Alzheimer’s: New gene may drive earliest brain changes
NEW YORK, NY (June 22, 2020)–A newly discovered Alzheimer’s gene may drive the first appearance of amyloid plaques in the brain, according to a study led by researchers at Columbia University Irving Medical Center.
Some variants of the gene, RBFOX1, appear to increase the concentration of protein fragments that make up these plaques and may contribute to the breakdown of critical connections between neurons, another early sign of the disease.
The finding could lead to new therapies that prevent Alzheimer’s and better ways of identifying people with the greatest risk of developing the disease.
In recent years, amyloid PET brain imaging has helped to reveal that the earliest signs of Alzheimer’s disease — deposits of amyloid in the brain – appear as early as 10 or 15 years before any symptoms of the disease become apparent.
But aside from the few cases caused by rare, inherited genes, researchers have been searching for the cause of excessive accumulation of amyloid in the brain of Alzheimer’s patients.
To find genes that drive EARLY amyloid accumulation, the new study examined the genomes of thousands of people whose PET images revealed amyloid deposits in the brain but who had not yet developed Alzheimer’s symptoms.
“By studying people with the earliest signs of Alzheimer’s, we can find genes that are unequivocally related to the start of disease. And these genes are more likely to lead to therapies that can prevent the disease from developing,” says Richard Mayeux, MD, chair of neurology at Columbia University Vagelos College of Physicians and Surgeons, who led the study.
The study looked through the genomes of nearly 4,300 people who did not have Alzheimer’s but whose brains already contained variable amounts of amyloid plaque, as measured by PET imaging using amyloid tracers.
A genetic analysis uncovered a link between the appearance of amyloid deposits and APOE, a known Alzheimer’s gene, and a novel gene, RBFOX1.
About 10% of people in the study (predominantly with European ancestry) had RBFOX1 variants that were linked with the emergence of amyloid deposition.
Lower amounts of RBFOX1 in the brain appeared to be associated with increased amyloid and global cognitive decline during life.
Why It Matters
Uncovering exactly how RBFOX1 regulates amyloid plaque could lead to ways to prevent plaque accumulation. Previous research has already suggested RBFOX1 is involved in the formation of amyloid precursors and the breakdown of synapses between neurons.
The connection between RBFOX1 and amyloid plaques may be relatively easy to untangle, unlike the well-known connection between APOE4 and amyloid, which is still not understood after decades of research.
“I think we’re going to find that these markers of eventual disease are where real progress can be made against Alzheimer’s,” Mayeux says. “It will be virtually impossible to change the disease course at the time symptoms appear. By then, the disease has already flourished for 10 to 15 years.”
“If we can target the genes that get amyloid started — and correct those problems somehow — we may be able to prevent the disease.”
The research appears in “Association Between Common Variants in RBFOX1, an RNA-Binding Protein, and Brain Amyloidosis in Early and Preclinical Alzheimer Disease,” published June 22 in JAMA Neurology.
Additional authors: Neha S. Raghavan (Columbia University Irving Medical Center); Logan Dumitrescu (Vanderbilt University); Elizabeth Mormino (Stanford University); Emily R. Mahoney (Vanderbilt); Annie J. Lee (CUIMC); Yizhe Gao (CUIMC); Murat Bilgel (National Institute on Aging, NIH); David Goldstein (CUIMC); Theresa Harrison (University of California, Berkeley); Corinne D. Engelman (University of Wisconsin); Andrew J. Saykin (Indiana University); Christopher D. Whelan (Biogen); Jimmy Z. Liu (Biogen); William Jagust (University of California, Berkeley); Marilyn Albert (Johns Hopkins University); Sterling C. Johnson (University of Wisconsin); Hyun-Sik Yang and Keith Johnson (Massachusetts General and Brigham and Women’s Hospitals); Paul Aisen (University of Southern California); Susan M. Resnick (NIA); Reisa Sperling (Massachusetts General and Brigham and Women’s Hospitals); Philip L. De Jager, (CUIMC); Julie Schneider and David A. Bennett (Rush University Medical Center); Matthew Schrag (Vanderbilt University Medical Center); Badri Vardarajan, PhD (CUIMC); and Timothy J. Hohman (Vanderbilt University Medical Center).
This research was supported in part by grants from the NIH (RF1-AG054023, K01-AG049164, R01-AG059716, R21-AG059941, HHSN311201600276P, K24-AG046373, R01-AG034962, R01-NS100980, P30-AG10161, R01-AG15819, R01-AG17917, R01-AG056534, R01AG036836, R01AG034570, R01-AG063689, U19-AG010483, U01-AG061356, U01-AG024904, P30-AG010133, R01-AG054047, and R01-AG019771); the Intramural Research Program of the NIA; the Vanderbilt Memory and Alzheimer’s Center; and The Columbia University Alzheimer’s Disease Research Center (NIH grant P50-AG008702).
Disclosure statements can be found in the paper.
Columbia University Irving Medical Center provides international leadership in basic, preclinical, and clinical research; medical and health sciences education; and patient care. The medical center trains future leaders and includes the dedicated work of many physicians, scientists, public health professionals, dentists, and nurses at the Vagelos College of Physicians and Surgeons, the Mailman School of Public Health, the College of Dental Medicine, the School of Nursing, the biomedical departments of the Graduate School of Arts and Sciences, and allied research centers and institutions. Columbia University Irving Medical Center is home to the largest medical research enterprise in New York City and State and one of the largest faculty medical practices in the Northeast. For more information, visit cuimc.columbia.edu or columbiadoctors.org.