[104] The end product, lactic acid, helps vaginal fluid maintain low pH and prevents the overgrowth of bacteria associated with BV [55]. Studies have also suggested an association between higher estrogen serum levels and reduced
BV prevalence [105]. The other mechanism by which HC, especially progestin, may affect the vaginal microbiota is through its inhibitory effect on uterine bleeding. Menstruation has been positively correlated with low Lactobacillus vaginal microbiota [54] and [75]. Data from cohorts of pregnant women also suggest stability of the microbiota during pregnancy [106]. Parenteral vaccines against mucosal pathogens of the genital tract have been successful, JAK pathway particularly when they induce strong serum IgG levels that cross mucosal epithelia to provide
local protection. The HPV vaccine is the most obvious example [107]. There are only a few examples of mucosal vaccines (oral polio, cholera, and influenza). Several factors have hindered the development of effective mucosal vaccines. Mucosal immune responses are, to a certain extent, compartmentalized. While vaginal, intranasal, and sublingual immunizations have GDC-0199 nmr been found to elicit adequate genital mucosal immune responses – the intranasal route, oral and rectal routes of immunization have been less successful [108]. In rodent models, the combination of parenteral and intranasal routes of immunization
yielded the best outcome when comparing combination approaches. Very few studies have been performed in humans. In one of the few studies conducted in women, vaginal immunization with the B subunit of cholera toxin resulted in higher cervicovaginal antibody responses compared to the oral and rectal immunization Ketanserin routes [109]. In men, parenteral and systemic immunizations resulted in the detection of IgG and IgA antibodies in semen. Intranasal and rectal routes of immunization have not been well explored in men. Another challenge of mucosal vaccination is immunological tolerance [110]. Most mucosal sites tend to exhibit mucosal tolerance via induction of regulatory T-cells (Treg) that dampen immune responses following antigen exposure. To overcome this tendency for tolerance, mucosal vaccines must be potent. Potency may be enhanced by the use of live vaccines, whole cell vaccines that express one or more pathogen-associated molecular pattern (PAMP), and/or the use of adjuvants. The impact of endogenous and exogenous sex hormones on mucosal immune responses must be considered when trying to optimize vaccine responses in the genital tract. The importance of this concept has been clearly demonstrated in animal models. Using a mouse model, the use of depot medroxyprogesterone acetate (DMPA) increased susceptibility to HSV-2 infection >100 fold [111].