Characterization of the Mucosal and Systemic Immune Responses Following Virus Vector-Based Gene Delivery into the Colonic Mucosa

Abstract

While adenovirus (Ad) vectors have been shown to elicit potent antigen-specific T cell responses, the kinetics and nature of antigen-specific mucosa! and systemic T-cell responses has rarely been examined, especially following mucosal administration of Ad-based vectors. In the present studies, the phenotypic and functional characterization of antigen-specific CD8+ T cell responses following intrarectal (i.r.) vaccination with an Ad vector expressing Gallus gallus ovalbumin (OVA) was conducted. The frequencies of OVA-specific CD8+ T cells was maximal at 2 weeks post-vaccination in all tissues examined and then declined, demonstrating normal expansion and contraction kinetics. CD8+ T cells induced in the course of immunization exhibited phenotypic characteristics of effector memory T cells including up-regulation of the cell surface molecules CD43, CD44 and a low level of expression of CD127 at both local and systemic sites. While the discordance between the number of tetramer-reactive and cytokine-producing OVA-specific CD8+ T cells was observed, CD8+ T cells appeared to be fully functional in vivo. Upon secondary antigen exposure, the CD8+ T cell population expanded dramatically, particularly at the mucosa! surfaces. In addition, the CD8+ T cell response generated in the course of i.r. priming protected mice from intravaginal (i. vag.) vaccinia virus one month after immunization, thus underscoring the importance of inducing a tissue-resident effector memory T cell subset for protection against pathogens at mucosal surfaces. In developing future vaccines for mucosal diseases, the induction of a tissue-resident effector memory T cell subset should be one of the immunization objectives. Lentiviral vectors represent an attractive mode of genetic vaccination. Most commonly used, vesicular stomatitis virus glycoprotein (VSVG)-pseudotyped lentiviral vectors do not efficiently infect epithelial cells from the apical side, and, therefore, are not suitable as mucosa! vaccines. In the present studies, Ebola Zaïre strain glycoprotein (EboZ)-pseudotyped lentiviral vectors, which have been previously used to deliver transgene to the lung epithelium, were delivered i.r. and evaluated as a mucosal booster vaccine. Rectal delivery of EboZ-pseudotyped lentiviral vectors expressing β-galactosidase (β-gal) had resulted in low, but detectable levels of β-gal expression 2 weeks after administration. When delivered on its own, EboZ-pseudotyped lentivirus did not prime detectable antigen-specific immune response. However, when delivered i.r. 30 days after i.r. Adβ-gal immunization, a significant enlargement (boost) of β-gal-specific CD8+ T cell responses, especially in the colonic lamina propria (LP), was observed as compared to the delivery of EboZ-pseudotyped vector encoding different transgenes or VSVG-pseudotyped lentivirus expressing β-gal. When these animals were i. vag. challenged with vaccinia virus expressing β-gal, a dramatic expansion of β-gal-specific CD8+ T cells, especially in the vaginal tract, was observed. In addition, this prime and boost strategy protected the mice from i. vag. vaccinia virus challenge. Therefore, i.r. Ad-based priming followed by i.r. EboZ-pseudotyped lentiviral boosting was an effective strategy for eliciting protective mucosal CD8+ T cell responses.