Lund's scientific career took off in 2008, when she was a postdoctoral researcher in the University of Washington lab of Dr. Alexander Rudensky, now chair of the immunology program at New York’s Sloan Kettering Institute. Lund set out to determine if depleting T-regs in herpes-infected mice might unleash a strong inflammatory response that could finally clear out the famously persistent herpes simplex type 2 virus.
To everyone’s surprise, the mice free of T-regs quickly died of an uncontrolled herpes infection. In the absence of regulatory T cells, other types of T cells, which move in to eliminate infected cells, seemed to be standing down. The results showed that, at least in the case of herpes, T-regs must have been promoting the immune response they were thought to suppress.
Lund was lead author of the paper, published in Science in 2008, a seminal study that made T-regs much more interesting, and puzzling.
“It was just an unexpected finding in the field,” Lund said. “That paper kind of set the stage for all the work I’ve done thereafter.”
Complex, contradictory roles in immunity
Previously, T-regs had been known for their calming effects on other, more celebrated T cells. They could prevent those aggressive T cell defenders from mistakenly, like an out-of-control mob, attacking its own healthy tissues. Lack of T-regs has been implicated in autoimmune diseases such as eczema and diabetes.
“T-regs are mostly recognized for their role in preventing autoimmunity, but clearly they’re doing something as well in the context of infection,” Lund said. “And now we have shown in many different mouse models of different infections — and also in humans — that they do different things at different times and in different places. So, there’s just so much exciting work to be done.”
The normal function of most T cells is an aggressive one: to seek out tissues that have been infected by viruses or show signs of cancer, and either mark them for death by other immune cells or kill them directly. These T-cell weapons include CD4 helper cells, which are so essential that, when HIV targets and wipes them out, a person becomes vulnerable to lethal infections and cancers — in other words, they develop AIDS.
T-regs in fact are a subtype of CD4 T cells. In the human body, regulatory T cells account for only about 2% of all white blood cells and about 10% of all CD4s. Yet in areas where our bodies have lots of interaction with the outside world — such as in the mucosal tissues that line the gut — they comprise 20% or more of the local complement of CD4 T cells.
Like all T cells, T-regs come in a wide variety of flavors, and the work they do — whether quieting down inflammation or ramping it up — has a lot to do with which receptors they carry. Their task is also defined by the chemical chatter they have with other cells in their environment. It is a language of molecular communication among immune cells — commands, for example, to activate, rest, attack, retreat, attract, repel, multiply or die — that scientists are very keen to decode.
So, when Lund and other scientists are exploring the immune signature of viral infection, they are not just counting T-regs, T cells and other components of the immune system. They are also logging long lists of chemical signals provoked by the interaction of cells when they encounter a threat.
The immune signature created by COVID-19
In the recent study of the immune signature created by COVID-19, Lund and her colleagues relied on a complex computer algorithm. It evaluated populations of dozens of different immune cell types — distinguished by different receptors — and traces of 71 different kinds of soluble, chemical signals. This mix of cells and signals together forms that signature of the immune response to the coronavirus, which can be compared to the patterns of immune responses to other viruses.
While T-regs are best known for tamping down the immune system, Lund’s herpes research had already proven that this is not always the case. So, it is unclear what this telltale COVID-19 signature means. The next step is to find out whether this increase in regulatory T cell levels is good or bad for patients.
In the case of COVID-19, Lund noted that the build-up of T-regs was found in circulating blood, while studies by other researchers have shown deficient levels of these cells in the airways itself, which is battling tissue-damaging inflammation. Lund hypothesizes that, in cases of severe COVID-19, T-regs are not functioning properly in lung mucosal tissue, and that a lack of T-regs tamping down the raging response of T cells to the infection could be contributing to disease.
“Maybe they’re not getting to the place where you need them,” Lund said. Current research by the group is looking to confirm that model.