Keywords
hepatocellular carcinoma - noncoding RNA - microRNA - long noncoding RNA - biomarker
Hepatocellular carcinoma (HCC) is a global health problem: It is the third leading
cause of cancer mortality and the sixth most common cancer worldwide.[1] At an advanced stage, this cancer is associated with a dismal prognosis due to lack
of curative treatment.[2] Like many other cancers, HCC is characterized by dysregulation of multiple gene
networks and signaling pathways that are normally involved in tissue homeostasis.
These genetic effects can involve both protein-coding genes as well as noncoding RNA
(ncRNA) genes. Although the former have been the focus of intense investigation, the
latter, with the exception of microRNAs (miRNAs), are only now gaining recognition
as contributors to HCC. ncRNAs are functional RNAs that are not transcribed into a
protein. A significant proportion of the human genome is actively transcribed into
ncRNAs, whereas only less than 2% of genome sequences encodes for protein coding genes.[3]
Transcribed ncRNAs include functionally important RNAs such as transfer RNA (tRNA)
and ribosomal RNA (rRNA), as well as small nucleolar RNAs (snoRNAs) that guide chemical
modification of RNA molecules, small interfering RNAs (siRNAs) that interfere with
translation of proteins, small nuclear ribonucleic acids (snRNAs) that process pre-messenger
RNAs (mRNAs), piwi-interacting RNAs (piRNAs) that are linked to transcriptional gene
silencing of retrotransposons, microRNAs (miRNAs) that modulate mRNA expression, and
long noncoding RNAs (lncRNAs) with mostly unknown functions.[4]
[5] Indeed, there are several different types of ncRNA, and the transcriptional landscape
is extremely heterogeneous. Although the number of ncRNAs encoded within the human
genome is unknown,[6] thousands of pervasively transcribed ncRNAs have been identified, and the numbers
of such transcripts are greater than those of protein-coding mRNA. Furthermore, some
ncRNAs also show clear evolutionary conservation that indirectly supports a functional
role. Several ncRNAs, such as miRNA and some recently identified long ncRNAs, have
been shown to play regulatory roles in diverse biological processes as well as in
pathological processes such as tumorigenesis.[6]
[7] Data regarding involvement of most types of ncRNA in HCC are currently lacking;
herein we will focus on miRNAs and lncRNAs that have been implicated in the pathogenesis
of HCC.
MicroRNAs in Hepatocellular Carcinoma
MicroRNAs in Hepatocellular Carcinoma
MicroRNAs are small ncRNA molecules of around 22 nucleotides in length that may regulate
gene expression, either by inhibiting target mRNA translation or by inducing its degradation
through pairing with complementary sequences within the 3′-untranslated regions (UTRs)
of targeted transcripts at the posttranscriptional and/or translational level.[8]
[9] To date, around 2,000 miRNAs have been identified in humans using advanced sequencing
technology.[10]
[11] Many of these have been shown to play critical roles in normal cellular functions
such as proliferation, apoptosis, and invasion.[12] Deregulated expression of several miRNAs has been reported in many different human
diseases, and in particular has been extensively investigated in many human cancers,
including HCC. It is estimated that approximately 2,000 miRNAs regulate or control
expression of approximately 30,000 genes, tuning their protein synthetic machinery.[13] Widespread alterations of miRNAs occur across the human genome in a broad array
of human cancers, and miRNA expression has been implicated in the pathogenesis and
progression of various cancers.[14] In fact, miRNAs may function either as tumor-suppressor genes or as oncogenes, by
targeting and silencing mRNAs involved in carcinogenesis. Recent studies show that
miRNA expression can be more useful than mRNA-based profiling for identifying tissue
type of tumor origin.[15] MicroRNAs have been implicated in several processes that define and contribute to
malignancy such as regulation of apoptosis and cell proliferation, angiogenesis, deregulated
cell signaling, etc. Deregulation of miRNA has been postulated as a critical component
of malignant transformation and tumor progression. Consequently, there is much interest
in developing miRNA-targeted therapies for HCC.[14]
There are extensive data from several publications that describe the involvement of
various miRNAs and their differential expression in HCC as well as in other types
of cancers. Deregulated expression of miRNA could contribute to the pathogenesis of
HCC through the downregulation of miRNAs that modulate oncogenes, or the upregulation
of miRNA that can target tumor suppressor genes.[16]
[17] Among the most prominent deregulated miRNAs in HCC are miR-221, miR-21, and miR-18
that are upregulated in HCC and miR-122a, miR-199a, and miR-200 that are downregulated
in HCC. [Table 1] summarizes selected differentially expressed miRNAs, their target genes, and potential
involvement in HCC or other cancers.
Table 1
Differential expression of selected microRNAs (miRNAs) in hepatocellular carcinoma
|
miRNA
|
Gene locus
|
Upregulated or
downregulated
|
Target gene
|
Associated functions
|
References
|
|
miR-1
|
20q13.33
|
Down
|
c-Met, ET-1
|
Metastasis, proliferation
|
[18]
|
|
miR-7–1
|
9q21.32
|
Down
|
PIK3CD, mTOR, p70S6K
|
Tumorigenesis, metastasis
|
[19]
|
|
miR-15a
|
13q14
|
Down
|
Bcl-2, cyclin D1, AKT3
|
Proliferation, apoptosis
|
[20]
[21]
|
|
miR-16–1
|
13q14
|
Down
|
Bcl-2, cyclin D1, AKT3
|
Proliferation, apoptosis
|
[20]
[21]
|
|
miR-17
|
13q31–32
|
Up
|
c-Myc, E2F
|
Angiogenesis
|
[22]
|
|
miR-18
|
13q31
|
Up
|
c-Myc, E2F
|
Angiogenesis
|
[23]
|
|
miR-19a
|
13q31.3
|
Up
|
c-Myc, E2F
|
Angiogenesis
|
[24]
[25]
|
|
miR-20a
|
13q31.3
|
Up
|
c-Myc, E2F
|
Angiogenesis
|
[23]
|
|
miR-21
|
17q23
|
Up
|
PTEN
|
Metastasis
|
[26]
[27]
|
|
miR-25
|
7q22.1
|
Up
|
Bim
|
Apoptosis
|
[28]
|
|
miR-26a
|
3p22.2
|
Down
|
CDK6, cyclin D1
|
Cell Cycle, angiogenesis
|
[29]
[30]
|
|
miR-29
|
1q32.2
|
Down
|
Bcl-2, Bcl-w, Ras
|
Apoptosis
|
[31]
[32]
|
|
miR-34a
|
1p36.22
|
Down
|
Cyclin D1, CDK4, and CDK2, c-Met
|
Cell cycle, proliferation, metastasis
|
[33]
[34]
|
|
miR-92–1
|
13q31.3
|
Up
|
c-Myc, E2F
|
Angiogenesis
|
[35]
|
|
miR-93
|
7q22.1
|
Up
|
Bim
|
Apoptosis
|
[36]
|
|
miR-106b
|
7q22.1
|
Up
|
Bim
|
Apoptosis
|
[37]
|
|
miR-122a
|
18q21
|
Down
|
Cyclin G1, Bcl-w
|
Cell cycle, apoptosis
|
[38]
[39]
|
|
miR-124
|
8q12.2
|
Down
|
ROCK2, EZH2
|
Metastasis
|
[40]
[41]
|
|
miR-125b
|
11q24
|
Down
|
Bcl-2, Bcl-w
|
Apoptosis
|
[42]
[43]
|
|
miR-126
|
9q34.3
|
Down
|
VEGF, VCAM-1
|
Angiogenesis, metastasis
|
[44]
|
|
miR-132
|
17p13.3
|
Down
|
VEGF
|
Angiogenesis
|
[45]
|
|
miR-136
|
14q32
|
Down
|
Bcl-2
|
Apoptosis
|
[46]
|
|
miR-141
|
12p13
|
Down
|
EMT, Tiam1
|
Metastasis
|
[47]
|
|
miR-145
|
5q32–33
|
Down
|
IRS1
|
Metastasis
|
[48]
[49]
|
|
miR-146a
|
5q34
|
Down
|
TRAF6, IRAK1
|
Angiogenesis, metastasis
|
[50]
|
|
miR-148a
|
7p15.2
|
Down
|
DNMT-1, c-Met
|
Metastasis
|
[51]
[52]
|
|
miR-155
|
21q21
|
Up
|
RhoA, TLR
|
Metastasis
|
[53]
|
|
miR-195
|
17p13
|
Down
|
CDK6, cyclin D1
|
Cell cycle
|
[54]
[55]
|
|
miR-198
|
3q13.33
|
Down
|
c-Met
|
Metastasis
|
[56]
|
|
miR-199a
|
19p13.2
|
Down
|
mTOR, PAK4
|
Proliferation, apoptosis
|
[57]
[58]
|
|
miR-200
|
1p36.3
|
Down
|
EMT
|
Metastasis
|
[59]
|
|
miR-216a
|
2p16.1
|
Up
|
PTEN
|
Metastasis
|
[60]
|
|
miR-221
|
Xp11.3
|
Up
|
Bmf; CDKN1B/p27/Kip1; CDKN1C/p57/Kip2, PTEN
|
Apoptosis, proliferation, angiogenesis, metastasis
|
[61]
[62]
|
|
miR-222
|
Xp11.3
|
Up
|
AKT, PTEN
|
Angiogenesis, metastasis
|
[63]
[64]
|
|
miR-223
|
Xq12–13.3
|
Down
|
Cyclin E, RhoB
|
Cell cycle, Apoptosis
|
[65]
|
|
miR-224
|
Xq28
|
Up
|
Bcl-2, Bcl-w
|
Apoptosis
|
[66]
[67]
|
|
miR-449a
|
5q11.2
|
Down
|
c-Met
|
Metastasis
|
[68]
|
|
miR-519d
|
19q13.42
|
Up
|
PTEN
|
Metastasis
|
[69]
|
Abbreviations: EMT, epithelial–mesenchymal transition; TLR, toll-like receptors.
Chronic viral infections such as hepatitis B (HBV) and hepatitis C (HCV) account for
the majority of all cases of HCC. Integration of the HBV DNA into the host genome
deregulates the cellular transcription program and sensitizes liver cells to carcinogenesis.[70] miRNA can regulate HBV infection through modulation of viral gene expression or
binding to viral gene transcripts.[71] miR-18a targets estrogen receptor-α (ER-α). Overexpression of miR-18a occurs in
HCC in females and provides a mechanism whereby ER-α mediated suppression of HBV transcription
can be blocked.[72] Modulation of DNA methyltransferases by miR-152 or miR-148, or the modulation of
HDAC4 by miR-1 can inhibit HBV replication.[73] Conversely, the hepatitis B virus X protein (HBx) can modulate expression of several
miRNA including members of the let-7 family that can target several different oncogenic
proteins that are commonly downregulated in HCC. Persistent infection with HCV leads
to the development of cirrhosis through repeated epithelial injury, tissue repair,
and regeneration,[74]
[75] providing a milieu that facilitates mutations and genomic aberrations, for example,
promoter methylation and deregulated expression of tumor suppressors such as p16 and
p53 that can lead to carcinogenesis.[76]
[77] Conversely, miRNA-196 can direct inhibit HCV transcription, and thereby may reduce
risk of HCC.
Hepatocellular carcinoma can also occur in the setting of nonviral-induced cirrhosis
as in alcoholic liver disease. Alcohol administration has been associated with reduced
expression of miRNAs such as miR-199, miR-200, and miR126, which have also been described
to be deregulated in HCC. Another risk factor for HCC is nonalcoholic steatohepatitis
(NASH); HCC can arise in the setting of fibrosis and cirrhosis. In a dietary model
of steatohepatitis, we reported deregulated expression of several miRNAs including
upregulation of miR-155.[78] miR-155 can target C/EBP β, a tumor suppressor gene that interestingly has also
been shown to downregulate HBV transcription.
Long Noncoding RNAs in Hepatocellular Carcinoma
Long Noncoding RNAs in Hepatocellular Carcinoma
Long noncoding RNAs (lncRNAs) are ncRNAs with a size of more than 200 nucleotides
in length.[79]
[80] Their biological effects are not well understood compared with miRNA, but they are
increasingly being implicated in the regulation of gene expression through diverse
mechanisms. LncRNAs can be transcribed by RNA polymerase II, and subsequently undergo
cotranscriptional modifications such as polyadenylation and pre-RNA splicing.[81] Although lncRNAs can vary considerably in length, their postulated median length
is approximately 592 nucleotides, which is much shorter compared with a median length
of approximately 2,453 nucleotides for mRNA.[82] Most lncRNAs are confined to the nucleus and involved in the epigenetic regulation
of gene expression.[82] They can be identified through bioinformatics analyses or a high-throughput analysis
such as microarrays and transcriptome analysis.[83] Recently, lncRNAs have been recognized to have crucial roles in the regulation of
gene expression and modulation of signaling pathways.[84] Several lncRNAs, such as H19, highly upregulated in liver cancer, TUC338, maternally
expressed 3, and metastasis-associated lung adenocarcinoma transcript 1 are aberrantly
expressed in human HCC ([Table 2]). Similar to protein-coding genes, lncRNA show tissue-specific expression, chromatin
marks, independent gene promoters, regulation by transcription factors, and splicing
of multiple exons into a mature transcript.[113] Large-scale genome-wide sequencing and next-generation sequencing first identified
several thousands of lncRNA transcripts within the mouse transcriptome, and subsequently
also in humans.[114] More recently, tiling microarrays and RNA-sequencing have increased the numbers
of known lncRNA.[115] Similar to other RNA, lncRNA that are involved in specific diseases may have clinical
or pathological roles as markers of disease or clinical behavior.
Table 2
Selected long noncoding RNAs (lncRNA) implicated in hepatocellular carcinoma
|
lncRNA
|
Gene locus
|
Size (kb)
|
Potential role in liver cancer
|
References
|
|
HULC
|
6p24.3
|
0.56
|
Upregulated in HCC. Increased expression is associated with histological grade or
HBV.
|
[85]
[86]
[87]
[88]
[89]
|
|
TUC338
|
12q13.13
|
0.59
|
Increased in cirrhosis and HCC. Modulates cell growth.
|
[5]
|
|
HEIH
|
5q35.3
|
1.7
|
Associated with HBV-HCC.
|
[90]
[91]
|
|
MEG3
|
14q32.3
|
1.8
|
Deregulated in HCC, associated with methylation. Predictive biomarker for monitoring
epigenetic therapy.
|
[90]
[92]
[93]
|
|
MVIH
|
10q22-q23
|
2.1
|
Microvascular invasion in HCC. Predicts recurrence-free survival, overall survival.
|
[90]
[94]
[95]
|
|
UCA1/CUDR
|
19p13.12
|
2.3
|
Involved in chemotherapeutic resistance.
|
[96]
[97]
|
|
H19
|
11p15.5
|
2.3
|
Increased in HCC or in peritumor areas Low peritumor/tumor expression correlates with
prognosis. Suppression of tumor metastasis through miR-220-dependent inhibition of
EMT, drug resistance.
|
[59]
[97]
[98]
[99]
[100]
[101]
[102]
|
|
HOTAIR
|
12q13.13
|
2.3
|
Inhibition reduces invasion and increases chemosensitivity.
|
[90]
[103]
[104]
[105]
[106]
|
|
HOTTIP
|
7p15.2
|
7.9
|
Upregulated in HCC. Predicts disease outcomes and tumor progression.
|
[107]
|
|
MALAT-1
|
11q13.1
|
8.7
|
Upregulated in HCC. Associated with tumor metastasis and recurrence.
|
[90]
[108]
[109]
|
|
LINC-ROR
|
18q21.31
|
22.8
|
Tumor cell survival during hypoxia.
|
[84]
[110]
[111]
|
|
lncRNA-ATB
|
|
2.4
|
Activated by TGF-β, promotes EMT, and triggers STAT3 signaling.
|
[112]
|
Abbreviations: EMT, epithelial–mesenchymal transition; HBV, hepatitis B virus; HCC,
hepatocellular carcinoma; TGF, tumor growth factor.
Recent studies have indicated that lncRNAs are important regulators of development
and involved in various pathological processes. The lncRNAs MALAT1 (metastasis associated
lung adenocarcinoma transcript 1), HOTAIR (HOX transcript antisense intergenic RNA),
H19, HULC (highly upregulated in liver cancer), and PRNCR1 (prostate cancer non-coding
RNA1) are aberrantly expressed in a variety of human cancers, especially in HCC.[90]
[116] MALAT1 promotes tumor cell viability, invasion, and metastasis and is markedly upregulated
in human and experimentally induced murine HCC.[108]
[109] It was observed that inhibition of MALAT1 in HepG2 cells could effectively reduce
cell viability, motility, invasiveness, and increase sensitivity to apoptosis.[108] The lncRNA, HOTAIR is significantly increased in HCC tissues from patients as well
as in liver cancer cell lines and the expression is correlated with poor prognosis.[103]
[104]
[105] Furthermore, HOTAIR can downregulate RNA binding motif protein-38 and promote cell
migration and invasion in HCC cell lines.[106] The H19 gene encodes a 2.3-kb lncRNA located at 11p15.5 that is exclusively expressed
from the maternal allele, and involved in genomic imprinting during growth and development.[100] H19 expression is upregulated in HBV-associated HCC.[101] The HULC gene is a 556-bp nucleotide located on chromosome 6p24.3 and was first
described as a lncRNA with highly specific upregulation in HCC.[117] Elevation of HULC by HBx promotes hepatoma cell proliferation through suppression
of p18 and may play a significant roles in hepatocarcinogenesis.[88] Despite the pervasive effects of lncRNA in the regulation of gene expression and
development, the function of lncRNAs in the molecular pathogenesis of HCC and other
cancers is not yet clear.
Ultraconserved RNAs (ucRNAs) are a group of lncRNAs transcribed from ultraconserved
elements (UCEs), genomic sequences greater than 200 bases that are 100% identical
across the genomes of human, mouse, and rat.[118] A total of 481 UCEs have been identified ranging in size from 200 to approximately
800 base pairs.[118] Some UCEs are located at genomic regions and fragile sites implicated with cancers.
Deregulated expression of transcribed ucRNA has been observed in several cancers including
leukemia and colon cancer.[119] A correlation of some ucRNA clinical prognostic factors, such as Myc expression,
has been reported in neuroblastoma.[120] We have reported the involvement of ucRNAs in HCC and have identified and cloned
the ucRNA TUC338 that is overexpressed in HCC, which can modulate cell cycle progression
and proliferation.[5] Despite the emerging evidence implicating a role of ucRNA in tumor growth and progression,
the precise role of ucRNAs remains unknown. A novel role of a transcribed ultraconserved
RNA TUC339 as an intercellular signaling mediator of growth was suggested in a recent
study showing enrichment of this ucRNA in extracellular vesicles released from HCC
cells.[121]
These observations indicate the potential involvement of diverse lncRNA in tumor growth,
tumor spread, and in intercellular signaling in HCC.
ncRNAs for the Diagnosis of Hepatocellular Carcinoma
ncRNAs for the Diagnosis of Hepatocellular Carcinoma
Several ncRNAs including both miRNA and lncRNA have been demonstrated in the circulation,
and in other body fluids in HCC and other cancers.[122]
[123]
[124]
[125] These observations offer the potential that miRNA may be useful for clinical applications
as diagnostic or prognostic biomarkers of disease. MicroRNA can be detected in the
circulation enclosed within extracellular vesicles such as exosomes or microvesicles,
associated with high-density lipoprotein or in association with proteins such as Argonaute
2.[126]
[127] Given the potential for miRNA to be transported to various sites within the circulation,
there is a possibility for miRNA to have effects in different tissues. However, the
biological effects of these circulating miRNA are not well known. MicroRNA enclosed
within extracellular vesicles can be taken up by cells with the subsequent modulation
of intercellular signaling in HCC cells.[128] In contrast, the functional effects of nonvesicular miRNA have not been elucidated
or described. RNA molecules are not generally taken up by passive mechanisms, and
are prone to degradation by endogenous nucleases. Thus, the presence of miRNA within
extracellular vesicles may also provide stability to ensure their functionality. Irrespective
of the functional effects, the ability to detect circulating miRNA that are selectively
released under certain conditions provides an opportunity for their use as potential
biomarkers of disease.
Chronic infection of HCV is a major cause for HCC, and a search for biomarkers of
HCC in persons with chronic HCV would be clinically useful. It was reported that miR-100,
miR-122, miR-221, and miR-224 are highly increased specifically in HCV-associated
HCC.[129]
[130] Urinary miRNA has also been suggested as a biomarker of HCC by providing a noninvasive
approach for the early diagnosis of HCC, before the onset of disease in HCV-positive
patients.[131] In addition, circulating miR-101 is identified as a potential biomarker for HBV-related
HCC and is correlated with the clinicopathological features and prognosis of HCC patients.[132]
ncRNAs as Prognostic Biomarkers for Hepatocellular Carcinoma
ncRNAs as Prognostic Biomarkers for Hepatocellular Carcinoma
Detection of the expression of specific miRNAs in tissues or in the circulation may
provide useful prognostic information about the course of the disease. Deregulated
expression of several miRNAs such as miR-199a, miR-199b-3p, miR-26, and miR-29 in
HCC tissues has been shown to correlate with patient survival.[133] Furthermore, it was observed that the decreased expression of miR-148b in HCC patients
is associated with poor survival prognosis.[52] Karakatsanis et al reported that miR-21, miR-31, miR-122, miR-221, and miR-222 were
significantly upregulated in HCC tissues and the expression of miR-21, miR-31, miR-122,
and miR-221 in HCC correlated with cirrhosis, while miR-21 and miR-221 associated
with tumor stage and poor prognosis.[134] The interpretation of studies is complicated by the heterogeneity and diverse etiologies
of HCC.
Like miRNA, the expression of certain lncRNAs can occur in a cancer-specific manner,
raising the potential for their use in diagnosis, prognosis, or therapy. High expression
of HOTAIR has been shown to predict tumor recurrence in patients with HCC.[103]
[104]
[105] HOTAIR has also been shown to correlate with a poor outcome in other cancers such
as breast cancer.
The risk of HCC has been associated with single nucleotide polymorphisms (SNPs) in
several different miRNAs. These are summarized in [Table 3].
Table 3
Genetic single nucleotide polymorphisms in selected noncoding RNAs associated with
risk of hepatocellular carcinoma
|
Association
|
MicroRNA
|
Single nucleotide polymorphism
|
References
|
|
Positive
|
miR-let-7
|
rs10877887
|
[135]
|
|
Positive
|
miR-34b/c
|
rs4938723
|
[136]
[137]
[138]
[139]
|
|
Positive
|
miR-101–1
|
rs7536540
|
[140]
|
|
Positive
|
miR-101–2
|
rs12375841
|
[140]
|
|
Positive
|
miR-106b-25
|
rs999885
|
[141]
[142]
|
|
Inconsistent
|
miR-146a
|
rs2910164
|
[143]
[144]
[145]
|
|
Inconsistent
|
miR-149
|
rs2292832
|
[146]
[147]
[148]
|
|
Inconsistent
|
miR-196a2
|
rs11614913
|
[145]
[147]
[149]
[150]
[151]
[152]
|
|
Negative
|
miR-371–373
|
rs3859501
|
[153]
|
|
Inconsistent
|
miR-499
|
rs3746444
|
[144]
[146]
[147]
[148]
[154]
|
|
Positive
|
HULC
|
rs7763881
|
[155]
|
|
Negative
|
MALAT1
|
rs619586
|
[155]
|
Abbreviations: HULC, highly upregulated liver cancer; MALAT1, metastasis associated
lung adenocarcinoma transcript 1.
Similar data for polymorphisms at genomic sites for lncRNA implicated in HCC have
not been reported. However, the majority of cancer-related single-nucleotide polymorphisms
identified are located in noncoding regions of the genome that could represent sites
of lncRNA transcripts.[156] Evaluation of genetic variations has not yet been incorporated into clinical practice,
and further validation of their utility for this purpose is needed. In particular,
data from some studies for miRNA-associated SNPs have not been concordant, likely
due to differences in ethnic background.
Therapeutic Modulation of ncRNA Expression for Hepatocellular Carcinoma
Therapeutic Modulation of ncRNA Expression for Hepatocellular Carcinoma
Although surgical resection or transplantation may offer the prospect of cure, many
patients with HCC are too advanced for these procedures at the time of diagnosis.
For these patients, locoregional or systemic therapies are of varying efficacy at
slowing tumor progression. Targeting ncRNAs that are deregulated in HCC and contribute
to the tumor phenotype or tumor chemosensitivity may offer potential new therapeutic
strategies. miRNAs can potentially suppress expression of several genes and thereby
could modulate multiple signaling pathways in cancer growth. Consequently, there is
increasing interest in therapeutic strategies to modulate expression of miRNAs.[80]
[157]
[158]
[159] Therapeutic use of miRNA-based strategies requires the ability to deliver to the
desired sites of action, acceptable safety with minimal toxicity, and a tolerable
off-target impact of targeting miRNA in other tissues. Knowledge of essential miRNAs
that are specifically involved in HCC pathogenesis or progression can suggest specific
targets for therapeutic intervention. One of the most prominently expressed miRNAs
in many human cancers, including HCC, is miR-21, overexpression of which is associated
with tumor stage and poor prognosis.[160] Several other miRNAs such as miR-151 and miR-221/222 are also markedly increased
in expression in HCC patients, have defined oncogenic targets, and are viable potential
targets for therapeutic intervention.[122] Similarly, therapeutic approaches to modulate downregulated tumor-suppressing miRNAs
in HCC are also an attractive strategy to arrest tumor progression. We have observed
that silencing of upregulated miR-221 using 2'-O-methyl phosphorothioate-modified
anti-miR-221 oligonucleotide can prevent orthotopic tumor progression in experimental
animals and increase survival rate.[61] Furthermore, silencing of miR-221 reduced tumor cell proliferation, increased markers
of apoptosis, and resulted in cell cycle arrest.[61]
Of particular relevance to HCC occurring in the setting of viral infection, therapeutic
modulation of expression of ncRNAs associated with viral hepatitis and HCC may have
the potential to reduce disease progression as well as hepatocarcinogenesis. In one
study, 18 miRNAs were exclusively expressed in HCV-associated HCC, with high specificity
and selectivity compared with all other liver diseases and normal tissue.[129] miR-122 is a hepatocyte-specific miRNA that is implicated in cholesterol, lipid,
and iron metabolism. miR-122 stimulates HCV replication through a unique and unusual
interaction with two binding sites in the 5′-UTR of HCV genome to mediate the stability
of the viral RNA.[161] Thus, therapeutic targeting miR-122 for the treatment of chronic HCV is attractive.
Indeed, miR-122 silencing in chronic HCV infected chimpanzees using a locked nucleic
acid- (LNA-) modified phosphorothioate oligonucleotide complementary to the 5′ end
of miR-122 resulted in a potent and sustained inhibition of HCV replication.[162] Phase I and II clinical trials using anti-miR-122 oligonucleotides that target miR-122
have shown both the safety and efficacy of this approach in humans. An alternate approach
is the use of small molecules to regulate miR-122 for HCV. However, the use of these
strategies is confounded by reports that miR-122 knockout in mice enhances liver tumor
formation.
Strategies to Manipulate miRNA
Strategies to Manipulate miRNA
There are several techniques that can be used to therapeutically manipulate the expression
of miRNAs. [Fig. 1] illustrates various strategies to modulate miRNA expression, through either inhibition
of miRNA or through replacement of miRNAs, and thereby modulate downstream gene expression.
Replacement of miRNA may be accomplished using miRNA mimetics, whereas inhibition
of miRNA can be accomplished by siRNAs or small hairpin RNAs. The delivery of a specific
anti-miRNA into cells prevents the miRNA from binding to their cognate target genes
thereby silencing miRNA function. In another strategy, an expression vector carrying
multiple binding sites to a targeted miRNA is introduced into cells, which serves
as a “sponge” and results in competitive inhibition of the target miRNA.[163] The delivery of miRNAs for replacement or constructs that can modulate the expression
of miRNA in tumor tissues can be accomplished using diverse techniques such as lentiviral
or adeno-associated viral vectors, cationic lipid nanoparticles, or direct local administration.
We have demonstrated the therapeutic efficacy of chemically modified, cholesterol
conjugated antisense oligonucleotides for the treatment of intrahepatic HCC xenografts
in mice.[61] Moreover, modulation of miR-26a resulted in a reduction of tumor formation and lentiviral
vectors carrying miRNA mimics against osteopontin successfully prevented the metastasis
of HCC into lungs in a mouse model.[164]
Fig. 1 Strategies to manipulate microRNA (miRNA) expression in hepatocellular carcinoma.
(A) Schematic of functional effect of miRNA in suppressing a target messenger RNA (mRNA)
that is involved in maintaining the tumor phenotype. Endogenous miRNA binds to complementary
sequences in three prime untranslated region (3′-UTR) of the target gene resulting
in translational repression of mRNA. (B) miRNA mimics comprise the exact oligonucleotide sequence of the endogenous miRNA
that binds to the same target gene and degrade the mRNA. (C) An antisense oligonucleotide strongly binds to a specific miRNA, silences its activity,
and prevents binding to the target mRNA. (D) A target block is an oligonucleotide designed to bind to a portion of miRNA target
on a specific mRNA without inhibition of translation thereby prevents miRNA-mediated
repression. (E) A miRNA sponge consists of an open reading frame (ORF) with a 3′-UTR that contains
several binding sites for a particular miRNA and serves as a competitive inhibitor.
Long noncoding RNA may also represent potential therapeutic targets. H19 is a lncRNA
that is highly expressed in HCC and has oncogenic effects. Therapeutic targeting of
H19 has been evaluated in patients with pancreatic, bladder, and ovarian cancer; studies
in HCC are also warranted. Strategies to modulate expression of HCC-associated lncRNA
are similar to those described for miRNA.
Hepatic uptake occurs rapidly following systemic administration of antisense oligonucleotides;
thus, hepatic tumors are appropriate indications for miRNA or lncRNA-based therapeutic
approaches compared with most other types of cancers. Chemical modifications reduce
degradation of native oligonucleotides. Encapsulation within nanoparticles may offer
similar advantages, but are limited by immune cell activation and nonspecific uptake.
Finally, it is not clear how many lncRNA regulate target gene expression and control
multiple signaling pathways. A better understanding of the role of ncRNAs and the
mechanism of regulation of target gene transcripts as well as molecular signaling
events would accelerate the development of novel therapeutic strategies for the arrest
of primary hepatic tumors.
Summary
Currently, a large amount of literature and experimental data is available regarding
the involvement of ncRNAs such as miRNAs in liver cancers. The data regarding other
ncRNA such as lncRNA are also rapidly expanding. A characterization of their deregulated
expression will provide potential markers for the diagnosis, prognosis, and therapy
of HCC. A better understanding of the molecular mechanisms underlying ncRNA-mediated
tumorigenesis may help to identify appropriate targets for intervention to control
tumor formation or progression. The development of ncRNA-based therapeutics has major
challenges. These include the need for tumor delivery, avoidance of immune response,
limitation of toxicity of targeting constructs, and minimization of off-target effects.
Improved approaches for directed therapy targeting noncoding RNA with the capability
of safe and effective administration in patients with liver disease are needed. Until
then, a more immediate clinical application of knowledge of deregulated miRNAs and
lncRNAs would reflect their use as candidate markers for diagnosis or prognosis.
Abbreviations
ER-α:
estrogen receptor-α
HBV:
hepatitis B virus
HBx:
hepatitis B virus X protein
HCV:
hepatitis C virus
HCC:
hepatocellular carcinoma
HOTAIR:
HOX transcript antisense intergenic RNA
HULC:
highly upregulated in liver cancer
LNA:
locked nucleic acid
lncRNAs:
long noncoding RNAs
MALAT1:
metastasis associated lung adenocarcinoma transcript 1
mRNAs:
messenger RNAs
miRNAs:
microRNAs
NASH:
nonalcoholic steatohepatitis
ncRNAs:
noncoding RNAs
piRNAs:
piwi-interacting RNAs
PRNCR1:
prostate cancer noncoding RNA1
rRNA:
ribosomal RNA
SNPs:
single nucleotide polymorphisms
siRNAS:
small interfering RNAs
snRNAs:
small nuclear ribonucleic acids
snoRNAs:
small nucleolar RNAs
tRNA:
transfer RNA
UCEs:
ultraconserved elements
ucRNAs:
ultraconserved RNAs
UTRs:
untranslated regions
