13 research outputs found
Development and Evaluation of Chitosan-Coated Liposomes for Oral DNA Vaccine: The Improvement of Peyer’s Patch Targeting Using a Polyplex-Loaded Liposomes
The aim of this study was to develop chitosan-coated and polyplex-loaded liposomes (PLLs) containing DNA vaccine for Peyer’s patch targeting. Plain liposomes carrying plasmid pRc/CMV-HBs were prepared by the reverse-phase evaporation method. Chitosan coating was carried out by incubation of the liposomal suspensions with chitosan solution. Main lipid components of liposomes were phosphatidylcholine/cholesterol. Sodium deoxycholate and dicetyl phosphate were used as negative charge inducers. The zeta potentials of plain liposomes were strongly affected by the pH of the medium. Coating with chitosan variably increased the surface charges of the liposomes. To increase the zeta potential and stability of the liposome, chitosan was also used as a DNA condensing agent to form a polyplex. The PLLs were coated with chitosan solution. In vivo study of PLLs was carried out in comparison with chitosan-coated liposomes using plasmid encoding green fluorescence protein as a reporter. A single dose of plasmid equal to 100 μg was intragastrically inoculated into BALB/c mice. The expression of green fluorescence protein (GFP) was detected after 24 h using a confocal laser scanning microscope. The signal of GFP was obtained from positively charged chitosan-coated liposomes but found only at the upper part of duodenum. With chitosan-coated PLL540, the signal of GFP was found throughout the intestine. Chitosan-coated PLL demonstrated a higher potential to deliver the DNA to the distal intestine than the chitosan-coated liposomes due to the increase in permanent positive surface charges and the decreased enzymatic degradation
Crystal Structure of a Cholera Toxin-Related Heat-Labile Enterotoxin from E. coli
Examination of the structure of Escherichia coli heat-labile enterotoxin in the AB5 complex at a resolution of 2.3 angstrom reveals that the doughnut-shaped B pentamer binds the enzymatic A subunit using a hairpin of the A2 fragment, through a highly charged central pore. Putative ganglioside G(M1-) binding sites on the B subunits are more than 20 angstrom removed from the membrane-crossing A1 subunit. This ADP-ribosylating (A1) fragment of the toxin has structural homology with the catalytic region of exotoxin A and hence also to diphtheria toxin
Expression of Cholera Toxin B Subunit in Transgenic Rice Endosperm
The synthetic cholera toxin B subunit (CTB) gene, modified according to
the optimized codon usage of plant genes, was introduced into a plant
expression vector and expressed under the control of the Bx17 HMW (high
molecular weight) wheat endosperm-specific promoter containing an
intron of the rice act1. The recombinant vector was transformed into
rice plants using a biolistic-mediated transformation method. Stable
integration of the synthetic CTB gene into the chromosomal DNA was
confirmed by PCR amplification analysis. A high level of CTB (2.1% of
total soluble protein) was expressed in the endosperm tissue of the
transgenic rice plants. The synthetic CTB produced only in the rice
endosperm demonstrated strong affinity for G(M1)-ganglioside, thereby
suggesting that the CTB subunits formed an active pentamer. The
successful expression of CTB genes in transgenic plants makes it a
powerful tool for the development of a plant-derived edible vaccine