Abstract
We currently have limited knowledge of the involvement of long non-coding RNAs (lncRNAs) in normal cellular processes and pathologies. Here, we identify and characterize SNHG5 as a stable cytoplasmic lncRNA with up-regulated expression in colorectal cancer. Depletion of SNHG5 induces cell cycle arrest and apoptosis in vitro and limits tumour outgrowth in vivo, whereas SNHG5 overexpression counteracts oxaliplatin-induced apoptosis. Using an unbiased approach, we identify 121 transcript sites interacting with SNHG5 in the cytoplasm. Importantly, knockdown of key SNHG5 target transcripts, including SPATS2, induces apoptosis and thus mimics the effect seen following SNHG5 depletion. Mechanistically, we suggest that SNHG5 stabilizes the target transcripts by blocking their degradation by STAU1. Accordingly, depletion of STAU1 rescues the apoptosis induced after SNHG5 knockdown. Hence, we characterize SNHG5 as a lncRNA promoting tumour cell survival in colorectal cancer and delineate a novel mechanism in which a cytoplasmic lncRNA functions through blocking the action of STAU1.
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Introduction
Aberrant proliferation and increased cell survival are key processes during malignant transformation and tumour progression. To facilitate these processes, a number of chromosomal rearrangements, mutations and epigenetic modifications are typically selected for in cancerous cells, resulting in an overall alteration of gene expression. Colorectal carcinoma (CRC) is the third most common cancer worldwide1. While invasive colorectal cancers that have not yet compromised regional lymph nodes (stage I–II) have relatively good prognoses with the current treatments and are curable in 73% of the cases, the progression of the disease is fast and untreated tumours rapidly disseminate to lymph nodes (stage III) and metastasize to distant sites (stage IV)2. Thus, a better understanding of the mechanisms driving the disease and identification of additional therapeutic targets is a priority for improving CRC treatment3. Several studies have pointed to the emerging roles of long non-coding RNAs (lncRNAs) in tumour development, which could provide new candidates for diagnostics and therapy.
Although mammalian genomes are widely transcribed, only 1–2% of the genomic output encodes for proteins4,5. Among the large fraction of non-coding transcripts, the class of lncRNAs, arbitrarily defined as transcripts longer than 200 nts, is receiving increasing attention and may present new opportunities for cancer diagnosis and treatment. Although thousands of lncRNAs have been identified, we still lack insight into the structural–functional significance of the vast majority of these molecules in regulating fundamental cellular processes. However, extensive gene expression and copy number variation analyses have linked alteration of lncRNA expression to tumour development. Resultantly, several lncRNAs, such as MALAT1, HOTAIR, ANRIL, PVT1 and lincRNA-p21, have been reported to play significant roles in cancer initiation and development6,7,8,9,10.
In this study, we aimed to identify and characterize lncRNAs functionally impacting on CRC. Profiling a large set of CRCs, we identified the cytoplasmic lncRNA SNHG5 as significantly overexpressed in tumours. We provide evidence that SNHG5 expression regulates the survival of CRC cells and the progression of CRC tumour xenografts in a mouse model. Importantly, whereas knockdown of SNHG5 prominently induces apoptosis, SNHG5 overexpression can protect CRC cells from oxaliplatin-induced apoptosis. While most of the hitherto characterized lncRNAs function in the nucleus, much less is known about lncRNAs and their mode of action in the cytoplasmic compartment. A notable exception being competing endogenous RNAs (ceRNAs), which act as molecular sponges for microRNAs hence relieving repression of target mRNAs11,12. Other known mechanisms for lncRNAs in the cytoplasm involve post-transcriptional regulation affecting mRNA stability or accessibility to the translational machinery13. Through an unbiased forward identification of mRNAs interacting with SNHG5 in the cytoplasm, we identify 121 interacting transcript sites in HCT116 CRC cells. Importantly, loss of SNHG5 reduces the protein levels of the interactors via destabilization of their mRNAs. We further characterize the interaction of SNHG5 with the target SPATS2, and demonstrate that loss of SPATS2 phenocopies the effect of SNHG5 depletion. STAU1 is a part of a highly conserved family of double-stranded RNA-binding proteins implicated in mRNA transport, stability and translation14,15,16,17. We show here that SNHG5 binding to target mRNAs protects these from STAU1-mediated degradation. Importantly, loss of STAU1 also rescues the apoptotic effect of SNHG5 depletion.
Hence, we here provide new insights into the significance of lncRNAs in CRC in general and to the specific role of SNHG5 in promoting CRC cell survival.
Results
SNHG5 is up-regulated in colorectal cancer
To identify non-coding RNAs deregulated in CRC, we profiled their expression in a cohort of 44 carcinomas, 39 adenomas, 20 adjacent normal mucosa and 10 CRC cell lines using a previously described custom-designed microarray platform18. As expected, the overall expression level of lncRNAs was lower than that of the protein-coding genes in all sample sets (Supplementary Fig. 1a)19.
Among the most significantly deregulated transcripts, we identified several lncRNAs previously found deregulated in cancer, such as ncRAN and GAS5, indicating the validity of our approach (Supplementary Fig. 1b,c). We focus here on SNHG5 for which no function in CRC has been ascribed so far. RNA-seq confirmed the up-regulation of SNHG5 in CRC in a larger independent cohort of 294 normal colon mucosa samples, 33 adenomas and 280 CRC samples (n=313) (Fig. 1a). This was confirmed also restricting the analysis to the 268 paired samples included in the same cohort (Supplementary Fig. 2a). Interestingly, we find SNHG5 to be significantly up-regulated both between normal tissues and adenomas, and from adenomas to carcinoma stage I (malignant tumour), suggesting SNHG5 up-regulation as an early event in CRC development (Fig. 1b).
SNHG5 is composed of six exons spliced into two main isoforms: the 1032 nts long SNHG5-1 and the shorter SNHG5-2 (430 nts) (Fig. 1c). SNHG5-2 is the most abundant isoform expressed in CRC (Supplementary Fig. 2b), and we refer to it as SNHG5 in the following experiments. Two snoRNAs, U50A and U50B, are encoded in introns 4 and 5, respectively. We profiled the expression of SNHG5 in a panel of human tissues and found it most highly expressed in muscles, liver and heart (Supplementary Fig. 2c). Reverse transcription (RT)–PCR analysis revealed that the SNHG5 transcript, like many other mRNA-like non-coding RNAs, is poly-adenylated (Supplementary Fig. 2d). The SNHG5 transcript has a half-life (t½) of 1 h, indicating an intermediate turnover rate when compared with transcripts with a very short half-life, such as MYC (t½=30 min), or more stable mRNAs, such as ACTB (t½=5–6 h) (Supplementary Fig. 2e). RNA fluorescence in situ hybridization (RNA-FISH) was performed using LNA probes spanning the exon–exon junctions 3–4 and 4–5, respectively, and showed SNHG5 to be predominantly cytosolic in both HCT116 CRC cells and in immortalized TIG-3 human fibroblasts (Fig. 1d). This was also demonstrated by subcellular fractionation studies and qRT–PCR (Fig. 1e). Polysome fractionation studies showed a clear SNHG5 enrichment in the light, un-translated fraction suggesting no association with ribosomes (Supplementary Fig. 2f). In conclusion, we characterize SNHG5 to be a stable and poly-adenylated ncRNA transcript not associated with ribosomes and with an up-regulated expression in CRC.
SNHG5 affects proliferation and survival of CRC cells
Towards identifying a function for SNHG5 we profiled its expression in a panel of CRC cell lines (Supplementary Fig. 3a) and designed two independent short interfering RNAs (siRNAs) targeting SNHG5 with knockdown efficiencies >75% (Fig. 1f). The cytosolic fraction of the transcript was the most strongly reduced when analysed 36 h after siRNA transfection (Supplementary Fig. 3b). Moreover, the expression levels of the U50A snoRNA remained unchanged, suggesting that the siRNAs target the spliced transcript and that phenotypic effects will be independent of the snoRNAs, which in these cell lines exerts a nuclear restricted expression (Supplementary Fig. 3c,d). To investigate biological processes affected by SNHG5 depletion, RNA-seq was performed in HCT116 cells 36 h after transfection with two independent siRNAs against SNHG5 or a negative control siRNA (Fig. 1g). We found 150 genes to be significantly deregulated by both SNHG5 siRNAs (fold change >3, FDR<0.05). Gene ontology analysis revealed a significant enrichment of genes involved in differentiation processes, such as mesoderm development, cell communication and metabolic processes (Fig. 1h). Furthermore, gene set enrichment analysis20 suggested that SNHG5 depletion impacts key survival pathways in CRC cells, such as the STAT3 pathway (Supplementary Fig. 3e). This was further confirmed using western blots for STAT3, a known STAT3 target gene BCL-XL, and BCL-2 (Supplementary Fig. 3f).
Importantly, knockdown of SNHG5 (Supplementary Fig. 3g) resulted in a strong anti-proliferative effect in CRC cells (Fig. 2a). This result was confirmed by cell cycle analysis using EdU incorporation, which revealed a significant decrease in the S-phase cell population in SNHG5-depleted cells (Fig. 2b). To investigate an impact of SNHG5 on survival, CRC cell lines were stained for cleaved Caspase-3 protein and analysed by flow cytometry, which revealed a strong induction of apoptosis in both HCT116, CACO-2 and DLD-1 cells (Fig. 2c, top). This was confirmed by western blots for cleaved PARP-1 (Fig. 2c, bottom).
As siRNA depletion studies may suffer from off-target effects, we subsequently investigated the effect of SNHG5 overexpression. Towards this, both a cDNA version (430 bp) and the entire genomic locus of SNHG5 (1800, bp) were cloned (Fig. 2d) and transiently expressed in HT-29 cells, which display a lower endogenous SNHG5 level as compared with HCT116, CACO-2 and DLD-1 cells (Supplementary Fig. 3a). Forty-eight hour after transfection a 60-fold average increase in the SNHG5 levels were detected by qRT–PCR in comparison to the empty vector control (Fig. 2e, left). The cells were subsequently treated for 24 h with oxaliplatin, a drug commonly employed in CRC treatment. Interestingly, using flow cytometry, we observed a significant decrease in the cleaved Caspase-3 positive population of HT-29 cells overexpressing SNHG5 (Fig. 2e right). This protective effect was evident for both the cDNA construct and the entire SNHG5 locus, suggesting no significance of the snoRNAs in this assay. No proliferative effect was observed in HT-29 cells overexpressing the SNHG5 lncRNA in the absence of drug treatment (Supplementary Fig. 4a,b). Next, we created a panel of SNHG5 mutants lacking individual exons and tested the ability of these mutants to protect HT-29 cells from oxaliplatin-induced apoptosis (Fig. 2f). Interestingly, whereas mutants for exons 2, 3, 5 and 6 all protected the cells to the same extend as full-length SNHG5, mutants lacking either exon 1 or exon 4 failed to protect against oxaliplatin-induced apoptosis (Fig. 2g).
We next employed a luminescent xenograft mouse model to query whether SNHG5 expression is required for tumour growth in vivo (Supplementary Fig. 4c). Luminescent HCT116 CRC cells holding doxycycline-inducible shRNAs targeting SNHG5 or GFP as control were subcutaneously injected into two groups of immune-compromised mice. To allow time for tumour establishment, doxycycline was added to the drinking water at day 13 after injection. SNHG5 levels were significantly reduced in the tumours following doxycycline treatment compared with the non-targeting control (Supplementary Fig. 4d). Importantly, we observed a significant negative effect on tumour growth following SNHG5 depletion (Fig. 2h; Supplementary Fig. 4e). SNHG5 depletion resulted in a significant reduction of tumour volume and weight as measured at the end of the experiments at day 35 (Fig. 2i,j). Altogether, this data suggest that SNHG5 expression functions to regulate proliferation and survival of CRC cells both in vitro and in vivo.
RIA-seq identifies primary downstream effectors of SNHG5
Until now, only few mechanisms for cytoplasmic lncRNAs have been revealed. To unveil the mechanism by which SNHG5 affects proliferation and apoptosis in the cytoplasm, we used an unbiased method, RIA-seq (RNA interactome analysis and sequencing), to map transcriptome-wide RNA–RNA interactions21. Two sets (Even and Odd) of eleven 3′-biotinylated DNA oligonucleotides were designed to specifically hybridize to SNHG5. A luciferase-specific oligonucleotide pool was used as negative control (Fig. 3a; Supplementary Fig. 5a). The pull-down efficiency was estimated by qRT–PCR to ∼50% of the endogenous SNHG5 transcript pool in HCT116 cells (Fig. 3b). The interacting RNA transcripts were identified using single-end 50 nucleotide Illumina sequencing and the sequence reads were mapped onto the Hg19 genome scaffold using the STAR aligner tool (see ‘Methods’ section for details). The relative enrichment of peaks present in both the Even and the Odd pools were calculated with respect to the luciferase pool, which was used as background reference. We identified 121 significant peaks overlapping between the Even and Odd pools (P value<0.05) (Fig. 3c; Supplementary Fig. 5b). About half of the peaks mapped to coding regions (51.4%) while the majority of the remaining peaks resided in 3′ UTR regions (40%) (Supplementary Fig. 5c).
We ranked a short list of SNHG5-interacting mRNAs based on the number of peaks (overlapping and not-overlapping) in each transcript and their local enrichment relative to the luciferase background pool (Supplementary Fig. 5d). The mRNA transcripts representing the peaks were subsequently validated in HCT116 by qRT–PCR using peak-specific primers (Fig. 3d; Supplementary Fig. 5d,e). We identified the SPATS2, PITRM1 and GLE1 mRNAs as the most enriched SNHG5-interacting transcripts. We further validated the RIA-seq data in CACO-2 and DLD-1 cells, where SNHG5 depletion was also found to affect cell survival (Fig. 2a). In these cells only the interaction with the SPATS2 mRNA could be consistently confirmed, probably due to lower expression levels of the other target transcripts in these cell lines (Supplementary Fig. 6a,b). Importantly, SNHG5 depletion results in a clear decrease of the target protein levels (Fig. 3e). To evaluate the effect of SNHG5 on the stability of the target transcripts, HCT116 cells were treated for 5 h with the RNA PolII inhibitor Triptolide following SNHG5 knockdown (Fig. 3f). The mRNA stabilities of all three top interactors were reduced on SNHG5 knockdown as quantified using qRT–PCR. Altogether, this data suggest that SNHG5 forms RNA–RNA interactions with target mRNAs in the cytoplasm and regulates their stability.
SPATS2 is a key downstream target of SNHG5
To further explore the underlying mechanism, we focused on the SNHG5–SPATS2 interaction and confirmed that SNHG5 depletion in HCT116, CACO-2 and DLD-1 cells, where both transcripts are expressed at similar levels (Supplementary Fig. 6c), results in a decrease of the SPATS2 protein levels (Fig. 4a). The SPATS2 gene product is a predicted cytoplasmic RNA-binding protein, but besides its potential involvement in the maturation of gonad cells SPATS2 functions are unknown22. Importantly, SNHG5 overexpression in HT-29 was found to increase SPATS2 protein levels (Fig. 4b). An RNA–RNA interaction site was computationally predicted to span the first exon of SNHG5 and the 3′ UTR of SPATS2. Both the thermodynamics prediction (Energy=−15.50 kcal mol−1; IntaRNA) and the conservation (PETcofold) point towards these regions as the interaction site. The interaction is only conserved among primates (phylogenetic tree predicted in PETcofold) and the phyloP base-wise conservation (100 vertebrates UCSC genome alignment) shows low evolutionary pressure on SNHG5 suggesting an evolutionary new binding site (Fig. 4c). As expected, overexpression of SNHG5 promotes the stabilization of the SPATS2 mRNA (Supplementary Fig. 6d). To identify the region in SNHG5 responsible for promoting SPATS2 mRNA stability, we overexpressed the panel of SNHG5 mutants and measured the stability of the SPATS2 mRNA following Triptolite treatment. Interestingly, the SNHG5 mutant lacking exon 1 failed to promote SPATS2 mRNA stability (Fig. 4d), thus sustaining the notion that SNHG5 interacts with SPATS2 via elements in SNHG5 exon 1.
We then assessed the binding of SNHG5 to the 3′-UTR of SPATS2 (nts 2,456–2,660) using a luciferase reporter system (Fig. 4e, top). The ectopic expression of SNHG5 in HEK293 cells increased the luciferase activity of the SPATS2 3′ UTR reporter construct, as compared with the control, whereas the SNHG5 mutant lacking exon 1 was unable to do so (Fig. 4e, bottom). In addition, we were able to compete the SNHG5 binding to the SPATS2 3′-UTR by co-transfecting the cells with a plasmid vector expressing the full-length SPATS2 mRNA. In addition, co-transfecting the full-length SPATS2 mRNA was also sufficient to compete the SNHG5 interaction with a second luciferase construct containing the SNHG5 binding site from the GLE1 3′-UTR (nts 2,496–2,706) (Supplementary Fig. 6e,f). Altogether, these data demonstrate that SNHG5 can directly bind and regulate SPATS2.
The SNHG5–SPATS2 axis promotes CRC cell survival
SPATS2 has not previously been implicated in cancer-related processes, however, RNA-seq data analysis of CRC-paired samples showed a significant up-regulation of the SPATS2 transcript in tumours versus correspondent normal tissues (Fig. 5a). Similarly, we find the two other top interactors GLE1 and PITRM1 to be up-regulated in CRC (Supplementary Fig. 7a). If the stabilizing effect of SNHG5 on the SPATS2 mRNA is important for the survival-promoting functions of SNHG5, we would expect loss of SPATS2 to impact on CRC cell survival. Indeed, knockdown of SPATS2 in CRC cell lines resulted in a significant reduction of cell viability (Fig. 5b; Supplementary Fig. 7b). Furthermore, phenocopying the effects observed on SNHG5 depletion, also the inhibition of SPATS2 expression down-regulates the STAT3 pathway, hence confirming the impact of SPATS2 expression on viability in CRC cell lines (Supplementary Fig. 7c). Moreover, ectopic SPATS2 expression in HT-29 cells prevented apoptosis induction on oxaliplatin treatment, thus recapitulating the SNHG5 overexpression phenotype (Fig. 5c).
To further explore the interaction between SNHG5 and SPATS2, we investigated the SNHG5 and SPATS2 expression patterns in primary CRCs and mouse xenograft tumours (Supplementary Fig. 7d). The correlation found in CRC samples was further confirmed by analyzing SPATS2 levels in the xenograft tumours, where knockdown of SNHG5 resulted in a significant decrease in SPATS2 mRNA levels (Fig. 5d). Finally, we investigated whether restoring SPATS2 expression in SNHG5-depleted CRC cells was sufficient to rescue the apoptotic phenotype. Indeed, in HCT116 cells ectopic expression of SPATS2-mediated a partial rescue from the anti-proliferative and pro-apoptotic effect following the SNHG5 depletion (Fig. 5e–g). Altogether, this data suggest that the SNHG5–SPATS2 interaction is important for promoting CRC cell survival.
SNHG5 impairs the association of SPATS2 with STAU1
We hypothesized that the binding of SNHG5 promoted SPATS2 mRNA stabilization via protecting the transcript from post-transcriptional regulators. The RNA-binding protein STAU1 has previously been described to destabilize mRNAs in the cytoplasm23. Interestingly, knocking down STAU1 resulted in an up-regulation in both transcript and protein levels of SPATS2 in HCT116 cells (Fig. 6a). To evaluate the effect of STAU1 depletion on SPATS2 transcript stability and to compare with the effect resulting from SNHG5 depletion, HCT116 cells were treated for 5 h with Triptolide following SNHG5 and STAU1 knockdown (Fig. 6b). As expected, the SPATS2 mRNA stability was reduced on SNHG5 depletion, whereas the opposite effect was measured after STAU1 knockdown. To validate SPATS2 as a direct target of STAU1, we performed RNA immunoprecipitation using a STAU1 antibody after ultraviolet cross-link. Importantly, the SPATS2 mRNA was enriched in the STAU1 pull-down compared with the IgG control. Moreover, depleting SNHG5 in HCT116 cells increased the association of SPATS2 with STAU1. Importantly, this was not observed for another known STAU1 target gene, ARF1 (Fig. 6c)13. This data suggests that SNHG5 impairs the association SPATS2 with STAU1. Having confirmed SPATS2 as a key target of SNHG5, and STAU1 as a regulator of SPATS2, we speculated if STAU1 could be implicated in CRC cell survival. Towards this, we combined knockdown of STAU1 with oxaliplatin treatment and measured the level of apoptosis. As evident from Supplementary Fig. 7e, loss of STAU1 reduced the level of apoptosis implicating STAU1 in CRC cell survival.
We queried the pathway hypothesizing that if SNHG5 and STAU1 have opposite functions on SPATS2 mRNA stability, loss of STAU1 might rescue the apoptosis seen following SNHG5 loss. Towards this, we combined the knockdown of SNHG5 and STAU1 and measured the resultant level of apoptosis in HCT116 cells. As evident from Fig. 6d,e, loss of STAU1 expression strongly reduced the apoptosis induction following SNHG5 depletion. In conclusion, our analyses demonstrate that SNHG5 promotes CRC cells survival by alleviating STAU1-induced degradation of SPATS2.
Discussion
In this study, we used a customized array platform to profile the expression of lncRNAs in a set of CRC samples and to identify lncRNA expression profiles correlating with disease progression. We identified SNHG5 as significantly up-regulated in CRC with respect to normal tissues and validated this expression pattern in an independent cohort of 313 CRCs. SNHG5 belongs to a large family of non-coding genes hosting small RNAs, such as snoRNAs and microRNAs, most often residing in the introns of the host genes. Following excision of the small RNAs, these host gene transcripts in general are unstable24, and many have been viewed as biologically inert carriers, where the small RNAs are thought to be the biologically relevant players25. Noticeable exceptions include host genes such as GAS5, TINCR, ncRAN and MIR31HG21,26,27,28, all of which have biological effects independent of their hosted small RNAs. SNHG5 has not previously been characterized in CRC but was reported as a translocation partner to BCL6 in a patient suffering from diffuse large B-cell lymphoma29. SNHG5 encodes the snoRNAs U50 and U50′ in introns 4 and 5, respectively. Whereas snoRNAs of the C/D box family are well-known to guide fibrillarin-mediated 2′O methylation of the ribosomal RNA, reduced expression and both somatic and germ line mutations in U50 have been reported from breast and prostate cancer30,31. Furthermore, a non-canonical function of the U50 snoRNA in modulating RAS activity was recently described32. Although currently unclear, this is likely independent from the SNHG5 mechanism characterized in this paper.
We find that SNHG5 expression levels are significantly elevated both in the transition between normal tissue and adenomas and between adenomas and early stage (I) carcinoma. Importantly, suppression of SNHG5 expression not only exerts a strong anti-proliferative effect and induces apoptosis, impacting key survival pathways such as the STAT3 pathway in vitro, but also reduces tumour progression in vivo. Moreover, SNHG5 overexpression prevents apoptosis induction in CRC cell lines treated with chemotherapeutic agents. We further characterize SNHG5 as a stable, cytoplasmic lncRNA not associated with polysomes. This prompted us to explore mechanisms for SNHG5 in the cytoplasm by isolating mRNAs interacting with the lncRNA using RIA-seq. This is in line with an increasing number of studies describing post-transcriptional mechanisms of gene expression regulation mediated by cytosolic lncRNAs22. We identified 121 significant sites of intermolecular interaction with SNHG5, located mainly in cis-regulatory sequences (3′ UTRs), and further pinpointed SPATS2 as an important direct target of SNHG5 in multiple CRC cell lines. SPATS2 is significantly up-regulated in CRC patients and knockdown of SNHG5 destabilizes the SPATS2 mRNA and significantly reduces SPATS2 protein expression. Vice versa, overexpression of SNHG5 leads to increased SPATS2 mRNA stability and protein expression. In vitro luciferase reporter assays demonstrated that this effect is mediated via direct interaction between a sequence motif in the SNHG5 exon 1 and the 3′ UTR of SPATS2, although we cannot rule out other interactions modes with other targets or in other cellular contexts. Importantly, manipulating the expression levels of SPATS2 in CRC cells phenocopies the cellular viability response following SNHG5 depletion or overexpression. Finally, restoring the expression of SPATS2 in SNHG5-depleted cells resulted in a partial rescue of the apoptotic phenotype induced by the inhibition of lncRNA. Hence, SPATS2 is a key downstream target of SNHG5. Interestingly, we find that the expression levels of SNHG5 and SPATS2 display a significant negative correlation in adenomas and xenograft tumours following SNHG5 knockdown, suggesting a contribution of the SNHG5–SPATS2 axis to tumorigenic events in CRC.
Several RNA-binding proteins have been described to regulate mRNA stability and decay33. Here, we demonstrate in CRC cells that the SNHG5–SPATS2 interaction impairs SPATS2-association with STAU1, a major regulator of the cytoplasmic RNA decay. STAU1 is part of a highly conserved family of double-stranded RNA-binding proteins implicated in mRNA transport, stability and translation; these processes depend on the ability of STAU1 to bind intra- or intermolecular RNA duplexes, most prominently found in 3′ UTRs of target mRNAs, and to recruit components of the cytosolic decay machinery, such as UPF1 (ref. 13). STAU1 is ubiquitously expressed, and whereas an important role for STAU1 in the development of the central nervous system has been described, the involvement of STAU1 in tumorigenic processes remains largely unexplored. STAU1 has previously been linked to lncRNA functions as a post-transcriptional regulator of the stability of specific mRNAs involved in epidermal terminal differentiation21,34 and cell cycle entry in gastric cancer cell lines35. We analysed a recently published hiCLIP dataset for STAU1 (ref. 17) and did not find such sites in SPATS2. This, however, is unsurprising as that study was performed in HEK293 cells in which SPATS2 is very lowly expressed. Although we cannot rule out an impact of STAU1 on SPATS2 translation, our data show that SPATS2 is sensitive to STAU1-mediated mRNA decay and that SNHG5 can limit the association of STAU1 to SPATS2. We also observe that STAU1 knockdown rescues the apoptotic phenotype resulting from SNHG5 depletion, thus demonstrating a genetic interaction between the SNHG5 and STAU1, promoting the stabilization of SPATS2. An intriguing hypothesis is that the up-regulation of SNHG5 during early stages of tumour progression may be required in the transforming cells to buffer the STAU1-mediated destabilization occurring on the SPATS2 mRNA, as well as other target mRNAs, hence promoting the survival of the pre-cancerous cells. Hence, inhibition of STAU1 decay activity on specific mRNA target provides an intriguing hypothesis for important early steps in CRC development but additional studies are needed to evaluate the overall importance of this mechanism.
Altogether, our data describe a role of SNHG5 in regulating cell survival in CRC and suggests SNHG5 as a potential candidate for RNA-based anti-cancer drug studies.
Methods
Cell culture and animal experiments
HCT116, LS174T and HT-29 CRC cell lines were maintained in McCoy’s medium (Invitrogen) supplemented with 10% fetal bovine serum (Hyclone) and penicillin/streptomycin (Invitrogen). CACO-2, and SW620 and HEK293 FT cell lines were maintained in DMEM medium (Invitrogen) supplemented with 10% fetal bovine serum and penicillin/streptomycin. DLD-1 cell line was maintained in RPMI medium (Invitrogen) supplemented with 10% fetal bovine serum and penicillin/streptomycin. Cell lines were obtained from the ATCC. DNA plasmids were transfected at a final concentration of 2.5 μg ml−1 by forward transfection using FuGENE HD Transfection Reagent (Promega, Fitchburg, WI, USA) according to manufacturer’s procedures. siRNA oligonucleotides (listed in Supplementary Table 3) were transfected at a final concentration of 50 nM by reverse transfection using RNAiMAX (Invitrogen), according to the manufacturer’s instructions. Cells were treated with oxaliplatin (EIMC United pharmaceutical) in aqueous solution at indicated concentrations and times, where appropriate. For the RNA stability assay the cells were treated at the indicated time points with 5 μg ml−1 Actinomycin D or 10 μM Triptolide (Sigma, St Louis, MO, USA). NMRI-nude adult females were obtained from Janvier Labs. All mouse experiments were approved by Dyreforsøgstilsynet according to Danish legislation (licence number 2012-15-2934-00306).
Tissue samples preparation and microarray analysis
The cancer specimens included in this study are from the colorectal cancer biobank at the Department of Molecular Medicine, Aarhus University Hospital. A total of 44 MSS and MSI primary stage I–IV (T2-4, N0-3, M0/1) CRCs, 39 adenomas and 20 normal colon mucosa samples were used in the array analyses. Finally, 280 fresh frozen microsatellite stable (MSS) or microsatellite instable (MSI), primary stage I-IV (T2-4, N0-3, M0/1) CRCs, 33 adenomas and 294 normal colon mucosa were used for validation using RNA-seq. The samples were obtained directly from surgery after removal of the necessary amount of tissue for routine pathology examination. Patients who had received preoperative chemotherapy and/or radiation of rectal cancers were excluded. Postoperatively, the tumours were histologically classified and staged according to the TNM system. Cases with hereditary colorectal cancer syndromes were not included in the study. The use of the human tissue samples for research purpose was approved by the Central Denmark Region Committees on Biomedical Research Ethics (DK; 1999/4678). Informed written consent was given by all participants. RNA from both tissues and cell lines was extracted using the RNeasy Mini kit following the manufacturer’s instructions. The microarray platform and analysis was previously described18. Arrays were normalized using the RMA implementation of the oligo software package and subsequently analysed using the LIMMA package. For differential transcript expression analysis, a linear model was fitted to the expression data.
RNA-FISH
HCT116 and TIG-3 human fibroblast were seeded and reverse transfected with the indicated siRNAs in chamber glass slides (LAB-TEK). Twenty-four hour after transfections, the cells were fixed in 3.7% formaldehyde (cat. 28906, Thermo Scientific, Rockford, IL, USA) overnight. Permeabilization was carried out with 70% EtOH at 2–8 °C for at least 60 min followed by 30 min incubation with 0.1 M triethanolamine (Sigma)+0.5% (v/v) acetic anhydride (Sigma) in water at room temperature (RT). The slides were prehybridized for 1 h at 55 °C with 100 μl of pre-hybridization buffer (50% formamide (Sigma)+5 × SSC+5 × Denhardts solution+0.5% Tween20 (Thermo scientific)). dFAM-labelled LNA-probes (Exiqon) were added to a final concentration of 20–30 nM in 100 μl of pre-hybridization buffer and incubated at 55 °C for 1 h in a humidified chamber. The slides were washed 3 × 10 min in 0.1 × SSC (Ambion) at 55 °C, followed by 3 × 2 min wash in 1 × PBS (Gibco) at room temperature and subsequently blocked in blocking buffer (10% heat inactivated goat serum (cat. 34864, Sigma)+0.5% blocking reagent in PBS-Tween) for 1 h at RT. For each slide 150 μl anti-FAM-POD diluted 1:40 in blocking buffer was added and incubated for 1 h at room temperature. The slides were washed twice 2 min in 1 × PBS and 50 μl Cy3-TSA substrate diluted 1:50 in diluent and incubated in the dark for 10 min at room temperature. Finally, the slides were mounted with DAPI (Life Technologies) nuclear stain. The SNHG5 probe can be obtained from Exiqon.
Vector construction
We amplified the entire SNHG5 genomic locus (±200 bp upstream and downstream the locus) by PCR (HiFi Platinum Taq, Invitrogen) using the following primers: gSNHG5 FW 5′-TACTGGCTGCGCACTTCG-3′, gSNHG5 RV 5′-TACCCTGCACAAACCCGAAA-3′. The amplicon was extracted from gel and cloned in pGEM T-Easy vector system (Promega) and further subcloned into pcDNA 3.1(+) (Invitrogen). The SNHG5 cDNA sequence was synthetically cloned in pUC57 backbone (Genescript technology) and subcloned into pcDNA 3.1. The pSNHG5 cDNA mutants were obtained using a Quickchange mutagenesis kit (Agilent) following manufacturer’s instructions. The primers used for the mutagenesis are listed in Supplementary Table 1. The lentiviral vector for the stable expression of SPATS2 cDNA (PLOHS_ccsbBEn_03998, GE Dharmacon) was used as template for subcloning into pcDNA 3.1(+) backbone using the following primers: SPATS2 cDNA forward EcoRI 5′-GAATTCGTGGCTCTAGAAGGGGAGGTGG-3′; SPATS2 cDNA reverse EcoRI 5′-GAATTCAATTAAATGCTACTTTCTCATAG-3′.
Crystal violet staining
Cells were seeded and reverse transfected in 6-well plates. Twenty-four, forty-eight and seventy-two hour after transfection, cells were washed twice in PBS (Gibco) and fixed with 4% formalin (Sigma) for 10 min, and stained with 0.1% crystal violet solution (Sigma). The amount of crystal violet staining was quantified using the ‘ColonyArea’ ImageJ plugin (Promega).
EdU incorporation assays
Cells grown in 6-well plates (NUNC) under appropriated conditions were pulsed with EdU (33 μM) for 20 min before fixation. The EdU was detected using Click-IT EdU Alexa-Fluor 647 Flow Cytometry Assay Kit (Molecular Probes, Life Technologies), according to the manufacturer’s protocol. Data were obtained by flow cytometric analysis of 15,000 cells per treatment and analysed with the FlowJo 887 software (Tree Star, Ashland, OR, USA).
Cleaved Caspase-3 staining
Cells were reverse transfected using RNAiMax reagent (Invitrogen) in six-well plates (NUNC). 36 h after transfection the cells were harvested and fixed in 4% formaldehyde methanol-free (Thermo Scientific) and incubated for 30 min on ice in 90% methanol in 1 × PBS pH 7.4 (Gibco). The cells were first stained with anti-cleaved Caspase-3 antibody (#9664, Cell signaling) in 1 × PBS-2% BSA (Sigma) for 1 h at room temperature in the dark, washed twice in 1 × PBS-2% BSA and stained with Alexa-Fluor 647 goat anti-rabbit secondary antibody (Life technology) for one additional hour at room temperature protected from light. For propidium iodide staining, the labelled cells were incubated in propidium iodide (Sigma) and RNase-A (Sigma) solution for 30 min at 37 °C. Data analysis was performed using the FlowJo 887 software.
Western blot analysis
Cells were seeded and reverse transfected in 6-well plates (NUNC). After 36 h, cells were harvested, washed once with PBS and the pellets lysed in RIPA buffer (150 nM NaCl, 0.1% sodium deoxycholate (Sigma), 0.1% SDS (Sigma), 50 mM Tris–HCl (pH 8), 1 mM EDTA (Sigma)) containing protease inhibitors (Complete Mini Protease Inhibitor Cocktail; Roche Applied Science). Proteins were separated by electrophoresis in 4–12% NuPAGE Bis–Tris gels (Invitrogen) and transferred to nitrocellulose membranes. The primary antibodies used were: GAPDH (Santa Cruz, sc-25778), cleaved PARP-1 (Cell signaling, 5625), PITRM1 (Pierce, PIEAPA531558), GLE1 (Abcam, ab69968), SPATS2 (Santa Cruz, sc-390306), Bcl-xL (Cell Signaling, 2762), Bcl-2 (Cell Signaling, 2876), STAT3 (Cell Signaling, 9132) and STAU1 (Proteintech, 14225-1-AP). Un-cropped scans of all western blots presented in the main figures are presented in Supplementary Fig. 8.
Northern blot
Cells were seeded and reverse transfected in 6-well plates (NUNC). After 36 h total RNA was isolated using Trizol reagent (Invitrogen). The RNA was separated by electrophoresis in 10% TBE-Urea gel (Acrylamide 10%, TBE-Urea 7M, APS 1 × , Temed 1 × ) and transferred to nitrocellulose membranes (Amersham). The membrane was cross-linked once at 120,000 μJ cm−2 with Stratalinker UV Crosslinker (Stratagene). Pre-hybridization was carried out at 50 °C for 1 h in Rapid hyb buffer (Amersham). The DNA probes were 32P-labelled with T4 PNK kinase (New England Biolabs) and the hybridization carried out 1.5 h at 50 °C. The membrane were 20 min in 50 ml 5 × SSC, 0.1% (w/v) SDS at room temperature and 2 × 15 min in 50 ml 1−0.1 × SSC, 0.1% (w/v) SDS at 50 °C. The probe signal was detected using FujiFilm Fluorescent Image Analyzer FLA-3000. DNA probes used were as follows:
U50 5′-TATCTCAGAAGCCAGATCCG-3′; The RNU6B probe was obtained from Exiqon.
Cell fractionation
Cells were grown in 15 cm dishes (NUNC). For each sample 1 million cells were harvested and the nuclear/cytoplasmic fractionation was performed using Nuclei EZ Lysis Buffer (Sigma), following the manufacturer’s protocol. In the SNHG5 siRNA pool knockdown experiments HCT116 cells were harvested 36 h after transfection using RNAiMax (Invitrogen).
RNA extraction and qRT–PCR analysis
Total RNA was isolated using Trizol reagent (Invitrogen), treated with TURBO DNase (Ambion, Life Technologies) and reverse transcribed using TaqMan Reverse Transcription kit (Applied Biosystems) using random hexamer primers. QRT–PCRs were performed using Sybr Green PCR Fast PCR Master Mix 2 × (Applied Biosystems). The house- keeping genes RPLP0, HPRT1 and GAPDH were used for normalization of qRT–PCR data, unless otherwise stated. The primers used are listed in Supplementary Table 1.
RNA sequencing
HCT116 cells were reverse transfected with All-star negative control (Qiagen), siSNHG5-1 or siSNHG5-2 for 36 h in 6-well plates (NUNC). RNA was extracted from three biological replicates, the quality assessed on the 2100 expert Bioanalyzer (Agilent) and sent for library preparation and sequencing on the Illumina Hiseq2000 by BGI Genomics (Hong Kong).
In vitro transcription and copies number quantification
Templates containing the T7 promoter were generated by PCR with high-fidelity DNA polymerase Platinum Taq (Invitrogen). PCR products were purified from agarose gels and 250 ng of template was in vitro transcribed using T7 RNA polymerase and the MAXIscript kit (Ambion, Life Technologies) for overnight at 37 °C. After 30 min DNAse treatment with TURBO DNA free at 37 C, the reactions were stopped by adding 0.5 mM EDTA. The concentration of the transcript was measured by A260 values and converted to the number of copies using the molecular weight of the RNA. Dilutions of this transcript were retro-transcribed as described above and the complementary DNA was used as standard curve for qPCR. The primers used for qPCR are: SPATS2 T7 forward 5′-GGATCCTAATACGACTCACTATAGTAGAAGGGGAGGTGGAGGAT-3′; SPATS2 T7 reverse 5′-GGATCCGCATTGGGCATTTTGAAGAA-3′; SNHG5 T7 forward 5′-GGATCCTAATACGACTCACTATAGCGGGTGGTAGGAACAATGG-3′; SNHG5 T7 reverse 5′-GGATCCTTTCATGTTTGTAAAACGAAGAGC-3′.
Luciferase assay
Luciferase reporter constructs containing regions of the SPATS2 (NM_001293286.1) and GLE1 (NM_001003722) 3′ UTRs were cloned into pMIR-REPORT firefly luciferase vector (Ambion). pRL-Tk Renilla luciferase reporter was used as transfection control and luciferase assay normalization. The assays were performed 48 h after transfection of the indicated constructs into 2.4 × 104 HEK293 cells per well (four wells each samples) seeded in 96-well plates. The cells were transfected with 50 ng of firefly luciferase vectors and 1 ng of the pRL-Tk Renilla reporter. The firefly reporters were competed by co-transfecting 50 ng of pcDNA 3.1 (+) expressing the SPATS2 cDNA. The reporter activities were measured using the Dual Glo Luciferase assay System (Promega) and GloMax Multi Detection System (Promega). The following primers were used for the fragment subcloning PmeI–HinIII into pMIR-REPORT: SPATS2 3′ UTR forward PmeI primer 5′-GTTTAAACGCCTCTATCCCAGAATGTGC-3′ and reverse HindIII primer 5′-AAGCTTTGCTACTTTCTCATAGACTTCCCTA-3′; GLE1 3′ UTR forward PmeI primer 5′-GTTTAAACCCTCCCTTGTCTCTAGTGTCTT-3′ and reverse Hind III primer 5′-AAGCTTCAACCATAACCCAGACTTGCAT-3′.
In vivo imaging acquisition to follow tumour development
A luminescent variant of the HCT116 cell lines were generated by transduction with the pFULT lentiviral vector containing the luciferase2-tdTomato cassette as described before36. The shRNA expressing cassettes harbouring a Tet-inducible promoter were generated as described previously by other labs37. Two millions freshly harvested cells from these shRNA subclones (200 μl from a stock solution of 10 millions cells per ml of PBS) were subcutaneously injected into the right flank of 22 weeks old NMRI-nude adult females (Janvier Labs). Tumour growth was measured based on the luminescent signal using the IVIS Lumina II system (Perkin Elmer), every 2–4 days from 1 week after cells injection. Mice were treated with doxycycline (ad libitum, active compound diluted in drinking water at 2.5 mg ml−1, from Piggidox powder, Boehringer Ingelheim) when shGFP tumours reached an average of 100 mm3. The doxycycline solution was changed every 2–3 days until the end of the experiment. The shRNA sequences are listed in Supplementary Table 3.
RNA interactome analysis and sequencing
HCT116 cells were collected (30 million per sample) and resuspended in 20 ml of PBS containing 1% Glutaraldehyde (Sigma) for 10 min at room temperature rotating. Glutaraldehyde was quenched with 2 ml of 1.25 M Glycine (Sigma) (1/10 total volume) for 5 min. The cell pellets were lysed in 2 ml lysis buffer (Tris–Cl pH 7 50 mM, EDTA RNAse-free 10 mM, SDS 1%, PMSF 1 × , protease inhibitor cocktail, Superase-In (Invitrogen)) and sonicated four times (25 cycles each, high pulse 30″ ON–45″OFF) using a BIORUPTOR (Diagenode). Cell lysates were centrifuged for 20 min @at 4 °C × 16,100g and the supernatant aliquoted for the immunoprecipitation. The lysates were pre-cleared for 30 min at 4 °C with 50 μl DynabeadsMyOne Streptavidin C1 (Life Technologies) in 2 ml of Hybridization solution (NaCl 750 mM, SDS 1%, Tris–Cl pH 7 50 mM, EDTA 1 mM, formamide 15%, PMSF 1 × , protease inhibitor cocktail, Superase-In, yeast RNA (Ambion) 0.1 mg ml−1). One ml of hybridization buffer containing 100 pmol of probes per ml of lysate was added to each sample and incubated for 4 h at 37 °C rotating. In parallel, the beads for the immunoprecipitation were blocked in hybridization solution 30 min at 4 °C. We added 100 μl of beads per 100 pmol of probes and incubated rotating 30 min at 37 °C. The samples were washed five times (5 min each) in 1 ml washing buffer (2 × SSC, SDS 0.5%, PMSF 1 × ) at 37 °C rotating. Each sample was Proteinase K (Invitrogen) treated for 45 min at 50 °C shaking before RNA was extracted. A total of 150 ng from each sample were sent for library preparation and sequencing on the Illumina Hiseq2000 at BGI Genomics (Hong Kong) using Truseq protocol. Primers and biotinylated probes sequences used for the pull-down and experiment validation are listed in Supplementary Tables 2 and 3, respectively.
RIA-seq bioinformatics analysis
Trimming. The short reads were trimmed using cutadapt to remove errors such as, for example, trailing adapter sequences. The following deviations from default were used: error-rate=0.05, minimum-length=25, overlap=4, quality-cutoff=20 as well as a list with the relevant Illumina adapter sequences given to the ‘-a’ option.
Mapping. Because the reads were generated from a mixture containing post-spliced mRNA, it was necessary to use a mapping approach that takes splice junctions into account. We used the STAR aligner with default options except for outFilterMismatchNoverLmax=0.1 and outFilterMatchNmin=16.
Peak calling. Peak calling was accomplished using the MACS2 algorithm with the following non-default options: P=1e−3, to-large, nomodel and shiftsize=X, where ‘X’ (the peak shift) was estimated individually for each sample using the SPP programme. The fLUC samples were pooled and used as reference background. The IDR algorithm was used to post-process the MACS2 results and to estimate the number of reproducible peaks from the two ODD sample replicates. Owing to a failed replicate, however, the IDR algorithm could not be applied to the EVEN condition, and instead the numbers of reproducible peaks for EVEN were extrapolated from the ODD condition. This gave a conservative result of 736 peaks and an optimal result of 905 peaks for both conditions, although any peaks called in intron areas were then subsequently removed, as these are most likely errors arising from an incorrect peak shift.
Motif finding. We used the meme-chip programme for motif finding. As input for meme-chip we used a region of 250 bp flanking each peak summit, for a total of 501 bp long sequences extracted from both ODD and EVEN peak lists. To prevent biases between the sizes of the two sets, sequences were randomly extracted from the larger set (EVEN) until the size of the smaller (ODD) was reached. Default parameters were used except that ‘-norc’ was used. This option prevents the programme from searching the reverse complement, which is irrelevant here as the sequences under consideration are single-stranded RNA.
RNA immunoprecipitation
HCT116 cells were cross-linked using 1500 μJ cm−2 and collected in cold PBS. Fifty millions cells per samples were subjected to nuclear/cytoplasmic fractionation using Nuclei EZ Lysis Buffer (Sigma), cytoplasmic fractions were collected and the volume adjusted in 2 × polysome buffer (Tris–Cl pH 7.4 20 mM, NaCl 200 mM, MgCl2 2.5 mM, Triton-X 1%, DTT 1 mM, protease inhibitor cocktail, Superase-In). Lysates were pre-cleared with yeast RNA (0.1 mg ml−1) and recombinant protein G agarose (Thermo Scientific) for 30 min at 4 °C. One per cent of the sample were used as input, the remaining samples incubated with STAU1 antibody (Proteintech, 14225-1-AP) or IgG from rabbit serum (I5006, Sigma) overnight at 4 °C, The RNA-antibody complexes were collected by incubation with Dynabeads protein G beads (Invitrogen). The samples were washed four times and Proteinase K treated before the RNA was extracted for qRT–PCR analysis.
RNA–RNA interaction prediction
Thermodynamic stable interaction sites of SNHG5 (ENST00000414002), the 3′ UTR of SPATS2 (NM 001293285.1) and the 3′ UTR of GLE1 (NM 001003722.1) were predicted with IntaRNA (version 1.2.5; default parameters)38. The interaction sites of lowest energy with SPATS2 (−15.50 kcal mol−1) and GLE1 (−14.7 kcal mol−1) span the exons 1 and 2 of SNHG5. The conservation of the interaction site was tested with PETcofold (version 3.2; maximal percentage of gaps in alignment column -g is set to 0.5)39. The transcript alignments were extracted from the genome-wide hg19 46way multiz alignments. We used the ‘Stitch MAF blocks’ function of the Galaxy browser to get a connected alignment for each exon, removed all sequences with more than 50% gaps from the alignments, and concatenated exons of the species that occurred in all exons.
Statistical testing
All P values are calculated using a two-tailed Student’s t-test, unless otherwise stated. For the analysis of the growth curves from the xenograft experiment, the following method was applied: Categoric variables were reported by means of contingency tables. Furthermore, for continuous variables, median and range were computed. To investigate their associations with the product and group parameters, univariate statistical analyses were performed using Kruskal–Wallis or Mann–Whitney non-parametric test. Moreover, multivariate analyses were carried out. Linear mixed-regression model, containing both fixed and random effects, was used to determine the relationship between luminescence growth and number of days after injection. The fixed part of the model included variables corresponding to the number of post-injection days and the different product treatments. Interaction terms were built into the model; random intercepts and random slopes were included to take time into account. The coefficients of the model were estimated by maximum likelihood and considered significant at the 0.05 levels. The power of analysis was reduced because of the limited number of xenograft tumours and few tumours did not have measurements for all variables. All P values reported are two sided and the significance level was set at 5% (P<0.05) Statistical analysis was performed using the STATA 13 software (Stata Corporation, College Station, TX, USA).
Data availability
The datasets generated during and/or analysed during the current study are available: the CRC microarray data: GSE76713. The CRC RNA-seq data: Supplementary Table 4. The RNA-seq data from HCT116 cells with knockdown of SNHG5: GSE76801. The RIA-seq data from HCT116 cells for SNHG5: GSE76792.
Additional information
How to cite this article: Damas, N. D. et al. SNHG5 promotes colorectal cancer cell survival by counteracting STAU1-mediated mRNA destabilization. Nat. Commun. 7, 13875 doi: 10.1038/ncomms13875 (2016).
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Acknowledgements
We thank Disa E. Tehler and Sophia J. Häfner for commenting on the manuscript; Kim Holmstrøm (Bioneer) for help with the RNA in situ hybridization experiments, and Steen Holmberg and Darima Petersen for help with the polysome profile experiments (Copenhagen University, DK). We thank Pr. Sanjiv Sam Gambhir (Stanford University, USA) for providing the pFULT lentiviral vector. Work in the Lund laboratory was supported by funding from the People Programme (Marie Curie Actions) of the European Union’s Seventh Framework Programme FP7/2007-2013/ under REA Grant Agreement 607720, the Danish Council for Independent Research (Sapere Aude programme), the Novo Nordisk Foundation, the Lundbeck Foundation, the Danish National Research Foundation (DNRF82) and the Danish Cancer Society.
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N.D.D. and A.H.L. designed the experiments, analysed the data and wrote the manuscript. All coauthors commented on the manuscript. N.D.D., M.M., C.C. and H.M.G. conducted the experiments. M.M.N., C.F.R., S.S., N.R., S.V. S.T. and J.S.P. performed bioinformatics analyses. L.L.C., T.Ø. and C.L.A. contributed clinical samples and analyses hereof, and R.B. contributed technical expertise on the RIA-seq protocol. All authors commented on the manuscript.
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Damas, N., Marcatti, M., Côme, C. et al. SNHG5 promotes colorectal cancer cell survival by counteracting STAU1-mediated mRNA destabilization. Nat Commun 7, 13875 (2016). https://doi.org/10.1038/ncomms13875
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DOI: https://doi.org/10.1038/ncomms13875
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