Abstract
The human genome contains thousands of long intergenic noncoding RNAs (lincRNAs). However, the functional roles of these transcripts and the mechanisms responsible for their deregulation in colorectal cancer (CRC) remain elusive. A novel lincRNA termed upregulated in CRC (UCC) was found to be highly expressed in human CRC tissues and cell lines. UCC levels correlated with lymph node metastasis, Dukes’ stage, and patient outcomes. In SW480 and SW620 cells, knockdown of UCC inhibited proliferation, invasion, and cell cycle progression and induced apoptosis in vitro. Xenograft tumors grown from UCC-silenced SW620 cells had smaller mean volumes and formed more slowly than xenograft tumors grown from control cells. Inversely, overexpression of UCC in HCT116 promoted cell growth and invasion in vitro. Bioinformatics analysis, dual-luciferase reporter assays, and RNA immunoprecipitation assays showed that miR-143 can interact with UCC, and we found that UCC expression inversely correlates with miR-143 expression in CRC specimens. Moreover, mechanistic investigations showed that UCC may act as an endogenous sponge by competing for miR-143, thereby regulating the targets of this miRNA. Our results suggest that UCC and miR-143 may be promising molecular targets for CRC therapy.
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Main
Worldwide, colorectal cancer (CRC) is the third most commonly diagnosed cancer in males and the second most commonly diagnosed cancer in females, and an estimated 1.4 million CRC cases and 693 900 CRC-related deaths occurred in 2012.1 Understanding the molecular mechanisms that govern tumor growth and metastasis is imperative for establishing early detection strategies as well as individualized treatment. Molecular analysis has enabled the development of diagnostic and therapeutic tools facilitating precision medicine that has previously been unavailable.2, 3 Although previous studies have documented that alterations in many oncogenes and tumor-suppressor genes are associated with CRC, the molecular and genetic bases of colorectal carcinogenesis remain largely unknown.4
The human transcriptome contains not only many protein-coding messenger RNAs (mRNAs) but also a large set of non-protein-coding transcripts that have structural, regulatory, or unknown functions. Recent studies have revealed that the human genome encodes many noncoding RNAs ranging from small regulatory RNAs such as microRNAs and Piwi-associated RNAs to long noncoding RNAs (lncRNAs, longer than 200 nucleotides). The exact number of lncRNAs encoded by the human genome is a matter of debate, but most estimates place the number in the tens of thousands.5, 6 Long intergenic noncoding RNAs (lincRNAs), a type of lncRNAs, are transcript units that discretely intervening between known protein-coding loci. Although the functions of a few lincRNAs, such as XIST and HOTAIR, have been characterized in some important cellular processes, such as X chromosome inactivation, genomic imprinting, pluripotency maintenance, and transcriptional regulation,7, 8 the functions of most annotated lincRNAs remain unexplored. However, several studies have implicated lincRNAs in a variety of disease states, including cancers.9, 10, 11 Recent studies have demonstrated that several lincRNAs are involved in the tumorigenesis and development of CRC.12, 13 However, an enormous number of lincRNAs remain to be elucidated and characterized.
In this study, differences in the lincRNA expression profiles between CRC and tumor-adjacent nontumor tissues were assessed via lincRNA expression microarray analysis, and we observed 124 dysregulated lincRNAs and 1583 dysregulated mRNAs in CRC samples. Among the upregulated lncRNAs, we characterized the pathologic relevance of lincRNA ENST00000602992 (which we termed upregulated in colorectal cancer, UCC) in CRC growth and progression. First, we measured the levels of UCC transcripts in CRC tissues and cell lines and confirmed the upregulation of UCC in CRC. The expression of UCC closely correlated with lymph node metastasis, Dukes’ stage and overall survival. Furthermore, we identified a role of UCC in CRC cell growth and metastasis based on in vitro and in vivo functional experiments. Finally, mechanistic investigations revealed that UCC can promote CRC progression by acting as a sponge for miR-143, which is known to have a key role in diverse physiological and pathological processes.14, 15, 16 Taken together, these results suggest that UCC and miR-143 may be promising molecular targets for CRC therapy.
Results
The novel lincRNA UCC is upregulated in CRC
To identify lincRNAs that are dysregulated in CRC, we employed a lincRNA microarray analysis covering 27 958 protein-coding transcripts and 7419 annotated and/or known lincRNAs (Agilent). Filtered by P-value and fold change (P<0.01 and fold change >2 or fold change <0.5 for lincRNAs/ mRNAs), a total of 124 lincRNAs and 1583 mRNAs were differentially expressed between four paired CRC and non-tumor tissues. Hierarchical clustering showed systematic variations in transcript expression levels between the paired tumor and non-tumor tissues (Supplementary Figures S1A and B). Gene Ontology (GO) and pathway analyses indicated that most differentially expressed genes were involved in cell proliferation as well as cell death control (Supplementary Figure S2). The top 30 differentially expressed lincRNAs are provided in Supplementary Table S1. The microarray data mentioned in this article are available in the National Center for Biotechnology Information Gene Expression Omnibus under accession number GSE75970.
We primarily focused on upregulated lincRNAs because this set of lincRNAs can be used more readily than downregulated lincRNAs as early diagnostic markers or therapeutic targets. We chose four overexpressed lincRNAs with fold changes in expression >2 based on microarray analysis and validated the expression results in an additional eight pairs of CRC and non-tumor tissues. UCC was the most highly upregulated lincRNA in CRC tissues compared to non-tumor tissues (Supplementary Figures S1C, S3 and Supplementary Table S1). Information from the UCSC Genome Browser shows that UCC is a 747-bp transcript with one exon and localizes in human chromosome 7p15.2 (Supplementary Figure S1D).
UCC expression correlates with CRC progression
Then, we examined levels of UCC in CRC tissues obtained from 78 independent patients at Sun Yat-sen Memorial Hospital of Sun Yat-sen University (Guangzhou, China) using quantitative real-time PCR (qRT-PCR). UCC expression in CRC tissues was increased in 50 cases (64%), whereas 28 cases (36%) showed downregulation or no evident difference in expression in CRC tissues compared with UCC expression in the paired non-tumor tissue (Figure 1a). Kaplan–Meier analysis suggested a positive correlation between tumoral UCC expression and a significantly reduced overall survival time among CRC patients with upregulated UCC expression compared to CRC patients without upregulated UCC expression (P<0.05, Figure 1b). High levels of UCC were also found in patients with lymph node metastasis and advanced Dukes’ stage (Figures 1c, d and Table 1). Consistently, UCC was upregulated in CRC cell lines (Figure 1e) and preferentially localized to the nucleus (Figure 1f). Taken together, these data show that UCC is indeed highly expressed in CRC in association with cancer progression.
Knockdown of UCC inhibits CRC cell growth and invasion
To evaluate the possible role of UCC in CRC, we transfected SW620 and SW480 cells with three different siRNAs against UCC (designated si-UCC#1-3), all of which efficiently knocked down the endogenous UCC level (Figure 2a). To avoid off-target effects, we chose si-UCC#2 and si-UCC#3 for subsequent experiments. The results of the CellTiter 96 AQueous One Solution Cell Proliferation Assay (MTS) indicated that silencing UCC reduced the viability of SW620 and SW480 cells (Figure 2b). Moreover, colony formation assays and EdU incorporation assays showed that UCC knockdown significantly inhibited the proliferative capacity of SW620 and SW480 cells (Figures 2c and d). These suppressive effects were confirmed by in vivo tumor growth assays. Xenograft tumors grown from UCC-silenced SW620 cells had smaller mean volumes and formed more slowly than xenograft tumors grown from control cells (Figures 2e and f). In addition, positive staining for the proliferation marker Ki-67 was significantly decreased in UCC-silenced cells compared to control cells (Figure 2g). Collectively, these data implied that suppression of UCC expression contributed to CRC cell growth inhibition.
To explore the potential mechanisms by which UCC enhances CRC cell growth in vitro, we analyzed differences in apoptosis and cell cycle distributions among SW620 and SW480 cells between UCC-depleted and control conditions via flow cytometry analysis. The percentage of early apoptotic cells was significantly increased in the si-UCC groups compared to the control groups (Figure 3a). In addition, significant G1/S arrest was observed in UCC-silenced cells (Figure 3b). In addition, UCC knockdown induced apoptosis of xenograft tumor cells in vivo, as determined by TUNEL assays (Figure 3c). These data demonstrated that induction of apoptosis and G1/S cell cycle arrest may contribute to UCC knockdown-mediated growth inhibition.
To further determine whether UCC is associated with the progression of CRC, we analyzed the effect of UCC knockdown on invasion of SW620 and SW480 cells. The results of the wound-healing assay showed that knockdown of UCC inhibited cell mobility compared with the control treatment (Figure 3d). In addition, Transwell assays indicated that the invasive capacity of the cells was significantly decreased by UCC knockdown (Figure 3e).
Overexpression of UCC abrogates CRC proliferation and invasion
We further assessed the biological function of UCC by upregulation its expression using pcDNA3.1-UCC plasmid vector, focusing on CRC cell line (HCT116) with moderate UCC level. UCC expression level was significantly elevated after transfection with pcDNA3.1-UCC vector (Supplementary Figure S4A). It was implied that overexpression of UCC increased the viability of HCT116 cells by MTS assay (Supplementary Figure S4B). Also, colony formation assays and EdU incorporation assays showed that UCC upregulation enhanced the proliferative potential of HCT116 cell (Supplementary Figures S4C and D). Taken together, these data indicated that overexpression of UCC promoted CRC cell growth.
In addition, we performed flow cytometry to analyze the differences in apoptosis and cell cycle distributions in HCT116 between UCC-overexpressed and control group. As expected, the percentage of early apoptotic cells was significantly decreased in the UCC-overexpressed groups compared to the control (Supplementary Figure S4E), and the proportion of G0/G1 was markedly declined after upregulation of UCC expression (Supplementary Figure S4F). Collectively, these results suggested that overexpression of UCC led to suppression of apoptosis and the proportion of G0/G1.
Furthermore, the wound healing and Transwell assays were conducted to investigate the biological role of UCC in cell invasion. Interestingly, the invasive potential of cells was enhanced in cells transfected with pcDNA3.1-UCC plasmid vector (Supplementary Figures S5A and B).
Inversely correlated expression of UCC and miR-143 in CRC
Accumulating evidence has shown that miRNAs are able to interact with lincRNAs and regulate their expression levels.17, 18 Thus, potential miRNA candidates targeting UCC were predicted using miRCode and DIANA-LncBase software.19, 20 The predicted sites of miR-143 binding to the UCC sequence are illustrated in Figure 4a. The level of UCC was upregulated in CRC tissues based on qRT-PCR, whereas miR-143 expression was downregulated in the same tumor specimens (Figure 4b). Spearman correlation analysis suggested a negative relationship between UCC and miR-143 expression (r=−0.27, P=0.018; Figure 4c). These results indicate that there might be an inverse correlation between the expression levels of UCC and miR-143.
miR-143 suppresses UCC function
We transfected SW620 and SW480 cells with the miR-143 inhibitor or with si-UCC#2 to study the UCC-mediated effects of miR-143 on cell proliferation and invasion. MTS proliferation assays revealed that the miR-143 inhibitor abrogated the effect of si-UCC#2 in reducing cell viability (Figure 5a). Consistently, the colony formation and EdU incorporation assays confirmed these findings (Figures 5b and c). Transwell invasion assays showed that the miR-143 inhibitor enhanced CRC cell invasion but that si-UCC#2 inhibited CRC cell invasion. Besides, co-transfection of si-UCC#2 with the miR-143 inhibitor abolished the repressive effect of si-UCC#2 on CRC cell invasion (Figure 5d), indicating that miR-143 suppresses UCC function.
UCC acts as a competing endogenous RNA by directly binding to miR-143
To examine the potential lincRNA–miRNA interaction, we subcloned full-length UCC or UCC harboring a site-directed mutation in the miR-143-binding site into the psiCHECK dual luciferase reporter vector (referred to as UCC-WT or UCC-MUT, respectively) (Figure 6a). Dual-luciferase assays showed a significant decrease in luciferase activities after co-transfecting cells with miR-143 mimics and the UCC-WT expression vector (P<0.05, Figure 6b) but not the UCC-MUT vector (P>0.05, Figure 6b). We further clarified the regulatory relationship between UCC and miR-143. Overexpressing miR-143 significantly inhibited UCC expression, whereas silencing UCC did not affect miR-143 expression (Figure 6c). Inversely, suppressing miR-143 enhanced UCC expression. Interestingly, attenuation of UCC expression was observed after co-transfection miR-143 inhibitor and si-UCC#2 when compared to the NC control group (Figure 6d). These results suggest that UCC is targeted by miR-143.
Previous studies have demonstrated that miRNAs are present in the form of miRNA ribonucleoprotein complexes that contain Ago2, the key component of the RNA-induced silencing complex (RISC).21, 22 Considering that UCC is exclusively localized to the nucleus (Figure 1f) and that Ago2 generally interacts with RNAs exported to the cytoplasm, we next performed RNA immunoprecipitation (RIP) using an anti-Ago2 antibody. The Ago2 protein was sufficiently immunoprecipitated from cell extracts. In addition, both UCC and miR-143 were enriched by 1.8–2.3-fold following immunoprecipitation using the anti-Ago2 antibody compared to IgG (Figure 6e).
miR-143 has been reported to target and repress KRAS, IGF1R, Bcl-2, and HK2 expression in CRC.23, 24, 25, 26, 27 Western blot assays revealed that the expression levels of these genes were dysregulated in CCD841 cells compared to SW620 cells (Supplementary Figure S6) and that forced expression of miR-143 triggered a significant silencing effect on the expression of these genes in SW620 cells, confirming that they are targets of miR-143 (Figure 6f). These repressive effects were also observed in SW620 cells transfected with si-UCC (Figure 6g). Furthermore, these effects were maintained by co-transfection with si-UCC and the miR-143 inhibitor (Figure 6h). Collectively, these results suggest that UCC regulates the target genes of miR-143 by sequestering endogenous miR-143. We provide evidence that UCC may act as an endogenous sponge by binding to miR-143, thus abolishing the miRNA-induced repression of its target genes.
Discussion
Although thousands of lincRNAs were identified recently, functional characterization of lincRNAs has just begun. Functional studies have indicated that some lincRNAs participate human cancer pathogenesis by acting as oncogenes or tumor suppressors.28, 29 In the current study, we showed that the novel lincRNA UCC is frequently overexpressed in advanced CRC tissues and that UCC upregulation correlates with lymph node metastasis and patient outcomes, suggesting a pro-oncogenic activity of UCC. This observation is further supported by the results of loss-of-function and gain-of-function approaches. Suppression of UCC expression significantly decreased CRC cell growth, induced apoptosis and G1/S arrest, and inhibited invasion, whereas overexpression of this lincRNA had the opposite effects.
miRNAs, which are ~22-nucleotide RNAs with sequence complementarity to the 3′-UTR of mRNAs of target genes, play an important role in gene regulation via translational repression and/or mRNA degradation.30, 31 lncRNAs are generally more readily accessible to miRNAs because no proteins are translated from the lncRNA sequence. Several lncRNAs, such as HULC, HOTAIR, HOTTIP, GAS5, and HOST2, have been identified as miRNA targets in various cancers,17, 18, 32, 33, 34 and these findings provide further understanding of lncRNA regulation during tumorigenesis.
Using online software, we identified UCC as a possible target of miR-143. Generally, miR-143 is downregulated in a variety of tumors, including lung cancer, pancreatic cancer, and melanoma.13, 14, 15, 16, 35, 36, 37, 38, 39 As a putative tumor suppressor, miR-143 participates in CRC development and progression by targeting KRAS, IGF1R, Bcl-2, and HK2.23, 24, 25, 26, 27 In addition, miR-143 is a plasma miRNA that provides high diagnostic accuracy for early-stage HCC39 and is a predictive factor for the response to fluoropyrimidine-based chemotherapy in patients with metastatic CRC,40 indicating the clinical relevance of miR-143. Although miR-143 has been experimentally shown to target many protein-coding genes, our data show that miR-143 also targets UCC. First, we found a negative correlation between UCC and miR-143 expression in clinical CRC specimens. Overexpressing miR-143 reduced UCC expression in CRC cells. In addition, we provide evidence that miR-143 targets UCC by directly binding to miRNA-binding sites in the UCC sequence.
Essentially, a miRNA is bound by a member of the Argonaute family of proteins and confers sequence specificity to a large protein complex. In the cytoplasm, the RNAi machinery uses Watson–Crick base pairing to target the RISC to a specific mRNA and facilitate its degradation.41, 42 Alternatively, the Argonaute protein family has been shown to mediate functional RNAi within the nucleus.43 A related process is well established in the nucleus of S. pombe, where instead of targeting cytoplasmic mRNAs for destruction, a small RNA targets the RNA-induced transcriptional silencing complex to the pericentromeric regions of each chromosome and facilitates the generation of heterochromatin.44, 45 Ago2 and the RNAi factors Dicer and TRBP were also detected in the human nucleus and can mediate functional RNAi in nucleus.46 Moreover, mature miRNAs can be transported from the cytoplasm to the nucleus by importin 8.47 That is, there is a primary machinery for Ago2-miRNA-mediated RNA silencing in cell nuclei in humans, which explains why UCC primarily localized to the nucleus can physically interact with Ago2. Similar miRNA regulation mechanisms were observed for other nuclear lncRNAs. For instance, MALAT1 is a well-known nuclear lncRNA that can be directly regulated by several miRNAs.48, 49
In summary, we have identified that a novel lincRNA, termed UCC, is upregulated in human CRC tissues and serves as a negative prognostic factor in CRC patients. Silencing UCC inhibits CRC cell proliferation and invasion and induces apoptosis. UCC functions as an oncogene in CRC, mechanistically acting by upregulating KRAS and other target genes in part through sponging miR-143.
Materials and Methods
Clinical specimens and cell culture
The use of human specimens in this study was sanctioned by the local ethics committee at Sun Yat-sen Memorial Hospital of Sun Yat-sen University (Guangzhou, China). None of the patients received preoperative chemotherapy or radiotherapy. The data collected included age, gender, overall survival, and tumor features such as tumor size, clinical stage, tumor invasion depth, tumor location, and occurrence of distant metastasis. Tumor and adjacent non-tumor tissues were snap-frozen in liquid nitrogen immediately after extraction and stored at −80 °C until total RNA was extracted. The human CRC cell lines SW480, SW620, HCT116, Caco-2, DLD-1, and HT29 and the colonic epithelial cell line CCD841 were obtained from American Type Culture Collection (ATCC, Rockville, MD, USA) and maintained in RPMI-1640 medium (Gibco, Grand Island, NY, USA) supplemented with 10% fetal bovine serum (FBS), 100 U/ml penicillin sodium and 100 mg/ml streptomycin sulfate in a humidified atmosphere (37 °C and 5% CO2).
RNA isolation and qRT-PCR
Total RNA was extracted and purified from tissues and cell lines with Trizol reagent (Life Technologies, Carlsbad, CA, USA) using a standard procedure. After the quality and quantity of the extracted total RNA were confirmed using a NanoDrop ND-1000 spectrophotometer (Thermo Scientific, Rockford, IL, USA), complementary DNA (cDNA) was synthesized using a reverse transcription kit (TaKaRa, Dalian, China) according to the manufacturer’s protocol. In brief, a master mixture containing 1 μl of cDNA sample, 10 μl of SYBR Green qRT-PCR Master Mix (Qiagen, Hilden, Germany) and 1 μl of primers was prepared on ice. The final volume was then adjusted to 20 μl with RNase-free water. All reactions were performed in a Roche LightCycler system (Roche, Basel, Switzerland). Relative expression was calculated using the 2−ΔΔCt method. Each PCR amplification was performed in triplicate to verify the results. The primer sequences used for PCR are listed as follows: UCC forward: 5′-GAAAGCATTTTGAAAGCCACTG-3′ and reverse: 5′-GAAACTCACCAACCCAAACCTC-3′; GAPDH forward: 5′-GCACCGTCAAGGCTGAGAAC-3′ and reverse: 5′-TGGTGAAGACGCCAGTGGA-3′; LINC01558 forward: 5′-AGCTGGAGATGTGGTCAACG-3′ and reverse: 5′-ATGGAGCCTTCCCAGTGTTG-3′; LINC00239 forward: 5′-GTGTGAAGCAAGGGACAGGT-3′ and reverse: 5′-GGGTGCGTCACTTTCCAATG-3′; HNF1A-AS1 forward: 5′-ACATGACGACCCCACTTCTC-3′ and reverse: 5′-TTGAGTCGTCCATGCCCT TG-3′.
LncRNA profiling
For lncRNA microarray, RNA purity and integrity was analyzed by Agilent Bioanalyzer 2100 (Agilent, Santa Clara, CA, USA). Qualified total RNA was further purified by RNeasy mini kit (Qiagen) and RNase-free DNase set (Qiagen). Total RNA was then amplified and labeled by Low Input Quick Amp Labeling Kit, One-Color (Agilent), following the manufacturer's instructions. Labeled cRNA were purified by RNeasy mini kit (Qiagen). Each Slide was hybridized with 600 ng Cy3-labeled cRNA using Gene Expression Hybridization Kit (Agilent) in Hybridization Oven (Agilent), according to the manufacturer's instructions. After 17 h hybridization, slides were washed in staining dishes (Thermo Scientific) with Gene Expression Wash Buffer Kit (Agilent), following the manufacturer's instructions. Slides were scanned by Agilent Microarray Scanner (Agilent) with default settings, Dye channel: Green, Scan resolution=3 μm, 20 bit. Data were extracted with Feature Extraction Software 10.7 (Agilent). Raw data were normalized by Quantile algorithm, Gene Spring Software 11.0 (Agilent).
Subcellular fractionation
The nuclear and cytosolic fractions of SW620 or SW480 cells were separated using the PARIS Kit (Life Technologies) according to the manufacturer’s instructions. RNA was extracted from both fractions. Then, qRT-PCR was performed to assess the expression ratios of specific RNA molecules between the nuclear and cytoplasmic fractions. GAPDH served as the cytosolic control, and U6 served as the nuclear control.
Cell transfection
The sequence of short-hairpin RNA (shRNA) directed against UCC (5′-GGAAGCCCTTGGTAAAGAATTCAAGAGATTCTTTACCAAGGGCTTCC-3′) was ligated into the pLKO.1-Puro vector (TaKaRa). Lentivirus was packaged into HEK 293 cells using Lipofectamine 2000 (Life Technologies) and collected from the supernatant in accordance with the manufacturer’s instructions. Lentiviral particles were used to infect SW620 cells. The synthesized and purified UCC gene fragment was inserted into the expression vector pcDNA3.1(+) (Invitrogen, Carlsbad, CA, USA) for overexpression this lincRNA in HCT116 cell line. Stable cell lines were established via puromycin selection and then used for subsequent in vitro and in vivo experiments. For transient transfection assays, miR-143 mimics, a miR-143 inhibitor, small interfering RNA (siRNA) duplexes (si-UCC#1, si-UCC#2 and si-UCC#3), and negative control (NC) RNA duplexes for miRNA mimics, the miR-143 inhibitor or the siRNAs were synthesized (Ribobio, Guangzhou, China). The siRNA sequence for si-UCC were si-UCC#1, 5′-GGAGAGACUGCUCUCUCAU-3′, si-UCC#2, 5′-GGAAGCCCUUGGUAAAGAA-3′ and si-UCC#3, 5′-GCUUGAUGUUAGAGCUUAA-3′. These oligonucleotides were transfected into SW620 and SW480 cells using Lipofectamine RNAiMAX (Invitrogen) according to the manufacturer’s protocol.
Cell growth assay
For cell proliferation assay, the MTS assay from Promega (Madison, WI, USA) (CellTiter 96 AQueous One Solution Cell Proliferation Assay) was used following manufacturer’s instruction. Briefly, cells in a 96-well plate were incubated in a humidified 5% CO2 chamber after transfection with indicated siRNAs or vector, followed by addition of 20 μl CellTiter 96 AQueous One Solution and 1–4 h incubation in humidified 5% CO2 chamber. The absorbance at 492 nm was recorded. The assay was performed using six replicates. For colony formation assay, the cells transfected with indicated oligonucleotides for 24 h or the stable HCT116 cells, and were seeded in six-well plates. After 14 day incubation, the number of clones were counted and analyzed.
Wound healing assay
Cells were incubated with normal cell growth medium in six-well plates. Once cultures reached 85% confluency, the cell layer was scratched with a 10 μl sterile pipette tip and washed with culture medium, then exchanged with medium containing 1% FBS cultured for 48 h. To prevent cell proliferation, which could confound the analysis of cell migration into the wound, cells were preincubated with mitomycin C (10 μg/ml) for 1 h at 37 °C. At different time points (0, 48 h), images of the plates were acquired using a microscope.
Transwell assays
Cell invasion assays were carried out using 24-well Transwell chambers with 8 μm pore size polycarbonate membrane (Costar, Corning, NY, USA). Briefly, the lower chamber was filled with 600 μl RPMI 1640 containing 20% FBS. Cells were trypsinized, counted and re-suspended in serum-free RPMI 1640. Cells (2 × 104) in 200 μl serum-free RPMI were added to the upper chamber. The cells were allowed to invade for 24 h at 37 °C before fixing. The non-invaded cells were removed from the upper surface of the membrane by scraping with a cotton swab. Cells on the bottom surface of the membrane were fixed with 95% ethanol and then stained with 1% crystal violet in methanol/PBS. Invasion was assessed by counting the number of stained cell nuclei from five randomly fields per filter in each group at × 200 magnification using a Zeiss (Melville, NY, USA) microscope system.
Cell cycle distribution and apoptosis analysis
To detect the effect of downregulation of UCC on cell cycle distribution and apoptosis, flow cytometry assay was performed. For cell cycle distribution analysis, SW620 and SW480 cells collected at 72 h after transfection with si-UCC, together with stable transfected HCT116 cells, were trypsinized and fixed with ice-cold 70% ethanol for 18 h at 4 °C. The fixed cells were stained with 50% mg/ml Propidium iodide (PI) (BD Pharmingen, San Diego, CA, USA) and 50 mg/ml RNase and then analyzed using a flow cytometer (BD Pharmingen). For apoptosis analysis, si-UCC transfected SW620 and SW480 cells harvested at 72 h after transfection, as well as stable transfected HCT116 cells, were stained with FITC-Annexin V and PI and then analyzed using a flow cytometer. Triplicate experiments with triplicate samples were performed.
Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and western blot assays
Total cell lysate was prepared with a buffer containing 20 mM Tris/HCl, pH 7.4, 300 mM NaCl and 1% Triton X-100. After centrifugation (10 000 × g, 10 min, 4 °C), the supernatant was separated via 10% sodium dodecyl sulfate-polyacrylamide gel electrophoresis, transferred to a PVDF membrane, and subjected to western blot analysis utilizing various antibodies. Antibodies recognizing KRAS (ab180772, dilution: 1/200), Bcl-2 (ab59348, dilution: 1/500), HK2 (ab37593, dilution: 1/200), IGF1R (ab39675, dilution: 1/500), and GAPDH (ab9485, dilution: 1/2500) were purchased from Abcam (Cambridge, MA, USA).
Immunocytochemistry and immunohistochemistry assays
At 48 h after transfection, the 5-ethynyl-2′-deoxyuridine (EdU) incorporation assay was performed using the Cell-Light EdU Apollo567 In Vitro Imaging Kit (Ribobio) according to the manufacturer’s instructions. The xenograft tumor tissues were harvested in 4% formaldehyde buffered with phosphate-buffered saline, embedded in paraffin and then sectioned. An antibody against Ki-67 (#9449, Cell Signaling Technology, Danvers, MA, USA, dilution: 1/400) was used for immunohistochemical analyses. Immunoreactivity in the sections was detected using a horseradish peroxidase (3,3′-diaminobenzidine substrate) kit (BioGenex, Fremont, CA, USA). The slides were then counterstained with hematoxylin, dehydrated and mounted. Terminal deoxynucleotidyl transferase-mediated deoxyuridine triphosphate nick-end labeling (TUNEL) (Roche) assays were carried out according to the manufacturer’s protocol.
The subcutaneous xenotransplantation model
Animal experiments were approved by the Sun Yat-sen University Institutional Animal Care and Use Committee and were conducted following the animal treatment policies of Sun Yat-sen University in accordance with the National Institutes of Health guidelines. After 1 × 106 cells were subcutaneously injected into the back flank of 5-week-old female BALB/C nude mice (n=5 per group), tumor growth was examined every 5 days for 4 weeks. The tumor volume was calculated according to the following equation: volume=length × width2 × 0.5.
Dual-luciferase reporter assay
The human UCC 3′-UTR luciferase reporter construct (UCC-WT) was generated by cloning UCC mRNA 3′-UTR sequence into downstream of psiCHECK luciferase reporter vector (Promega). The miR-143 target site-mutation UCC 3′-UTR luciferase reporter (UCC-MUT) construct was generated by employing direct-site mutagenesis using mutation primers that mutate the miR-143-binding site. Nucleotide sequence of the constructs were confirmed by DNA sequencing. SW620 cells were seeded at 3 × 104 cells per well into 24-well plates and allowed to settle overnight. Next day, cells were co-transfected with wild-type or mutant reporter plasmids and miR-143 mimics. Twenty-four hours after co-transfection, the relative luciferase activity was measured using the dual-luciferase reporter assay system (Promega). Data were normalized by dividing Firefly luciferase activity with that of Renilla luciferase. For each luciferase construct, three independent transfections were performed (each in triplicate). Fold increase was calculated by defining the activity of the psiCHECK-Control vector as 1.
RNA immunoprecipitation
RIP was performed using the EZ-Magna RIP Kit (Millipore, Billerica, MA, USA) according to the manufacturer’s instructions. Briefly, cells were collected and lysed in complete RIP lysis buffer. Then, the cell extract was incubated with RIP buffer containing magnetic beads conjugated to a human anti-Ago2 antibody (Millipore). Samples were incubated with proteinase K with shaking to digest proteins; subsequently, immunoprecipitated RNA was isolated. The RNA concentration was measured using a NanoDrop spectrophotometer, and RNA quality assessed using a bioanalyzer (Agilent). Afterwards, purified RNA was subjected to qRT-PCR analysis.
Statistical methods
Statistical analysis was performed using SPSS 13.0 statistical software (SPSS, Inc. Chicago, IL, USA). All numerical data are presented as the means±S.D. for multiple samples, except for the relative UCC level in patients with/without lymph node metastasis or advanced Dukes’ stage, which is presented as median with range, because there are several samples with very high expression levels. The paired sample t-test was used to evaluate the differences in lncRNA expression between the paired groups. The chi-square test (χ2 test) or Mann–Whitney test was used for non-parametric variables, and (two-tailed) Student’s t-test or one-way analysis of variance (ANOVA) was used for parametric variables. Survival was calculated using the Kaplan–Meier method and was analyzed via the log-rank test. A P-value of 0.05 or less was considered significant.
References
Torre LA, Bray F, Siegel RL, Ferlay J, Lortet-Tieulent J, Jemal A . Global cancer statistics, 2012. CA Cancer J Clin 2015; 65: 87–108.
Dienstmann R, Salazar R, Tabernero J . Personalizing colon cancer adjuvant therapy: selecting optimal treatments for individual patients. J Clin Oncol 2015; 33: 1787–1796.
Friedman AA, Letai A, Fisher DE, Flaherty KT . Precision medicine for cancer with next-generation functional diagnostics. Nat Rev Cancer 2015; 15: 747–756.
Ogino S, Chan AT, Fuchs CS, Giovannucci E . Molecular pathological epidemiology of colorectal neoplasia: an emerging transdisciplinary and interdisciplinary field. Gut 2011; 60: 397–411.
Ulitsky I, Bartel DP . lincRNAs: genomics, evolution, and mechanisms. Cell 2013; 154: 26–46.
Iyer MK, Niknafs YS, Malik R, Singhal U, Sahu A, Hosono Y et al. The landscape of long noncoding RNAs in the human transcriptome. Nat Genet 2015; 47: 199–208.
Pasque V, Tchieu J, Karnik R, Uyeda M, Dimashkie AS, Case D et al. X chromosome reactivation dynamics reveal stages of reprogramming to pluripotency. Cell 2014; 159: 1681–1697.
Guttman M, Donaghey J, Carey BW, Garber M, Grenier JK, Munson G et al. lincRNAs act in the circuitry controlling pluripotency and differentiation. Nature 2011; 477: 295–300.
Hu G, Tang Q, Sharma S, Yu F, Escobar TM, Muljo SA et al. Expression and regulation of intergenic long noncoding RNAs during T cell development and differentiation. Nat Immunol 2013; 14: 1190–1198.
Liu B, Sun L, Liu Q, Gong C, Yao Y, Lv X et al. A cytoplasmic NF-κB interacting long noncoding RNA blocks IκB phosphorylation and suppresses breast cancer metastasis. Cancer Cell 2015; 27: 370–381.
Tseng YY, Moriarity BS, Gong W, Akiyama R, Tiwari A, Kawakami H et al. PVT1 dependence in cancer with MYC copy-number increase. Nature 2014; 512: 82–86.
Han D, Wang M, Ma N, Xu Y, Jiang Y, Gao X . Long noncoding RNAs: novel players in colorectal cancer. Cancer Lett 2015; 361: 13–21.
Hu Y, Chen HY, Yu CY, Xu J, Wang JL, Qian J et al. A long non-coding RNA signature to improve prognosis prediction of colorectal cancer. Oncotarget 2014; 5: 2230–2242.
Cordes KR, Sheehy NT, White MP, Berry EC, Morton SU, Muth AN et al. miR-145 and miR-143 regulate smooth muscle cell fate and plasticity. Nature 2009; 460: 705–710.
Pagliuca A, Valvo C, Fabrizi E, Martino S, Biffoni M, Runci D et al. Analysis of the combined action of miR-143 and miR-145 on oncogenic pathways in colorectal cancer cells reveals a coordinate program of gene repression. Oncogene 2013; 32: 4806–4813.
Zhang JX, Song W, Chen ZH, Wei JH, Liao YJ, Lei J et al. Prognostic and predictive value of a microRNA signature in stage II colon cancer: a microRNA expression analysis. Lancet Oncol 2013; 14: 1295–1306.
Wang J, Liu X, Wu H, Ni P, Gu Z, Qiao Y et al. CREB up-regulates long non-coding RNA, HULC expression through interaction with microRNA-372 in liver cancer. Nucleic Acids Res 2010; 38: 5366–5383.
Chiyomaru T, Fukuhara S, Saini S, Majid S, Deng G, Shahryari V et al. Long non-coding RNA HOTAIR is targeted and regulated by miR-141 in human cancer cells. J Biol Chem 2014; 289: 12550–12565.
Jeggari A, Marks DS, Larsson E . miRcode: a map of putative microRNA target sites in the long non-coding transcriptome. Bioinformatics 2012; 28: 2062–2063.
Paraskevopoulou MD, Georgakilas G, Kostoulas N, Reczko M, Maragkakis M, Dalamagas TM et al. Diana-LncBase: experimentally verified and computationally predicted microRNA targets on long non-coding RNAs. Nucleic Acids Res 2013; 41: D239–D245.
Filipowicz W, Bhattacharyya SN, Sonenberg N . Mechanisms of post-transcriptional regulation by microRNAs: are the answers in sight? Nat Rev Genet 2008; 9: 102–114.
Hutvagner G, Simard MJ . Argonaute proteins: key players in RNA silencing. Nat Rev Mol Cell Biol 2008; 9: 22–32.
Kent OA, Fox-Talbot K, Halushka MK . RREB1 repressed miR-143/145 modulates KRAS signaling through downregulation of multiple targets. Oncogene 2013; 32: 2576–2585.
Gregersen LH, Jacobsen A, Frankel LB, Wen J, Krogh A, Lund AH . MicroRNA-143 down-regulates hexokinase 2 in colon cancer cells. BMC Cancer 2012; 12: 232.
Borralho PM, Simões AE, Gomes SE, Lima RT, Carvalho T, Ferreira DM et al. miR-143 overexpression impairs growth of human colon carcinoma xenografts in mice with induction of apoptosis and inhibition of proliferation. PLoS ONE 2011; 6: e23787.
Su J, Liang H, Yao W, Wang N, Zhang S, Yan X et al. MiR-143 and MiR-145 regulate IGF1R to suppress cell proliferation in colorectal cancer. PLoS ONE 2014; 9: e114420.
Qian X, Yu J, Yin Y, He J, Wang L, Li Q et al. MicroRNA-143 inhibits tumor growth and angiogenesis and sensitizes chemosensitivity to oxaliplatin in colorectal cancers. Cell Cycle 2013; 12: 1385–1394.
Huarte M . The emerging role of lncRNAs in cancer. Nat Med 2015; 21: 1253–1261.
Serviss JT, Johnsson P, Grandér D . An emerging role for long non-coding RNAs in cancer metastasis. Front Genet 2014; 5: 234.
Bartel DP . MicroRNAs: target recognition and regulatory functions. Cell 2009; 136: 215–233.
Maroney PA, Yu Y, Fisher J, Nilsen TW . Evidence that microRNAs are associated with translating messenger RNAs in human cells. Nat Struct Mol Biol 2006; 13: 1102–1107.
Ge Y, Yan X, Jin Y, Yang X, Yu X, Zhou L et al. fMiRNA-192 and miRNA-204 directly suppress lncRNA HOTTIP and interrupt GLS1-mediated glutaminolysis in hepatocellular carcinoma. PLoS Genet 2015; 11: e1005726.
Zhang Z, Zhu Z, Watabe K, Zhang X, Bai C, Xu M et al. Negative regulation of lncRNA GAS5 by miR-21. Cell Death Differ 2013; 20: 1558–1568.
Gao Y, Meng H, Liu SP, Hu JJ, Zhang YM, Jiao TT et al. LncRNA-HOST2 regulates cell biological behaviors in epithelial ovarian cancer through a mechanism involving microRNA let-7b. Hum Mol Genet 2015; 24: 841–852.
Ma Q, Jiang Q, Pu Q, Zhang X, Yang W, Wang Y et al. MicroRNA-143 inhibits migration and invasion of human non-small-cell lung cancer and its relative mechanism. Int J Biol Sci 2013; 9: 680–692.
Pham H, Rodriguez CE, Donald GW, Hertzer KM, Jung XS, Chang HH et al. miR-143 decreases COX-2 mRNA stability and expression in pancreatic cancer cells. Biochem Biophys Res Commun 2013; 439: 6–11.
Li R, Zhang L, Jia L, Duan Y, Li Y, Wang J et al. MicroRNA-143 targets Syndecan-1 to repress cell growth in melanoma. PLoS ONE 2014; 9: e94855.
Zhou P, Chen WG, Li XW . MicroRNA-143 acts as a tumor suppressor by targeting hexokinase 2 in human prostate cancer. Am J Cancer Res 2015; 5: 2056–2063.
Zhang ZQ, Meng H, Wang N, Liang LN, Liu LN, Lu SM et al. Serum microRNA 143 and microRNA 215 as potential biomarkers for the diagnosis of chronic hepatitis and hepatocellular carcinoma. Diagn Pathol 2014; 9: 135.
Simmer F, Venderbosch S, Dijkstra JR, Vink-Börger EM, Faber C, Mekenkamp LJ et al. MicroRNA-143 is a putative predictive factor for the response to fluoropyrimidine-based chemotherapy in patients with metastatic colorectal cancer. Oncotarget 2015; 6: 22996–23007.
Grewal SI . RNAi-dependent formation of heterochromatin and its diverse functions. Curr Opin Genet Dev 2010; 20: 134–141.
Morris KV, Chan SW, Jacobsen SE, Looney DJ . Small interfering RNA-induced transcriptional gene silencing in human cells. Science 2004; 305: 1289–1292.
Zamudio JR, Kelly TJ, Sharp PA . Argonaute-bound small RNAs from promoter-proximal RNA polymerase II. Cell 2014; 156: 920–934.
Volpe TA, Kidner C, Hall IM, Teng G, Grewal SI, Martienssen RA . Regulation of heterochromatic silencing and histone H3 lysine-9 methylation by RNAi. Science 2002; 297: 1833–1837.
Hall IM, Shankaranarayana GD, Noma K, Ayoub N, Cohen A, Grewal SI . Establishment and maintenance of a heterochromatin domain. Science 2002; 297: 2232–2237.
Gagnon KT, Li L, Chu Y, Janowski BA, Corey DR . RNAi factors are present and active in human cell nuclei. Cell Rep 2014; 6: 211–221.
Wei Y, Li L, Wang D, Zhang CY, Zen K . Importin 8 regulates the transport of mature microRNAs into the cell nucleus. J Biol Chem 2014; 289: 10270–10275.
Han Y, Liu Y, Zhang H, Wang T, Diao R, Jiang Z et al. Hsa-miR-125b suppresses bladder cancer development by down-regulating oncogene SIRT7 and oncogenic long non-coding RNA MALAT1. FEBS Lett 2013; 587: 3875–3882.
Hirata H, Hinoda Y, Shahryari V, Deng G, Nakajima K, Tabatabai ZL et al. Long noncoding RNA MALAT1 promotes aggressive renal cell carcinoma through Ezh2 and interacts with miR-205. Cancer Res 2015; 75: 1322–1331.
Acknowledgements
This work was supported by grants from the National Natural Science Foundation of China (nos 81572348, 81372819, 81572596, and 81602123), the Specialized Research Fund for the Doctoral Program of Higher Education (no. 20120171110075), the Science and Technology Planning Project of Guangdong Province (nos 2013B021800099 and 2014A020212386), the Guangdong Province Natural Science Foundation (nos 2015A030313115 and 2016A030313363), the Foundation of Guangzhou Science and Technology Bureau (nos 2014J4100170 and 201510010206) and Sun Yat-sen University (no. 13ykzd14).
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Huang, FT., Chen, WY., Gu, ZQ. et al. The novel long intergenic noncoding RNA UCC promotes colorectal cancer progression by sponging miR-143. Cell Death Dis 8, e2778 (2017). https://doi.org/10.1038/cddis.2017.191
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DOI: https://doi.org/10.1038/cddis.2017.191
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