An antibody that blocks EBV in two types of human cells
AMMO1 was discovered using techniques first developed to search for antibodies against HIV, a disease unique it its ability to elude antibody defenses through rapid mutation of its surface proteins, the typical targets of antibodies.
Since his lab was able to isolate AMMO1, McGuire has been testing it in laboratory mice that were genetically engineered to carry human B cells. In the most recent experiment, AMMO1 protected 100% of the mice from a challenge of a high dose of EBV. The same antibody was also cross-reactive: It was effective against a similar virus that attacks another animal species.
Previous attempts to develop an EBV vaccine for humans have focused on a target on the surface the virus called gp350, which it uses to lock onto the surface of B cells. However, there is no similar target on the surface of epithelial cells, which could explain why gp350 vaccines were not effective.
AMMO1, on the other hand, appears to protect against EBV in both B cells and epithelial cells. This may be because it blocks a different protein that the virus may need to break into either cell type. Known as the gH/gL complex, this versatile molecular gadget, part of the break-in toolkit of Epstein-Barr virus, could turn out to be its weakness.
With these results in hand, McGuire and his team are continuing to work toward development of a vaccine that could teach the body’s B cells to make AMMO1 whenever a vaccinated person is exposed to the virus. Years of research lie ahead, and history shows that what looks promising in preclinical work may never make it into human arms.
Yet a great deal hangs on the success of such efforts. Given the broad range of lethal mischief EBV wreaks on humanity, an injection that blocks this virus would take a place among immunizations against hepatitis B and human papillomavirus as the first truly effective anticancer vaccines.