DP220103531). R.A.M. was supported by the Cancer Council (South Australia) Beat Cancer Project.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Processed data are available in Supplementary Files. The raw transcriptome and small RNA sequencing data are available upon request.

Acknowledgments

The authors thank Darling Rojas-Canales (Flinders University, Adelaide, Australia) for help with flow cytometry.

Conflicts of Interest

The authors declare no conflicts of interest.

References

  1. Zhou, G.; Myers, R.; Li, Y.; Chen, Y.; Shen, X.; Fenyk-Melody, J.; Wu, M.; Ventre, J.; Doebber, T.; Fujii, N.; et al. Role of AMP-activated protein kinase in mechanism of metformin action. J. Clin. Investig. 2001, 108, 1167–1174. [Google Scholar] [CrossRef] [PubMed]
  2. Kalender, A.; Selvaraj, A.; Kim, S.Y.; Gulati, P.; Brûlé, S.; Viollet, B.; Kemp, B.E.; Bardeesy, N.; Dennis, P.; Schlager, J.J.; et al. Metformin, independent of AMPK, inhibits mTORC1 in a rag GTPase-dependent manner. Cell Metab. 2010, 11, 390–401. [Google Scholar] [CrossRef] [PubMed]
  3. Pierotti, M.A.; Berrino, F.; Gariboldi, M.; Melani, C.; Mogavero, A.; Negri, T.; Pasanisi, P.; Pilotti, S. Targeting metabolism for cancer treatment and prevention: Metformin, an old drug with multi-faceted effects. Oncogene 2013, 32, 1475–1487. [Google Scholar] [CrossRef] [PubMed]
  4. Hirsch, H.A.; Iliopoulos, D.; Struhl, K. Metformin inhibits the inflammatory response associated with cellular transformation and cancer stem cell growth. Proc. Natl. Acad. Sci. USA 2013, 110, 972–977. [Google Scholar] [CrossRef]
  5. Hirsch, H.A.; Iliopoulos, D.; Tsichlis, P.N.; Struhl, K. Metformin selectively targets cancer stem cells, and acts together with chemotherapy to block tumor growth and prolong remission. Cancer Res. 2009, 69, 7507–7511. [Google Scholar] [CrossRef] [PubMed]
  6. Tomimoto, A.; Endo, H.; Sugiyama, M.; Fujisawa, T.; Hosono, K.; Takahashi, H.; Nakajima, N.; Nagashima, Y.; Wada, K.; Nakagama, H.; et al. Metformin suppresses intestinal polyp growth in ApcMin/+ mice. Cancer Sci. 2008, 99, 2136–2141. [Google Scholar] [CrossRef] [PubMed]
  7. Bragagnoli, A.C.; Araujo, R.L.C.; Ferraz, M.W.; Dos Santos, L.V.; Abdalla, K.C.; Comar, F.; Santos, F.A.; Oliveira, M.A.; Carvalheira, J.B.C.; Cárcano, F.M.; et al. Metformin plus lrinotecan in patients with refractory colorectal cancer: A phase 2 clinical trial. Br. J. Cancer 2021, 124, 1072–1078. [Google Scholar] [CrossRef] [PubMed]
  8. Singh, A.R.; Gu, J.J.; Zhang, Q.; Torka, P.; Sundaram, S.; Mavis, C.; Hernandez-Ilizaliturri, F.J. Metformin sensitizes therapeutic agents and improves outcome in pre-clinical and clinical diffuse large B-cell lymphoma. Cancer Metab. 2020, 8, 10. [Google Scholar] [CrossRef] [PubMed]
  9. Rocha, G.Z.; Dias, M.M.; Ropelle, E.R.; Osório-Costa, F.; Rossato, F.A.; Vercesi, A.E.; Saad, M.J.; Carvalheira, J.B. Metformin amplifies chemotherapy-induced AMPK activation and antitumoral growth. Clin. Cancer Res. Off. J. Am. Assoc. Cancer Res. 2011, 17, 3993–4005. [Google Scholar] [CrossRef]
  10. Wang, J.L.; Lan, Y.W.; Tsai, Y.T.; Chen, Y.C.; Staniczek, T.; Tsou, Y.A.; Yen, C.C.; Chen, C.M. Additive Antiproliferative and Antiangiogenic Effects of Metformin and Pemetrexed in a Non-Small-Cell Lung Cancer Xenograft Model. Front. Cell Dev. Biol. 2021, 9, 688062. [Google Scholar] [CrossRef]
  11. Yang, J.; Nie, J.; Ma, X.; Wei, Y.; Peng, Y.; Wei, X. Targeting PI3K in cancer: Mechanisms and advances in clinical trials. Mol. Cancer 2019, 18, 26. [Google Scholar] [CrossRef]
  12. Zhang, W.; Liu, H.T. MAPK signal pathways in the regulation of cell proliferation in mammalian cells. Cell Res. 2002, 12, 9–18. [Google Scholar] [CrossRef] [PubMed]
  13. Miyoshi, H.; Kato, K.; Iwama, H.; Maeda, E.; Sakamoto, T.; Fujita, K.; Toyota, Y.; Tani, J.; Nomura, T.; Mimura, S.; et al. Effect of the anti-diabetic drug metformin in hepatocellular carcinoma in vitro and in vivo. Int. J. Oncol. 2014, 45, 322–332. [Google Scholar] [CrossRef] [PubMed]
  14. Li, W.; Yuan, Y.; Huang, L.; Qiao, M.; Zhang, Y. Metformin alters the expression profiles of microRNAs in human pancreatic cancer cells. Diabetes Res. Clin. Pract. 2012, 96, 187–195. [Google Scholar] [CrossRef] [PubMed]
  15. Kobayashi, M.; Kato, K.; Iwama, H.; Fujihara, S.; Nishiyama, N.; Mimura, S.; Toyota, Y.; Nomura, T.; Nomura, K.; Tani, J.; et al. Antitumor effect of metformin in esophageal cancer: In vitro study. Int. J. Oncol. 2013, 42, 517–524. [Google Scholar] [CrossRef] [PubMed]
  16. Kato, K.; Gong, J.; Iwama, H.; Kitanaka, A.; Tani, J.; Miyoshi, H.; Nomura, K.; Mimura, S.; Kobayashi, M.; Aritomo, Y.; et al. The antidiabetic drug metformin inhibits gastric cancer cell proliferation in vitro and in vivo. Mol. Cancer Ther. 2012, 11, 549–560. [Google Scholar] [CrossRef] [PubMed]
  17. Avci, C.B.; Harman, E.; Dodurga, Y.; Susluer, S.Y.; Gunduz, C. Therapeutic potential of an anti-diabetic drug, metformin: Alteration of miRNA expression in prostate cancer cells. Asian Pac. J. Cancer Prev. APJCP 2013, 14, 765–768. [Google Scholar] [CrossRef] [PubMed]
  18. Dobin, A.; Davis, C.A.; Schlesinger, F.; Drenkow, J.; Zaleski, C.; Jha, S.; Batut, P.; Chaisson, M.; Gingeras, T.R. STAR: Ultrafast universal RNA-seq aligner. Bioinformatics 2013, 29, 15–21. [Google Scholar] [CrossRef] [PubMed]
  19. Li, H.; Handsaker, B.; Wysoker, A.; Fennell, T.; Ruan, J.; Homer, N.; Marth, G.; Abecasis, G.; Durbin, R. The Sequence Alignment/Map format and SAMtools. Bioinformatics 2009, 25, 2078–2079. [Google Scholar] [CrossRef]
  20. Anders, S.; Pyl, P.T.; Huber, W. HTSeq—A Python framework to work with high-throughput sequencing data. Bioinformatics 2015, 31, 166–169. [Google Scholar] [CrossRef]
  21. Love, M.I.; Huber, W.; Anders, S. Moderated estimation of fold change and dispersion for RNA-seq data with DESeq2. Genome Biol. 2014, 15, 550. [Google Scholar] [CrossRef] [PubMed]
  22. Hsu, S.D.; Lin, F.M.; Wu, W.Y.; Liang, C.; Huang, W.C.; Chan, W.L.; Tsai, W.T.; Chen, G.Z.; Lee, C.J.; Chiu, C.M.; et al. miRTarBase: A database curates experimentally validated microRNA-target interactions. Nucleic Acids Res. 2011, 39, D163–D169. [Google Scholar] [CrossRef] [PubMed]
  23. Xiao, F.; Zuo, Z.; Cai, G.; Kang, S.; Gao, X.; Li, T. miRecords: An integrated resource for microRNA-target interactions. Nucleic Acids Res. 2009, 37, D105–D110. [Google Scholar] [CrossRef] [PubMed]
  24. Agarwal, V.; Bell, G.W.; Nam, J.W.; Bartel, D.P. Predicting effective microRNA target sites in mammalian mRNAs. eLife 2015, 4, e05005. [Google Scholar] [CrossRef] [PubMed]
  25. Vejnar, C.E.; Zdobnov, E.M. MiRmap: Comprehensive prediction of microRNA target repression strength. Nucleic Acids Res. 2012, 40, 11673–11683. [Google Scholar] [CrossRef] [PubMed]
  26. Wong, N.; Wang, X. miRDB: An online resource for microRNA target prediction and functional annotations. Nucleic Acids Res. 2015, 43, D146–D152. [Google Scholar] [CrossRef] [PubMed]
  27. Paraskevopoulou, M.D.; Georgakilas, G.; Kostoulas, N.; Vlachos, I.S.; Vergoulis, T.; Reczko, M.; Filippidis, C.; Dalamagas, T.; Hatzigeorgiou, A.G. DIANA-microT web server v5.0: Service integration into miRNA functional analysis workflows. Nucleic Acids Res. 2013, 41, W169–W173. [Google Scholar] [CrossRef] [PubMed]
  28. John, B.; Enright, A.J.; Aravin, A.; Tuschl, T.; Sander, C.; Marks, D.S. Human MicroRNA targets. PLoS Biol. 2004, 2, e363. [Google Scholar] [CrossRef] [PubMed]
  29. Breuer, K.; Foroushani, A.K.; Laird, M.R.; Chen, C.; Sribnaia, A.; Lo, R.; Winsor, G.L.; Hancock, R.E.; Brinkman, F.S.; Lynn, D.J. InnateDB: Systems biology of innate immunity and beyond--recent updates and continuing curation. Nucleic Acids Res 2013, 41, D1228–D1233. [Google Scholar] [CrossRef]
  30. Shannon, P.; Markiel, A.; Ozier, O.; Baliga, N.S.; Wang, J.T.; Ramage, D.; Amin, N.; Schwikowski, B.; Ideker, T. Cytoscape: A software environment for integrated models of biomolecular interaction networks. Genome Res. 2003, 13, 2498–2504. [Google Scholar] [CrossRef]
  31. Assenov, Y.; Ramirez, F.; Schelhorn, S.E.; Lengauer, T.; Albrecht, M. Computing topological parameters of biological networks. Bioinformatics 2008, 24, 282–284. [Google Scholar] [CrossRef] [PubMed]
  32. Bindea, G.; Mlecnik, B.; Hackl, H.; Charoentong, P.; Tosolini, M.; Kirilovsky, A.; Fridman, W.H.; Pages, F.; Trajanoski, Z.; Galon, J. ClueGO: A Cytoscape plug-in to decipher functionally grouped gene ontology and pathway annotation networks. Bioinformatics 2009, 25, 1091–1093. [Google Scholar] [CrossRef]
  33. Choi, W.Y.; Giraldez, A.J.; Schier, A.F. Target protectors reveal dampening and balancing of Nodal agonist and antagonist by miR-430. Science 2007, 318, 271–274. [Google Scholar] [CrossRef] [PubMed]
  34. Orang, A.; Ali, S.R.; Petersen, J.; McKinnon, R.A.; Aloia, A.L.; Michael, M.Z. A functional screen with metformin identifies microRNAs that regulate metabolism in colorectal cancer cells. Sci. Rep. 2022, 12, 2889. [Google Scholar] [CrossRef] [PubMed]
  35. Bailey, C.J.; Wilcock, C.; Scarpello, J.H. Metformin and the intestine. Diabetologia 2008, 51, 1552–1553. [Google Scholar] [CrossRef] [PubMed]
  36. Liu, K.; Li, X.; Cao, Y.; Ge, Y.; Wang, J.; Shi, B. MiR-132 inhibits cell proliferation, invasion and migration of hepatocellular carcinoma by targeting PIK3R3. Int. J. Oncol. 2015, 47, 1585–1593, Retraction in:/10.3892/ijo.2021.5238. [Google Scholar] [CrossRef] [PubMed]
  37. Staton, A.A.; Giraldez, A.J. Use of target protector morpholinos to analyze the physiological roles of specific miRNA-mRNA pairs in vivo. Nat. Protoc. 2011, 6, 2035–2049. [Google Scholar] [CrossRef] [PubMed]
  38. Musi, N.; Hirshman, M.F.; Nygren, J.; Svanfeldt, M.; Bavenholm, P.; Rooyackers, O.; Zhou, G.; Williamson, J.M.; Ljunqvist, O.; Efendic, S.; et al. Metformin increases AMP-activated protein kinase activity in skeletal muscle of subjects with type 2 diabetes. Diabetes 2002, 51, 2074–2081. [Google Scholar] [CrossRef] [PubMed]
  39. Petroulakis, E.; Mamane, Y.; Le Bacquer, O.; Shahbazian, D.; Sonenberg, N. mTOR signaling: Implications for cancer and anticancer therapy. Br. J. Cancer 2006, 94, 195–199. [Google Scholar] [CrossRef]
  40. Magnuson, B.; Ekim, B.; Fingar, D.C. Regulation and function of ribosomal protein S6 kinase (S6K) within mTOR signalling networks. Biochem. J. 2012, 441, 1–21. [Google Scholar] [CrossRef]
  41. Slattery, M.L.; Wolff, E.; Hoffman, M.D.; Pellatt, D.F.; Milash, B.; Wolff, R.K. MicroRNAs and colon and rectal cancer: Differential expression by tumor location and subtype. Genes Chromosomes Cancer 2011, 50, 196–206. [Google Scholar] [CrossRef] [PubMed]
  42. Michael, M.Z.; SM, O.C.; van Holst Pellekaan, N.G.; Young, G.P.; James, R.J. Reduced accumulation of specific microRNAs in colorectal neoplasia. Mol. Cancer Res. MCR 2003, 1, 882–891. [Google Scholar] [PubMed]
  43. Lu, J.; Getz, G.; Miska, E.A.; Alvarez-Saavedra, E.; Lamb, J.; Peck, D.; Sweet-Cordero, A.; Ebert, B.L.; Mak, R.H.; Ferrando, A.A.; et al. MicroRNA expression profiles classify human cancers. Nature 2005, 435, 834–838. [Google Scholar] [CrossRef] [PubMed]
  44. Cummins, J.M.; He, Y.; Leary, R.J.; Pagliarini, R.; Diaz, L.A., Jr.; Sjoblom, T.; Barad, O.; Bentwich, Z.; Szafranska, A.E.; Labourier, E.; et al. The colorectal microRNAome. Proc. Natl. Acad. Sci. USA 2006, 103, 3687–3692. [Google Scholar] [CrossRef] [PubMed]
  45. Udhane, S.S.; Legeza, B.; Marti, N.; Hertig, D.; Diserens, G.; Nuoffer, J.M.; Vermathen, P.; Fluck, C.E. Combined transcriptome and metabolome analyses of metformin effects reveal novel links between metabolic networks in steroidogenic systems. Sci. Rep. 2017, 7, 8652. [Google Scholar] [CrossRef] [PubMed]
  46. Hess, C.; Unger, M.; Madea, B.; Stratmann, B.; Tschoepe, D. Range of therapeutic metformin concentrations in clinical blood samples and comparison to a forensic case with death due to lactic acidosis. Forensic Sci. Int. 2018, 286, 106–112. [Google Scholar] [CrossRef]
  47. Paleari, L.; Burhenne, J.; Weiss, J.; Foersch, S.; Roth, W.; Parodi, A.; Gnant, M.; Bachleitner-Hofmann, T.; Scherer, D.; Ulrich, C.M.; et al. High Accumulation of Metformin in Colonic Tissue of Subjects With Diabetes or the Metabolic Syndrome. Gastroenterology 2018, 154, 1543–1545. [Google Scholar] [CrossRef] [PubMed]
  48. Gaedcke, J.; Grade, M.; Camps, J.; Sokilde, R.; Kaczkowski, B.; Schetter, A.J.; Difilippantonio, M.J.; Harris, C.C.; Ghadimi, B.M.; Moller, S.; et al. The rectal cancer microRNAome—microRNA expression in rectal cancer and matched normal mucosa. Clin. Cancer Res. Off. J. Am. Assoc. Cancer Res. 2012, 18, 4919–4930. [Google Scholar] [CrossRef] [PubMed]
  49. Falzone, L.; Scola, L.; Zanghi, A.; Biondi, A.; Di Cataldo, A.; Libra, M.; Candido, S. Integrated analysis of colorectal cancer microRNA datasets: Identification of microRNAs associated with tumor development. Aging 2018, 10, 1000–1014. [Google Scholar] [CrossRef]
  50. Zhao, Z.; Ma, X.; Hsiao, T.H.; Lin, G.; Kosti, A.; Yu, X.; Suresh, U.; Chen, Y.; Tomlinson, G.E.; Pertsemlidis, A.; et al. A high-content morphological screen identifies novel microRNAs that regulate neuroblastoma cell differentiation. Oncotarget 2014, 5, 2499–2512. [Google Scholar] [CrossRef]
  51. Zhao, Z.; Partridge, V.; Sousares, M.; Shelton, S.D.; Holland, C.L.; Pertsemlidis, A.; Du, L. microRNA-2110 functions as an onco-suppressor in neuroblastoma by directly targeting Tsukushi. PLoS ONE 2018, 13, e0208777. [Google Scholar] [CrossRef] [PubMed]
  52. Zhao, Z.; Ma, X.; Shelton, S.D.; Sung, D.C.; Li, M.; Hernandez, D.; Zhang, M.; Losiewicz, M.D.; Chen, Y.; Pertsemlidis, A.; et al. A combined gene expression and functional study reveals the crosstalk between N-Myc and differentiation-inducing microRNAs in neuroblastoma cells. Oncotarget 2016, 7, 79372–79387. [Google Scholar] [CrossRef] [PubMed]
  53. Salendo, J.; Spitzner, M.; Kramer, F.; Zhang, X.; Jo, P.; Wolff, H.A.; Kitz, J.; Kaulfuss, S.; Beissbarth, T.; Dobbelstein, M.; et al. Identification of a microRNA expression signature for chemoradiosensitivity of colorectal cancer cells, involving miRNAs-320a, -224, -132 and let7g. Radiother. Oncol. J. Eur. Soc. Ther. Radiol. Oncol. 2013, 108, 451–457. [Google Scholar] [CrossRef] [PubMed]
  54. Mokutani, Y.; Uemura, M.; Munakata, K.; Okuzaki, D.; Haraguchi, N.; Takahashi, H.; Nishimura, J.; Hata, T.; Murata, K.; Takemasa, I.; et al. Down-Regulation of microRNA-132 is Associated with Poor Prognosis of Colorectal Cancer. Ann. Surg. Oncol. 2016, 23, 599–608. [Google Scholar] [CrossRef] [PubMed]
  55. Song, H.; He, P.; Shao, T.; Li, Y.; Li, J.; Zhang, Y. Long non-coding RNA XIST functions as an oncogene in human colorectal cancer by targeting miR-132-3p. J. BUON. Off. J. Balk. Union Oncol. 2017, 22, 696–703. [Google Scholar]
  56. Zheng, Y.B.; Luo, H.P.; Shi, Q.; Hao, Z.N.; Ding, Y.; Wang, Q.S.; Li, S.B.; Xiao, G.C.; Tong, S.L. miR-132 inhibits colorectal cancer invasion and metastasis via directly targeting ZEB2. World J. Gastroenterol. 2014, 20, 6515–6522. [Google Scholar] [CrossRef]
  57. Qin, J.; Ke, J.; Xu, J.; Wang, F.; Zhou, Y.; Jiang, Y.; Wang, Z. Downregulation of microRNA-132 by DNA hypermethylation is associated with cell invasion in colorectal cancer. OncoTargets Ther. 2015, 8, 3639–3648. [Google Scholar] [CrossRef]
  58. Liu, Z.; Wang, H.; Cai, H.; Hong, Y.; Li, Y.; Su, D.; Fan, Z. Long non-coding RNA MIAT promotes growth and metastasis of colorectal cancer cells through regulation of miR-132/Derlin-1 pathway. Cancer Cell Int. 2018, 18, 59. [Google Scholar] [CrossRef] [PubMed]
  59. Zhang, M.; Li, Y.; Wang, H.; Yu, W.; Lin, S.; Guo, J. LncRNA SNHG5 affects cell proliferation, metastasis and migration of colorectal cancer through regulating miR-132-3p/CREB5. Cancer Biol. Ther. 2019, 20, 524–536. [Google Scholar] [CrossRef] [PubMed]
  60. Greenwell, I.B.; Flowers, C.R.; Blum, K.A.; Cohen, J.B. Clinical use of PI3K inhibitors in B-cell lymphoid malignancies: Today and tomorrow. Expert Rev. Anticancer Ther. 2017, 17, 271–279. [Google Scholar] [CrossRef]
  61. Thorpe, L.M.; Yuzugullu, H.; Zhao, J.J. PI3K in cancer: Divergent roles of isoforms, modes of activation and therapeutic targeting. Nat. Rev. Cancer 2015, 15, 7–24. [Google Scholar] [CrossRef] [PubMed]
  62. Dhillon, A.S.; Hagan, S.; Rath, O.; Kolch, W. MAP kinase signalling pathways in cancer. Oncogene 2007, 26, 3279–3290. [Google Scholar] [CrossRef] [PubMed]
  63. Felli, N.; Fontana, L.; Pelosi, E.; Botta, R.; Bonci, D.; Facchiano, F.; Liuzzi, F.; Lulli, V.; Morsilli, O.; Santoro, S.; et al. MicroRNAs 221 and 222 inhibit normal erythropoiesis and erythroleukemic cell growth via kit receptor down-modulation. Proc. Natl. Acad. Sci. USA 2005, 102, 18081–18086. [Google Scholar] [CrossRef] [PubMed]
  64. Ciafre, S.A.; Galardi, S.; Mangiola, A.; Ferracin, M.; Liu, C.G.; Sabatino, G.; Negrini, M.; Maira, G.; Croce, C.M.; Farace, M.G. Extensive modulation of a set of microRNAs in primary glioblastoma. Biochem. Biophys. Res. Commun. 2005, 334, 1351–1358. [Google Scholar] [CrossRef] [PubMed]
  65. Stinson, S.; Lackner, M.R.; Adai, A.T.; Yu, N.; Kim, H.J.; O’Brien, C.; Spoerke, J.; Jhunjhunwala, S.; Boyd, Z.; Januario, T.; et al. TRPS1 targeting by miR-221/222 promotes the epithelial-to-mesenchymal transition in breast cancer. Sci. Signal. 2011, 4, ra41. [Google Scholar] [CrossRef] [PubMed]
  66. Galardi, S.; Mercatelli, N.; Giorda, E.; Massalini, S.; Frajese, G.V.; Ciafre, S.A.; Farace, M.G. miR-221 and miR-222 expression affects the proliferation potential of human prostate carcinoma cell lines by targeting p27Kip1. J. Biol. Chem. 2007, 282, 23716–23724. [Google Scholar] [CrossRef] [PubMed]
  67. Kobayashi, M.; Saito, A.; Tanaka, Y.; Michishita, M.; Kobayashi, M.; Irimajiri, M.; Kaneda, T.; Ochiai, K.; Bonkobara, M.; Takahashi, K.; et al. MicroRNA expression profiling in canine prostate cancer. J. Vet. Med. Sci. 2017, 79, 719–725. [Google Scholar] [CrossRef] [PubMed]
  68. Shah, M.Y.; Calin, G.A. MicroRNAs miR-221 and miR-222: A new level of regulation in aggressive breast cancer. Genome Med. 2011, 3, 56. [Google Scholar] [CrossRef] [PubMed]
  69. O’Hara, A.J.; Wang, L.; Dezube, B.J.; Harrington, W.J., Jr.; Damania, B.; Dittmer, D.P. Tumor suppressor microRNAs are underrepresented in primary effusion lymphoma and Kaposi sarcoma. Blood 2009, 113, 5938–5941. [Google Scholar] [CrossRef]
  70. Howe, E.N.; Cochrane, D.R.; Richer, J.K. The miR-200 and miR-221/222 microRNA families: Opposing effects on epithelial identity. J. Mammary Gland Biol. Neoplasia 2012, 17, 65–77. [Google Scholar] [CrossRef]
  71. Fornari, F.; Gramantieri, L.; Ferracin, M.; Veronese, A.; Sabbioni, S.; Calin, G.A.; Grazi, G.L.; Giovannini, C.; Croce, C.M.; Bolondi, L.; et al. MiR-221 controls CDKN1C/p57 and CDKN1B/p27 expression in human hepatocellular carcinoma. Oncogene 2008, 27, 5651–5661. [Google Scholar] [CrossRef] [PubMed]
  72. Kim, Y.K.; Yu, J.; Han, T.S.; Park, S.Y.; Namkoong, B.; Kim, D.H.; Hur, K.; Yoo, M.W.; Lee, H.J.; Yang, H.K.; et al. Functional links between clustered microRNAs: Suppression of cell-cycle inhibitors by microRNA clusters in gastric cancer. Nucleic Acids Res. 2009, 37, 1672–1681. [Google Scholar] [CrossRef] [PubMed]
  73. Medina, R.; Zaidi, S.K.; Liu, C.G.; Stein, J.L.; van Wijnen, A.J.; Croce, C.M.; Stein, G.S. MicroRNAs 221 and 222 bypass quiescence and compromise cell survival. Cancer Res. 2008, 68, 2773–2780. [Google Scholar] [CrossRef] [PubMed]
  74. Fuse, M.; Kojima, S.; Enokida, H.; Chiyomaru, T.; Yoshino, H.; Nohata, N.; Kinoshita, T.; Sakamoto, S.; Naya, Y.; Nakagawa, M.; et al. Tumor suppressive microRNAs (miR-222 and miR-31) regulate molecular pathways based on microRNA expression signature in prostate cancer. J. Hum. Genet. 2012, 57, 691–699. [Google Scholar] [CrossRef]
  75. Yamashita, R.; Sato, M.; Kakumu, T.; Hase, T.; Yogo, N.; Maruyama, E.; Sekido, Y.; Kondo, M.; Hasegawa, Y. Growth inhibitory effects of miR-221 and miR-222 in non-small cell lung cancer cells. Cancer Med. 2015, 4, 551–564. [Google Scholar] [CrossRef] [PubMed]
  76. Forrest, A.R.; Kanamori-Katayama, M.; Tomaru, Y.; Lassmann, T.; Ninomiya, N.; Takahashi, Y.; de Hoon, M.J.; Kubosaki, A.; Kaiho, A.; Suzuki, M.; et al. Induction of microRNAs, mir-155, mir-222, mir-424 and mir-503, promotes monocytic differentiation through combinatorial regulation. Leukemia 2010, 24, 460–466. [Google Scholar] [CrossRef]
  77. Cesarini, V.; Silvestris, D.A.; Tassinari, V.; Tomaselli, S.; Alon, S.; Eisenberg, E.; Locatelli, F.; Gallo, A. ADAR2/miR-589-3p axis controls glioblastoma cell migration/invasion. Nucleic Acids Res. 2018, 46, 2045–2059. [Google Scholar] [CrossRef] [PubMed]
  78. Lu, A.; Wang, Z.; Wang, S. Role of miR-589-3p in human lumbar disc degeneration and its potential mechanism. Exp. Ther. Med. 2018, 15, 1616–1621. [Google Scholar] [CrossRef]
  79. Niethammer, P.; Bastiaens, P.; Karsenti, E. Stathmin-tubulin interaction gradients in motile and mitotic cells. Science 2004, 303, 1862–1866. [Google Scholar] [CrossRef]
  80. Borghese, L.; Fletcher, G.; Mathieu, J.; Atzberger, A.; Eades, W.C.; Cagan, R.L.; Rorth, P. Systematic analysis of the transcriptional switch inducing migration of border cells. Dev. Cell 2006, 10, 497–508. [Google Scholar] [CrossRef]
  81. Wang, J.; Yao, Y.; Ming, Y.; Shen, S.; Wu, N.; Liu, J.; Liu, H.; Suo, T.; Pan, H.; Zhang, D.; et al. Downregulation of stathmin 1 in human gallbladder carcinoma inhibits tumor growth in vitro and in vivo. Sci. Rep. 2016, 6, 28833. [Google Scholar] [CrossRef] [PubMed]
  82. Belletti, B.; Nicoloso, M.S.; Schiappacassi, M.; Berton, S.; Lovat, F.; Wolf, K.; Canzonieri, V.; D’Andrea, S.; Zucchetto, A.; Friedl, P.; et al. Stathmin activity influences sarcoma cell shape, motility, and metastatic potential. Mol. Biol. Cell 2008, 19, 2003–2013. [Google Scholar] [CrossRef]
  83. Bieche, I.; Lachkar, S.; Becette, V.; Cifuentes-Diaz, C.; Sobel, A.; Lidereau, R.; Curmi, P.A. Overexpression of the stathmin gene in a subset of human breast cancer. Br. J. Cancer 1998, 78, 701–709. [Google Scholar] [CrossRef] [PubMed]
  84. Singer, S.; Ehemann, V.; Brauckhoff, A.; Keith, M.; Vreden, S.; Schirmacher, P.; Breuhahn, K. Protumorigenic overexpression of stathmin/Op18 by gain-of-function mutation in p53 in human hepatocarcinogenesis. Hepatology 2007, 46, 759–768. [Google Scholar] [CrossRef]
  85. Chen, G.; Wang, H.; Gharib, T.G.; Huang, C.C.; Thomas, D.G.; Shedden, K.A.; Kuick, R.; Taylor, J.M.; Kardia, S.L.; Misek, D.E.; et al. Overexpression of oncoprotein 18 correlates with poor differentiation in lung adenocarcinomas. Mol. Cell. Proteom. MCP 2003, 2, 107–116. [Google Scholar] [CrossRef]
  86. Friedrich, B.; Gronberg, H.; Landstrom, M.; Gullberg, M.; Bergh, A. Differentiation-stage specific expression of oncoprotein 18 in human and rat prostatic adenocarcinoma. Prostate 1995, 27, 102–109. [Google Scholar] [CrossRef]
  87. Abal, M.; Obrador-Hevia, A.; Janssen, K.P.; Casadome, L.; Menendez, M.; Carpentier, S.; Barillot, E.; Wagner, M.; Ansorge, W.; Moeslein, G.; et al. APC inactivation associates with abnormal mitosis completion and concomitant BUB1B/MAD2L1 up-regulation. Gastroenterology 2007, 132, 2448–2458. [Google Scholar] [CrossRef] [PubMed]
  88. Liu, Z.; Lu, H.; Shi, H.; Du, Y.; Yu, J.; Gu, S.; Chen, X.; Liu, K.J.; Hu, C.A. PUMA overexpression induces reactive oxygen species generation and proteasome-mediated stathmin degradation in colorectal cancer cells. Cancer Res. 2005, 65, 1647–1654. [Google Scholar] [CrossRef]
  89. Golouh, R.; Cufer, T.; Sadikov, A.; Nussdorfer, P.; Usher, P.A.; Brunner, N.; Schmitt, M.; Lesche, R.; Maier, S.; Timmermans, M.; et al. The prognostic value of Stathmin-1, S100A2, and SYK proteins in ER-positive primary breast cancer patients treated with adjuvant tamoxifen monotherapy: An immunohistochemical study. Breast Cancer Res. Treat. 2008, 110, 317–326. [Google Scholar] [CrossRef]
  90. Ngo, T.T.; Peng, T.; Liang, X.J.; Akeju, O.; Pastorino, S.; Zhang, W.; Kotliarov, Y.; Zenklusen, J.C.; Fine, H.A.; Maric, D.; et al. The 1p-encoded protein stathmin and resistance of malignant gliomas to nitrosoureas. J. Natl. Cancer Inst. 2007, 99, 639–652. [Google Scholar] [CrossRef]
  91. Yuan, R.H.; Jeng, Y.M.; Chen, H.L.; Lai, P.L.; Pan, H.W.; Hsieh, F.J.; Lin, C.Y.; Lee, P.H.; Hsu, H.C. Stathmin overexpression cooperates with p53 mutation and osteopontin overexpression, and is associated with tumour progression, early recurrence, and poor prognosis in hepatocellular carcinoma. J. Pathol. 2006, 209, 549–558. [Google Scholar] [CrossRef] [PubMed]
  92. Marklund, U.; Brattsand, G.; Shingler, V.; Gullberg, M. Serine 25 of oncoprotein 18 is a major cytosolic target for the mitogen-activated protein kinase. J. Biol. Chem. 1993, 268, 15039–15047. [Google Scholar] [CrossRef] [PubMed]
  93. Han, G.; Wu, Z.; Zhao, N.; Zhou, L.; Liu, F.; Niu, F.; Xu, Y.; Zhao, X. Overexpression of stathmin plays a pivotal role in the metastasis of esophageal squamous cell carcinoma. Oncotarget 2017, 8, 61742–61760. [Google Scholar] [CrossRef] [PubMed]
  94. Leiphrakpam, P.D.; Lazenby, A.J.; Smith, L.M.; Brattain, M.G.; Are, C. Stathmin expression in metastatic colorectal cancer. J. Surg. Oncol. 2021, 123, 1764–1772. [Google Scholar] [CrossRef] [PubMed]
  95. Suzuki, K.; Watanabe, A.; Araki, K.; Yokobori, T.; Harimoto, N.; Gantumur, D.; Hagiwara, K.; Yamanaka, T.; Ishii, N.; Tsukagoshi, M.; et al. High STMN1 Expression Is Associated with Tumor Differentiation and Metastasis in Clinical Patients with Pancreatic Cancer. Anticancer Res. 2018, 38, 939–944. [Google Scholar] [CrossRef]
  96. Ikeda, Y.; Tanji, E.; Makino, N.; Kawata, S.; Furukawa, T. MicroRNAs associated with mitogen-activated protein kinase in human pancreatic cancer. Mol. Cancer Res. MCR 2012, 10, 259–269. [Google Scholar] [CrossRef]
  97. Baldassarre, G.; Belletti, B.; Nicoloso, M.S.; Schiappacassi, M.; Vecchione, A.; Spessotto, P.; Morrione, A.; Canzonieri, V.; Colombatti, A. p27(Kip1)-stathmin interaction influences sarcoma cell migration and invasion. Cancer Cell 2005, 7, 51–63. [Google Scholar] [CrossRef]
Cancers 16 02055 g001
Figure 1. Metformin induces gene and miRNA expression changes affecting miRNA-based networks in colorectal cancer cells. (A) Volcano plots for transcriptome and small RNA profiling of HCT116 cells treated with 2.5 mM metformin are shown. (i) Protein-coding genes and (ii) miRNAs that were identified by sequencing are shown. Red dots represent differentially expressed genes/miRNAs, while those in black represent no significant changes. Advaita iPathway Guide tool was used to generate the plot. Y axis represents log10 (p value), and x axis represents log2 fold change. Differentially expressed mRNAs and miRNAs were identified with thresholds set at p ≤ 0.05 and 1 ≤ log2 fold change ≤ −1. (B) miRNA-based network affected by metformin treatment of colorectal cancer cells is shown. This is an organic layout of the integrated network associated with 2.5 mM metformin treatment of HCT116 cells. Protein–protein interactions are from the InnateDB signalling network, and miRNA–target pairs are collated from validated and predicted databases. miRNAs are shown as triangles, and genes are the circular nodes. The miRNA–gene interactions are shown as red lines, while gene–gene interactions are blue. The pink and orange nodes represent downregulated genes and miRNAs, respectively, while green and purple nodes are upregulated genes and miRNAs, respectively.
Figure 1. Metformin induces gene and miRNA expression changes affecting miRNA-based networks in colorectal cancer cells. (A) Volcano plots for transcriptome and small RNA profiling of HCT116 cells treated with 2.5 mM metformin are shown. (i) Protein-coding genes and (ii) miRNAs that were identified by sequencing are shown. Red dots represent differentially expressed genes/miRNAs, while those in black represent no significant changes. Advaita iPathway Guide tool was used to generate the plot. Y axis represents log10 (p value), and x axis represents log2 fold change. Differentially expressed mRNAs and miRNAs were identified with thresholds set at p ≤ 0.05 and 1 ≤ log2 fold change ≤ −1. (B) miRNA-based network affected by metformin treatment of colorectal cancer cells is shown. This is an organic layout of the integrated network associated with 2.5 mM metformin treatment of HCT116 cells. Protein–protein interactions are from the InnateDB signalling network, and miRNA–target pairs are collated from validated and predicted databases. miRNAs are shown as triangles, and genes are the circular nodes. The miRNA–gene interactions are shown as red lines, while gene–gene interactions are blue. The pink and orange nodes represent downregulated genes and miRNAs, respectively, while green and purple nodes are upregulated genes and miRNAs, respectively.
Cancers 16 02055 g001
Cancers 16 02055 g002
Figure 2. Differentially expressed genes and miRNAs associated with metformin treatment of HCT116 cells are overrepresented in PIK3-AKT and MAPK signalling pathways. (A) Functionally grouped network of enriched categories was generated for all the differentially expressed genes with degree ≥ 1 by querying the KEGG database using ClueGO plug-in. Pathways are represented as nodes, and the node size represents the term’s enrichment significance (i). The node pie chart represents the KEGG pathway analysis of selected genes. Only the most significant term in the group is labelled, and the size of each category within the pie chart represents the number of included terms (ii). (Term p value corrected with Bonferroni step down ≤ 0.05) (B) Real-time PCR analyses of relative mRNA (i) and miRNA (ii) levels in HCT116 cells for genes identified in PI3K-Akt and MAPK signalling pathways as being influenced by 2.5 mM metformin treatment are shown. Cells were treated with 2.5 mM metformin for 72 h and compared with cells in control medium. Results are expressed as mean ± SD of at least 3 replicates, and the expression levels of selected mRNAs and miRNAs were normalised to B2M and miR-16 expression levels, respectively. Statistical significance is indicated with asterisks (* p ≤ 0.05, ** p ≤ 0.01, *** p ≤ 0.001, **** p ≤ 0.0001).
Figure 2. Differentially expressed genes and miRNAs associated with metformin treatment of HCT116 cells are overrepresented in PIK3-AKT and MAPK signalling pathways. (A) Functionally grouped network of enriched categories was generated for all the differentially expressed genes with degree ≥ 1 by querying the KEGG database using ClueGO plug-in. Pathways are represented as nodes, and the node size represents the term’s enrichment significance (i). The node pie chart represents the KEGG pathway analysis of selected genes. Only the most significant term in the group is labelled, and the size of each category within the pie chart represents the number of included terms (ii). (Term p value corrected with Bonferroni step down ≤ 0.05) (B) Real-time PCR analyses of relative mRNA (i) and miRNA (ii) levels in HCT116 cells for genes identified in PI3K-Akt and MAPK signalling pathways as being influenced by 2.5 mM metformin treatment are shown. Cells were treated with 2.5 mM metformin for 72 h and compared with cells in control medium. Results are expressed as mean ± SD of at least 3 replicates, and the expression levels of selected mRNAs and miRNAs were normalised to B2M and miR-16 expression levels, respectively. Statistical significance is indicated with asterisks (* p ≤ 0.05, ** p ≤ 0.01, *** p ≤ 0.001, **** p ≤ 0.0001).
Cancers 16 02055 g002
Cancers 16 02055 g003
Figure 3. Metformin-associated differentially expressed miRNAs directly target molecular components of PI3K-AKT and MAPK signalling pathways. (A) Gene expression changes associated with exogenous overexpression of selected miRNA were assessed by real-time RT-PCR and compared with NC mimic. Results are expressed as mean ± SD of at least 3 replicates, and expression levels were normalised to ACTB levels. Statistical significance is indicated with asterisk (** p ≤ 0.01, *** p ≤ 0.001). (B) PIK3R3 (i) and STMN1 (ii) protein levels and densitometry analysis in cells transfected with miR-132-3p/miR-2110/NC mimic and miR-222-3p/miR-589-3p/NC mimic are shown, respectively, as measured by Western blot analysis 76 h post-transfection. Results are expressed as mean ± SD of 3 replicates, and statistical significance is indicated with asterisks (* p ≤ 0.05, ** p ≤ 0.01, *** p ≤ 0.001 and **** p ≤ 0.0001). (C) Validation of direct targeting of PIK3R3 and STMN1 by corresponding miRNAs is shown. mRNA levels of miR-2110 target gene (PIK3R3) and miR-222-3p and miR-589-3p target gene (STMN1) in HCT116 cells co-transfected with miRNA mimics or NC mimics and with NC target protectors or PIK3R3/STMN1 target protectors for 72 h and normalised to ACTNB expression levels are shown. Results are expressed as mean ± SD of 3 replicates, and statistical significance is indicated with asterisks (ns p > 0.05, * p ≤ 0.05, ** p ≤ 0.01).
Figure 3. Metformin-associated differentially expressed miRNAs directly target molecular components of PI3K-AKT and MAPK signalling pathways. (A) Gene expression changes associated with exogenous overexpression of selected miRNA were assessed by real-time RT-PCR and compared with NC mimic. Results are expressed as mean ± SD of at least 3 replicates, and expression levels were normalised to ACTB levels. Statistical significance is indicated with asterisk (** p ≤ 0.01, *** p ≤ 0.001). (B) PIK3R3 (i) and STMN1 (ii) protein levels and densitometry analysis in cells transfected with miR-132-3p/miR-2110/NC mimic and miR-222-3p/miR-589-3p/NC mimic are shown, respectively, as measured by Western blot analysis 76 h post-transfection. Results are expressed as mean ± SD of 3 replicates, and statistical significance is indicated with asterisks (* p ≤ 0.05, ** p ≤ 0.01, *** p ≤ 0.001 and **** p ≤ 0.0001). (C) Validation of direct targeting of PIK3R3 and STMN1 by corresponding miRNAs is shown. mRNA levels of miR-2110 target gene (PIK3R3) and miR-222-3p and miR-589-3p target gene (STMN1) in HCT116 cells co-transfected with miRNA mimics or NC mimics and with NC target protectors or PIK3R3/STMN1 target protectors for 72 h and normalised to ACTNB expression levels are shown. Results are expressed as mean ± SD of 3 replicates, and statistical significance is indicated with asterisks (ns p > 0.05, * p ≤ 0.05, ** p ≤ 0.01).
Cancers 16 02055 g003
Cancers 16 02055 g004
Figure 4. Metformin-associated differentially expressed miRNAs regulate PI3K-AKT and MAPK signalling pathways to suppress cell proliferation and induce cell cycle arrest. (A) Proliferation of CRC cells 96 h post-transfection with miR-132-3p, miR-2110, miR-222-3p and miR-589-3p mimics is shown. Quantitative results of crystal violet staining of transfected HCT116, RKO, SW480, HT29, DLD1 and Caco2 cells confirmed the reduction in cell proliferation with miR-132-3p, miR-2110 and miR-589-3p mimic transfection. “−” denotes a NC mimic, while “+” denotes a specific miRNA mimic. (B) Proliferation of different colorectal cancer cell lines 96 h after transfection with PIK3R3 (i) or STMN1 (ii) siRNA is shown. Quantitative results of crystal violet staining of transfected HCT116, RKO, SW480, HT29, DLD1 and Caco2 cells validated the suppression of cell proliferation following PIK3R3 or STMN1 gene knockdown. “−” denotes NC siRNA, while “+” denotes gene-specific siRNA. Statistical significance is indicated with asterisks (ns p > 0.05, * p ≤ 0.05, ** p ≤ 0.01, *** p ≤ 0.001, **** p ≤ 0.0001). (C) Cell viability measurements using crystal violet assays in HCT116 cells co-transfected with STMN1 or PIK3R3 target protectors with corresponding miRNA mimics or NC mimics and with negative control target protector for 72 h. Results are expressed as mean ± SD of at least 5 replicates, and statistical significance is indicated with asterisks (ns p > 0.05, * p ≤ 0.05, ** p ≤ 0.01). (D) Alteration in p70 S6 kinase phosphorylation levels of HCT116 cells after transfection with miR-132-3p, miR-2110 mimics or PIK3R3 siRNA compared to NC is shown. Densitometry results were normalised against corresponding α-actinin protein levels. Results are expressed as mean ± SD of 3 replicates, and statistical significance is indicated with asterisk (** p ≤ 0.01, *** p ≤ 0.001). (E) Cell cycle distribution of HCT116 cells after transfection with miRNA mimics, PIK3R3 and STMN1 siRNA or metformin treatment for 96 h are shown. Histograms show the percentage of HCT116 cells in different cell cycle phases following transfection with miR-132-3p, miR-2110, miR-222-3p, miR-589-3p miRNA mimics, PIK3R3 and STMN1 siRNAs or treatment with 2.5 mM metformin. Results are expressed as mean ± SD of 3 replicates compared to the negative control, and statistical significance is indicated with asterisks (*** p ≤ 0.001, **** p ≤ 0.0001).
Figure 4. Metformin-associated differentially expressed miRNAs regulate PI3K-AKT and MAPK signalling pathways to suppress cell proliferation and induce cell cycle arrest. (A) Proliferation of CRC cells 96 h post-transfection with miR-132-3p, miR-2110, miR-222-3p and miR-589-3p mimics is shown. Quantitative results of crystal violet staining of transfected HCT116, RKO, SW480, HT29, DLD1 and Caco2 cells confirmed the reduction in cell proliferation with miR-132-3p, miR-2110 and miR-589-3p mimic transfection. “−” denotes a NC mimic, while “+” denotes a specific miRNA mimic. (B) Proliferation of different colorectal cancer cell lines 96 h after transfection with PIK3R3 (i) or STMN1 (ii) siRNA is shown. Quantitative results of crystal violet staining of transfected HCT116, RKO, SW480, HT29, DLD1 and Caco2 cells validated the suppression of cell proliferation following PIK3R3 or STMN1 gene knockdown. “−” denotes NC siRNA, while “+” denotes gene-specific siRNA. Statistical significance is indicated with asterisks (ns p > 0.05, * p ≤ 0.05, ** p ≤ 0.01, *** p ≤ 0.001, **** p ≤ 0.0001). (C) Cell viability measurements using crystal violet assays in HCT116 cells co-transfected with STMN1 or PIK3R3 target protectors with corresponding miRNA mimics or NC mimics and with negative control target protector for 72 h. Results are expressed as mean ± SD of at least 5 replicates, and statistical significance is indicated with asterisks (ns p > 0.05, * p ≤ 0.05, ** p ≤ 0.01). (D) Alteration in p70 S6 kinase phosphorylation levels of HCT116 cells after transfection with miR-132-3p, miR-2110 mimics or PIK3R3 siRNA compared to NC is shown. Densitometry results were normalised against corresponding α-actinin protein levels. Results are expressed as mean ± SD of 3 replicates, and statistical significance is indicated with asterisk (** p ≤ 0.01, *** p ≤ 0.001). (E) Cell cycle distribution of HCT116 cells after transfection with miRNA mimics, PIK3R3 and STMN1 siRNA or metformin treatment for 96 h are shown. Histograms show the percentage of HCT116 cells in different cell cycle phases following transfection with miR-132-3p, miR-2110, miR-222-3p, miR-589-3p miRNA mimics, PIK3R3 and STMN1 siRNAs or treatment with 2.5 mM metformin. Results are expressed as mean ± SD of 3 replicates compared to the negative control, and statistical significance is indicated with asterisks (*** p ≤ 0.001, **** p ≤ 0.0001).
Cancers 16 02055 g004
Disclaimer/Publisher’s Note: The statements, opinions and data contained in all publications are solely those of the individual author(s) and contributor(s) and not of MDPI and/or the editor(s). MDPI and/or the editor(s) disclaim responsibility for any injury to people or property resulting from any ideas, methods, instructions or products referred to in the content.

Share and Cite

MDPI and ACS Style

Orang, A.; Marri, S.; McKinnon, R.A.; Petersen, J.; Michael, M.Z. Restricting Colorectal Cancer Cell Metabolism with Metformin: An Integrated Transcriptomics Study. Cancers 2024, 16, 2055. https://doi.org/10.3390/cancers16112055

AMA Style

Orang A, Marri S, McKinnon RA, Petersen J, Michael MZ. Restricting Colorectal Cancer Cell Metabolism with Metformin: An Integrated Transcriptomics Study. Cancers. 2024; 16(11):2055. https://doi.org/10.3390/cancers16112055

Chicago/Turabian Style

Orang, Ayla, Shashikanth Marri, Ross A. McKinnon, Janni Petersen, and Michael Z. Michael. 2024. "Restricting Colorectal Cancer Cell Metabolism with Metformin: An Integrated Transcriptomics Study" Cancers 16, no. 11: 2055. https://doi.org/10.3390/cancers16112055

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop