Decoding Lupus

Researchers scan DNA "bar codes" to study autoimmune response


People with systemic lupus erythematosus can experience a variety of symptoms, such as fatigue, joint pain, skin rashes, and kidney problems. Often the symptoms come and go in episodes called flares.

In lupus, the immune system goes haywire and produces antibodies that are directed against the body itself.

A team of Emory scientists has been investigating some fundamental questions about lupus: Where do the cells that produce the self-reactive antibodies come from? Are they all the same?

Emory researchers Iñaki Sanz and Chris Tipton share some recent progress on these questions in an article published this summer in Nature Immunology. Sanz is a Georgia Research Alliance Eminent Scholar, director of the Lowance Center for Human Immunology, and head of the rheumatology division in the Department of Medicine at Emory’s School of Medicine; Tipton is assistant professor of medicine.

The immune system can produce many types of antibodies, directed against infectious viruses (good) or against human proteins as in lupus (harmful). Each antibody-secreting cell carries DNA rearrangements that reflect the makeup of its antibody product. With next-generation sequencing technology, scientists can use the DNA to identify and track that cell, like reading a bar code on an item in a supermarket.

Tipton, Sanz, and their colleagues have been using these DNA bar codes to deepen our understanding of immune responses in lupus. They obtained blood samples from eight patients experiencing lupus flares and compared them to eight healthy people who had recently been vaccinated against influenza or tetanus.

When the immune system is responding to something it’s seen before, such as when someone receives a booster vaccine, the bar codes of the antibody-producing cells look quite similar to each other. A set of just a few antibody-producing cells multiply and expand. By contrast, the researchers found that in lupus, many different cells are producing antibodies.

“We expected to see an expansion of the cells that produce autoantibodies, but instead we saw a very broad expansion of cells with all types of specificities,” Tipton says.

This is different from another autoimmune disease, multiple sclerosis, in which the autoantibody-producing cells attack a limited set of proteins found in the nervous system.

While the researchers did not directly investigate the effects of drugs used to treat lupus, their findings could guide drug development, because they precisely define the subsets of antibody-producing cells that cause patients the most trouble.

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