Fetal Lymphoid Progenitors Become Restricted to B-1 Fates Coincident with IL-7Rα Expression.

B-1 cells represent a sub-fraction of B lymphocytes that participate in T cell-independent antibody production and contribute to innate immunity. While the production of B-1 cells is favored during the fetal waves of lymphopoiesis, it has been unclear when and how that differentiation option is specified. To clarify this, lymphoid and hematopoietic progenitors of fetal liver (FL) and adult bone marrow (ABM) were examined for the B cell differentiation potential. Mouse common lymphoid progenitors (CLPs) and more primitive KSL fraction of FL and ABM were transferred to SCID mice and donor-derived B cell subsets were analyzed 4 weeks later. CLPs were also cultured on ST2 stromal cells for 6 days prior to transplantation. While Lin- IL-7Rα+ CLPs from ABM differentiated to B-1, B-2 and marginal zone B (MZB) cells, equivalent cells from d15 FL differentiated mostly to B-1a cells. We found that fetal CLPs had less ability to colonize the bone marrow than adult CLPs. However, the fetal/adult difference was already present when progenitors were cultured in an identical condition before transplantation. More primitive KSL fraction of FL could generate the same broad spectrum of B cells typical of adults, including splenic MZB cells. In conclusion, we argue that FL and ABM-CLPs are intrinsically different regarding B-1/B-2 fates and the difference is acquired just before or coincident with the acquisition of IL-7Rα expression.

The neutralizing antibody response to the vaccinia virus A28 protein is specifically enhanced by its association with the H2 protein.

The vaccinia virus (VACV) entry-fusion complex (EFC) is composed of at least nine membrane proteins. Immunization of mice with individual EFC genes induced corresponding protein-binding antibody but failed to protect against VACV intranasal challenge and only DNA encoding A28 elicited low neutralizing antibody. Because the A28 and H2 proteins interact, we determined the effect of immunizing with both genes simultaneously. This procedure greatly enhanced the amount of antibody that bound intact virions, neutralized infectivity, and provided partial protection against respiratory challenge. Neither injection of A28 and H2 plasmids at different sites or mixing A28 and H2 sera enhanced neutralizing antibody. The neutralizing antibody could be completely removed by binding to the A28 protein alone and the epitope was located in the C-terminal segment. These data suggest that the interaction of H2 with A28 stabilizes the immunogenic form of A28, mimicking an exposed region of the entry-fusion complex on infectious virions.

Co-administration of viral vector-based vaccines suppresses antigen-specific effector CD8 T cells.

In this study, we explored immune responses after intramuscular co-administration of the HIV-1 gp160 Env gene-expressing adenovirus (Ad) vector and modified vaccinia virus Ankara (MVA) vector in a mouse model. Surprisingly, the simultaneous vaccination of the two vaccines, either as a mixture or separately, suppressed responses, when compared with the administration of each vaccine separately. Ad vaccine or MVA vaccine, co-administered with a mock MVA or mock Ad vector, also resulted in suppressing HIV-specific effector T-cell responses, and a part of antigen-specific memory T-cell responses. In an in vitro experiment, the two vectors infected individual cells and MVA suppressed the transgene expression produced by the adenovirus vector. This viral interference may involve soluble factor(s), secreted by virus-infected cells. Our study may help in designing a vaccination regimen and in investigating viral interference.

Engineering the vaccinia virus L1 protein for increased neutralizing antibody response after DNA immunization.

BACKGROUND: The licensed smallpox vaccine, comprised of infectious vaccinia virus, has associated adverse effects, particularly for immunocompromised individuals. Therefore, safer DNA and protein vaccines are being investigated. The L1 protein, a component of the mature virion membrane that is conserved in all sequenced poxviruses, is required for vaccinia virus entry into host cells and is a target for neutralizing antibody. When expressed by vaccinia virus, the unglycosylated, myristoylated L1 protein attaches to the viral membrane via a C-terminal transmembrane anchor without traversing the secretory pathway. The purpose of the present study was to investigate modifications of the gene expressing the L1 protein that would increase immunogenicity in mice when delivered by a gene gun. RESULTS: The L1 gene was codon modified for optimal expression in mammalian cells and potential N-glycosylation sites removed. Addition of a signal sequence to the N-terminus of L1 increased cell surface expression as shown by confocal microscopy and flow cytometry of transfected cells. Removal of the transmembrane domain led to secretion of L1 into the medium. Induction of binding and neutralizing antibodies in mice was enhanced by gene gun delivery of L1 containing the signal sequence with or without the transmembrane domain. Each L1 construct partially protected mice against weight loss caused by intranasal administration of vaccinia virus. CONCLUSION: Modifications of the vaccinia virus L1 gene including codon optimization and addition of a signal sequence with or without deletion of the transmembrane domain can enhance the neutralizing antibody response of a DNA vaccine.

Induction of robust immune responses against human immunodeficiency virus is supported by the inherent tropism of adeno-associated virus type 5 for dendritic cells.

The ability of adeno-associated virus serotype 1 to 8 (AAV1 to AAV8) vectors expressing the human immunodeficiency virus type 1 (HIV-1) Env gp160 (AAV-HIV) to induce an immune response was evaluated in BALB/c mice. The AAV5 vector showed a higher tropism for both mouse and human dendritic cells (DCs) than did the AAV2 vector, whereas other AAV serotype vectors transduced DCs only poorly. AAV1, AAV5, AAV7, and AAV8 were more highly expressed in muscle cells than AAV2. An immunogenicity study of AAV serotypes indicates that AAV1, AAV5, AAV7, and AAV8 vectors expressing the Env gp160 gene induced higher HIV-specific humoral and cell-mediated immune responses than the AAV2 vector did, with the AAV5 vector producing the best responses. Furthermore, mice injected with DCs that had been transduced ex vivo with an AAV5 vector expressing the gp160 gene elicited higher HIV-specific cell-mediated immune responses than did DCs transduced with AAV1 and AAV2 vectors. We also found that AAV vectors produced by HEK293 cells and insect cells elicit similar levels of antigen-specific immune responses. These results demonstrate that the immunogenicity of AAV vectors depends on their tropism for both antigen-presenting cells (such as DCs) and non-antigen-presenting cells (such as muscular cells) and that AAV5 is a better vector than other AAV serotypes. These results may aid in the development of AAV-based vaccine and gene therapy.

Robust HIV-specific immune responses were induced by DNA vaccine prime followed by attenuated recombinant vaccinia virus (LC16m8 strain) boost.

Recombinant vaccinia virus-based vaccine combined with DNA vaccine has produced a protective immune response against HIV infection in non-human primates. In this study, we explored the immunogenicity of a recombinant vaccinia virus (LC16m8 strain), which has been used in children without severe side effects. The vaccinia virus expressing an HIV(89.6)env gene (vLC-Env) alone or combined with a DNA vaccine expressing the HIV(89.6)env gene (pCAG-Env) was characterized in BALB/c mice. Vaccination of vLC-Env induced much higher HIV-specific humoral and cell-mediated immune responses than that of pCAG-Env. Priming with pCAG-Env further enhanced vLC-Env induced immune responses, especially cell-mediated immune response. Moreover, efficient expression of Env protein was achieved following infection of bone marrow dendritic cells by vLC-Env in vitro. Administration of vLC-Env-infected dendritic cells to mice generated a high cell-mediated immune response. These results demonstrate that priming with pCAG-Env and boosting with vLC-Env represents a logical candidate for vaccination against HIV infection.

A modified HIV challenge assay in mice by using luciferase-expressing vaccinia virus.

In this study, we developed a simple and sensitive assay in mice for a challenge experiment by using a recombinant vaccinia virus dual-expressing antigen (HIV Env gp160) and firefly luciferase. This assay can detect the vaccine effect at real-time in vivo by using a small amount of mouse serum. The luciferase activity in mouse serum was in agreement with the viral titer in the ovary. This assay would be applicable as a challenge model for infectious diseases.

Polygene DNA vaccine induces a high level of protective effect against HIV-vaccinia virus challenge in mice.

Single HIV-1 subtype DNA vaccine is unlikely to provide reactive protection across a wide range of HIV strains since the HIV virus changes the antigenic sites, particularly, in env gene. To overcome these issues, we constructed a multivalent poly-epitope DNA vaccine. A polygenic DNA vaccine encoding 20 antigenic epitopes from the HIV-1 Env, Gag, and Pol proteins of several clades was constructed using humanized and optimized codons and it was named here hDNA vaccine. In mice, this hDNA vaccine stimulated the following strong (1) antigen-specific serum antibody (Ab) responses, (2) delayed-type hypersensitivity, (3) the activation of IFN-gamma secretion cells targeting gp120 and synthetic antigenic peptides, in addition (4) a significant level of several peptide specific cytotoxic T lymphocytes (CTL) responses. Challenged with modified vaccinia viruses vPE16 and vP1206 expressing HIV-1 env and gag.pol genes, respectively, demonstrated the viral titers in the ovary of the mice vaccinated with hDNA significantly less compared to the unvaccinated mice. Thus, the use of polygene DNA vaccine appears to induce a high level of HIV-specific immune responses and is very effective against challenge with recombinant HIV-vaccinia viruses.

Adjuvant effect of multi-CpG motifs on an HIV-1 DNA vaccine.

Synthetic oligodeoxynucleotides (ODN) containing unmethylated CpG motifs trigger an immune response characterized by the activation of B cells, NK cells and monocytes/macrophages. Based on evidence that the immunogenicity of DNA vaccines can be augmented by the addition of CpG motifs, 5-20 additional CpG motifs were cloned into a pUC-derived plasmid. Treating bone-marrow derived dendritic cells (BM-DCs) with CpG-enriched plasmids in vitro boosted their expressions of MHC class II molecules, the CD40 and CD86 activation markers. Co-administering the CpG-enriched plasmids with a DNA vaccine encoding the envelope glycoprotein of HIV to BALB/c mice significantly increased HIV-specific cell mediated and humoral immunity. A significant boost was observed when the CpG plasmid was administered either 2 or 4 days after DNA vaccination. Plasmids containing 20 CpG copies were the most effective immune enhancers both in vitro and in vivo. These results suggest that plasmids containing multiple CpG motifs may improve the immunogenicity of DNA vaccines.

Detection of Progeny Immune Responses after Intravenous Administration of DNA Vaccine to Pregnant Mice.

A number of factors influence the development of tolerance, including the nature, concentration and mode of antigen presentation to the immune system, as well as the age of the host. The studies were conducted to determine whether immunizing pregnant mice with liposome-encapsulated DNA vaccines had an effect on the immune status of their offspring. Two different plasmids (encoding antigens from HIV-1 and influenza virus) were administered intravenously to pregnant mice. At 9.5 days post conception with cationic liposomes, injected plasmid was present in the tissues of the fetus, consistent with trans-placental transfer. When the offspring of vaccinated dams were immunized with DNA vaccine, they mounted stronger antigen-specific immune responses than controls and were protected against challenge by homologous influenza virus after vaccination. Moreover, such immune responses were strong in the offspring of mothers injected with DNA plasmid 9.5 days after coitus. These results suggest that DNA vaccinated mothers confer the antigen-specific immunity to their progeny. Here we describe the methods in detail as they relate to our previously published work.