[Immunization of rats with a targeted fusion anticaries DNA vaccine].

OBJECTIVE: To observe the expression of a targeted fusion anticaries DNA vaccine pGJA-P in situ. To compare the levels of specific antibodies and anticaries efficacy generated by pGJA-P and pGLUA-P, a fusion anticaries DNA vaccine. METHODS: pGJA-P was administrated intramuscularly or intranasally to rats, and the expression of recombinant protein was detected by immunohistochemistry technique. Wistar rats were fed a cariogenic diet and orally infected with S. mutans, then immunized with pGJA-P or pGLUA-P via the intramuscular or intranasal route. All rats received a booster immunization 2 weeks later. At the termination of the experiment, blood and saliva samples were collected for assay of antibodies by ELISA and jaws were obtained for caries evaluation by the Keyes method. RESULTS: Recombinant protein could be detected in muscle in intramuscularly immunized rats and in nasal mucosa in intranasally immunized rats. Rats immunized intramuscularly with pGJA-P had significantly higher serum IgG levels than others (P < 0.01). Rats immunized intranasally or intramuscularly with pGJA-P had significantly higher salivary IgA levels than others (P < 0.01). Keyes scores of pGJA-P groups were significantly lower than those of pGLUA-P groups and pCI groups (P < 0.01). CONCLUSIONS: pGJA-P could be correctly expressed in vivo. pGJA-P generated increased humoral immune response and anticaries efficacy compared with pGLUA-P.

Colicin diversity: a result of eco-evolutionary dynamics.

Colicins are plasmids that are carried in Escherichia coli. They code for a toxic protein and for proteins that confer on the host immunity against this toxin. When bacteria carry plasmids their growth rate is reduced. At the same time, the production of toxins makes it possible for colicinogenic bacteria to invade bacterium strains that are not immune. In natural bacterium populations there is a high diversity of colicin types. The reason for the maintenance of this diversity has been the subject of much recent debate. We have studied a simple eco-evolutionary model of the interaction of bacteria with colicins and show that high diversity of colicins is to be expected. We find two different dynamical modes each with a high diversity: a hyperimmunity mode and a multitoxicity mode. Bacteria are immune to most toxins in the first mode but in fact produce very few toxins. In the second mode bacteria are immune only to those toxins that they actually produce. In the second mode toxin levels per bacterium are much higher, whereas immunity levels per bacterium are lower.