About the Authors:
Giorgia Benegiamo
Contributed equally to this work with: Giorgia Benegiamo, Gianluigi Mazzoccoli
Current address: University of Zurich, Institute of Pharmacology and Toxicology – Chronobiology and Sleep Research Unit
Affiliation: Gastroenterology Unit, IRCCS “Casa Sollievo della Sofferenza”, Hospital San Giovanni Rotondo (FG), San Giovanni, Italy
Gianluigi Mazzoccoli
Contributed equally to this work with: Giorgia Benegiamo, Gianluigi Mazzoccoli
Affiliation: Department of Medical Sciences, Division of Internal Medicine IRCCS Scientific Institute and Regional General Hospital “Casa Sollievo della Sofferenza”, San Giovanni Rotondo (FG), Italy
Francesco Cappello
Affiliations Euro-Mediterranean Institute of Science and Technology (IEMEST), Palermo, Italy, Department of Experimental Biomedicine and Clinical Neurosciences, Section of Human Anatomy, University of Palermo, Palermo, Italy
Francesca Rappa
Affiliation: Department of Experimental Biomedicine and Clinical Neurosciences, Section of Human Anatomy, University of Palermo, Palermo, Italy
Nunzia Scibetta
Affiliation: Unit of Pathology, Civic Hospital, Palermo, Italy
Jude Oben
Affiliation: University College London (UCL)-Institute of Liver and Digestive Health, Division of Medicine, Royal Free Campus, London, United Kingdom
Azzura Greco
Affiliation: Institute of Hepatology, Foundation for Liver Research, London, United Kingdom
Roger Williams
Affiliation: Institute of Hepatology, Foundation for Liver Research, London, United Kingdom
Angelo Andriulli
Affiliation: Gastroenterology Unit, IRCCS “Casa Sollievo della Sofferenza”, Hospital San Giovanni Rotondo (FG), San Giovanni, Italy
Manlio Vinciguerra
* E-mail: [email protected] (VP); [email protected] (MV)
Affiliations Euro-Mediterranean Institute of Science and Technology (IEMEST), Palermo, Italy, University College London (UCL)-Institute of Liver and Digestive Health, Division of Medicine, Royal Free Campus, London, United Kingdom
Valerio Pazienza
* E-mail: [email protected] (VP); [email protected] (MV)
Affiliation: Gastroenterology Unit, IRCCS “Casa Sollievo della Sofferenza”, Hospital San Giovanni Rotondo (FG), San Giovanni, Italy
Introduction
Basic cell functions such as proliferation, growth, differentiation, autophagy and glucose and lipid metabolism show time related fluctuations, and when the oscillations are rhythmic with a periodicity of approximately 24 h the rhythmicity is defined circadian [1]. Cellular circadian rhythmicity is driven by molecular clockworks comprised of translational-transcriptional feedback loops put in place by a set of genes, called core clock genes, coding for proteins that in turn suppress gene expression in a cycle that completes itself in one day. Clock genes are transcriptionally activated by the basic helix–loop–helix-PAS transcription factors CLOCK and ARNTL (or its paralog ARNTL2), which heterodimerize and bind to E-box enhancer elements in the promoters of the Period (PER 1, 2 and 3) and Cryptochrome (CRY1 and 2) genes. The PER and CRY mRNAs translate into PER and CRY proteins to form a repression complex which translocates back into the nucleus, interact directly with CLOCK and ARNTL heterodimer and inhibits its transactivation [2], [3]. Notably, a growing body of evidence suggests that the feeding behavior and nutrient metabolic pathways can entrain and modulate the circadian clocks and in turn the clock gene machinery regulates multiple metabolic pathways and metabolite availability, driving the expression of clock controlled genes and transcription factors (DBP, TEF, HLF, E4BP4, DEC1-2) [4], [5], [6].
Viruses may utilize the cellular machinery to replicate, as they need host-cell replication proteins to support their own replication. Circadian variation of expression of genes that regulate the cell cycle may influence viral replication, determining daily peaks in synchrony with the cell cycle. E4BP4, a transcription factor that regulates mammalian circadian oscillatory mechanism, coordinates expression of viral genes with the cellular molecular clock and represses viral promoter sequences [7], [8]. Viral immediate-early genes appear to synchronize to 24 h rhythmicity and large DNA viruses may exhibit circadian periodicity with respect to persistent viral replication and reactivation from latency [7], [8]. Viruses are able to exploit the circadian system for optimal timing of infection and large DNA viruses show amplified DNA replication in response to terminal differentiation, suggesting a regulation mediated by circadian pathways [9].
Chronic hepatitis C virus infection (HCV) is a viral pandemic and the leading cause of liver fibrosis and cirrhosis, often progressing to liver cancer (hepatocellular carcinoma, HCC) [10]. Hepatitis C virus has evolved over a period of several thousand years and the most commonly used classification distinguishes six major genotypes. These genotypes are further divided into subtypes that differ from each other by 20–25% in nucleotide sequence, resulting in sequence diversity over the complete genome up to 35% [11]. The ability of the HCV core protein to interfere with glucose and lipid metabolic pathways and to modulate gene transcription, as well as cell proliferation and death, has been well characterized [12], [13], [14] and depends on the viral genotype: genotype 1b is the most aggressive and associated to HCC, while genotype 3a is more associated to lipid accumulation in the liver [11].
To date the interplay between HCV infection and/or replication and the clock gene machinery is unknown. To address this issue we used two in vitro models of HCV infection, Huh-7 cells expressing the HCV core protein of two different genotypes (1b and 3a) and OR6 cells replicating the full-length HCV genotype 1b genome, and we evaluated liver biopsies of patients with HCV infection.
Materials and Methods
Ethics Statement
Human biopsies: all the procedures followed were in accordance with the ethical standards of the responsible committees (institutional and national) on human experimentation and with the Helsinki Declaration of 1975 (as revised in 2008). Written informed consents were obtained from patients at the time of biopsy and the study was approved by Ethics Committee of the Civic Hospital, Palermo, Italy.
Human Sample Collection
Formalin-fixed paraffin embedded liver biopsies were retrospectively collected from files of the Unit of Pathology of the Civic Hospital, Palermo, Italy. 5 cases were selected of HCV genotype 1b in absence of liver cirrhosis, 5 cases were also selected of HCV genotype 1b in presence of liver cirrhosis. Finally, we selected in our files 5 age-matched cases of normal liver biopsies obtained during autoptic examination of subjects without hepatic diseases. The clinical characteristics of the patients studied are summarized in Table 1, in terms of clinical history.
[Figure omitted. See PDF.]
Table 1. Clinical and pathological characteristics of the patients studied.
https://doi.org/10.1371/journal.pone.0060527.t001
Immunohistochemistry
Immunohistochemistry was performed by iVIEW DAB Detection Kit for Ventana BenchMark XT automated slide stainer on sections with 4–5 µm of thickness from human liver biopsies [15]. For immunostaining it has been used the primary antibody for PER2 (dilution 1∶100, Cat. No. sc-101105, Santa Cruz Biotechnology CA USA). Positive and negative controls were run concurrently. Results were semiquantitated in blind by three expert pathologists (FR, FC and NS) and percentage of positive nuclei was calculated in 10 random high power fields (at magnification of 400X).
Cell Culture, Transfection and Serum-Shock Induced Synchronization Procedure
Human hepatoma Huh-7 cells were cultured at 37°C in 5% CO2 atmosphere in DMEM medium supplemented with 10% fetal bovine serum (FBS), 100 U/ml penicillin and 100 ng/ml streptomycin (Invitrogen Life Technologies, Milan, Italy). OR6 cells were kindly donated by Dr. Ikeda [16]. pIRES2-EGFP plasmids containing the HCV 1b core-encoding region or the 3a or GFP alone [17] and Flag-tagged pCMV Sport2 PER2 plasmid [18], were transfected into Huh-7 cells and in OR6 cells with Lipofectamine 2000 (Invitrogen Life Technologies, Milan Italy) and with Amaxa™ NucleofectorTM Kit V (Lonza, Cologne Germany), respectively, following manufacturer’s instructions. The serum shock induced synchronization was performed as follows: approximately 4×105 cells/6 wells were plated the day before the experiments. At the day of the experiments, culture medium was exchanged with serum-rich medium (DMEM containing 50% FBS) and after 2 hours this medium was replaced with serum free DMEM. The cells were harvested at different time points: 1 h, 4 h, 10 h, 16 h, 22 h and 28 h after serum shock.
Luciferase Assays
Luciferase assays to monitor HCV replication in OR6 cells were performed as previously described [16], using a luciferase reporter assay (Promega, Madison, WI, USA).
Quantitative Real Time PCR
Total RNA was extracted from HCV-core transfected Huh-7 cells and from OR6 cells replicating the full length HCV genome using the RNeasy® Mini Kit (Qiagen S.p.a. Milan, Italy) and subsequently digested by DNase I. cDNA was synthesized from 100 ng total RNA with Quantifast RT-PCR kit (Qiagen). For real-time PCR, we used the following SYBR Green QuantiTect Primers purchased from Qiagen: RevErbα (QT00000413), RoRα (QT00072380), ARNTL (QT00068250), ARNTL2 (QT00011844), CLOCK (QT00054481), PER1 (QT00069265), PER2 (QT00011207), PER3 (QT00097713), CRY1 (QT00025067) and CRY2 (QT00094920). For HCV quantification the following primers were used: Forward 104 (5′-AGA GCC ATA GTG GTC TGC GG-3′) and Reverse 197R (5′-CTT TCG CGA CCC AAC ACT AC-3′) described in [33]. Reactions were set up in 96-well plates using a 7700 Real-Time PCR System (Applied Biosystems, Foster City, CA, USA) and all samples were assayed in triplicate. Expression levels of target gene were normalized using the housekeeping control gene TATA binding protein (TBP, QT00000721).
Western Blotting
Huh-7 control cells and cells transfected with either genotype HCV core protein 1b, HCV core 3a or with the empty vector were lysed and processed for immunoblotting analysis with specific antibodies as previously described [19]. Quantitative measurements of bands were performed using the NIH-Image analysis program Scion IMAGE (Scion Corp., Frederick, MD, USA).
Antibodies
Rabbit and mouse polyclonal antibody directed against ARNTL2, ClOCK, PER1, PER2, CRY1, CRY2 and β-actin were from Santa Cruz Biotechnology, Santa Cruz, CA, USA. ARNTL and Rev-Erbα antibodies were purchased from Millipore S.p.a., Milan, Italy. The monoclonal anti-core (C7–50) antibody was obtained from Vinci-Biochem (Florence, Italy).
Statistical Analysis
Results are expressed as means ± SE of at least three different experiments. Comparisons were made using Student’s t-test as appropriate. Differences were considered as significant at P<0.05.
Results
Altered Clock Genes Expression in OR6 Replicating the Full Length HCV RNA
As viruses are highly dependent on cellular machinery for replication, it was proposed that the viral replication may be synchronized to the molecular clockwork and that in turn the circadian clock may influence viral replication [7].
With this premise in mind, we sought to analyze by qRT-PCR the time-qualified expression of a panel of clock genes (Rev-Erbα, Rorα, ARNTL, ARNTL2, CLOCK, PER1, PER2, PER3, CRY1 and CRY2) in OR6 cells, which express full length HCV replicon of genotype 1b [16]. The latter was able to perturb clock gene expression as shown in Figure 1A and B. A significant downregulation of CRY2 mRNA levels was observed over all the six time points, while PER2 mRNA was significantly decreased at 1 h, 10 h, 16 h, 22 h and 28 h after serum shock. Rev-Erbα, Rorα, ARNTL mRNA levels did not show statistically significant changes between OR6 cells lacking a functional HCV 1b full replicon (hereafter referred to as “cured”) and HCV-infected OR6 cells (Fig. 1A). CLOCK mRNA resulted significantly downregulated at 1 h after serum shock in OR6 induced to express HCV full length RNA when compared to cured OR6 cells (Fig. 1A). ARNTL2 mRNA levels showed a trend, though not reaching statistical significance, towards a decrease over all the time points considered in HCV-infected compared to cured OR6. Moreover, time related patterns of expression of PER1 and PER3 were asynchronous in induced OR6 as compared to control cells. We then sought to confirm if PER2 and CRY2 mRNA dowregulation was similarly observed at the protein level. PER2 and CRY2 proteins were found decreased in OR6 HCV replicating cells as compared to control cells (Figure 2A).
[Figure omitted. See PDF.]
Figure 1. qRT-PCR analysis of clock gene mRNA expression in OR6 control cells (cured, not expressing the HCV 1b full replicon) and in HCV replicating OR6 cells (HCV).
Control (cured) OR6 cells and OR6 cells replicating HCV genotype 1b were serum shocked and RNA was extracted every 1 h, 4 h, 10 h, 16 h, 22 h and 28 h after serum shock. mRNA levels of Rev-Erbα, Rorα, ARNTL, ARNTL2, CLOCK, PER1, PER2, PER3, CRY1 and CRY2 genes were assessed by qRT-PCR (A and B). Values were normalized against TBP as housekeeping control gene. Results are expressed as means ± SE of three independent experiments. * = p<0.05 in HCV replicating cells versus control cured OR6 cells.
https://doi.org/10.1371/journal.pone.0060527.g001
[Figure omitted. See PDF.]
Figure 2. Mutual antagonism between HCV genotype 1b replication and PER2 expression in OR6 cells.
(A) Representative immunoblots of PER2 and CRY2 protein expression in HCV replicating OR6 cells versus control (cured) cells. 1 out of 3 blots is showed. β-actin was used as a loading control. (B) PER2 overexpression in HCV replicating OR6 cells using a Flag-tagged construct. HCV replicating OR6 cells or control OR6 cells were electroporated with Flag-PER2, 24 hours after electroporation protein lysates were processed for immunoblotting and Flag levels were detected with a specific antibody. β-actin was used as a loading control. (C) HCV replication was detected by a luciferase reporter assay in HCV replicating OR6 cells 24 hours post electroporation with a control (GFP) or Flag-PER2 construct. (D) qRT-PCR to detect HCV RNA levels upon control (GFP) or Flag-PER2 plasmid electroporation in HCV replicating OR6 cells HCV RNA values were normalized against TBP as housekeeping control gene (C and D). Results are expressed as means ± SE of three independent experiments. * = p<0.05, ** = p<0.01 in HCV replicating OR6 cells overexpressing Flag-PER2 versus HCV replicating OR6 cells overexpressing GFP.
https://doi.org/10.1371/journal.pone.0060527.g002
PER2 Overexpression Hampers HCV RNA Replication
In order to elucidate the interplay between the clock gene machinery and HCV replication, we decided to focus our attention on the role of PER2, as its role in regulating the daily rhythm of IFN-γ and its tumor suppressor activity have been already demonstrated [20], [21]. For this purpose, we overexpressed Flag-tagged Per2 protein [18] in OR6 cells replicating the HCV genotype 1b full length RNA (Figure 2B). The efficiency of transfection was about 50–60% in OR6 cells (data not shown). As previously described, OR6 cells contain a very efficient luciferase reporter system for monitoring HCV RNA levels [16]. Upon PER2 overexpression, we observed approximately 35% reduction in luciferase activity in HCV-expressing OR6 cells compared to untransfected cells (Fig. 2C). Consistently, HCV RNA levels were significantly reduced by 27% in PER2-overexpressing OR6 cells, as assessed by qRT-PCR (Fig. 2D). Altogether, these data demonstrate for the first time that circadian protein PER2 can hinder the replication of HCV genotype 1b.
Interferon Stimulated Genes in OR6 Cells Overexpressing PER2 Protein
Biomolecules mediating innate immune defenses, such as the Interferon Stimulated Genes (ISGs) products, can prevent the translation of HCV and cellular mRNAs to limit viral replication and can also initiate apoptosis if the cell is overwhelmed. In order to replicate, HCV machinery can interact directly with ISGs and neutralize their expression and function. To understand the role of PER2 in diminishing HCV RNA replication we evaluated by qRT-PCR the mRNA expression levels of a subset of ISGs (OAS1, Mx1, IRF9, PKR) in PER2 overexpressing OR6 HCV RNA replicating and cured cells as compared to GFP-transfected OR6 HCV replicating and cured cells.
OR6 cells expressed OAS1, Mx1, IRF9 and PKR at the mRNA level, both in cured and infected cells (Figure 3, A-D). PER2 overexpression had no effect in cured cells, compared to the condition of GFP overexpression. OAS1 mRNA levels were significantly decreased, and Mx1 and IRF9 were significantly increased exclusively in GFP-transfected OR6 HCV replicating cells (Figure 3, A–D). In turn, PER2 overexpression was able to efficiently restore OAS1, whilst Mx1 and IRF9 mRNA levels returned to the basal level in OR6 HCV replicating cells. PKR expression did not display significant changes in any of the conditions tested (Figure 3, A–D).
[Figure omitted. See PDF.]
Figure 3. qRT-PCR analysis of interferon stimulated genes (ISGs: OAS1, Mx1, IRF9, PKR) mRNAs expression levels in control (cured) OR6 cells and HCV replicating OR6 cells electroporated with GFP (cured GFP, HCV GFP) or with Flag-PER2 (cured PER2, HCV PER2) A, B, C and D.
mRNA was extracted 24 hours after electroporation with the respective constructs and ISGs levels were normalized to TBP as housekeeping gene. Results are expressed as means ± SE of three independent experiments. * = p<0.05, ** = p<0.01 in HCV replicating OR6 cells overexpressing GFP versus OR6 control cells overexpressing GFP or Flag-PER2. # = p<0.05 in HCV replicating OR6 cells overexpressing Flag-PER2 versus HCV replicating OR6 cells overexpressing GFP.
https://doi.org/10.1371/journal.pone.0060527.g003
Clock Gene Expression in Huh-7 Cells Expressing the HCV Core Protein of Genotype 1b or 3a
To investigate a possible role of HCV core proteins in the impairment of the clock gene machinery, we evaluated by qRT-PCR the mRNA expression levels of a panel of clock genes (Rev-Erbα, Rorα, ARNTL, ARNTL2, CLOCK, PER1, PER2, PER3, CRY1 and CRY2) in an additional relevant cell line, human hepatoma Huh-7 cells transiently expressing the HCV core protein of genotype 1b or 3a [17]. As shown in Figure 4, ARNTL, CLOCK and PER3 mRNA levels resulted significantly increased by the HCV core protein 1b, while PER2, CRY1 and CRY2 were found significantly decreased. These results were consistent with those obtained in the OR6 cell line (Fig. 1, A and B). No alterations were observed in Huh-7 cells transfected with HCV core protein of genotype 3a (Fig. 4). Rev-Erbα, Rorα, and ARNTL2 mRNA levels were not changed in either of the genotypes. In regard to PER1 expression, HCV core protein genotype 1b tended to induce decrease in its mRNA expression level, without reaching statistical significance.
[Figure omitted. See PDF.]
Figure 4. qRT-PCR analysis of clock gene mRNAs expression levels in Huh-7 cells overexpressing the HCV core proteins genotype 1b and 3a.
Huh-7 cells were transiently transfected with HCV core proteins 1b and 3a as previously described [17], or with GFP. 48 hours after transfection mRNA levels of Rev-Erbα, Rorα, ARNTL, ARNTL2, CLOCK, PER1, PER2, PER3, CRY1 and CRY2 genes were assessed by qRT-PCR. Values were normalized against TBP as housekeeping control gene. Light gray: GFP transfected cells; dark gray: HCV core protein genotype 3a transfected cells; black: HCV core protein genotype 1b transfected cells. Results are expressed as means ± SE of three independent experiments. * = p<0.05 in HCV core proteins transfected versus GFP transfected control cells.
https://doi.org/10.1371/journal.pone.0060527.g004
Immunoblot Detection of Circadian Proteins in Huh-7 Cells Expressing the HCV Core Protein of Genotype 1b or 3a
To corroborate the mRNAs expression profile data and with the intent to assess whether the dysregulation of clock gene expression levels resulted in a differential expression pattern at protein level, we analyzed Rev-Erbα, Rorα, ARNTL, ARNTL2, CLOCK, PER1, PER2, CRY1 and CRY2 by immunoblotting 48 hours after HCV core transfection in Huh-7 cells. As shown in Figure 5, HCV core protein of genotype 1b was able to decrease CLOCK, PER2, CRY1 and CRY2 protein levels. Rev-Erbα, Rorα, ARNTL, ARNTL2 and PER1 protein levels were unmodified. In regard to the HCV core genotype 3a, only CLOCK protein expression resulted increased at the same time point and no other changes were observed (Figure 5, A and B). The differences between CLOCK mRNA and protein levels in both conditions of HCV core protein 1b and 3a overexpression are suggestive of a post-transcriptional mechanism of regulation of CLOCK protein in Huh-7 cells. Post-transcriptional regulations are crucial for the rhythmic activity of the circadian molecular clockworks, and in particular have been shown to play a part in the generation of time related variations of CLOCK protein levels in the Drosophila Melanogaster [22].
[Figure omitted. See PDF.]
Figure 5. Immunoblot detection of circadian proteins in Huh-7 cells expressing the HCV core protein genotype 1b or 3a and GFP-expressing control cells.
(A) 48 hours after transfection cells were lysed and equal amounts of proteins were loaded on a 10% polyacrylamide gel, separated by electrophoresis and immunoblotted with specific Rev-Erbα, Rorα, CLOCK, ARNTL, ARNTL2, PER1, PER2, CRY1 and CRY2 primary antibodies. β-actin expression served as loading control. (B) Densitometric quantification of CRY2, PER2 and CLOCK proteins normalized to β-actin expression of three different experiments.
https://doi.org/10.1371/journal.pone.0060527.g005
PER2 in the Liver of Patients Infected with HCV Genotype 1b
We next sought to confirm if the downregulation of PER2 protein observed in the two in vitro HCV genotype 1b cell models (Huh-7 and OR6) was found in the patho-physiological context of liver of patients infected with HCV genotype 1b (whose clinical characteristics are reported in Table 1). Immunostaining for PER2 showed significant differences (p<0.005) in the percentage of positive nuclei between hepatitis and, either, cirrhosis or normal liver. In particular, 37% of nuclei of hepatocytes in hepatitis showed immunopositivity for PER2, while only 7% of nuclei of hepatocytes in cirrhosis and 3% of nuclei of hepatocytes in normal liver were immunopositive. In cirrhosis, PER2 Immunopositivity was also observed in the cytoplasm of hepatocytes (Fig. 6).
[Figure omitted. See PDF.]
Figure 6. Representative panel of immunostainings performed for PER2 in samples of normal liver, hepatitis related to HCV (genotype 1b positive) and cirrhosis arisen on HCV infection (genotype 1b positive)
(A). Positivity of nuclei of hepatocytes in hepatitis was significantly higher compared with those in cirrhosis. The latter was comparable to that of hepatocytes in normal liver. In cirrhosis, PER2 Immunopositivity is also observed in the cytoplasm of hepatocytes. Positive control of esophagus showed immunopositivity in the nuclei of all cells (C). Pictures showed the same area observed with a lower (above) and higher (below) magnification. (B) Histogram shows statistical results for the evaluation of immunopositivity for PER2. Significant differences (** = p<0.005) in the percentage of positive nuclei were found between biopsies of hepatitis and either cirrhosis and normal liver.
https://doi.org/10.1371/journal.pone.0060527.g006
Discussion
Both HCV infection and disruption of the cellular circadian clock have been shown to heavily impact on hepatic lipid and glucose metabolism inducing enhanced lipid accumulation, condition that can predispose to serious liver disorders such as steatohepatitis, cirrhosis and hepatocellular carcinoma (HCC) [6], [10]. Clock genes regulate the timing of DNA repair, apoptosis, and cell proliferation, processes that when altered are hallmarks of carcinogenesis. About 5% to 15% of genome-wide mRNA expression exhibits a circadian rhythm of oscillation driven by the clock genes [23], [24], including some established tumor suppressor genes and oncogenes [23], [24]. Mutation or dysregulation of clock genes have been associated with increased susceptibility to HCC and other cancer types in several animal models as well as in humans [25], [26], [27].
To our knowledge, the interactions between the cellular circadian clock and HCV life cycle in hepatocytes have not been studied up until now. We show here for the first time that HCV genotype 1b, but not 3a, induced profound alterations in the mRNA and protein expression of the clock gene machinery in two cellular models, the OR6 cells harboring the full replicon of HCV genotype 1b and in Huh-7 cells expressing HCV core protein. Consistent findings indicated downregulation of PER2 and CRY2 proteins by HCV genotype 1b in both cellular models. Interestingly, downregulation of PER2 and CRY2 occurs also in fibrotic livers and HCC [27], [28]. In addition, high expression of PER2 gene was associated with significantly better outcomes in liver metastasis of colorectal carcinoma [29], and high PER2 protein levels are protective from carbon tetrachloride-induced hepatotoxicity [30].
In this study, we focused on the role of PER2 on HCV replication, as this circadian protein regulates the rhythms of IFN-γ signaling, critical for innate and adaptive immunity against HCV infection [20], [21], while CRY2 is involved in NF-kB activation and pro-inflammatory processes [31]. A recent elegant study showed that PER2, rather than CRY proteins, is the critical nodal point for circadian oscillations in cells and in the intact organism [32]. Our analysis of human liver biopsies revealed that HCV genotype 1b induces a massive increase in nuclear PER2 nuclear localization in hepatocytes in hepatitis in absence of cirrhosis compared to control livers, while PER2 immunopositivity is also observed in the cytoplasm of HCV genotype 1b infected hepatocytes. Interestingly, in chronically infected HCV patients, as well as in cirrhosis, hepatocytes at late stage of infection dominate the cell population, resulting in the production of high density, poorly infectious HCV particles, while in acutely infected non cirrhotic patients there is a production of low density highly infectious HCV particles [33]. We speculate that this may have an effect on PER2 subcellular localization: an increase in nuclear localization together with a decrease in the mRNA and total protein levels in cell models is consistent with the fact that nuclear PER2 forms a repression complex that interacts directly with the core clock machinery blocking its own production [2], [3] (Figure 7). Nevertheless, further in depth in vivo and in vitro studies are required to understand the mechanisms of PER2 intracellular trafficking and degradation dependent on HCV infection.
[Figure omitted. See PDF.]
Figure 7. Scheme illustrating the antagonism between HCV genotype 1b replication and PER2 in hepatocytes.
HCV core protein genotype 1b, via a yet undefined mechanism, induces a downregulation of PER2 mRNA. PER2 protein produced in the cytoplasm accumulates in the nucleus, as observed in human liver biopsies infected with HCV genotype 1b, where could further inhibit the production of its own RNA [2], [3]. Alteration of this equilibrium by exogenous overexpression of PER2 protein hampers HCV genotype 1b replication.
https://doi.org/10.1371/journal.pone.0060527.g007
One of the most remarkable findings was that exogenous overexpression of PER2 protein in OR6 cells hampered HCV RNA replication, which was found to be decreased by ∼30%. Consistently, PER2 overexpression influenced the HCV-dependent altered expression of ISG products, OAS1, Mx1, IRF9, which prevent the translation of HCV and cellular mRNAs to limit viral replication [34]. One of the major antiviral mechanisms of interferon is the activation of OAS1, which leads to the production of short oligonucleotides that in the presence of viral infections activate ribonucleases that destroy viral mRNA within infected cells inhibiting viral replication [35]. Noteworthy, in our study Per2 overexpression potentiated the activation of OAS1, suggesting a possible mechanism involved into the observed reduction of HCV RNA levels. Although exogenous PER2 overexpression reduced the apparently coherent elevated levels of Mx1 and IRF9 in OR6 replicating the HCV RNA, we assume that some viral components act to modulate viral load by means of the activation or inhibition of host defense proteins in order to maintain low steady levels of virus in the infected cells, enabling HCV to escape from the host immune surveillance, and facilitating persistent viral infection.
In conclusion, we found that HCV core protein genotype 1b is able to impair the clock gene machinery suggesting that HCV may adopt this strategy to better exploit the host-cell replication machinery. On the other hand, overexpression of the circadian protein PER2 hampers HCV RNA replication. Circadian regulation of viral replication has potential applications in the development of therapeutic strategies. Circadian rhythm-based treatments (i.e. chronotherapies), have been employed against metabolic, immune-related and neoplastic diseases [36], [37]. Standard therapy for HCV patients involves administration of interferon-α and ribavirin (a nucleoside analogue) [11], [34]. Recently, an interferon/ribavirin-free therapy based on newly identified and efficacious protease inhibitors (telaprevir, boceprevir) promisingly entered into the clinic to treat HCV patients [38].
In light of our findings, the new strategies to inhibit viral replication could address the circadian relationship between host cell and hosted viruses, with the aim to improve the efficacy of treatment modalities through optimized timing of therapeutic regimens, minimizing the toxicity of pharmacological agents and targeting in a better way virus replication.
Acknowledgments
We are grateful to Prof. Masanori Ikeda for providing us the OR6 cell line. We thank Prof. Francesco Negro in whose laboratory the plasmids pIRES2- EGFP/Core 1b and 3a were generated. We thank also Michela Borghesan for technical help and Shilpa Chokshi for constructive discussion.
Author Contributions
Conceived and designed the experiments: GM FC MV VP. Performed the experiments: GB FR NS AG. Analyzed the data: GM FC JO RW AA MV VP. Contributed reagents/materials/analysis tools: GM FC NS AA MV VP. Wrote the paper: GM MV VP.
Citation: Benegiamo G, Mazzoccoli G, Cappello F, Rappa F, Scibetta N, Oben J, et al. (2013) Mutual Antagonism between Circadian Protein Period 2 and Hepatitis C Virus Replication in Hepatocytes. PLoS ONE 8(4): e60527. https://doi.org/10.1371/journal.pone.0060527
1. Bass J (2012) Circadian topology of metabolism. Nature 491: 348–356.
2. Edery I (2000) Circadian rhythms in a nutshell. Physiol Genomics 3: 59–74.
3. Nagoshi E, Saini C, Bauer C, Laroche T, Naef F, et al. (2004) Circadian gene expression in individual fibroblasts: cell-autonomous and self-sustained oscillators pass time to daughter cells. Cell 119: 693–705.
4. Sahar S, Sassone-Corsi P (2012) Regulation of metabolism: the circadian clock dictates the time. Trends Endocrinol Metab 23: 1–8.
5. Ohdo S (2010) Chrono-drug-delivery focused on biological clock: intra- and inter-individual variability of molecular clock. Adv Drug Deliv Rev 62: 857–858.
6. Tevy MF, Giebultowicz J, Pincus Z, Mazzoccoli G, Vinciguerra M (2013) Aging signaling pathways and circadian clock-dependent metabolic derangements. Trends Endocrinol Metab.
7. Shadan FF (2007) A circadian model for viral persistence. Med Hypotheses 68: 546–553.
8. Kalamvoki M, Roizman B (2011) Circadian CLOCK histone acetyl transferase localizes at ND10 nuclear bodies and enables herpes simplex virus gene expression. Proc Natl Acad Sci U S A 107: 17721–17726.
9. Collaco AM, Rahman S, Dougherty EJ, Williams BB, Geusz ME (2005) Circadian regulation of a viral gene promoter in live transgenic mice expressing firefly luciferase. Mol Imaging Biol 7: 342–350.
10. El-Serag HB (2012) Epidemiology of viral hepatitis and hepatocellular carcinoma. Gastroenterology 142: 1264–1273 e1261.
11. Ripoli M, Pazienza V (2011) Impact of HCV genetic differences on pathobiology of disease. Expert Rev Anti Infect Ther 9: 747–759.
12. Yoshida T, Hanada T, Tokuhisa T, Kosai K, Sata M, et al. (2002) Activation of STAT3 by the hepatitis C virus core protein leads to cellular transformation. J Exp Med 196: 641–653.
13. Moriya K, Fujie H, Shintani Y, Yotsuyanagi H, Tsutsumi T, et al. (1998) The core protein of hepatitis C virus induces hepatocellular carcinoma in transgenic mice. Nat Med 4: 1065–1067.
14. Pazienza V, Clement S, Pugnale P, Conzelman S, Foti M, et al. (2007) The hepatitis C virus core protein of genotypes 3a and 1b downregulates insulin receptor substrate 1 through genotype-specific mechanisms. Hepatology 45: 1164–1171.
15. Rappa F, Greco A, Podrini C, Cappello F, Foti M, et al. (2013) Immunopositivity for Histone MacroH2A1 Isoforms Marks Steatosis-Associated Hepatocellular Carcinoma. PLoS ONE 8: e54458.
16. Ikeda M, Abe K, Dansako H, Nakamura T, Naka K, et al. (2005) Efficient replication of a full-length hepatitis C virus genome, strain O, in cell culture, and development of a luciferase reporter system. Biochem Biophys Res Commun 329: 1350–1359.
17. Abid K, Pazienza V, de Gottardi A, Rubbia-Brandt L, Conne B, et al. (2005) An in vitro model of hepatitis C virus genotype 3a-associated triglycerides accumulation. J Hepatol 42: 744–751.
18. Albrecht U, Sun ZS, Eichele G, Lee CC (1997) A differential response of two putative mammalian circadian regulators, mper1 and mper2, to light. Cell 91: 1055–1064.
19. Pazienza V, Vinciguerra M, Andriulli A, Mangia A (2010) Hepatitis C virus core protein genotype 3a increases SOCS-7 expression through PPAR-{gamma} in Huh-7 cells. J Gen Virol 91: 1678–1686.
20. Arjona A, Sarkar DK (2006) The circadian gene mPer2 regulates the daily rhythm of IFN-gamma. J Interferon Cytokine Res 26: 645–649.
21. Miyazaki K, Wakabayashi M, Chikahisa S, Sei H, Ishida N (2007) PER2 controls circadian periods through nuclear localization in the suprachiasmatic nucleus. Genes Cells 12: 1225–1234.
22. Kim EY, Bae K, Ng FS, Glossop NR, Hardin PE, et al. (2002) Drosophila CLOCK protein is under posttranscriptional control and influences light-induced activity. Neuron 34: 69–81.
23. Schibler U (2007) The daily timing of gene expression and physiology in mammals. Dialogues Clin Neurosci 9: 257–272.
24. Canaple L, Kakizawa T, Laudet V (2003) The days and nights of cancer cells. Cancer Res 63: 7545–7552.
25. Zhu Y, Stevens RG, Leaderer D, Hoffman A, Holford T, et al. (2008) Non-synonymous polymorphisms in the circadian gene NPAS2 and breast cancer risk. Breast Cancer Res Treat 107: 421–425.
26. Chu LW, Zhu Y, Yu K, Zheng T, Yu H, et al. (2008) Variants in circadian genes and prostate cancer risk: a population-based study in China. Prostate Cancer Prostatic Dis 11: 342–348.
27. Lin YM, Chang JH, Yeh KT, Yang MY, Liu TC, et al. (2008) Disturbance of circadian gene expression in hepatocellular carcinoma. Mol Carcinog 47: 925–933.
28. Chen P, Kakan X, Zhang J (2010) Altered circadian rhythm of the clock genes in fibrotic livers induced by carbon tetrachloride. FEBS Lett 584: 1597–1601.
29. Oshima T, Takenoshita S, Akaike M, Kunisaki C, Fujii S, et al. (2011) Expression of circadian genes correlates with liver metastasis and outcomes in colorectal cancer. Oncol Rep 25: 1439–1446.
30. Chen P, Li C, Pang W, Zhao Y, Dong W, et al. (2009) The protective role of Per2 against carbon tetrachloride-induced hepatotoxicity. Am J Pathol 174: 63–70.
31. Narasimamurthy R, Hatori M, Nayak SK, Liu F, Panda S, et al. (2012) Circadian clock protein cryptochrome regulates the expression of proinflammatory cytokines. Proc Natl Acad Sci U S A 109: 12662–12667.
32. Chen R, Schirmer A, Lee Y, Lee H, Kumar V, et al. (2009) Rhythmic PER abundance defines a critical nodal point for negative feedback within the circadian clock mechanism. Mol Cell 36: 417–430.
33. Keum SJ, Park SM, Park JH, Jung JH, Shin EJ, et al. (2012) The specific infectivity of hepatitis C virus changes through its life cycle. Virology 433: 462–470.
34. Jonas MM (1996) Interferon-alpha for viral hepatitis. J Pediatr Gastroenterol Nutr 23: 93–106.
35. Kwon YC, Kang JI, Hwang SB, Ahn BY (2012) The ribonuclease L-dependent antiviral roles of human 2′,5′-oligoadenylate synthetase family members against hepatitis C virus. FEBS Lett 587: 156–164.
36. Kang TH, Sancar A (2009) Circadian regulation of DNA excision repair: implications for chrono-chemotherapy. Cell Cycle 8: 1665–1667.
37. Quera Salva MA, Hartley S, Barbot F, Alvarez JC, Lofaso F, et al. (2011) Circadian rhythms, melatonin and depression. Curr Pharm Des 17: 1459–1470.
38. Lange CM, Zeuzem S (2012) Perspectives and challenges of interferon-free therapy for chronic hepatitis C. J Hepatol Oct 24. doi:pii: S0168-8278(12)00818-5. 10.1016/j.jhep.2012.10.019. [Epub ahead of print].
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Abstract
Background
Hepatitis C virus (HCV) infects approximately 3% of the world population and is the leading cause of liver disease, impacting hepatocyte metabolism, depending on virus genotype. Hepatic metabolic functions show rhythmic fluctuations with 24-h periodicity (circadian), driven by molecular clockworks ticking through translational-transcriptional feedback loops, operated by a set of genes, called clock genes, encoding circadian proteins. Disruption of biologic clocks is implicated in a variety of disorders including fatty liver disease, obesity and diabetes. The relation between HCV replication and the circadian clock is unknown.
Methods
We investigated the relationship between HCV core infection and viral replication and the expression of clock genes (Rev-Erbα, Rorα, ARNTL, ARNTL2, CLOCK, PER1, PER2, PER3, CRY1 and CRY2) in two cellular models, the Huh-7 cells transiently expressing the HCV core protein genotypes 1b or 3a, and the OR6 cells stably harboring the full-length hepatitis C genotype 1b replicon, and in human liver biopsies, using qRT-PCR, immunoblotting, luciferase assays and immunohistochemistry.
Results
In Huh-7 cells expressing the HCV core protein genotype 1b, but not 3a, and in OR6 cells, transcript and protein levels of PER2 and CRY2 were downregulated. Overexpression of PER2 led to a consistent decrease in HCV RNA replicating levels and restoration of altered expression pattern of a subset of interferon stimulated genes (ISGs) in OR6 cells. Furthermore, in liver biopsies from HCV genotype 1b infected patients, PER2 was markedly localized to the nucleus, consistent with an auto-inhibitory transcriptional feedback loop.
Conclusions
HCV can modulate hepatic clock gene machinery, and the circadian protein PER2 counteracts viral replication. Further understanding of circadian regulation of HCV replication and rhythmic patterns of host-hosted relationship may improve the effectiveness of HCV antiviral therapy. This would extend to hepatic viral infections the current spectrum of chronotherapies, implemented to treat metabolic, immune related and neoplastic disease.
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