Nip the HPV encoded evil in the cancer bud: HPV reshapes TRAILs and signaling landscapes

A growing appreciation of misrepresented signaling pathways prompts the realization that spatio-temporal deregulation is likely to contribute broadly to cervical cancer development and may affect the sensitivity and resistance of cancer to targeted therapies. Tremendous experimental work has been done in improving our knowledge that cervical cancer arises from abnormal decision making by cancer cells. These decisions related to cell death or survival are made by molecular signaling networks that process information from outside and from within the HPV infected cervical cancer cells and initiate responses that determine the cell's survival. We dissect this segment of discussion into subheadings that describe regulation of linear signaling cascades in HPV infected cells.

Several hints have emerged that indicate that cervical cancer is associated with loss of TGF-β responsiveness (gradual decline in TGF receptors) and because cervical epithelial differentiation is altered by E7. For a better understanding of the underlying mechanisms, status of TGF-β2 and TGF-βRII expression was examined in transgenic mice expressing the oncogene E7 of HPV16 under control of the human Keratin-14 promoter (K14-E7 transgenic mice). The results indicated that there was an overexpression of TGF-β2 and decrease of TGF-βRII expression in this particular model of cervical carcinogenesis [45]. HPV mediates TGFα induced c-fos/c-jun heterodimer formation to regulate expression of oncogenes Figure 2[46]. Surprisingly, there is a research work that illustrates that E6 and E7 encoded by HPV-16 induce activation of TGF beta1 promoter [47]. It was additionally indicated by a contemporary study that inhibition of E7 expression lowered the expression level of TGF-beta1 and induced apoptosis [48]. Detailed structural insights identified that a 9-bp sequence, GGGGCGGGG, representing the consensus Sp1-binding site between -109 and -100 of the TGF-beta 1 promoter, was the major target for E6-mediated transactivation [49]. There is progressive loss of HPV-16 E2 which is higher in CIN3 than in CIN1 or CIN2, and there is a correlation between loss of HPV-16 E2 expression and loss of TGF-beta1 at the lesion site [50]. TGF-beta1 signaling cascade is involved in induction of chromosomal instability in HPV positive cervical cancer cells and inhibition of TGF-beta1 signaling by an inhibitor of TGFRI prevented telomere-mediated chromosomal instability [51].

Overexpression of SMAD2/3 may be involved in the genesis of cervical cancer Figure 2[52]. However this report is in contradiction to another finding that suggested that weak cytoplasmic SMAD4 staining and the absence of Smad4 nuclear staining was associated with poor survival in cervical cancer patients [53]. E7 facilitated the nuclear translocation of Smad proteins (SMAD 2, SMAD3 and SMAD4) in a ligand-independent manner. More intriguingly, E7 interacted with MH1 Domain of SMAD3 to repress TGF-β-mediated transcription Figure 2[27, 28]. It is necessary to have a better knowledge of regulation of SMAD subsets by HPV encoded proteins in cervical cancer cells. How these SMAD proteins are degraded or rescued in HPV infected cancer cells to regulate cancer progression still is incompletely understood. SMAD7 heterozygous, silent G to C variant in codon 391 was reported in HPV positive and negative cervical cancer samples. However this report did not identify a relationship between SMAD7 mutation and carcinogenesis [54].

However there is a direct piece of evidence that indicates that TGF-beta1 and IL-4 repress HPV-16 oncogene transcription [55]. Enforced expression of nuclear factor I in TGF-beta-sensitive HPV16-immortalized human keratinocytes (HKc/HPV16) inhibited TGF-beta mediated repression of E6 and E7 [56]. Experiments on transgenic mice provided evidence that HPV-11 transformed xenografts showed up-regulation of TGF beta 1 expression and down-regulation of the expression levels of bcl-2, c-myc, c-Ha-ras, c-jun and NFkB [57, 58]. It is noteworthy that HPV-16 transformed cells show down-regulation of bcl-2 and NFkB as well as NFkB function upon TGF beta 1 treatment [57, 58].

It still is confusing whether TGF signaling initially acts as a barrier to HPV encoded proteins associated activities. Putting pieces of evidence together indicate contradictory roles of TGF signaling. It appears that TGF signaling is induced in HPV infected cervical cancer cells however other research findings reveal that HPV encoded proteins degrade SMAD proteins to repress TGF signaling. Cervical carcinogenesis was noted in HPV infected cells both in absence and presence of TGF signaling. In depth studies are required to provide a detailed mechanism.

Interestingly, high-throughput technologies, including the analyses of protein networks have considerably enhanced our current understanding that binding of WNTs to frizzled (FZD) and LRP5 or LRP6 co-receptors transduces a signal across the plasma membrane that results in the activation of the Dishevelled (DVL) protein. Activated DVL inhibited the destruction complex and facilitated accumulation of CTNNB1 in the nucleus where it acted as a co-activator for Wnt target genes. Results obtained through immunohistochemistry revealed that normal cervical epithelium showed staining of β-catenin only on the membrane. However, cytoplasmic and nuclear staining was observed only on the basal proliferating layer of the normal stratified squamous epithelium. There is further elaboration of Wnt signaling mediated biological implications and it is clear that activation and stabilization of the catenin is controlled by HPV encoded proteins and various other oncogenes. SV40 small t antigen (smt) was reported to stabilize catenin by inhibiting PP2A [59]. Moreover it is also suggested that HPV encoded proteins stabilize catenin by suppressing SIAH-1. SIAH-1 is a target gene of p53 which is degraded by HPV encoded proteins and targeted inhibition of HPV encoded proteins resulted in restoration of SIAH. Genetic and biochemical data have demonstrated that E6 and E7 facilitated beta-catenin nuclear accumulation [60].

These finding indicated that there is an activated Wnt/β-catenin signaling cascade in HPV-associated premalignant lesions that plays an efficient role in accelerating cervical carcinogenesis. Activation of the Wnt pathway acted as secondary events that are necessary for malignant transformation of HPV-infected epithelial cells [61]. It is also relevant to mention that negative regulators of Wnt signaling are epigenetically repressed and a recent report clarifies an association between DKK3 and SFRP2 promoter methylation in cervical cancer [62].

As discussed in the introductory section that E2 functions as a repressor of the viral upstream regulatory region (URR) promoter that drives transcription of the E6 and E7 oncogenes, therefore loss of E2 is a prerequisite for increased E6/E7 expression. To identify whether the inhibition of E6/E7 expression by activated Notch1 occurs at the level of URR promoter activity, HeLa cells were transiently transfected with a plasmid for the URR promoter and an expression vector for activated Notch1. It was noted that URR promoter activity was significantly reduced by cotransfection of the activated Notch1 expression. Additionally it was observed that Notch-1 repressed URR by inhibiting AP-1. Notch1 inhibited c-Fos protein and simultaneously enhanced another Fos family member, Fra-1. Fra-1 lacked a transcription activating domain and acted as a suppressor rather than an inducer of AP-1-dependent transcription [63].

The data gained through electrophoretic mobility shift assays indicated that Notch overexpression was correlated to altered AP-1 DNA binding activity and complex composition. After inducing a moderate level of Notch expression, an increased DNA binding was demonstrated byAP-1. However cells transfected with high expression levels of Notch displayed a decrease in cFos signal and an increase in Fra1 signal [64]. It is convincing to note that explants of HaCaT cells co-expressing Jagged1and E6/E7 generated tumors greater than 90 mm3. However, co-expression of Delta1 and E6/E7 generated lesions of less than 10 mm3. It was noted that Jagged-1 and E6/E7 co-expressing cancer cells used PI3K/Akt signaling axis to induce EMT [65]. More detailed insights suggest that Jagged-1 induced HES-1 that repressed Manic Fringe (negative regulator of Jagged-1 mediated signaling). These HES1 binding sites were found at nucleotide position −250 upstream of the transcriptional start site of Manic Fringe [66]. Notch-1 is also indicated to behave differently as HPV infected cells use Notch-1 during the progression from cervical intraepithelial lesions (CIN) to invasive cervical carcinoma [67].

Cellular and molecular studies have outstandingly clarified existing concepts of role of HPV in cervical cancer. It is now evident that HPV oncoproteins transform noncancerous epithelial cells into cancerous carcinomas by targeting key tumor suppressors and pro-apoptotic proteins and additionally impair tumor suppressor and apoptotic pathways. Therefore multi-targeted approach based on targeting of HPV encoded proteins and misrepresented pathways has shown promise in restoring apoptotic pathway. We subdivide next coming section into generalized approaches in inducing apoptosis in HPV infected cervical cancer cells and TRAIL mediated signaling in HPV infected cervical cancer cells. Treating cervical cancer cells with Withaferin A resulted in downregulation of HPV-E6 and E7 oncoproteins [68]. A recent report adds a new dimension to role of HPV-16E6 in cervical cancer cells. It is intriguing to note that enforced expression of 16-E6 in cervical cancer cells stimulated the expression of p53 and induced apoptosis [69]. Interestingly, leaf extract of Bryophyllum pinnata was effective in repressing HPV18 transcription. It also suppressed oncogenic c-Fos and c-Jun expression [70]. n-Hexane and chloroform extracts of Anisomeles malabarica induced death in HPV16-positive cervical cancer cells [71].

Progressively there is a significant accumulation of research reports which have categorized HPV encoded proteins as oncogenes that suppress apoptosis. In the upcoming section we dissect viral encoding genes which have been experimentally investigated regarding their roles in cervical cancer progression and underlying mechanisms which induce resistance against TRAIL mediated apoptosis.

Cellular studies indicate that TRAIL binds to several distinct receptors and it is a well established piece of information that DR4 and DR5 contain the intracellular death domain (DD) essential for the induction of apoptosis following receptor ligation. Contrary to this, DcR1 nor DcR2 are unable to induce apoptosis due to a complete or partial lack of the intracellular DD, respectively. Using high-throughput technologies, we are able to understand that binding of TRAIL to TRAIL-R1 or TRAIL-R2 induces trimerization of TRAIL-R1 or TRAIL-R2, and FADD binds to the trimerized TRAIL- R1 or TRAIL-R2 death domains. Then, FADD acts as an adaptor molecule that is involved in signal dissemination by recruiting caspase 8, which initiates a proteolytic cascade involving other caspases eventually leading to cell death [72]. TRAIL mediated signaling is shown in Figure 3.

It has lately been shown that pretreating HPV16 E7 expressing cervical cancer cells with HDAC inhibitors considerably sensitized cells to TRAIL. c-FLIP suppression by HDAC inhibitors restores death receptor-mediated apoptosis in HeLa cells. HDAC inhibitors target anti-apoptotic proteins and induce TRAIL mediated apoptosis in resistant cancer cells by enhancing surface expression of TRAIL receptors and re-distribution of TRAIL receptors into lipid rafts (reviewed by [73]). It has previously been shown that E7 oncoprotein binds to multiple functional partners, particularly pRB and HDAC1 and HDAC2 [74]. However, targeted inhibition of HPV16- E7 abolished HDAC inhibitors mediated sensitization to TRAIL [75]. There is a contradictory report that indicates that E6/E7-siRNA induces senescence rather than apoptosis in SiHa cells [76]. Increasing technologies have revolutionized our understanding of the underlying mechanisms which are opted by HPV for the development of cervical cancer, implying that HPVs have evolved immunoevasive mechanisms. It is now known that HPV escapes immunosurveillance by repressing the genes involved in IFN signaling (STAT1), proapoptotic genes (TRAIL), and pathogen recognition receptors (TLR3, RIG-I, and MDA5) [77]. Cells treated with cAMP analog 8-CPT-cAMP (adenylyl cyclase activator), PDE inhibitors (isobutylmethylxanthine) or PKA inhibitors displayed an upregulated expression of Smac/DIABLO. This observation signifies the fact that cAMP/PKA/CREB pathway is an important regulator of Smac/DIABLO transcription [78]. Although it has been shown that HPV encoded E5 protein utilizes cAMP/PKA/CREB pathway to stimulate the expression of genes [31]. It needs to be tested with reference to pro-apoptotic and antiapoptotic gene subsets in cervical cancer cells. E2F1has also been shown to directly bind and activate the promoter of Smac/DIABLO, through the E2F1-binding sites [79].

It is surprising to note that HPV-E2 gene disruption is one of the key features of HPV-induced cervical malignant transformation and is tumor suppressing gene encoded by HPV. Laboratory investigations have revealed that HPV16-E2 inhibits c-FLIP and renders cell hypersensitive to apoptotic signal. It was confirmed by overexpressing cFLIP in cancer cells that completely hampered E2 mediated apoptotic response [80]–[83]. Co-immunoprecipitation and western blot analyses suggest an interaction between HPV 16-E2 and cFLIP isoforms thus inhibiting the recruitment of cFLIP to DISC. Characteristically it has been suggested that targeting of p53 by HPV encoded proteins resulted in transcriptional repression of Puma and abrogation of translocation of Bax to mitochondrial membrane. Puma is a proapoptotic protein that acts as an upstream activator of Bax, by inducing a conformational change thus facilitating the transmigration of Bax from the cytosol to the mitochondrial membrane [84]. Cervical cancer cells treated with cyano analogue of boswellic acid displayed reduced viral E6 mRNA expression and enhanced expression of Puma through p53 pathway [85]. Antisense and peptide aptamers targeting HPV E6/E7 have been shown to induce target cell apoptosis through activation of pRb [86, 87]. It has also been shown that p53 triggers the expression of pro-apoptotic proteins (Noxa, Puma and Bax) and repressed the expression of pro-proliferative factors CyclinB1, cdc2, and Cdc25c [88]. Moreover there is study that challenges classical concept of pRb in suppressing cancer via negative regulation of E2F1. It highlights tumor suppressor role of E2F1. E2F1 up-regulates the expression of the pro-apoptotic proteins PUMA, Noxa and Bim. It needs detailed investigation in cervical cancer cells to have a better understanding of the role of E2F1 in cervical cancer progression. Keeping in view tumor suppressor role of E2F1 it will be necessary to identify relationship between pRb, E2F1 and regulation of pro-apoptotic genes [89].

Targeted inhibition of HPV16-E6 resulted in restoration of sensitivity to TRAIL [90]. There is sufficient experimental evidence that transfection of HPV16-E6 gene into cells with wild-type p53, substantially decreased the level of p53 protein, that resulted in suppression of DR4 induction by DNA-damaging agents [91]. Transiently transfecting HPV16-E5 gene into immortalized human keratinocyte cell line HaCaT severely repressed activation of caspase-3 upon TRAIL and FasL treatment [92]. Confluence of information suggests that HPV degrades p53 that results in suppression of p53 mediated expression of death receptors. However there is a finding that shows that IFN-beta increases TRAIL expression both directly at the mRNA level and indirectly by enhancing surface protein levels [93]. HPV16-E6 positive cervical cancer cells displayed a rapid reduction in the protein levels of both FADD and procaspase 8, which resulted in suppression of the activation of caspases 8, 3 and 2 [94]. FZD8 was found to be highly expressed in HeLa cells and in future it would be interesting to note if targeting of FZD8 in cervical cancer cells could be helpful in overcoming resistance against TRAIL [95]. Similar approach has been tested in breast cancer cells and has been shown to be effective [96].

Researchers are targeting the anti-apoptotic machinery and associated signaling cascades that impair TRAIL mediated apoptosis. Wogonin, a flavonoid isolated from the root of the medicinal herb Scutellaria baicalensis Georgi was reported to be useful in sensitizing cervical cancer cells to TRAIL [97]. It has lately been suggested that bortezomib and nelfinavir considerably enhanced the efficacy of an apoptosis-inducing TRAIL receptor antibody [98]. Aspirin and TRAIL significantly repressed ERK1/2 activation and down-regulated Mcl-1 [99]. Various reports suggest that phosphorylated ERK1/2 induces TRAIL resistant phenotype and aspirin has been shown to inhibit pERK1/2. ERK pathway activation increases the expression of prosurvival proteins, particularly Mcl-1, by stimulating de novo gene expression. It is intriguing to note that expression of Mcl-1 in tumor cells can be regulated at the transcriptional level or through post translational modifications by ERK [100]. Artesunate is an anti-malarial drug that is explored to be effective in sensitizing cervical cancer cells to TRAIL mediated apoptosis by suppressing pro-survival proteins, such as survivin, XIAP and Bcl-XL [101]. Noatbly strong synergistic apoptosis-inducing effect of the combination of rhTRAIL and MG132, particularly in CIN II/III lesions indicates that rhTRAIL combined with proteasome inhibitors open new horizons of therapeutic strategies for CIN II/III [102]. Luteolin synergistically acts with rh TRAIL to induce apoptosis in HeLa cells [103]. HPV control of TRAIL mediated signaling is shown in Figure 3.

Phenylethyl isothiocyanate (PEITC) increased the expression of the DR4 and DR5 in cervical cancer cells [104]. Likewise, synergistic treatment with taxol and pristimerin induced cervical cancer apoptosis by enhancing intracellular ROS, upregulation of DR5 and activation of Bax [105]. Cisplatin also enhanced DR5 expression in cervical cancer cells [106]. Irradiation cells showed a p53-dependent rise in DR5 membrane expression [107]. It is surprising to note that proteasome inhibitor MG132 substantially stimulated DR4 and DR5 membrane expression in HeLa. However in SiHa only DR5 membrane expression was upregulated from almost unnoticeable to notable levels independent of p53 [108]. This finding adds a new layer of information that p53 is not indispensible for expression of DR5.

DR5 promoter contains multiple Sp1 binding sites, which may contribute to the increased DR5 expression [109, 110]. Sp1 binding sites are also present in promoter region of TRAIL gene [111]. It has also been shown that Sp1 is phosphorylated by ERK that enhanced DNA binding affinity of SP1 [112]. DNMT-mediated hypermethylation of promoter regions cause transcriptional repression and it has been shown that epigenetic repression is induced by DNMT in the proximity of the TRAIL promoter [113]. Moreover, H3K27me3 epigenetic mark at the DR5 promoter represses its expression. However it has been indicated that interference strategies directed against Suz12 and Ezh2 promoted DR5 expression [114]. It is also important to mention that in HPV16 E6 and E7 expressing cervical cancer cells have considerably enhanced DNMT activity and there is a transcriptional down-regulation of E-Cadherin in these cells [115, 116]. It has been shown that JNK is involved in stimulating the expression of DR through CHOP and SP1. Using different kinase inhibitors, including the p42/44 MAPK inhibitor PD098059, the p38 MAPK inhibitor SB203580, and the JNK1/2 inhibitor SP600125 it was confirmed that DR5 expression was regulated by JNK. Among the inhibitors tested, the JNK1/2 inhibitor SP600125 effectively impaired DCA-induced DR5 expression, whereas the p42/44 and p38 MAPK inhibitors failed to repress DR5 expression. Cardamonin isolated from black cardamom induces the expression of DRs using CHOP and SP1. The relationship was confirmed by abrogation of CHOP and SP1 that resulted in inhibition of mediated up-regulation of DRs [117]. MEK kinase 1 (MEKK1) is a serine threonine kinase that is activated following etoposide treatment and activates IKK. IKK mediated inactivation of IKB results in sequestration of NF-kappaB from IKB. NFKB translocates into the nucleus to stimulate the expression of DR4 [118]. DR4 is a p53 target gene and is transcriptionally controlled by p53 through a functional intronic p53 binding site (p53BS) [119]. It is also relevant to mention that cells treated with EGF show a decrease in DR5 expression. Detailed analysis indicates that EGF treatment facilitates co-existence of NFKB with HDAC at the binding site present in intronic region of DR5. However etoposide treatment inhibits NFKB mediated recruitment of HDAC to binding site [120]. Cervical cancer cells treated with naringin displayed increased cell surface appearance of DR and mitochondria-mediated apoptosis in human cervical cancer (SiHa) cells Ramesh et al, [121].

It is becoming successively more understandable that nanoparticles (NPs) have become an important tool in many industries including healthcare. Substantial fraction of information has revealed that compared with free antitumor drugs, drug-loaded long-circulating nanovectors show prolonged circulation time in plasma, enhanced accumulation in tumor tissues, and better-quality therapeutic activity. Functionalizing nanovectors with targeting moieties can promote specific receptor-mediated endocytosis, limiting non-specific uptake into the normal tissues. TRAIL has also been conjugated to different nanocarriers to improve the specificity of the delivery system and it has been shown that a nanocomplex system between the positively charged TRAIL and the negatively charged chondroitin sulfate (CS) (CS/TRAIL) was designed and applied in poly (lactide-co-glycolide) (PLGA) microspheres (MSs). The results indicated that TC-loaded PLGA MSs significantly inhibited tumour growth [122]. Furthermore, another recently published work indicated that nanoparticle modified with polyethyleneimine was applied to be a vector of TRAIL for cervical cancer gene therapy [123].

TRAIL resistance has been frequently observed in cancer cells and different approaches are being tested to overcome the TRAIL resistant phenotype. There are different subsets of anti-apoptotic proteins which are over-expressed thus inducing resistance against TRAIL. Results have shown that natural flavonoid chrysin inhibited STAT3 phosphorylation thus repressing transcriptional regulation of Mcl-1. Proof of the concept was provided by treating cervical cancer cells with STAT3-specific inhibitor, cucurbitacin-I, which decreased Mcl-1 levels and enhanced TRAIL-induced cell death [124]. Likewise 5,7-Dihydroxyflavone is a dietary flavonoid has also been reported to overcome resistance against TRAIL by effectively targeting STAT3 phosphorylation. Additionally, Bcl-2, Mcl-1, and IAPs were down-regulated and pro-apoptotic protein Bax was found to be up-regulated [125]. Equol is an isoflavan produced by intestinal bacteria and has been shown to enhance TRAIL-induced apoptosis of HeLa cells through a death receptor-mediated caspase pathway. Data suggested that Equol enhanced TRAIL-induced apoptosis through activation of caspase-3, -8, -9, and cleavage of BID [126].

It is essential to investigate role of HPV encoded proteins in suppressing TRAIL mediated apoptosis. How HPV encoded proteins mediate expression of TRAIL, DR4/DR5 and DcRs is insufficiently studied. It is astonishing to note that HPV16 E2 and E6 are RNA-binding proteins and contain a protein-RNA interaction domain in their C-terminal regions. In addition, E2 and E6 interact with multiple cellular splicing factors like serine/arginine (SR) proteins [127]. This relationship of HPV encoded proteins with regulators of mRNA splicing needs detailed investigation with reference to TRAIL, DRs and subsets of tumor suppressors. Moreover, impairment of TRAIL mediated apoptosis in HPV infected cancer cells needs additional laboratory based experimentations addressing modes of repression of TRAIL and DR4/DR5 at transcriptional and post-transcriptional level. Do HPV encoded proteins recruit silencing machinery at TRAIL and DR4/5 promoters or is there a miRNA mediated regulation of TRAIL and DR4/DR5 or is there an enhanced degradation of DRs are some questions which demand extensive research. Although some cell type specific studies have revealed that c-Cbl-mediated ubiquitination of TRAIL receptors has a main role in the endosomal sorting leading to the degradative pathway. However none of the studies indicated any relationship between HPV encoded proteins in directing degradation of DRs in cervical cancer cells [128]. However it is clear that HPV encoded proteins use ubiquitin ligases (cullin 1 ubiquitin ligase complex) to degrade tumor suppressors [129]. Membrane-associated RING-CH (MARCH) ubiquitin ligase is also reported to ubiquitinate TRAIL-R1 and impairing its cell surface expression [130].

Integrative genomics and genetics approaches have proven to be a functional tool in elucidating the complex relationships often found in gene regulatory networks and reconstitution of tumor-suppressive miRNA, or sequence-specific knockdown of oncogenic miRNAs by ‘antagomirs,’ has produced favorable antitumor outcomes in experimental models. We discuss existing knowledge gaps that need to be bridged prior to the consideration of miRNA-based experimental cancer gene therapy. These include our incomplete understanding of rate-limiting cellular components that impact the efficiency of this posttranscriptional gene-silencing phenomenon in HPV expressing cervical cancer cells. We partition this section into regulation of miRNAs by p53 and miRNA subsets which are documented to suppress and promote cervical cancer. We partition this section into regulation of miRNAs by p53 and miRNA subsets which are documented to suppress and promote cervical cancer.

It is now clear that HPV encoded proteins target p53 to inhibit apoptosis of host cells. In the next section we discuss subsets of miRNA which are known targets of p53 and are inhibited by degrading p53. Detailed studies suggested that cortisol induced HPV-E6 expression and suppressed p53 and miR-145 in cervical cancer cells. MiR-145 expression in cervical cancer cells was wild-type p53-dependent, and cortisol down-regulated miR-145 expression [131]. miR-23b and miR-34a were also known targets of P53 however HPV encoded proteins repressed the expression of miR-23b by degrading p53 [80]–[83, 132]. Figure 4. miR-15a/miR-16/miR195/miR-497 family, miR-143/miR-145 and the miR-106-363 cluster appeared to be misrepresented in HPV positive cervical cancer cells [133]. HPV encoded proteins regulate expression of miRNAs in infected cells and Figure 4 illustrates the mechanisms.

HPV encoded proteins use methylation machinery to suppress tumor suppressor miRNAs and there is a direct piece of evidence that reveals hypermethylation of miR-124a and miR-203 in the precursor lesions [134]. There is also considerable evidence regarding increased methylation levels of hsa-miR-124-1 and hsa-miR-124-2 that strongly correlated with reduced hsa-miR-124 expression in cervical tissue specimens [135]. miR-218 was also found to be downregulated [136]. It appears that tumor suppressor miRNA subsets are repressed by installing co-repressor machinery at the promoter regions.

Phosphoinositide 3-kinase catalytic subunit delta (PIK3CD) is a miR-125b target and cells reconstituted with miR-125b represented inhibition of PI3K/Akt/mTOR pathway , while Bid was up-regulated in miR-125b-overexpressing cells [137]. MiR-384-5p is also a known regulator of PIK3CD [138]. MiR-7 has been shown to disrupt PI3K/Akt/mTOR signaling axis [139]. However precise role of miR-384-5p and miR-7 needs to be determined in HPV expressing cervical cancer cells.

miR-17-5p and miR-143 act as tumor suppressors in cancer cells by targeting TP53INP1 and Bcl-2 respectively [140]–[142]. Fascinatingly, overexpression of miR-424 repressed the expression of checkpoint kinase 1 (Chk1) and substantially inhibited cancer progression [143, 144]. miR-214 negatively regulates N-acetylgalactosaminyltransferase 7 (GALNT7) and distinctly inhibits cervical cancer cell proliferation, migration, and invasion [145]. miR-372 and miR-223 are down-regulated in cervical cancer and restoration of these miRNAs inhibited cell migration and invasion [146, 147]. miR-375 is a tumor suppressor gene and is downregulated in cervical cancer cells however it has been reported that HPV16 E6/E7 does not directly regulate miR-375 expression [80]–[83, 148].

It is noteworthy that transiently transfecting pre-miR-34c-3p, in HPV positive cervical cancer cells caused S-phase arrest and apoptosis [149]. It is worth describing that introduction of expression vectors for miR-203 into HPV positive cells substantially limited HPV amplification. It has also been noted that miR-203 expression is regulated through MAPK/PKC pathway and interestingly, this pathway is hampered in E7 expressing cells. Pharmacological activation of PKC pathway is speculated to trigger the expression of miR-203 via AP-1, AP-2, and Sp-1 transcription factor families whose binding sites are present in miR-203. Therefore E7 expressing cells treated with PKC activators did not display an increase in expression of miR-203 [150]. E5 expressing cervical cancer cells showed upregulated miR-146a and repressed miR-324-5p [151]. MiR-497 is a tumor suppressor and targets IGF-1R however it is downregulated in cervical cancer cells [152]. It has been shown that cervical cancer cells treated with mTOR inhibitors displayed an increase in expression of miR-143. It was noted that mTOR was involved in repressing the expression of miR-143 [153]. Additional studies are required to dissect the precise pathway downstream to mTOR that represses the expression. Tumor suppressor miRNA subsets are shown in Figure 5.

miR-10a, miR-205 and miR-133b are upregulated in cervical cancer and promote migration and invasion [154]–[156]. CYR61 and CTGF are members of the cysteine rich 61/connective tissue growth factor/nephroblastoma (CCN) family of growth regulators and have tumor suppressing properties. However targeting of CYR61 and CTGF by miR-205 promotes cellular proliferation [155]. CHL1 gene – close homolog of L1, also known as CALL - cell adhesion L1-like encodes a one-pass trans-membrane cell adhesion molecule (CAM) capable of both homotypic and heterotypic binding and has tumor suppressing properties. It is negatively controlled by miR-10a [154]. miR-133b enhances cell proliferation via negative regulation of mammalian sterile 20-like kinase 2 (MST2), cell division control protein 42 homolog (CDC42) and ras homolog gene family member A (RHOA). Additionally, miR-133b overexpressing cells have activated AKT1 and ERK1/2 [156]. Up-regulation of miR-19a and miR-19b promoted cell growth and invasion. The Cullin family member of RING E3 ubiquitin ligases (CUL5) is negatively regulated. Cullin-RING E3 ubiquitin ligase are involved in chaperone-mediated protein regulation and act as tumor suppressors. [143, 144]. Therefore it is notable that HPV encoded proteins use various strategies to inhibit Cullin 5 mediated degradation of oncoproteins. miR-20a promoted migration and invasion of cervical cancer cells [157]. miR-886-5p is overexpressed in cervical cancer cells and impair apoptosis by negatively regulating Bax [158]. E7 protein of HPV binds to pRB, a negative regulator of E2F that results in sequestration of E2F from pRB. Binding sites for E2F1 and E2F3 have been identified in the promoter of miR-15b and targeted inhibition of HPV16-E7 resulted in downregulation of miR-15b in cancer cells [159] Figure 4. It has lately been shown that HPV16-positive cancer cells have a downregulated miR-218. Detailed analysis showed that HPV16-E6 oncoprotein suppressed the expression of miR-218 and rescued Laminin 5 β3 (LAMB3). LAMB3 is negatively regulated by miR-218 and cells reconstituted with LAMB3 displayed enhanced migratory potential [160]. Likewise, methylation-mediated transcriptional repression of hsa-miR-149, -203 and -375 is noted in cervical cancer [161]. miR-182 is an oncomir and inhibition of miR-182 in HeLa xenograft mouse model, resulted in tumor growth regression. Moreover expression of miRNA subsets in cervical cancer cell lines displayed two up-regulated (miR-182 and -183) and nine down-regulated (miR-211, 145, 223, 150, 142-5p, 328, 195, 199b, 142-3p) miRNAs [162]. hsa-miR-15a-3p induces apoptosis in cancer cells via negative regulation of Bcl-xL [163]. Similarly, cell reconstructed with miR-214 showed increased expression of Bax, caspase-9, caspase-8 and caspase-3. Moreover, it has been persuasively revealed that miR-214 is regulated by DNA methylation and histone deacetylation [164]. NDRG2 distinctively enhanced Bcl-2 expression and increased the Bcl-2/Bax ratio, which decreased sensitivity of Hela cells to drug-induced apoptosis. However cancer cells expressing miR-15b and miR-16 demonstrated a down-regulated Bcl-2. It is still not know how NDRG2 knock down stimulates the expression of miR-15b and miR-16 [141, 142]. Moreover a cell-type specific study indicates that NDRG2 is negatively regulated by miR-650 [165]. Oncogenic miRNA subsets are shown in Figure 6.

There is a complicated network by which miRNA subsets are transcriptionally triggered by downstream effectors of various signaling cascades and in turn miRNA subsets regulate modulators of signaling cascades. How HPV encoded proteins reconstitute signaling, transcriptional and epigenetic machinery to regulate tumor suppressor miRNAs and oncomirs still is a mystery.

On a similar note, Arsenic trioxide induced cervical cancer apoptosis by downregulating HPV-E6 and upregulating p53 [166]. There is a progressive increase in improving the RNA interference strategies. In line with this approach, it has recently been explored that chitosan is appropriate as a carrier for delivery of siRNA into cancer and delivery of chitosan/HPV16 E7 siRNA nanoparticles in vivo is an effective therapy for cervical cancer [167]. E6/E7 specific siRNA-induced transcriptional gene silencing has recently been effectivley tested in cervical cancer cells [168]. Chloroform Extract of Rasagenthi Mezhugu, induced DNA damage and apoptosis in cervical cancer cells [169]. More interestingly, anti-DR5 monoclonal antibody, MD5-1 with a DNA vaccine encoding calreticulin (CRT) linked to human papillomavirus type 16 (HPV-16) E7 antigen (CRT/E7(detox)) provided unique opportunities for the development of therapeutic strategies. The study revealed biological functionality and highlighted that administration of CRT/E7(detox) in mice bearing the E7-expressing tumor, generated the most potent therapeutic anti-tumor effects as well as highest levels of E7-specific CD8+ T cells [170]. There is a finding that has demonstrated a correlation between the shrinkage of HPV16 E6 and E7+ tumors versus DC and LC infiltration in a murine model of cervical cancer thus adding new evidence of the preclinical efficacy of Dendritic cells (DCs) and Langerhans cells (LCs) mediated killing. There is also sufficient evidence that suggests that expression of TRAIL decoy receptors is reduced following introduction of E6 and E7 into host cells [171]. Using different in-vitro strategies, E6 and E7 proteins are targeted to suppress carcinogenesis. These targeted approaches included treatment of cervical cancer cells with biflavonoid amentoflavone, curcumin and Ruthenium oligonucleotides. Cervical cancer cells treated with hesperetin (flavonoid from citrus fruits) displayed an upregulated Fas death receptor and its adaptor protein FADD. Additionally, there was an increased expression of different caspases, p53 and Bax Alshatwi et al, [172].

It was shown that targeted inhibition of E6 and E7 resulted in rescue of p53 Lee et al. [173], Maher et al. [174], Reschner et al. [175]. Moreover, delivery of monoclonal antibodies against E6 in transformed cervical keratinocytes has also been tested. There was an enhanced p53 activity after targeting of E6 Togtema et al. [176]. It needs to be pursued with reference to miRNA subsets which are influenced after treatment with antibodies against E6. Future studies must converge on additional natural compounds with minimal off target effects and considerable efficacy.

GRIM-19 has been acclaimed as tumor suppressor as cells reconstituted with GRIM-19 displayed ubiquitination and degradation of E6AP, and disrupted the E6/E6AP complex. The abrogation of E6/E6AP complex protected p53 from degradation and promoted cell apoptosis [177]. It is impelling to note that phenomenal strides have been made in identifying regulators of cervical cancer. A better understanding of positive and negative regulators will enable the scientists to effectively target oncogenes that promote HPV expression. In line with this approach, it has recently been identified that interaction of mixed lineage leukemia 5 gene (MLL5β) with the AP-1-binding site at the distal region of the HPV18 long control region led to activation of E6/E7 transcription. Targeted inhibition of MLL5β drastically repressed both E6 and E7 expression [178].

In line with this approach, it has been proved that HPV E2 is negative transcriptional modulator of HPV E6 and E7 oncogenes, and also an apoptosis-inducing agent. There is an increasing trend of transiently transfecting tumor suppressor genes into cancer cells to enhance the efficacy of chemotherapy and radiations. A recent report indicated that oncolytic adenovirus armed with human papillomavirus E2 gene in combination with radiation demonstrated considerably augmented antitumor efficacy [80]–[83]. Similarly, pretreatment with dihydrotanshinone increased radiation induced apoptosis in cervical cancer cells through down-regulated HPV E6 gene expression [179]. It has lately been explored that pentoxifylline sensitized human cervical tumor cells to cisplatin-induced apoptosis by inhibiting NF-kappa B and anti-apoptotic proteins [180]. Transgenic mouse model has been developed with malignant cervical lesions allowing the study of the cooperative effect between HPV16-E6/E7 expression and the lack of RXRα in cervical cancer development [181]. This model could be useful to investigate efficacy of chemopreventive and chemotherapeutic strategies. It has been persuasively documented that acetoxychavicol acetate (ACA) with cisplatin (CDDP) worked with effective synergy in HPV-positive human cervical carcinoma cells and induced cell death [182]. HPV encoded proteins control host proteins using an array of post-translational modifications, many of which create binding sites for specific protein-interaction domains thus reconstructing signaling cascades for regulation of cell proliferation. We have discussed common strategies used by HPV encoded proteins for modulation of protein network to impair apoptosis in host cells.