Bone marrow plasma cells produce antibodies. These comprise two long and two short protein chains. The pathological proliferation of plasma cells can lead to an overproduction of the short chains. These associate to fibrils and deposit in organs. The result is fatal organ failure. A research team from the Technical University of Munich (TUM) and Heidelberg University has now identified the mutation behind the disease in a patient.
Antibodies are vital for the survival of human beings. They typically consist of two longer and thus heavier amino acid chains and two lighter ones. In rare cases, the plasma cells multiply excessively, flooding the body with light antibody chains.
In people suffering from light chain amyloidosis (AL amyloidosis), these light chains are deposited as extremely fine fibers, so-called amyloid fibrils, in tissue or in organs. The disease is often recognized only after the deposits already compromise the function of organs. In many cases AL amyloidosis is fatal.
To date, little was known about the exact cause of this amyloidosis. Depending on the organ affected, the symptoms vary considerably. Furthermore, each patient produces different types of antibodies. The disease is thus difficult to diagnose at an early stage.”
Johannes Buchner, professor of biotechnology, Technical University of Munich
A mutation triggers the deadly disease
Using various analytical and database-supported methods, the team of scientists succeeded in identifying eleven mutations caused by the disease in the antibodies of a patient with advanced AL amyloidosis.
Further investigations showed that exactly one mutation was responsible for the destabilization and formation of the disease-causing amyloid fibrils. This mutation causes the unstable light chain to lose its structure after breaking into fragments, which then form the deadly amyloid fibrils.
“Our study shows that mutations that lead to unstable light chains are an important factor in the occurrence of amyloidosis,” says Pamina Kazman, who carried out the majority of the measurements. “In the long term, we hope that these and other studies will lead to new, earlier diagnostic methods and possibly even new treatment options.”
The research was funded by the German Research Foundation (DFG). The protein structures were determined at the synchrotron radiation sources of the Paul Scherrer Institute in Villigen (Switzerland) and the European synchrotron radiation source in Grenoble (France).