Prevalence of antibodies against virus-like particles of Epidermodysplasia verruciformis-associated HPV8 in patients at risk of skin cancer.

There is increasing evidence for widespread occurrences of infection with Epidermodysplasia verruciformis-related human papillomaviruses, both in the general population and in immunosuppressed patients. In order to test for the prevalence of antibodies directed against the native L1 epitopes exposed on the surface of the virions, we have established an IgG-specific enzyme-linked immunosorbent assay with L1 virus-like particles of the Epidermodysplasia verruciformis-specific human papillomavirus 8 as antigen to screen 567 representative serum samples from the general population and immunosuppressed/dermatologic patients. Among healthy European donors (n = 210), 7.6% were found to be seropositive. In a group of renal transplant recipients (n = 185) the antibody prevalence was elevated to 21.1%, irrespective of the presence or absence of skin cancer. High positivity rates could be detected among (i) immunocompetent patients with nonmelanoma skin tumors (45.6%, n = 79) and (ii) Psoralene/UVA treated psoriasis patients (42.9%, n = 42). In contrast, anti-human papillomavirus 8-virus-like particle antibodies were found in only 6.8% of Hodgkin lymphoma patients (n = 44).

Multiplicity of uses of monoclonal antibodies that define papillomavirus linear immunodominant epitopes.

During the last 10 yr, we have derived monoclonal antibodies from animals immunized with denatured bovine papillomaviruses type 1 major capsid (L1) protein, mapped their corresponding immunodominant epitopes to within a single amino acid (aa), and compared the reactivity of authentic L1 proteins to the predicted response by collinear analysis of the aa sequences of the same and other papillomaviruses (PVs). The data obtained from this approach has provided us with new insights into the sensitivity and specificity of the antibody response to viral proteins. We have included here some observations and conclusions that appear to be generic for the immune response, some of which might have applications for working with linear epitopes in other experimental systems.

Identification of conformational epitopes of the BPV-1 capsid recognized by competitive inhibition of sera from infected or immunized animals.

Conformational papillomavirus (PV) capsid epitopes are the major targets of neutralizing antibodies. BPV1 virion surface epitopes were analyzed for type-specificity, induction of neutralization, and topographical location with antibodies from selected humans, and BPV1 or -2 immunized or infected cattle, rabbits and mice. Rabbit sera produced against deer PV (DPV) or BPV2 and human sera reacted with intact BPV1 in ELISA, indicating the presence of cross-reactive conformational epitopes on the surface of BPV1 virions. However, competitive binding assays performed on intact BPV1 capsids using unlabeled and biotin-conjugated antibodies revealed that the conformational epitopes of BPV1 recognized by rabbit, bovine and human antibodies were topographically different. Only hyperimmune sera to intact BPV1, BPV2 or DPV neutralized BPV1-induced focus formation of C127 cells with the highest neutralizing titers observed for bovine and rabbit antibodies produced against intact BPV1. Our study showed the complexity of conformational capsid epitopes of BPV1 and their importance for inducing a protective humoral immune response in animals inoculated or immunized with BPV1.

Antigenicity of bovine papillomavirus type 1 (BPV-1) L1 virus-like particles compared with that of intact BPV-1 virions.

Virus-like-particles (VLPs) of various papillomavirus (PV) types have been produced by expressing recombinant L1 proteins in eukaryotic cells. Although VLPs have the same ultrastructural appearance as native virions and their immunogenicity appears to be similar, their antigenicity has not been carefully evaluated. For this reason, the antigenicity of intact bovine PV type 1 (BPV-1) virions was compared with that of BPV-1 recombinant L1 VLPs by ELISA using a well-characterized panel of polyclonal and monoclonal antibodies generated against intact and denatured BPV-1 particles. The structural integrity of the authentic virions and recombinant VLPs was verified by electron microscopy. The specificity of antibodies raised against intact BPV-1 virions and their reactivity with VLPs revealed that the immunodominant, type-specific, conformational epitopes of intact virions were reproduced on VLPs. However, many monoclonal antibodies that define cross-reactive, non-conformational (linear) epitopes cryptic to the authentic BPV-1 virion tested positively when reacted with intact VLPs. One monoclonal antibody, which recognizes a BPV-1 and deer PV surface conformational epitope, did not react with VLPs. Therefore, although VLPs can be used to immunize animals against infection, the external exposure of broadly cross-reactive epitopes of intact L1 VLPs suggests that the use of L1 VLPs in antigenicity studies such as serological screening should be done with caution.

HPV-1 L1 protein expressed in cos cells displays conformational epitopes found on intact virions.

Seven polyclonal and monoclonal antibodies were characterized for their ability to react specifically with either conformational or nonconformational epitopes of the HPV-1 virion. Using these antibodies, it was shown that the HPV-1 L1 protein (when expressed by an SV40 vector in cos cells) displayed conformational epitopes characteristic of intact viral particles. In addition, the L1 capsid protein was translocated normally into cell nuclei, was of appropriate size (57 kDa), and could be isolated in native form by immunoprecipitation techniques. Most importantly, the screening of expressed papillomavirus capsid proteins for reactivity with conformation-dependent antibodies represents a new, general methodology for ensuring that such proteins will be suitable for use in vaccine development or in the serologic detection/typing of human papillomavirus infections.

Prospects for human papillomavirus vaccine development: emerging HPV vaccines.

This review concentrates on recent advances in human papillomavirus vaccine development. Strategies for prophylactic HPV subunit vaccines utilizing recombinantly synthesized, immunogenic virus-like particles are discussed. Therapeutic strategies focusing on the induction of cell-mediated immunity and gene manipulation for the treatment of established HPV-associated disease are also reviewed.

Mutant canine oral papillomavirus L1 capsid proteins which form virus-like particles but lack native conformational epitopes.

Recently, the L1 capsid protein of canine oral papillomavirus (COPV) has been used as an effective systemic vaccine that prevents viral infections of the oral mucosa. The efficacy of this vaccine is critically dependent upon native L1 conformation and, when purified from Sf9 insect cells, the L1 protein not only displays type-specific, conformation-dependent epitopes but it also assembles spontaneously into virus-like particles (VLPs). To determine whether VLP formation was coupled to the expression of conformation-dependent epitopes, we generated a series of N- and C-terminal L1 deletion mutants and evaluated their ability to form VLPs (by electron microscopy) and to react with conformation-dependent antibodies (by immunofluorescence microscopy). We found that (a) deletion of the 26 C-terminal residues generated a mutant protein which formed VLPs efficiently and folded correctly both in the cytoplasm and in the nucleus; (b) further truncation of the L1 C terminus (67 amino acids) resulted in a capsid protein which formed VLPs but which failed to express conformational epitopes; (c) deletion of the first 25 N-terminal amino acids also abolished expression of conformational epitopes (without altering VLP formation) but the native conformation of this deletion mutant could be restored by the addition of the human papillomavirus type 11 N terminus. These results demonstrate that VLP formation and conformational epitope expression can be dissociated and that the L1 N terminus has a critical role in protein folding. In addition, it appears that correct L1 protein folding is not dependent upon the nucleoplasmic environment.

The pathogenesis of advanced cervical cancer provides the basis for an empirical therapeutic vaccine.

The pathogenesis of carcinogenic human papillomavirus (HPV) infections of the cervix includes early induction of peripheral tolerance of tissue-infiltrating lymphocytes and an imbalanced Th2 response to HPV early virus proteins. As lesions become progressively dysplastic, major histocompatibility complex (MHC)-1 molecules are down-regulated on the surface of abnormal keratinocytes. When the target of MHC-1 class-restricted cytotoxic lymphocytes disappears, immune deviation to a Th2 response becomes more dominant. After severely dysplastic lesions become invasive, cervical cancer cells die and release HPV E6 and E7 oncoproteins that react with anti-E6 and anti-E7 antibodies to form insoluble immune complexes in antibody excess under the continuing influence of immune deviation. On the basis of this knowledge of the pathogenesis of advanced cervical cancer, we believe that successful immunotherapeutic treatments of these patients will use a vaccine formulation that will break peripheral tolerance in association with biological response modifiers that will enable the patient's immune system to switch classes from Th2 to Th1 while up-regulating MHC-1 molecules on cancer cells. Like prophylactic vaccines against HPV, successful therapeutic vaccine against cervical cancer may have to be universal rather than individualized to be efficacious.

A formalin-inactivated vaccine protects against mucosal papillomavirus infection: a canine model.

A formalin-inactivated canine oral papilloma homogenate was used as a vaccine to prevent infection by the oncogenic, mucosotropic canine oral papillomavirus (COPV) in beagle dogs. Twenty-six dogs received 2 doses of phosphate-buffered saline intradermally and 99 dogs received 2 doses of the inactivated vaccine. One month after the second dose all dogs were challenged with infectious COPV by scarification of the oral mucosa. All of the control dogs developed papillomas by 6-8 weeks after challenge while none of the vaccinated dogs did. This vaccine has been used successfully in approximately 60,000 line bred beagles with no untoward effects and with long-lasting protection. These data demonstrate that a systemically administered, formalin-inactivated vaccine can protect against mucosal infection by COPV and suggest approaches for the development of human papillomavirus vaccines.

The expressed L1 proteins of HPV-1, HPV-6, and HPV-11 display type-specific epitopes with native conformation and reactivity with neutralizing and nonneutralizing antibodies.

Previous studies demonstrated that the human papillomavirus (HPV) type 1 L1 protein, expressed in cos cells by an SV40-based vector, displays conformational epitopes characteristic of native virions. In this study, we analyzed the expression of HPV-1, HPV-6, and HPV-11 L1 proteins in order to determine the forms of conformational epitopes expressed by recombinant L1 proteins. Using both immunofluorescence and immunoprecipitation techniques, polyclonal and monoclonal antibodies (MAbs) generated against native HPV-11 virions reacted with expressed L1 proteins of HPV-6 and/or HPV-11, but not HPV-1. Similarly, polyclonal antibodies and MAbs generated against HPV-1 virions reacted with the expressed L1 protein of HPV-1, but not HPV-6 or HPV-11. Of two MAbs that neutralized HPV-11 infection of murine fetal foreskin xenografts, one reacted with the expressed L1 protein of both HPV-6 and HPV-11, and the other reacted with HPV-11 only. A nonneutralizing conformationally dependent MAb reacted with the expressed L1 protein of both HPV-6 and HPV-11. These results demonstrate that expressed HPV L1 proteins retain type-specific, neutralizing, and nonneutralizing conformational epitopes and that cos cells may be utilized to evaluate host immune responses to such epitopes.

Human papillomavirus types 6 and 11 have antigenically distinct strongly immunogenic conformationally dependent neutralizing epitopes.

Antibodies reactive to HPV types 6 and 11 were tested in ELISA and HPV-11 neutralization assays to determine whether these closely related types shared cross-reactive neutralizing epitopes. A series of HPV-11 neutralizing monoclonal antibodies (N-MAbs) that targeted conformational epitopes on infectious HPV-11 and HPV-11 L1 virus-like particles (VLPs) were tested for type-specificity of reactivity using intact HPV-6 L1 VLPs. Polyclonal antisera generated against intact HPV-6 L1 VLPs were also tested for HPV-11 neutralizing capacity using the athymic mouse xenograft system. The results demonstrated that conformationally dependent neutralizing epitopes on HPV-11 were very type-specific. Three of the four HPV-11 N-MAbs were negative for binding to HPV-6 L1 VLP, and the fourth demonstrated binding to HPV-6 L1 VLPs that was several orders of magnitude weaker than its binding to HPV-11 L1 VLP. The polyclonal anti-HPV-6 L1 VLP antiserum was only partially protective against HPV-11 infectivity even at a low dilution of 1:100. In contrast, polyclonal anti-HPV-11 L1 VLP antiserum was completely protective at dilutions greater than 1:10,000.

Role of conformational epitopes expressed by human papillomavirus major capsid proteins in the serologic detection of infection and prophylactic vaccination.

Human papillomaviruses (HPVs) cause a variety of cutaneous warts, mucosal condylomata, and dysplasias and are etiologic in cervical cancer. Papillomavirus (PV) conformational epitopes on the surface of virions are type-specific and are the target of neutralizing antibodies. In this study, we describe two methods of in vitro expression of HPV major capsid (L1) proteins which mimicked conformational epitopes and demonstrate their type specificity and ability to react with neutralizing and/or conformation-dependent antibodies. The L1 open reading frames (ORFs) for HPV-1, 6, 11, and 16 were molecularly cloned into a SV 40 expression vector and the encoded gene products were expressed in mammalian (cos) cells. Similarly, the L1 ORFs for HPV-6, 11, 16, and 18 were molecularly cloned into recombinant baculovirus and the encoded gene products were expressed in insect (SF9) cells. The expressed L1 proteins reacted by immunofluorescence and immunoprecipitation with polyclonal and monoclonal antibodies generated against their corresponding native virions and by Western blotting with antibodies that recognized nonconformational epitopes of denatured virions. The recombinant L1 proteins expressed conformational epitopes in both cos and Sf9 cells that were type-specific and displayed neutralizing epitopes. The ability to express, purify, and qualitate the reactivity of recombinant L1 proteins will now permit the serologic analysis of host response to HPV infection and the development of prophylactic PV subunit vaccines.

Systemic immunization with papillomavirus L1 protein completely prevents the development of viral mucosal papillomas.

Infection of mucosal epithelium by papillomaviruses is responsible for the induction of genital and oral warts and plays a critical role in the development of human cervical and oropharyngeal cancer. We have employed a canine model to develop a systemic vaccine that completely protects against experimentally induced oral mucosal papillomas. The major capsid protein, L1, of canine oral papillomavirus (COPV) was expressed in Sf9 insect cells in native conformation. L1 protein, which self-assembled into virus-like particles, was purified on CsCl gradients and injected intradermally into the foot pad of beagles. Vaccinated animals developed circulating antibodies against COPV and became completely resistant to experimental challenge with COPV. Successful immunization was strictly dependent upon native L1 protein conformation and L1 type. Partial protection was achieved with as little as 0.125 ng of L1 protein, and adjuvants appeared useful for prolonging the host immune response. Serum immunoglobulins passively transferred from COPV L1-immunized beagles to naive beagles conferred protection from experimental infection with COPV. Our results indicate the feasibility of developing a human vaccine to prevent mucosal papillomas, which can progress to malignancy.

Characterization of a major neutralizing epitope on human papillomavirus type 16 L1.

Persistent infection with human papillomavirus type 16 (HPV-16) is strongly associated with the development of cervical cancer. Neutralizing epitopes present on the major coat protein, L1, have not been well characterized, although three neutralizing monoclonal antibodies (MAbs) had been identified by using HPV-16 pseudovirions (R. B. Roden et al., J. Virol. 71:6247-6252, 1997). Here, two of these MAbs (H16.V5 and H16.E70) were demonstrated to neutralize authentic HPV-16 in vitro, while the third (H16.U4) did not. Binding studies were conducted with the three MAbs and virus-like particles (VLPs) composed of the reference L1 sequence (114K) and three variant L1 sequences: Rochester-1k (derived from viral stock DNA), GU-1 (derived from cervical biopsy DNA), and GU-2 (derived from biopsy DNA, but containing some sequence changes likely to be artifactual). While all three MAbs bound to 114K and Rochester-1k VLPs, GU-1 VLPs were not recognized by H16.E70, and both H16.E70 and H16.V5 failed to bind to GU-2 VLPs. Site-directed mutagenesis was used to replace disparate amino acids in the GU-2 L1 with those found in the 114K L1. Alteration of the amino acid at position 50, from L to F, completely restored H16.V5 binding and partially restored H16.E70 binding, while complete restoration of H16.E70 binding occurred with GU-2 VLPs containing both L50F and T266A alterations. Immunization of mice with L1 variant VLPs revealed that GU-2 VLPs were poorly immunogenic. The L50F mutant of GU-2 L1, in which the H16.V5 epitope was restored, elicited HPV-16 antibody responses comparable to those obtained with 114K VLPs. These results demonstrate the importance of the H16.V5 epitope in the generation of potent HPV-16 neutralizing antibody responses.