, Swiftwater, PA, USA) [74]. Safety and immune response non-inferiority has been demonstrated for co-administration of Cervarix® and Boostrix®-IPV (diphtheria, tetanus, acellular pertusis, inactivated polio; GlaxoSmithKline Biologicals, Rixensart, Belgium) [75]. These encouraging results might eventually lead to co-formulation of HPV and
other vaccines, particularly with hepatitis B where vaccination schedules and adjuvants appear most compatible. Several second-generation HPV prophylactic vaccines are under development with the goal of addressing PD0332991 order some of the inherent limitations of the current vaccines. The approach that is by far the most advanced is to simply increase the valency of an L1 VLP vaccine to address the issue of type-restricted protection. Merck appears to be well advanced in a Phase III efficacy trial of a nonavalent vaccine, which, in addition to the four types in Gardasil®, contains L1 VLPs of types 31, 33, 45, 52 and 58 [76]. Even if the vaccine is entirely type-specific, Selleckchem Trametinib it would have the potential
to prevent approximately 85% of cervical cancer-associated HPV infections [6]. Vaccines based on L1-pentameric subunits produced in E. coli have been generated to address the cost of production in eukaryotic cells [77]. These capsomere-based vaccines have demonstrated protection from experimental challenge in animal models [78]. Phase I clinical trials of a capsomere-based vaccine are anticipated in the near future [76]. Alternatives for lowering the cost of manufacturing being investigated include the generation of the L1 VLPs in alternative yeast production systems, such as Pichia pastoris [79], or in plants [80]. Live recombinant viral and bacterial vectors, such a measles [81], adeno-associated virus [82] and Salmonella typhi [83], expressing L1 have also generated promising results in preclinical of studies. Vaccines based on the minor virion protein, L2, have generated increasing interest in recent years (reviewed
in [84]). L2 contains some remarkably broad cross-type neutralizing epitopes. These epitopes are able to induce antibodies that prevent infection by genital and cutaneous HPV types both in cultured cells and animal models. Simple L2 polypeptides generated in E. coli or synthetically can elicit these broadly cross-neutralizing antibodies, raising the possibility of an inexpensive monovalent vaccine with the potential to be broadly protective. However, neutralizing antibody titers to L2-based immunogens are invariably lower than homologous type neutralizing titers elicited by VLP-based immunogens. There have been a number of strategies employed to increase L2-induced neutralizing titers, including virus-like display approaches and fusion to immunogenic peptides. Whether the responses will be sufficient to induce long-term type specific and cross-type protection remains to be determined.