| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
|
|
|
|||||||
|
|||||||||
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
FOCUS REVIEW |
1 Laboratory of Cellular and Molecular Biology, National Institute on Aging, NIH Biomedical Research Center, 251 Bayview Boulevard, Suite 100, Room 6C228, Baltimore, Maryland 21224, USA
2 Department of Pathology, Johns Hopkins Medical Institutions, Baltimore, Maryland 21287, USA
(Correspondence should be addressed to P J Morin at Laboratory of Cellular and Molecular Biology, National Institute on Aging, NIH Biomedical Research Center; Email: morinp{at}mail.nih.gov)
This paper is one of 6 papers that form part of a special Focus Section on microRNAs. The Guest Editors for this section were Professor Alfredo Fusco, Naples, Italy, and Professor Carlo M Croce, Columbus, OH, USA.
 |
Abstract |
|---|
|
Introduction |
|---|
|
miRs |
|---|
22 nt long functional mature miR. The mature miR can then assemble into a ribonucleoprotein complex known as the RNA-induced silencing complex (RISC) to participate in RNA interference (Pratt & MacRae 2009). While the exact composition of the RISC is not fully known and may be somewhat variable, the main components are: 1) members of the Argonaute family of proteins, which bind directly to the small regulatory RNA, and 2) a small regulatory RNA (such as miR or siRNA) that directs the complex to its mRNA targets through direct base-pairing. Through the RISC, miRs can down-regulate their targets by inhibiting mRNA translation and/or promoting mRNA degradation. The mode of repression may depend, in part, on the level of complementarity of the miRs (with perfect or near-perfect complementarity favoring mRNA degradation). The mechanism of target regulation is complex, but recent work suggests a two-step process by which translation inhibition occurs first and is then followed by mRNA decay due to deadenylation of the mRNA (Fabian et al. 2009). The extent of each of these processes may be variable, and this may account for the observation that target mRNAs are sometimes found to be inhibited exclusively at the mRNA stability level, exclusively at the translational level, or through a combination of both mechanisms. The 5' region of a miR, called the ‘seed region’ (nucleotides 2–8 of the miR), is crucial for miR targeting and function, although other factors are also important (Bartel 2004, Grimson et al. 2007). In mammals, miR target sites are often imperfect and located in the 3' UTR of the target genes (Gu et al. 2009), although they can also be found in the 5' UTR or even in the coding region. Because miRs do not require perfect complementarity for functional interactions with mRNA targets, a single miR can regulate multiple targets and conversely, multiple miRs are known to regulate individual mRNAs (Lewis et al. 2003). In addition to down-regulating their target genes, miRs have also been reported to activate some targets (Vasudevan et al. 2007).
While miR genes are typically expressed from their own promoters in intergenic regions, a significant portion of miR genes are located within other transcriptional units (Baskerville & Bartel 2005), usually in intronic regions, but sometimes in exonic regions as well. The exact mechanisms by which these intragenic miRs are processed still remain to be elucidated but appear to be Drosha-independent. The expression of these miRs is coupled with their host genes and subjected to the same regulatory controls (Baskerville & Bartel 2005). Intronic miRs can regulate genes involved in pathways of the host genes, adding to the complexity of these regulatory loops (Barik 2008).
|
miR targets |
|---|
As indicated above, in addition to computational methods, several functional approaches are being used to identify actual targets of miRs. A straightforward approach consists of over-expressing or down-regulating specific miRs in cultured cells and examining the effects on mRNA and/or protein levels using gene expression profiling or proteomics approaches. This approach was used, for example, to identify mRNAs regulated by miR-1 and miR-124 (Lim et al. 2005), and this was done by over-expressing those miRs and observing the resulting changes in gene expression using microarrays. While this type of experiments identifies regulation at the mRNA stability levels, translational regulation can be addressed by performing proteomics analyses (Grosshans & Filipowicz 2008). Stable isotope labeling by amino acids in cell culture (SILAC) followed by mass spectroscopy has been a particularly useful approach in the investigation of the translational effects of miRs. SILAC has been used to identify miR-1 targets in HeLa cells (Vinther et al. 2006), and these targets exhibited a significant overlap with targets identified using microarrays. Similarly, other studies confirmed that the levels of hundreds of proteins were affected following changes in the expression of specific miRs (Baek et al. 2008, Selbach et al. 2008). As a whole, these studies showed that miR expression often led to simultaneous mRNA degradation and protein translation inhibition of the targets, and that these effects were dependent on the presence of seed sequences in the 3' UTR of the target mRNAs.
Finally, a number of biochemical methods have been designed to directly identify the interactions between the miRs and their corresponding targets. For example, labeled/tagged miRs have been used in pull-down experiments to identify mRNAs that these miRs can bind to Orom & Lund (2007) and Hsu et al. (2009). In addition, it is well known that miRs are part of the RISC complex along with different members of the Argonaute (Ago) family, and this property has been used to enrich for targets of specific miRs. For example, following forced expression of miR-124a, immunoprecipitation of Ago2 led to the enrichment of known miR-124a targets (Karginov et al. 2007). Interestingly, the mRNAs that were significantly enriched by immunoprecipitation included targets that were also down-regulated in total mRNA, and these targets were very likely to contain the seed site. Another approach consists of synthesizing cDNA clones from known mRNA templates using endogenous miRs as primers (Vatolin et al. 2006). Sequencing of the synthesized cDNAs then allows the identification of the miRs as well as the binding sites on the mRNA.
|
miRs and cancer |
|---|
Important insights into the mechanisms of miR function in cancer have been provided through the demonstration that miRs are involved in known oncogenic pathways. For example, the three human RAS oncogenes (H-, K-, and N-RAS) all contain let-7 sites in their 3' UTR (Johnson et al. 2005). Interestingly, the let-7 family of miRs, which is typically down-regulated in various tumors, has been shown to negatively regulate the RAS oncogenes in lung tumors, therefore acting as tumor suppressor genes (Johnson et al. 2005, Kumar et al. 2008). Similarly, miR-15 and miR-16 have been shown to target the BCL2 oncogene, leading to its down-regulation and apoptosis in leukemic cells (Cimmino et al. 2005). As an example of miRs acting as oncogenes, miR-221 and miR-222 can target and inhibit the expression of the p27Kip tumor suppressor (le Sage et al. 2007). Indeed, high levels of these miRs were shown to maintain low p27 protein and elevated proliferation. Another oncogenic pathway, the p53 pathway, also includes miR components. In fact, the p53 tumor suppressor has been shown to transcriptionally induce miR-34 following genotoxic stress and this induction is important in mediating p53 function (Chang et al. 2007, He et al. 2007, Raver-Shapira et al. 2007, Tarasov et al. 2007).
There is evidence that miR expression patterns may be useful in cancer diagnosis and outcome prediction. Indeed, miR profiling of normal versus tumor tissues using various techniques has consistently shown a large number of deregulated miR genes, most of which are typically down-regulated (Calin & Croce 2006b). Interestingly, in a pioneering study that included 334 cancer samples from multiple cancers, the global expression patterns of miRs were found to be extremely accurate in distinguishing lineage and differentiation state (Lu et al. 2005). Most of the changes were again found to be down-regulation of the miRs and a subsequent study showed that a general down-regulation of miRs in cells (achieved through a knockdown of miR processing enzymes) led to enhanced cellular transformation and tumorigenesis, suggesting a crucial role for these genes in the process of transformation (Kumar et al. 2007).
|
miR expression in ovarian carcinoma |
|---|
|
An integrative genomic approach that included miR microarray, array-based comparative genomic hybridization, cDNA microarray, and tissue array was used to evaluate miR changes in epithelial ovarian cancer (Zhang et al. 2008). The authors found that both genomic losses and epigenetic alterations may be responsible for miR down-regulation. Out of 35 miRs deregulated between ovarian carcinoma and the normal controls (immortalized ovarian surface epithelial cells), 31 (88.6%) were down-regulated in cancer tissues compared with non-cancer tissues. The down-regulated genes included miRs let-7d and miR-127, which had been previously implicated in cancer. Thirteen miRs were down-regulated in high-grade tumors compared with low-grade tumors. Furthermore, down-regulation was higher in late-stage cancers as compared with early-stage cancers, suggesting a tumor suppressor function for the down-regulated miRs. Among 44 miRs down-regulated in late-stage tumors, three miRs, miR-15a, miR-34a, and miR-34b are believed to be tumor suppressors.
The region containing miR-182 was amplified in 28.9% of EOC, implying an oncogene-type function for this miR, whereas, miR-15a was deleted in 23.9% of EOC suggesting a tumor suppressive role. DNA copy number amplification and deletion were correlated with miR-182 and miR-15a expressions respectively, in both primary tumors and cell lines. However, DNA copy number changes could explain the expression of only 6 of the 33 abnormally expressed miRs. EOC cell lines that were treated with DNA demethylating and histone deacetylase (HDAC) inhibitors exhibited up-regulation of 16 miRs, which suggests epigenetic modification as another crucial factor determining the expression of miRs in EOC. In the tumors, loss of miR-377, miR-368, and miR-495 cluster, which is localized at Dlk1–Gtl2 domain, results in higher proliferation and in shorter survival of the patients (Zhang et al. 2008).
Genome-wide analysis of miR copy number abnormalities in ovarian carcinoma
Using array-based comparative genomic hybridization, these authors found that genomic regions containing miR genes frequently exhibited copy number abnormalities (Zhang et al. 2006). In particular, copy number losses of the region containing miR-218-1 and SLIT2 were observed in 15.5% of ovarian carcinomas. There was a positive correlation between miR copy number changes and the miR expression levels of 73.1% of the miR genes. In addition, experiments with demethylating agents suggested that up to 33% of miRs may be regulated by epigenetic mechanisms.
Hypoxia-responsive miRs in ovarian carcinoma
The screening of a panel of 157 miRs allowed the identification of miR-210 as the most highly and consistently up-regulated miR, following hypoxia induction (Giannakakis et al. 2008). Interestingly, miR-210 is located at chromosome 11p15.5 within a frequent region of loss of heterozygosity in ovarian carcinoma. The gene copy number of miR-210 was reduced in 64% of ovarian carcinomas, and these alterations were associated with decreased levels of miR-210, suggesting a tumor suppressive function for this gene.
miR expression signature in ovarian carcinoma
In another study, 15 normal ovarian samples, 69 ovarian malignant tumors, and five ovarian carcinoma cell lines were studied by miR microarray analysis (Iorio et al. 2007). The unsupervised hierarchical clustering classified the samples into two distinct categories representing ‘normal’ and ‘cancer samples/cell lines’. A total of 29 and 39 miRs were found to be aberrantly expressed by significance analysis of microarrays (SAM) and prediction analysis of microarrays (PAM) analysis respectively. MiR-200a and miR-141 were highly up-regulated, whereas miR-199a, miR-140, miR-145, and miR-125b1 were most significantly down-regulated. Although some of the miRs were deregulated in all the subtypes, certain miRs could differentiate different subtypes (serous, endometrioid, and clear cell) of ovarian carcinomas. For example, miR-200a and miR-200c were up-regulated in all the three subtypes, miR-200b and miR-141 were up-regulated in serous as well as endometrioid, and miR-21, miR-203, and miR-205 were up-regulated only in endometrioid. Among the down-regulated miRs, miR-145 was down-regulated in serous and clear cell carcinomas, while miR-222 was down-regulated in both endometrioid and clear cell carcinomas. miR expression profiles were not dependent on the grade or stage of the disease. The treatment of ovarian carcinoma cell lines with the demethylating agent 5-aza-2'-deoxycytidine resulted in induction of miR-21, miR-203, miR-146b, miR-205, miR-30-5p, and miR-30c. Since miR-21, miR-203, and miR-205 were observed over-expressed in ovarian carcinoma, these experiments suggest that hypomethylation could be responsible for the observed expression patterns of these miRs in cancer. However, it was also interesting to observe that the most significantly up-regulated miRs belong to the same family and were localized in pairs: miR-200a and miR-200b at chromosome 1p36.33, and miR-200c and miR-141 at chromosome 12p13.31. This study is consistent with others showing that mechanisms of miR deregulation in ovarian carcinoma include copy number changes as well as epigenetic mechanisms (Zhang et al. 2006, 2008).
Identification of differentially expressed miRs in ovarian carcinoma and identification of PTEN as a target of miR-214
Using miR microarrays, 36 miRs were found deregulated between normal ovarian cells and epithelial ovarian tumors, with miR-199a*, miR-214, miR-200a, and miR-100 being the most highly differentially expressed candidates (Yang et al. 2008a). miR-199a*, miR-214, and miR-200a were up-regulated in 53, 56, and 43% tumor tissues respectively, and their expression was associated with high-grade and late-stage tumors. miR-100 was down-regulated in 76% of tumors. The authors selected miR-214 for further study and found PTEN as one of its potential targets, implicating this miR in the regulation of the AKT survival pathway.
miR expression profiles in serous ovarian carcinoma
In this study, 23 miRs were found aberrantly expressed in at least 60% of ovarian cancer samples (Nam et al. 2008a). Among 11 up-regulated miRs, miR-21 topped the list showing its expression in 85% samples; whereas among 12 down-regulated, miR-125b was the most significant and exhibited down-regulation in 95% tumor samples. Fifty percent of miRs reported in this study were also found in the Iorio study (Iorio et al. 2007). The most significantly altered miRs in both studies were: miR-200a/b/c, miR-141, miR-21, miR-145, miR-99a, let-7, and miR-125b.
Identification of miRs that are differentially expressed in ovarian carcinoma: importance of the let-7 family
Our laboratory investigated miR expression profiles in 34 ovarian carcinoma tissues as well as ten ovarian carcinoma cell lines (Dahiya et al. 2008). A total of 25 up-regulated and 31 down-regulated miRs were identified. We also found five up-regulated and 23 down-regulated miRs in ovarian carcinoma cell lines compared with non-neoplastic cells. Fourteen miRs were deregulated in both tissues and cell lines (Table 1). MiR-221 was the most highly elevated miR in both tissues and cell lines (ninefold and sevenfold respectively), while miR-21 was significantly decreased in both sample types (threefold and ninefold respectively). Among the different let-7 family members, let-7e and let-7f showed more than twofold deregulation in at least 60% of the tumor samples. The other let-7 family members (let-7g, let-7d, let-7c, let-7a-e, let-7i, let-7a, and let-7b) were not down-regulated as consistently, but each one of them was found decreased twofold or more in at least 20% of the tumors. Overall, 94% of the tumors had at least one let-7 family member down-regulated at least twofold. Cell lines exhibited down-regulation of the let-7 family members as well. This study suggested an important role for let-7 family members in ovarian carcinoma.
Comprehensive analysis of miR repertoire in ovarian carcinoma using massively parallel sequencing technologies
Using novel massively parallel sequencing technology (454 sequencing) to sequence small RNA cDNA libraries derived from epithelial ovarian cancers and normal samples, this group was able to generate comprehensive miR digital profiles for these tissues (Wyman et al. 2009). In their data, the investigators identified 498 previously annotated miRs, six novel and 39 candidate miRs. They found 124 miRs that were differentially expressed in cancers of various subtypes compared with the normal ovarian cells. A subset of 37 miRs were over-expressed in all epithelial ovarian cancer subtypes and 21 were under-expressed (Table 1). Among those, several were validated by RT-PCR. The validated over-expressed miRs included several members of the miR-200 family, while the down-regulated genes included miR-100, miR-210, miR-22, and miR-222.
|
Roles of miRs in ovarian carcinoma chemotherapy |
|---|
In a recent report where primary and recurrent cases of ovarian cancers were compared, 60 miRs were found deregulated more than twofold between primary and recurrent disease (Laios et al. 2008). In contrast to several studies reporting a majority of miRs to be down-regulated in cancer tissues, a marked up-regulation of miRs in recurrent compared with primary tumors was observed (52 miRs showed over-expression and 8 showed under-expression of >twofold in recurrent versus primary tumors). miR-223 (up) and miR-9 (down) were the most highly deregulated genes in the recurrent versus primary samples (Laios et al. 2008).
When cisplatin resistance was specifically examined for miR expression, and tumors from responders were compared with those of non-responders, 34 statistically significant changes were found (24 miRs were higher in the non-response group and 10 were higher in the complete response group; Yang et al. 2008b). Let-7i was the most down-regulated miR in the chemotherapy resistant patients. In addition, functional analyses confirmed that reduced let-7i expression increased the resistance of ovarian and breast cancer cells to cisplatin. In another study, elevation of miR-214 was found to be responsible for development of resistance against cisplatin (Yang et al. 2008a). miR-214 also has anti-apoptotic functions, as blocking miR-214 expression made A2780 cells more sensitive to cisplatin-induced apoptosis (Yang et al. 2008a). Another expression profiling study in a panel of cisplatin-, paclitaxel-, and cyclosporin A-resistant ovarian carcinoma cells revealed the expressions of let-7e, miR-30c, miR-125b, miR-130a, and miR-335 in all the resistant cell lines (Sorrentino et al. 2008). While analyzing their downstream targets, the investigators found a direct relationship between down-regulation of miR-130a with up-regulation of M-CSF, a gene already known to be up-regulated in ovarian carcinoma.
|
miR targets and pathways in ovarian carcinoma |
|---|
|
|
|
miRs in detection and diagnosis of ovarian carcinoma |
|---|
40%) compared with the group with a higher HMGA2/let-7 ratio (<10%). Another study showed that miR-214, miR-199*, and miR-200a were associated with high-grade and late-stage tumors (Yang et al. 2008a). Tumors with higher expression of miR-200a had a median overall survival of 27.5 months compared with 61 months for those with no significant expression (Nam et al. 2008a). Interestingly, polymorphisms in miRs may affect their function and be of prognostic value. For example, the precursor miR-146a, which targets BRCA1 and BRCA2, exhibits a G to C polymorphism in ovarian and breast cancers (Shen et al. 2008). This polymorphism results in a change from G:U pair to a C:U mismatch in the miR stem region. Ovarian cancer patients showing G to C polymorphism were typically diagnosed younger than the patients having common mir-146a allele (Shen et al. 2008). Additionally, with the presence of the variant allele, there was increased production of mature mir-146a that may be responsible for early onset of the disease. Interestingly, miRs can also be detected in serum samples (Feng et al. 2008, Lawrie et al. 2008, Lodes et al. 2009), suggesting that they may represent useful detection biomarkers. By RT-PCR analysis, miR-21, miR-92, miR-93, miR-126, and miR-29a were found up-regulated, while miR-155, miR-127, and miR-99b were found down-regulated in serum collected from ovarian carcinoma patients (Resnick et al. 2009). Up-regulation of miR-21, miR-92, and miR-93 in the serum of three cancer patients with normal CA-125 level suggests that miRs may be complementary to current detection approaches. Interestingly, circulating tumor-derived exosomes (small lipid vesicles) have been found to contain miRs that could potentially be used as detection and/or diagnostic markers (Taylor & Gercel-Taylor 2008). The use of exosomes-derived miRs in diagnosis may circumvent the need for biopsy material.
|
Therapeutic potential of miRs |
|---|
In addition, miRs against known oncogenes could potentially be used to repress the expression of these genes in tumors. For example, over-expression of miR-15 and miR-16 was shown to induce apoptosis in leukemic cells through the ability of these miRs to target BCL2 (Cimmino et al. 2005). Similarly, miR-34a was shown to target E2F3 and induce apoptosis in neuroblastoma cells (Welch et al. 2007). In ovarian carcinoma, let-7 is commonly down-regulated and is shown to target HMGA2 (Shell et al. 2007), a gene that may be responsible for de-differentiation during ovarian carcinoma progression (Park et al. 2007, Shell et al. 2007). Re-introduction of let-7 has therefore been suggested as a possible approach for the therapy of ovarian carcinoma (Park et al. 2007).
Finally, miR may be useful in ensuring tight tissue-specific control of transgene expression in gene therapy. Indeed, by incorporating carefully chosen specific miR target sites into a therapeutic mRNA, it may be possible to inhibit this mRNA in tissues where its expression is not wanted, thereby minimizing its toxicity and side effects (Brown & Naldini 2009). In cancer, expression of a toxic gene such as thymidine kinase, or re-expression of a tumor suppressor gene, could potentially be made more specific by including, in these transgenes, sites for miRs that are expressed in normal tissues, but not in cancer cells. Clearly, a detailed knowledge of miR expression in normal and neoplastic tissues will be crucial for the success of these approaches.
|
Perspectives |
|---|
|
Declaration of interest |
|---|
|
Funding |
|---|
|
Acknowledgements |
|---|
|
References |
|---|
Baek D, Villen J, Shin C, Camargo FD, Gygi SP & Bartel DP 2008 The impact of microRNAs on protein output. Nature 455 64–71.[CrossRef][Web of Science][Medline]
Barik S 2008 An intronic microRNA silences genes that are functionally antagonistic to its host gene. Nucleic Acids Research 36 5232–5241.
Bartel DP 2004 MicroRNAs: genomics, biogenesis, mechanism, and function. Cell 116 281–297.[CrossRef][Web of Science][Medline]
Bartels CL & Tsongalis GJ 2009 MicroRNAs: novel biomarkers for human cancer. Clinical Chemistry 55 623–631.
Baskerville S & Bartel DP 2005 Microarray profiling of microRNAs reveals frequent coexpression with neighboring miRNAs and host genes. RNA 11 241–247.
Bohnsack MT, Czaplinski K & Gorlich D 2004 Exportin 5 is a RanGTP-dependent dsRNA-binding protein that mediates nuclear export of pre-miRNAs. RNA 10 185–191.
Brown BD & Naldini L 2009 Exploiting and antagonizing microRNA regulation for therapeutic and experimental applications. Nature Reviews. Genetics 10 578–585.[Web of Science][Medline]
Calin GA & Croce CM 2006a MicroRNA-cancer connection: the beginning of a new tale. Cancer Research 66 7390–7394.
Calin GA & Croce CM 2006b MicroRNA signatures in human cancers. Nature Reviews. Cancer 6 857–866.[CrossRef][Web of Science][Medline]
Calin GA & Croce CM 2007 Chromosomal rearrangements and microRNAs: a new cancer link with clinical implications. Journal of Clinical Investigation 117 2059–2066.[CrossRef][Web of Science][Medline]
Calin GA, Dumitru CD, Shimizu M, Bichi R, Zupo S, Noch E, Aldler H, Rattan S, Keating M, Rai K et al. 2002 Frequent deletions and down-regulation of micro-RNA genes miR15 and miR16 at 13q14 in chronic lymphocytic leukemia. PNAS 99 15524–15529.
Calin GA, Sevignani C, Dumitru CD, Hyslop T, Noch E, Yendamuri S, Shimizu M, Rattan S, Bullrich F, Negrini M et al. 2004 Human microRNA genes are frequently located at fragile sites and genomic regions involved in cancers. PNAS 101 2999–3004.
Calin GA, Ferracin M, Cimmino A, Di Leva G, Shimizu M, Wojcik SE, Iorio MV, Visone R, Sever NI, Fabbri M et al. 2005 A microRNA signature associated with prognosis and progression in chronic lymphocytic leukemia. New England Journal of Medicine 353 1793–1801.
Chang TC, Wentzel EA, Kent OA, Ramachandran K, Mullendore M, Lee KH, Feldmann G, Yamakuchi M, Ferlito M, Lowenstein CJ et al. 2007 Transactivation of miR-34a by p53 broadly influences gene expression and promotes apoptosis. Molecular Cell 26 745–752.[CrossRef][Web of Science][Medline]
Cimmino A, Calin GA, Fabbri M, Iorio MV, Ferracin M, Shimizu M, Wojcik SE, Aqeilan RI, Zupo S, Dono M et al. 2005 miR-15 and miR-16 induce apoptosis by targeting BCL2. PNAS 102 13944–13949.
Corney DC, Flesken-Nikitin A, Godwin AK, Wang W & Nikitin AY 2007 MicroRNA-34b and microRNA-34c are targets of p53 and cooperate in control of cell proliferation and adhesion-independent growth. Cancer Research 67 8433–8438.
Creighton CJ, Nagaraja AK, Hanash SM, Matzuk MM & Gunaratne PH 2008 A bioinformatics tool for linking gene expression profiling results with public databases of microRNA target predictions. RNA 14 2290–2296.
Cullen BR 2004 Transcription and processing of human microRNA precursors. Molecular Cell 16 861–865.[CrossRef][Web of Science][Medline]
Dahiya N, Sherman-Baust CA, Wang TL, Davidson B, Shih Ie M, Zhang Y, Wood W III, Becker KG & Morin PJ 2008 MicroRNA expression and identification of putative miRNA targets in ovarian cancer. PLoS ONE 3 e2436.[CrossRef][Medline]
Ebert MS, Neilson JR & Sharp PA 2007 MicroRNA sponges: competitive inhibitors of small RNAs in mammalian cells. Nature Methods 4 721–726.[CrossRef][Web of Science][Medline]
Fabian MR, Mathonnet G, Sundermeier T, Mathys H, Zipprich JT, Svitkin YV, Rivas F, Jinek M, Wohlschlegel J, Doudna JA et al. 2009 Mammalian miRNA RISC recruits CAF1 and PABP to affect PABP-dependent deadenylation. Molecular Cell 35 868–880.[CrossRef][Web of Science][Medline]
Feng G, Li G, Gentil-Perret A, Tostain J & Genin C 2008 Elevated serum-circulating RNA in patients with conventional renal cell cancer. Anticancer Research 28 321–326.
Flynt AS & Lai EC 2008 Biological principles of microRNA-mediated regulation: shared themes amid diversity. Nature Reviews. Genetics 9 831–842.[CrossRef][Web of Science][Medline]
Fung-Kee-Fung M, Oliver T, Elit L, Oza A, Hirte HW & Bryson P 2007 Optimal chemotherapy treatment for women with recurrent ovarian cancer. Current Oncology 14 195–208.[CrossRef][Medline]
Garcia M, Jemal A, Ward EM, Center MM, Hao Y, Siegel R & Thun MJ 2007 In Global Cancer Facts & Figures 2007 Available: www.cancer.org. Atlanta, GA: American Cancer Society.
Giannakakis A, Sandaltzopoulos R, Greshock J, Liang S, Huang J, Hasegawa K, Li C, O'Brien-Jenkins A, Katsaros D, Weber BL et al. 2008 miR-210 links hypoxia with cell cycle regulation and is deleted in human epithelial ovarian cancer. Cancer Biology & Therapy 7 255–264.[Web of Science][Medline]
Grimson A, Farh KK, Johnston WK, Garrett-Engele P, Lim LP & Bartel DP 2007 MicroRNA targeting specificity in mammals: determinants beyond seed pairing. Molecular Cell 27 91–105.[CrossRef][Web of Science][Medline]
Grosshans H & Filipowicz W 2008 Proteomics joins the search for microRNA targets. Cell 134 560–562.[CrossRef][Web of Science][Medline]
Gu S, Jin L, Zhang F, Sarnow P & Kay MA 2009 Biological basis for restriction of microRNA targets to the 3' untranslated region in mammalian mRNAs. Nature Structural & Molecular Biology 16 144–150.[CrossRef][Web of Science][Medline]
He L, He X, Lim LP, de Stanchina E, Xuan Z, Liang Y, Xue W, Zender L, Magnus J, Ridzon D et al. 2007 A microRNA component of the p53 tumour suppressor network. Nature 447 1130–1134.[CrossRef][Medline]
Horwich MD & Zamore PD 2008 Design and delivery of antisense oligonucleotides to block microRNA function in cultured Drosophila and human cells. Nature Protocols 3 1537–1549.[CrossRef][Web of Science][Medline]
Hsu RJ, Yang HJ & Tsai HJ 2009 Labeled microRNA pull-down assay system: an experimental approach for high-throughput identification of microRNA-target mRNAs. Nucleic Acids Research 37 e77.
Hu X, Macdonald DM, Huettner PC, Feng Z, El Naqa IM, Schwarz JK, Mutch DG, Grigsby PW, Powell SN & Wang X 2009 A miR-200 microRNA cluster as prognostic marker in advanced ovarian cancer. Gynecologic Oncology 114 457–464.[CrossRef][Web of Science][Medline]
Hutvagner G, Simard MJ, Mello CC & Zamore PD 2004 Sequence-specific inhibition of small RNA function. PLoS Biology 2 E98.[CrossRef][Medline]
Iorio MV, Visone R, Di Leva G, Donati V, Petrocca F, Casalini P, Taccioli C, Volinia S, Liu CG, Alder H et al. 2007 MicroRNA signatures in human ovarian cancer. Cancer Research 67 8699–8707.
Jiang Q, Wang Y, Hao Y, Juan L, Teng M, Zhang X, Li M, Wang G & Liu Y 2009 miR2Disease: a manually curated database for microRNA deregulation in human disease. Nucleic Acids Research 37 D98–104.
John B, Enright AJ, Aravin A, Tuschl T, Sander C & Marks DS 2004 Human microRNA targets. PLoS Biology 2 e363.[CrossRef][Medline]
John B, Sander C & Marks DS 2006 Prediction of human microRNA targets. Methods in Molecular Biology 342 101–113.[Medline]
Johnson SM, Grosshans H, Shingara J, Byrom M, Jarvis R, Cheng A, Labourier E, Reinert KL, Brown D & Slack FJ 2005 RAS is regulated by the let-7 microRNA family. Cell 120 635–647.[CrossRef][Web of Science][Medline]
Karginov FV, Conaco C, Xuan Z, Schmidt BH, Parker JS, Mandel G & Hannon GJ 2007 A biochemical approach to identifying microRNA targets. PNAS 104 19291–19296.
Krek A, Grun D, Poy MN, Wolf R, Rosenberg L, Epstein EJ, MacMenamin P, da Piedade I, Gunsalus KC, Stoffel M et al. 2005 Combinatorial microRNA target predictions. Nature Genetics 37 495–500.[CrossRef][Web of Science][Medline]
Kumar MS, Lu J, Mercer KL, Golub TR & Jacks T 2007 Impaired microRNA processing enhances cellular transformation and tumorigenesis. Nature Genetics 39 673–677.[CrossRef][Web of Science][Medline]
Kumar MS, Erkeland SJ, Pester RE, Chen CY, Ebert MS, Sharp PA & Jacks T 2008 Suppression of non-small cell lung tumor development by the let-7 microRNA family. PNAS 105 3903–3908.
Laios A, O'Toole S, Flavin R, Martin C, Kelly L, Ring M, Finn SP, Barrett C, Loda M, Gleeson N et al. 2008 Potential role of miR-9 and miR-223 in recurrent ovarian cancer. Molecular Cancer 7 35.[CrossRef][Medline]
Lawrie CH, Gal S, Dunlop HM, Pushkaran B, Liggins AP, Pulford K, Banham AH, Pezzella F, Boultwood J, Wainscoat JS et al. 2008 Detection of elevated levels of tumour-associated microRNAs in serum of patients with diffuse large B-cell lymphoma. British Journal of Haematology 141 672–675.[CrossRef][Web of Science][Medline]
Lee RC, Feinbaum RL & Ambros V 1993 The C. elegans heterochronic gene lin-4 encodes small RNAs with antisense complementarity to lin-14. Cell 75 843–854.[CrossRef][Web of Science][Medline]
Lewis BP, Shih IH, Jones-Rhoades MW, Bartel DP & Burge CB 2003 Prediction of mammalian microRNA targets. Cell 115 787–798.[CrossRef][Web of Science][Medline]
Lim LP, Lau NC, Garrett-Engele P, Grimson A, Schelter JM, Castle J, Bartel DP, Linsley PS & Johnson JM 2005 Microarray analysis shows that some microRNAs downregulate large numbers of target mRNAs. Nature 433 769–773.[CrossRef][Medline]
Lodes MJ, Caraballo M, Suciu D, Munro S, Kumar A & Anderson B 2009 Detection of cancer with serum miRNAs on an oligonucleotide microarray. PLoS ONE 4 e6229.[CrossRef][Medline]
Lu J, Getz G, Miska EA, Alvarez-Saavedra E, Lamb J, Peck D, Sweet-Cordero A, Ebert BL, Mak RH, Ferrando AA et al. 2005 MicroRNA expression profiles classify human cancers. Nature 435 834–838.[CrossRef][Medline]
Lu L, Katsaros D, de la Longrais IA, Sochirca O & Yu H 2007 Hypermethylation of let-7a-3 in epithelial ovarian cancer is associated with low insulin-like growth factor-II expression and favorable prognosis. Cancer Research 67 10117–10122.
Maragkakis M, Reczko M, Simossis VA, Alexiou P, Papadopoulos GL, Dalamagas T, Giannopoulos G, Goumas G, Koukis E, Kourtis K et al. 2009 DIANA-microT web server: elucidating microRNA functions through target prediction. Nucleic Acids Research 37 W273–W276.
McGuire WP, Hoskins WJ, Brady MF, Kucera PR, Partridge EE, Look KY, Clarke-Pearson DL & Davidson M 1996 Cyclophosphamide and cisplatin compared with paclitaxel and cisplatin in patients with stage III and stage IV ovarian cancer. New England Journal of Medicine 334 1–6.
Meister G, Landthaler M, Dorsett Y & Tuschl T 2004 Sequence-specific inhibition of microRNA- and siRNA-induced RNA silencing. RNA 10 544–550.
Mishra PJ & Merlino G 2009 MicroRNA reexpression as differentiation therapy in cancer. Journal of Clinical Investigation 119 2119–2123.[Web of Science][Medline]
Nam EJ, Yoon H, Kim SW, Kim H, Kim YT, Kim JH, Kim JW & Kim S 2008a MicroRNA expression profiles in serous ovarian carcinoma. Clinical Cancer Research 14 2690–2695.
Nam S, Kim B, Shin S & Lee S 2008b miRGator: an integrated system for functional annotation of microRNAs. Nucleic Acids Research 36 D159–D164.
Orom UA & Lund AH 2007 Isolation of microRNA targets using biotinylated synthetic microRNAs. Methods 43 162–165.[CrossRef][Web of Science][Medline]
Ozols RF & Young RC 1984 Chemotherapy of ovarian cancer. Seminars in Oncology 11 251–263.[Web of Science][Medline]
Park SM, Shell S, Radjabi AR, Schickel R, Feig C, Boyerinas B, Dinulescu DM, Lengyel E & Peter ME 2007 Let-7 prevents early cancer progression by suppressing expression of the embryonic gene HMGA2. Cell Cycle 6 2585–2590.[Web of Science][Medline]
Peter ME 2009 Let-7 and miR-200 microRNAs: guardians against pluripotency and cancer progression. Cell Cycle 8 843–852.[Web of Science][Medline]
Piver MS, Malfetano J, Baker TR & Hempling RE 1992 Five-year survival for stage IC or stage I grade 3 epithelial ovarian cancer treated with cisplatin-based chemotherapy. Gynecologic Oncology 46 357–360.[CrossRef][Web of Science][Medline]
Pratt AJ & MacRae IJ 2009 The RNA-induced silencing complex: a versatile gene-silencing machine. Journal of Biological Chemistry 284 17897–17901.
Raver-Shapira N, Marciano E, Meiri E, Spector Y, Rosenfeld N, Moskovits N, Bentwich Z & Oren M 2007 Transcriptional activation of miR-34a contributes to p53-mediated apoptosis. Molecular Cell 26 731–743.[CrossRef][Web of Science][Medline]
Rehmsmeier M, Steffen P, Hochsmann M & Giegerich R 2004 Fast and effective prediction of microRNA/target duplexes. RNA 10 1507–1517.
Resnick KE, Alder H, Hagan JP, Richardson DL, Croce CM & Cohn DE 2009 The detection of differentially expressed microRNAs from the serum of ovarian cancer patients using a novel real-time PCR platform. Gynecologic Oncology 112 55–59.[CrossRef][Web of Science][Medline]
Roubelakis MG, Zotos P, Papachristoudis G, Michalopoulos I, Pappa KI, Anagnou NP & Kossida S, Human microRNA target analysis and gene ontology clustering by GOmir, a novel stand-alone applicationBMC Bioinformatics 10 Suppl_6 2009 S20.
le Sage C, Nagel R, Egan DA, Schrier M, Mesman E, Mangiola A, Anile C, Maira G, Mercatelli N, Ciafre SA et al. 2007 Regulation of the p27(Kip1) tumor suppressor by miR-221 and miR-222 promotes cancer cell proliferation. EMBO Journal 26 3699–3708.[CrossRef][Web of Science][Medline]
Saito Y, Liang G, Egger G, Friedman JM, Chuang JC, Coetzee GA & Jones PA 2006 Specific activation of microRNA-127 with downregulation of the proto-oncogene BCL6 by chromatin-modifying drugs in human cancer cells. Cancer Cell 9 435–443.[CrossRef][Web of Science][Medline]
Selbach M, Schwanhausser B, Thierfelder N, Fang Z, Khanin R & Rajewsky N 2008 Widespread changes in protein synthesis induced by microRNAs. Nature 455 58–63.[CrossRef][Web of Science][Medline]
Sethupathy P, Corda B & Hatzigeorgiou AG 2006 TarBase: a comprehensive database of experimentally supported animal microRNA targets. RNA 12 192–197.
Shell S, Park SM, Radjabi AR, Schickel R, Kistner EO, Jewell DA, Feig C, Lengyel E & Peter ME 2007 Let-7 expression defines two differentiation stages of cancer. PNAS 104 11400–11405.
Shen J, Ambrosone CB, DiCioccio RA, Odunsi K, Lele SB & Zhao H 2008 A functional polymorphism in the miR-146a gene and age of familial breast/ovarian cancer diagnosis. Carcinogenesis 29 1963–1966.
Sorrentino A, Liu CG, Addario A, Peschle C, Scambia G & Ferlini C 2008 Role of microRNAs in drug-resistant ovarian cancer cells. Gynecologic Oncology 111 478–486.[CrossRef][Web of Science][Medline]
Tagawa H & Seto M 2005 A microRNA cluster as a target of genomic amplification in malignant lymphoma. Leukemia 19 2013–2016.[CrossRef][Web of Science][Medline]
Tarasov V, Jung P, Verdoodt B, Lodygin D, Epanchintsev A, Menssen A, Meister G & Hermeking H 2007 Differential regulation of microRNAs by p53 revealed by massively parallel sequencing: miR-34a is a p53 target that induces apoptosis and G1-arrest. Cell Cycle 6 1586–1593.[Web of Science][Medline]
Taylor DD & Gercel-Taylor C 2008 MicroRNA signatures of tumor-derived exosomes as diagnostic biomarkers of ovarian cancer. Gynecologic Oncology 110 13–21.[CrossRef][Web of Science][Medline]
Valastyan S, Reinhardt F, Benaich N, Calogrias D, Szasz AM, Wang ZC, Brock JE, Richardson AL & Weinberg RA 2009 A pleiotropically acting microRNA, miR-31, inhibits breast cancer metastasis. Cell 137 1032–1046.[CrossRef][Web of Science][Medline]
Vasudevan S, Tong Y & Steitz JA 2007 Switching from repression to activation: microRNAs can up-regulate translation. Science 318 1931–1934.
Vatolin S, Navaratne K & Weil RJ 2006 A novel method to detect functional microRNA targets. Journal of Molecular Biology 358 983–996.[CrossRef][Web of Science][Medline]
Vinther J, Hedegaard MM, Gardner PP, Andersen JS & Arctander P 2006 Identification of miRNA targets with stable isotope labeling by amino acids in cell culture. Nucleic Acids Research 34 e107.
Volinia S, Calin GA, Liu CG, Ambs S, Cimmino A, Petrocca F, Visone R, Iorio M, Roldo C, Ferracin M et al. 2006 A microRNA expression signature of human solid tumors defines cancer gene targets. PNAS 103 2257–2261.
Welch C, Chen Y & Stallings RL 2007 MicroRNA-34a functions as a potential tumor suppressor by inducing apoptosis in neuroblastoma cells. Oncogene 26 5017–5022.[CrossRef][Medline]
Wheeler BM, Heimberg AM, Moy VN, Sperling EA, Holstein TW, Heber S & Peterson KJ 2009 The deep evolution of metazoan microRNAs. Evolution and Development 11 50–68.[CrossRef]
Wright JD, Shah M, Mathew L, Burke WM, Culhane J, Goldman N, Schiff PB & Herzog TJ 2009 Fertility preservation in young women with epithelial ovarian cancer. Cancer 115 4118–4126.[CrossRef][Web of Science][Medline]
Wyman SK, Parkin RK, Mitchell PS, Fritz BR, O'Briant K, Godwin AK, Urban N, Drescher CW, Knudsen BS & Tewari M 2009 Repertoire of microRNAs in epithelial ovarian cancer as determined by next generation sequencing of small RNA cDNA libraries. PLoS ONE 4 e5311.[CrossRef][Medline]
Yang H, Kong W, He L, Zhao JJ, O'Donnell JD, Wang J, Wenham RM, Coppola D, Kruk PA, Nicosia SV et al. 2008a MicroRNA expression profiling in human ovarian cancer: miR-214 induces cell survival and cisplatin resistance by targeting PTEN. Cancer Research 68 425–433.
Yang N, Kaur S, Volinia S, Greshock J, Lassus H, Hasegawa K, Liang S, Leminen A, Deng S, Smith L et al. 2008b MicroRNA microarray identifies Let-7i as a novel biomarker and therapeutic target in human epithelial ovarian cancer. Cancer Research 68 10307–10314.
Zeng Y & Cullen BR 2004 Structural requirements for pre-microRNA binding and nuclear export by exportin 5. Nucleic Acids Research 32 4776–4785.
Zhang L, Huang J, Yang N, Greshock J, Megraw MS, Giannakakis A, Liang S, Naylor TL, Barchetti A, Ward MR et al. 2006 microRNAs exhibit high frequency genomic alterations in human cancer. PNAS 103 9136–9141.
Zhang W, Dahlberg JE & Tam W 2007 MicroRNAs in tumorigenesis: a primer. American Journal of Pathology 171 728–738.
Zhang L, Volinia S, Bonome T, Calin GA, Greshock J, Yang N, Liu CG, Giannakakis A, Alexiou P, Hasegawa K et al. 2008 Genomic and epigenetic alterations deregulate microRNA expression in human epithelial ovarian cancer. PNAS 105 7004–7009.
This article has been cited by other articles:
|
|
 |
|
  A. Fusco MicroRNAs: a great challenge for the diagnosis and therapy of endocrine cancers Endocr. Relat. Cancer, January 29, 2010; 17(1): E3 - E4. [Full Text] [PDF]
|
|
| ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
| HOME | HELP | FEEDBACK | SUBSCRIPTIONS | ARCHIVE | SEARCH | TABLE OF CONTENTS |
Top
Abstract
Introduction
