Effects of epitopes combination and adjuvants on immune responses to anti-Alzheimer disease DNA vaccines in mice.

Alzheimer disease (AD) is a neurodegenerative disorder characterized by neuropathological hallmarks including deposits of the beta-amyloid peptide (AssP). Studies have shown that immunization with Abeta42 peptide reduces both the spatial memory impairments and Alzheimer disease-like neuropathologic changes in Alzheimer disease transgenic mice, but can cause side effect of a cell-mediated autoimmune meningoencephalitis. Recently, some studies showed that DNA vaccination could be used to generate an antibody response to Abeta without the adverse cell-mediated immune effect. In the current study, we generate four DNA vaccine plasmids (pV-GE1, pV-GE2, pV-GE3, and pV-GE4) against Alzheimer disease by separately fusing Abeta epitope sequences (coding for EFGH, DAEFGH, EFGH+EFGH, and EFGH+DAEFGH) with IgG heavy chain coding region of mouse. Meanwhile, the full-length gene Abeta encoding plasmid (pV-Abeta), empty vector (pVAX) and synthetic AssP were also included as control. The sera of BALB/c mice immunized via intramuscular with plasmids and peptide were tested by indirect ELISA for auto-AssP immunoreactivity. The results showed that all the DNA vaccine plasmids induced AssP-specific antibodies; moreover pV-GE2 and pV-Abeta constructs elicited higher antibody titers than other constructs (P < 0.05). To further enhance the immune response, GM-CSF encoding plasmid (pGM-CSF) and purified BCG-DNA were used as molecular adjuvants. BCG-DNA could enhance humoral and cellular immune responses simultaneously and did not alter the phenotype of the immune responses, whereas pGM-CSF showed no obvious effect on immune response. These results suggest that this immunization strategy of using Abeta epitope encoding plasmid plus BCG-DNA adjuvant may serve as the basis for developing anti-Alzheimer disease vaccines.

[Progress on genetic susceptibility to ankylosing spondylitis].

Ankylosing spondylitis (AS) is a highly heritable, common inflammatory rheumatic disease. Since 1970s, evidence has increasingly pointed to HLA-B27 as the major gene involved in susceptibility to AS. However, genome-wide scan and association studies have shown, in addition to HLA, regions outside the HLA are involved in susceptibility to AS. Furthermore, there is compelling evidence that non-B27 genes, either within or outside the HLA, are involved in disease aetiology. This review mainly summarized different genes associated with AS, and the current progress in this exciting area.

Protection of tree shrews by pVAX-PS DNA vaccine against HBV infection.

The immunological protection of pVAX-PS, a DNA vaccine, was assessed in the tree shrews model. pVAX-PS was constructed by inserting the gene encoding the middle (pre-S2 plus S) envelope protein of HBV into a plasmid vector pVAX1. Tree shrews (Tupaia belangeri chinenesis) were experimentally infected with human HBV by inoculation with human serum positive for HBV markers. DNA vaccination-induced seroconversion and antibody to HBV surface antigen (anti-HBs) were analyzed by ELISA, and protective effects elicited by pVAX-PS vaccination against subsequent HBV challenge were evaluated by detection of HBV seromarkers and observation of hepatic lesions in HBV-infected tree shrews. The results shown that anti-HBs were detectable in serum at week 2 after pVAX-PS vaccination and peaked at week 4, and immunization with pVAX-PS decreased the positive conversion rate of HBV seromarkers and relieved hepatic lesions in tree shrews challenged with HBV. These results indicated that pVAX-PS immunization could induce remarkable humoral immune response and prevent the experimental tree shrews from infection of HBV.