In a lentiviral vector delivery system, HSV-1 glycoprotein B expressed in feline immunodeficiency virus vector showed cross-protection against both HSV-1
and HSV-2 vaginal challenge in mice [107]. A plasmid based vaccine which includes gD2, UL46 and UL47 formulated with a novel cationic lipid-based adjuvant was effective as a prophylactic and therapeutic vaccine in guinea pigs [108]. Novel routes of delivery are also being evaluated. With increasing evidence for importance of TRM T-cells, there is growing interest in stimulation of genital mucosal immunity through mucosal delivery methods. For instance, intranasal delivery of gB1 packaged in non-ionic surfactant vesicles protected mice from see more HSV-2 vaginal challenge [109]. Mucosal immunization with gD2 adjuvanted with IC31 [45] or given in a DNA prime followed by a protein boost delivered through liposomal encapsulation [110], both of which stimulate a Th1 response, protected mice from HSV-2 vaginal challenge. Combining the DNA approach with trans-dermal microneedle delivery was found to have a dose-sparing effect
www.selleckchem.com/products/MLN-2238.html in mice; localization of the effector cells is undefined [111]. The “prime-pull” approach in which mice were immunized followed by application of chemokine to genital area is another novel approach that will require further study [39]. There are two ongoing Phase I/II trials of therapeutic vaccines which use novel antigens and adjuvants. One vaccine design consists of 32 35-mer HSV-2 peptides directed against 22 HSV-2 proteins complexed with human heat shock protein 70 and saponin adjuvant. This vaccine increased detection of HSV-2 specific CD4+ and CD8+ T-cell responses in HSV-2 seropositive
persons and was safe in a Phase I trial [112], and is being tested in a Phase II trial for prevention of shedding and lesions (NCT01687595). A subunit vaccine containing secreted gD2, and truncated ICP4, which was identified as a CD8+ others T-cell antigen through a high-throughput proteomic screening method, formulated with an adjuvant to stimulate humoral and cellular immunity, showed efficacy against infection and recurrent disease in the guinea pig model [66], and is being tested in a Phase I/II trial as a therapeutic vaccine (NCT01667341). The field of HSV vaccines is rapidly evolving. Although the results of the prophylactic glycoprotein D2 vaccine were disappointing, the field has been reenergized by improved understanding of the frequency of viral shedding, the importance of the mucosal immune response, availability of novel adjuvants and delivery mechanisms, identification of T cell epitopes via proteomic screening and advancement in replication competent and replication-incompetent candidates. In addition, we have learned from past vaccine studies; we need to depend on objective evidence of seroconversion rather than the variable phenotype of clinical disease in preventative vaccine studies.