An immunologist muses about inflammation through cell interactions.

I spend my lab hours trying to understand what prompts T cells — a type of white blood cell — to specialize. Some T cells produce soluble molecules that rattle the immune system into an inflamed state; other cells generate molecules that calm the system back down.

Upon infection, cells such as macrophages — another type of white blood cell — produce soluble molecules called interleukins that direct the fate of the responding T cells. An emerging curiosity in the field is which interleukins make certain T cells become pro-inflammatory, and which cause other T cells to become anti-inflammatory. This decision is crucial for determining whether an immune response induces or suppresses inflammation.

Recently, investigators have turned their attention towards an interleukin known as IL-27. This is produced by activated macrophages and was initially thought to induce IFNγ, a signalling molecule that activates macrophages even more.

But work by Nico Giraldi and his colleagues at Genentech in South San Francisco, and other groups, has recast IL-27 as a molecule that primarily directs T cells to suppress inflammation. In a paper published in March, Giraldi's team confirmed that IL-27 acts in this way because it causes CD4+ and CD8+ T cells to make the anti-inflammatory IL-10, and does not work through an alternative pathway (M. Batten et al. J. Immunol. 180, 2752–2756; 2008). Mice with Listeria infections or autoimmune tissue inflammation in their brains and spinal cords generated fewer IL-10-producing T cells when they lacked an IL-27 receptor. Whether an analogous interaction occurs in humans is not known, but, if it does occur, this research could become medically useful.

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