Bacteria such as E. coli communicate with each other by releasing what are known as signalling molecules. They also do this whenever they sense other bacteria nearby. VP882 keeps a proverbial eye on the numbers of such molecules being released. If hosts are few and far between, the bacteriophage patiently bides its time, but as soon as it detects enough bacteria in the vicinity, it attacks and injects its genetic material into a bacterium.
This causes the host to produce so many new VP882 phages that it eventually ruptures and dies. Once released, these phages can mount the next wave of attacks on nearby bacteria, continuing until there are none left.
Whereas most phages target just one specific kind of bacterium, VP882 is the exception that proves the rule. VP882 has been shown capable of fighting an array of pathogens, including E. coli, Vibrio cholerae and the bacterium that causes salmonella. Potentially, therefore, VP882 could in future be used to fight a host of bacterial infections. With bacteria becoming increasingly resistant to antibiotics, the search is on for alternative therapies like this.