1 Department of Pathology and Animal health, Faculty of Veterinary medicine FEDERICO II Naples University, Via F. Delpino, 1 80137 Naples, Italy
2 Regina Elena Cancer Institute, Laboratory of Virology, Via delle Messi d'Oro, 156 00158 Rome, Italy
Correspondence
Giuseppe Borzacchiello
borzacch{at}unina.it
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ABSTRACT |
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MAIN TEXT |
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Bracken fern (genus Pteridium) is believed to be the only higher plant proven to cause cancer naturally in animals (Smith, 1997). The fern contains immunosuppressive, mutagenic, clastogenic and carcinogenic chemicals. Previous studies have pointed out a strong relationship between bovine papillomavirus (BPV) and bracken fern. BPV-2 DNA was found in 69 % of experimental bladder cancers and in 7 of 15 naturally occurring ones. This high degree of association between bladder cancers and BPV-2 suggested that this virus could play a role in bladder oncogenesis (Campo et al., 1992
).
A possible aetiopathogenic mechanism is that BPV-1/2 infect the epithelium of the bladder and produce an abortive or latent infection, as already hypothesized for BPV-4 in gastrointestinal tumours (Borzacchiello et al., 2003; Campo et al., 1994
). The immunosuppressants and chemical carcinogens in bracken act synergistically with the virus to induce the formation of pre-neoplastic lesions. During neoplastic progression, the ras gene is activated (Campo et al., 1990
) and expression of the tumour suppressor fragile histidine tetrads locus is downregulated (Borzacchiello et al., 2001
).
Most previous studies have been performed under experimental conditions and in few cases of naturally occurring bladder cancer; studies on large populations of cows are lacking.
In an attempt to validate the aetiopathogenic role of the association between BPV and bovine bladder cancers, our study was carried out on a large population of cattle from southern Italy, a region in which bracken fern is widespread and CEH is endemic. Samples were analysed for the presence of BPV DNA, E5 protein and telomerase activity. Telomerase is an enzyme that induces immortalization by preventing the progressive loss of telomere length during DNA replication (Bodnar et al., 1998).
Examination of bladders from 4- to 24-year-old cows was performed at public slaughterhouses in the south of Italy. Tumour samples from all animals affected and from a number of healthy cows were collected for both histological and molecular analysis.
PCR amplification of viral sequences using consensus primers was done according to methods described previously (Borzacchiello et al., 2001). These primers allow the amplification of a 307 bp DNA amplicon encompassing the BPV E5 sequence. A fragment corresponding to the expected size was amplified in 46 of 60 samples (77 %), from which DNA of PCR-quality was obtained. To determine the papillomavirus serotype, PCR amplicons were sequenced and proven to correspond to the expected region of BPV-2. An example of this analysis is shown in Fig. 1
. Lower positivity (17 of 34) for BPV-2 sequences was detected in the bladder mucosa of healthy cows as a control. The high incidence of BPV-2 DNA in all samples, both abnormal and normal mucosa, indicates clearly a high circulation of this virus in the areas examined. However, the difference between groups (pathologic versus normal samples) was statistically significant (P<0·01, Fisher's exact test and
2), strongly suggesting an association of BPV-2 with cellular abnormalities of the urinary bladder. There was no association between the presence of viral DNA and a particular histological type of tumour (data not shown), indicating that the different histological features may be related to other factors. Viral DNA was also detected in pre-neoplastic lesions, supporting its role in tumour development. The high incidence of BPV-2 DNA in normal bladder possibly reflects the presence of an abortive or latent infection that may be activated by the immunosuppressive and/or carcinogenic chemicals in bracken fern.
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The absence of E5 staining in tumours that lacked BPV-2 DNA ruled out artefactual results, such as cross-reactivity with cellular proteins.
Interestingly, no normal urinary bladder with BPV DNA sequences showed positivity for E5 protein. These data demonstrate that the viral DNA is transcriptionally active only in abnormal tissue and reinforce the hypothesis that BPV is capable of infecting the urinary mucosa and remaining latent in normal tissue until some factors trigger viral gene expression. It is not known how latent viral DNA is activated but the chemicals of bracken fern are strong candidates. The flavonoid quercetin is present in high concentrations in the fronds of the fern. Quercetin is mutagenic and clastogenic, leading to single-strand DNA breaks (Campo, 1997; Plaumann et al., 1996
) and chromosomal rearrangements (Leal et al., 2003
). It promotes the full in vitro transformation of primary bovine cells infected with BPV-4 DNA (Cairney & Campo, 1995
; Pennie & Campo, 1992
) and upregulates viral DNA transcription via a cis-acting element in the viral transcriptional promoter (Connolly et al., 1998
). The consequent increased expression of the viral oncoproteins forces the cells to proliferate, despite quercetin-induced DNA damage (Beniston et al., 2001
). These findings have led to the suggestion that quercetin is a co-carcinogen of BPV-4 in vivo. However, the actual role of quercetin in bracken-related carcinogenicity is still an open question (Shahin et al., 1999
).
The hypothesis of a role of BPV in the pathogenesis of urinary bladder tumours seems also to be suggested by the analysis of telomerase activity in the urothelial tumour samples. The increased activity of cellular telomerase, a ribonucleoprotein enzyme that synthesizes telomeric DNA, is well documented in various immortalized cell lines. Telomerase activity is also detected in various animal and human cancers, and telomerase activation is thought to be a crucial factor in immortalization of cells and tumourigenesis (Argyle & Nasir, 2003; Kim et al., 1994
).
Recent reports indicate that papillomaviruses may also affect telomerase activity: the E6E7 genes of human papillomavirus type 16 (HPV-16) increase telomerase activity during epithelial cell immortalization (Baege et al., 2002), whereas the E2 gene downregulates the human telomerase reverse transcriptase promoter (Lee et al., 2002
).
Telomerase activity was analysed in bladder samples using a commercial telomerase detection kit (Trapeze, Intergen) that utilizes the telomeric repeat amplification, whose sequence is highly conserved through mammalian species (Moyzis et al., 1988). Briefly, specimens from a subset of tumours and controls, from which protein could be extracted, were lysed in CHAPS buffer, and after protein content normalization, were subjected to PCR amplification according to the manufacturer's instructions. Analysis of each sample consisted of two assays: one with a protein extract and one with an extract that had been heat-treated at 80 °C. Heat treatment inactivates the telomerase and serves as a negative control. Aliquots of the reactions were subjected to electrophoresis on a non-denaturing 10 % polyacrylamide gel. After electrophoresis, the gel was stained with ethidium bromide. A representative assay of positive tumour samples is shown in Fig. 3
.
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The presence of viral DNA, of endocytoplasmic E5 protein and the alteration of telomerase activity only in BPV-associated bladder tumours strongly supports that, in areas of CEH and of bracken fern infestation, more than 70 % of tumours are caused by BPV infection. The virus and chemicals in bracken fern appear to act synergistically in inducing cell transformation and immune escape.
These results open the perspective to start a vaccination programme to eradicate infection. Since E5 seems likely to play a role in urinary bladder carcinogenesis, it would represent a target for immunomediated therapies. Recently, it has been reported that mouse vaccination with HPV-16 E5 reduced the growth of tumours induced by E5-expressing cells (Liu et al., 2000). The potential for E5 vaccination should be validated in naturally occurring animal models and, moreover, the development of therapeutic/preventive immunoprophylaxis for these mucosal tumours would represent a model for human pathologies and could add precious indications for their treatment.
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ACKNOWLEDGEMENTS |
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Received 11 June 2003;
accepted 21 July 2003.