The accumulation of the protein amyloid beta in the brain is a sign of Alzheimer’s disease. Sufficiently large quantities cause plaque, which blocks the function of the nerve cells and thereby impair the patient’s memory and cognitive ability.
A small proportion of Alzheimer’s patients have a hereditary risk gene, which causes overproduction of amyloid beta in the brain. In all other cases, the cause of the disease has so far been explained by the body’s lack of ability to break down and remove amyloid beta. However, these new findings provide a more nuanced picture:
“In our study, we show that accumulation of amyloid in the brain is associated with high levels of specific amyloid peptides in the cerebrospinal fluid. This means that overproduction of amyloid beta may contribute to development of Alzheimer’s disease in some people, even if they do not carry the hereditary risk gene for Alzheimer’s. The fact that the disease in these individuals can be attributed to both the overproduction of and problems in breaking down amyloid beta may be of significance to the future development of drugs and treatments”, explains Niklas Mattsson, researcher at Lund University and specialist physician at Skåne University Hospital.
The study noted increased levels of amyloid beta in a large group of patients with no hereditary risk gene. More than 330 people from Sweden participated in the study, some of whom suffered from mild cognitive disorders (which may be an early sign of Alzheimer’s), while others were part of a control group of healthy individuals.
“We were surprised by the results. Our study emphasises that Alzheimer’s is probably a more heterogeneous disease than we previously believed”, continues Niklas Mattsson.
“The results are important because they increase the understanding of how Alzheimer’s disease arises. Our hope is that this and other similar studies can increase the possibilities of personalising treatments that slow down the disease in the future”, says Oskar Hansson, reader at Lund University and consultant at Skåne University Hospital.
However, further studies are needed to verify the results. Apart from the number of participants, the strengths of this study include the use of three different methods to achieve acurate measurement results: cerebrospinal fluid samples, the use of a so-called PET scanner, and genetic analysis. A weakness of the study is that it does not include any measured observations of the brain tissue, which is often the case in studies of Alzheimer’s disease.
The study has received funding from Lund University, as well as the European Research Council (ERC), the Swedish Research Council (VR), the Marianne and Marcus Wallenberg Foundation and Region Skåne (through so-called ALF grants).
The results have been published in the esteemed journal Nature Communications.
Increased Amyloidogenic APP Processing in APOE ε4-Negative Individuals with Cerebral β-Amyloidosis, Nature Communications, published 2016. Authors: Niklas Mattsson, Philip S. Insel, Sebastian Palmqvist, Erik Stomrud, Danielle van Westen, Lennart Minthon, Henrik Zetterberg, Kaj Blennow and Oskar Hansson. http://www.nature.com/ncomms/2016/160307/ncomms10918/full/ncomms10918.html
For more information
Niklas Mattsson, researcher at the Department of Clinical Sciences in Malmö, Lund University, and physician at the Department of Neurology, Skåne University Hospital, Lund, +46 (0)46 17 10 00, firstname.lastname@example.org
Oskar Hansson, reader at the Department of Clinical Sciences in Malmö, Lund University, and consultant at the Memory Clinic, Skåne University Hospital, +46 (0)72 226 77 45, email@example.com
Phone: +46 (0)730623858
Lund University was founded in 1666 and is ranked as one of the top 100 universities in the world. With high-quality education and research at eight faculties, we are one of the most comprehensive universities in Scandinavia. The University has 47000 students and 7000 staff based in Lund, Helsingborg and Malmö. Lund is often considered to be Sweden’s most attractive study destination and huge investments are currently being made in the new research facilities MAX IV and ESS in the city.