Human papillomavirus (HPV) infection is associated with a broad spectrum of benign and malignant neoplastic epithelial changes. The association of HPV with neoplastic transformation has been extensively investigated in lesions of the uterine cervix. Moreover, the role of HPV in malignant transformation of the cervical epithelium is well established. On the other hand, HPV-DNA has been found to be less common in penile cancer cases (1). The incidence of penile cancer is lower compared to cervical cancer. Although several epidemiological, clinical and pathological studies have indicated that this virus is sexually transmitted, detailed information on the association of HPV with penile cancer has yet to be sufficiently elucidated as compared to cervical cancer. HPV infection is the most common sexually transmitted disease, thus the risk factor increases with certain sexual behaviors. The highest prevalence of HPV infection is observed in sexually active adolescents and young adults. The virus affects the squamous epithelium of the male genitalia in a similar way to the female genital tract (1–3).

The HPV viral oncogenes, E6 and E7, are the main contributors to the development of HPV-induced cancers, probably due to the integration of the viral genes in the host cell genome. E6 and E7 react with the tumor suppressor gene products p53 and pRb in host cell proteins, resulting in induced cellular immortalization, transformation and carcinogenesis, due to their interference with cell cycle and apoptosis control (4). p16^INK4a belongs to the inhibitors of cyclin-dependent kinase (CDK)-4 families (INK4a family) that decelerate the cell cycle by inactivating the cyclin-dependent kinase inhibitors. By interacting with CDK4 and CDK6, p16^INK4a inhibits the formation of the cyclin D/CDK4 and CDK6 complex, which is a proliferation-stimulating protein. The p16^INK4a protein prevents the phosphorylation of pRb family members. Normally, the overexpression of p16^INK4a results in the inhibition of E2F-dependent transcription and of cell cycle progression at the G1 to S phase of the cell cycle (5). The nuclear and cytoplasmic overexpression of p16^INK4a protein was previously reported for certain cancers (5–10).

NF-κB was first discovered as a protein bound to the κ immunoglobulin light chain gene enhancer in the nuclei of B cells (11). NF-κB transcription factors consist of five homologous subunits, such as RelA/p65, c-Rel, RelB, p50/NF-κB1 and p52/NF-κB2. IκB-bound NF-κB dimers are IκB kinase (IKK) complexes, comprising two catalytic (IKKα and IKKβ) and one regulatory (IKKγ/NEMO) subunit (12). The causal relationship between chronic inflammation and cancer is widely accepted. Numerous investigations have identified nuclear factor-κB (NF-κB) as an important modulator in driving chronic inflammation to cancer. This transcriptional factor is indispensable for the malignant progression of transformed cells associated with various inflammatory cells and a network of signaling molecules. Significant factors for cancer development include self-sufficiency in growth signals, insensitivity to growth inhibitors, evasion of apoptosis, limitless proliferation potential, tissue invasion and sustained angiogenesis. Experimental evidence revealing specific mechanisms by which NF-κB influences cancer initiation, promotion and progression has been reported (13,14). The expression and function of numerous cytokines, chemokines, growth factors and survival factors are NF-κB-dependent. NF-κB activation has been implicated in a variety of processes related to transformation and oncogenesis (15).

To the best of our knowledge, the immunohistochemical localization of NF-κB associated with HPV infection in penile cancer was previously reported using materials obtained from previous studies of Kenya, East Africa and Nagasaki, Japan (16,17). The purpose of this study was to determine the relationship among HPV infection, p16^INK4a, p53 and NF-κB in penile cancer in northern Thailand.

Penile cancer is a relatively rare disease in Europe and the United States, with incidence rates varying from 0.5–1.5 per 100,000 men. On the other hand, in developing countries, it is a more common type of cancer, with an incidence of 2–5 per 100,000 men. The highest frequency of penile cancer occurs in Asia, Africa and Latin America (1).

HPV is a large family of DNA viruses with more than 100 different HPVs, and with approximately 40 HPVs infecting the genital mucosa following sexual transmission. HPVs are classified into two groups depending on whether it causes benign or malignant tumors. The high-risk group includes HPV-16, -18, -31, -33, -35, -39, -45, -51, -54, -56, -58, -59, -66, -68 and -69; and the low-risk group includes HPV-6, -11, -26, -30, -34, -40, -42, -43, -44, -53, -55, -57, -61, -62, -64, -67, -70, -71, -73, -74, -79, -81, -82, -83 and -84 (2). The most common oncogenic HPV genotypes causing cervical cancer are HPV-16 and-18. HPV-16 is the most prevalent high-risk type and is found in cervical cancer, with HPV-18 being the second most prevalent. However, in our investigation, HPV-18 was found to be the most prevalent type in penile cancer in northern Thailand (18). HPVs are believed to be the primary causal agents for the development of benign and malignant tumors in mucosal and skin lesions, and high-risk types such as HPV-16 and -18 are associated with more than 90% of all cervical cancers. HPV-6 and-11 are usually associated with common genital condyloma. However, we cannot exclude the possibility of cancer formation from low-risk HPV types. The prevalence of HPV-DNA is significantly greater in cancer of the genital organs than in other organs. HPV-related disease is well documented in lesions of the female genital organs, and results have been obtained using a wide range of epidemiological, clinical and molecular techniques. The prevalence of HPV in the tumor tissue has been reported to vary considerably. The frequency of HPV-positive (Fig. 1B) penile cancer (76.5%) reported in this study (Table I) is similar to that reported by Picconi et al (71%) (19) and Cupp et al (66%) (20). Higher expression rates were reported by Senba et al (79%) (18), Sarkar et al (82%) (21) and Tornesello et al (83%) (22). Lower expression rates were reported by Tornesello et al (46%) (1), Rubin et al (42%) (23) and Cubilla et al (31%) (24).

HPV is a DNA tumor virus whose genome is organized in three regions, including the early gene (E1 to E7), the late gene (L1 and L2) regions and the upper regulatory region. The nuclear protein in E6 and E7 of HPV is considered to be one of the two major proteins involved in malignant transformation that is consistently transcribed in HPV-positive cervical cancers. HPV E6 and E7 oncoproteins are essential factors for HPV oncogenesis. Inactivation of tumor suppressor p53 and pRb is a common event in the carcinogenesis of human cells. E7- and E6-induced genetic instability leads to the activation of oncogenes and inactivation of tumor suppressor genes. In HPV infection, significant interactions are noted between pRb and p53 proteins, which are important molecules in the cell cycle and apoptosis control. Notably, pRb and p53 proteins are mutated in many human types of cancer. Both E6 and E7 oncogenes interact with pRb and p53, which inhibit the activities of these tumor suppressors. The cell cycle in the S phase normally leads to apoptosis via pRb activity. However, in HPV-infected cells, this process is counteracted by the viral E6 protein, which targets p53 for proteolytic degradation (4). The E7 protein interacts with pRb, an important negative point of entry into the S phase of the cell division cycle. In the hypophosphorylated state, a combination of E7 and pRb activates the E2F transcription factors that trigger the expression of proteins necessary for DNA replication and cell cycle progression. Phosphorylation of pRb by G1 cyclin-dependent kinases releases E2F, leading to cell cycle progression in the S phase. Since E7 is able to bind to unphosphorylated pRb, it may prematurely induce cells to enter the S phase by disrupting pRb-E2F complexes (25). The loss of p53 function is implicated in the pathogenesis of tumors as well as in the prognosis of many neoplasms. The mutant protein accumulates in the nucleus of tumor cells and is identified by immunohistochemical reaction. The frequency of the overexpression of the p53 protein product was reported to be 41–89% in penile squamous cell carcinomas (8,26,27). Our data showed that overexpression of the p53 protein product was detected in 37 (72.5%) of 51 penile cancer cases with and without HPV infection.

The p16^INK4a is a cyclin-dependent kinase inhibitor that prevents the phosphorylation of pRb family members. Normally, the overexpression of p16^INK4a results in the inhibition of E2F-dependent transcription and of cell cycle progression at the G1 to S checkpoint (5). The repression of the p16^INK4a gene expression by hypermethylation or mutation is a common occurrence in cancer. There is a close association between p16^INK4a overexpression and high-risk HPV infection. Therefore, overexpression of p16^INK4a is suggested to be a useful marker for evaluating HPV activity in cancer lesions and its precursors (6,9). The overexpression frequency of p16^INK4a was reported to be 55–97% in cervical squamous cell carcinoma (6–8) and 48–80% in cervical adenocarcinoma (28,29). The overexpression frequency of p16^INK4a was previously reported to be 29–50% in penile squamous cell carcinoma (9,10). Klaes and co-workers reported that p16^INK4a is a specific biomarker used to identify dysplastic cervical epithelia in sections of cervical biopsy samples or cervical smears (7). As shown in Table I, overexpression of the p16^INK4a protein product was observed in 24 (61.5%) of 39 HPV-positive cases, and in 3 (25.0%) of 12 HPV-negative cases. Therefore, overexpression of p16^INK4a was higher in HPV-positive vs. HPV-negative cases. Moreover, overexpression of p16^INK4a was found to have a higher prevalence in cervical vs. penile cancer (30,31). In our data, no significant association of a p16^INK4a (Fig. 1C) and p53 (Fig. 1D) abnormality with HPV-DNA was noted in the penile cancer.

Two pathways are identified in NF-κB signaling. One depends on NEMO, IKKβ activation, nuclear localization of RelA/p50 dimers, and is associated with inflammation. The other depends on IKKα activation probably via the upstream kinase NIK and nuclear localization of p52/RelB dimers. The two pathways involved in the activation of NF-κB are implicated in oncogenesis (32). Activation of NF-κB was observed in many types of cancer, including melanoma, lung cancer, colon cancer, multiple myeloma, pancreatic cancer, esophageal adenocarcinoma, leukemia and lymphoma. Increased NF-κB activity is associated with viral infections. NF-κB activity is modulated for many different viruses, such as HIV-1, HTLV-1, EBV, HBV, adenovirus and HPV (33–38). NF-κB-dependent proliferation and protection from apoptosis are likely to have significant effects on the oncogenesis of HPV associated with cancers. As shown in Table I and Fig. 1E and F, NF-κB was detected in the HPV-positive (94.9%) and HPV-negative cases (33.3%) in the nucleus and/or cytoplasm, respectively. HPV E6- and E7-positive cells have shown IL-1b-induced NF-κB activation and elevated levels of NF-κB components (35). E6 as opposed to E7 expression was found to be associated with the nuclear location of these components. It is frequently reported that HPV-encoded E6 and E7 oncoproteins are important regulatory proteins in host cells, which are associated with the transcriptional activity of NF-κB (33). A fraction of the E7 protein is found in association with the IκB kinase complex and attenuates the induced kinase activity of IκB kinase α (IKKα) and IKKβ, resulting in impaired IκBα phosphorylation and degradation. While E7 obviates IKK activation in the cytoplasm, the E6 protein reduces NF-κB p65-dependent transcriptional activity within the nucleus. It is suggested that the HPV oncogene-mediated suppression of NF-κB activity contributes to HPV escaping from the immune system (34).