We haven’t feature lyme disease much here, although it’s a highly problematic pathogen that will become more common with a warming climate. The exact same goes for Zika, a much newer danger in the United States. This week in the New York Times, an article by Amy Harmon covers the idea of changing the gene pool in white-footed mice in Nantucket to fight Lyme disease, and a video explains how infecting the Aedes aegypti mosquito may help stop the spread of Zika. Below, the article:

Can genetically engineered mice save Nantucket from the scourge of Lyme disease?

If the 10,000 residents of the Massachusetts island did not have such a soft spot for deer, they might not be entertaining the prospect, which could provide the groundwork for an even more exotic approach to controlling tick-borne diseases on the mainland.

But popular opinion has long opposed public health officials’ recommendation of radically reducing the population of deer that serve as a food source for ticks carrying the Lyme pathogen and a convenient place for adult females to lay their eggs.

“The people who get sick yell and scream at me for not doing anything about it,’’ said Malcolm MacNab, the chairman of the Nantucket Board of Health, “and the others yell and scream at me because I want to kill the deer.” Dr. MacNab said nearly 40 percent of Nantucket residents had had Lyme disease.

So when he heard that Kevin Esvelt, an evolutionary biologist at the Massachusetts Institute of Technology, wanted to gauge the island’s interest in a new approach, he invited the scientist to present it at a public meeting on Monday.

Although deer help spread ticks that carry Lyme, Dr. Esvelt explained to about two dozen residents at the meeting, the disease can also be controlled earlier in the tick’s food chain. Ticks typically contract the pathogen from white-footed mice, which they often feed on while still larvae, passing it on to humans and other mice when they bite again.

Using new genome-engineering tools, he proposes to create mice that are immune to the Lyme-causing pathogen, or to a protein in the tick’s saliva, or both, to break the cycle of transmission.

If that worked — and there is reason to think it would — he would then apply for permission to release thousands of the mice on a smaller, uninhabited island. If the number of infected ticks proved to be sufficiently reduced after two years, Nantucket could be next. The release of a few hundred thousand engineered mice over the course of about a year, Dr. Esvelt said, would ensure a stable population of resistant mice.

There is no company behind the project, which Dr. Esvelt estimated could take as long as a decade to complete. But he said he thought he could get government and philanthropic funding

because it would provide evidence that might justify the use of another technology he has helped to pioneer, called “gene drive,” to attack Lyme disease elsewhere.

In the Northeast and Upper Midwest, the areas of the United States where Lyme is most prevalent, it would not be feasible to release enough engineered mice to spread the genes for Lyme immunity through the native mouse population.

Read the rest of the piece here.