Two research studies, co-led by UC Davis neurologist Charles DeCarli and conducted by an international team that included more than 80 scientists at 71 institutions in eight countries, has advanced understanding of the genetic components of Alzheimer's disease and of brain development. Both studies appear in the April 15 edition of the journal Nature Genetics.
The first study, based on a genetic analysis of more than 9,000 people, has found that certain versions of four genes may speed shrinkage of a brain region involved in making new memories. The brain area, known as the hippocampus, normally shrinks with age, but if the process speeds up, it could increase vulnerability to Alzheimer's disease, the research suggests.
The second paper identifies two genes associated with intracranial volume — the space within the skull occupied by the brain when the brain is fully developed in a person's lifespan, usually around age 20.
DeCarli is an internationally renowned pioneer in the field of neuroimaging of the aging brain who has been at the forefront of developing and using quantifiable imaging techniques to define the relationship between structure and function in the healthy aging brain and to characterize the changes associated with vascular and Alzheimer's dementias. He is professor of neurology and director of the UC Davis Alzheimer's Disease Center and the UC Davis Imaging of Dementia and Aging Laboratory.
Genetic variants of hippocampus study
The gene variants identified in the first study do not cause Alzheimer's, but they may rob the hippocampus of a kind of "reserve" against the disease, which is known to cause cell destruction and dramatic shrinkage of this key brain site. The result is severe loss of memory and cognitive ability.
Scientists calculated that hippocampus shrinkage in people with these gene variants accelerates by about four years on average. The risk of Alzheimer's doubles every five years beginning at age 65, so a person of that age would face almost twice the Alzheimer's risk if he or she had these versions of the gene.
Looked at another way, if a person with one of these variants did get Alzheimer's, the disease would attack an already compromised hippocampus and so would lead to a more severe condition at a younger age than otherwise, the research suggests.
"This is definitely a case of 'bigger is better,'" said DeCarli. "We already know that Alzheimer's disease causes much of its damage by shrinking hippocampus volume. If someone loses a greater-than-average amount of volume due to the gene variants we've identified, the hippocampus is more vulnerable to Alzheimer's."
Why the aging hippocampus normally decreases in volume is unclear. The new research shows that the genes most strongly linked to shrinkage are involved in maturation of the hippocampus and in apoptosis, or programmed cell death – a continual process by which older cells are removed from active duty.
The scientists suggest that if the gene variants they identified do affect either maturation or the rate at which cells die, this could underlie at least some of the increased rates of hippocampus shrinkage.
"Either by making more or healthier hippocampal neurons or preventing them from dying with advancing age, the healthy versions of these genes influence how people remember as they get older," said DeCarli. "The alternate versions of the genes may not fully provide these benefits."
The researchers hope that they can find ways to protect the hippocampus from premature shrinkage or slow its decline by studying the normal regulation of the proteins coded by these genes.
The genetic analysis draws on what is known as a genome-wide association study -- research aimed at finding the common genetic variants associated with specific diseases or other conditions. Different versions of a gene usually come down to changes in just one of the tens of thousands of DNA "letters" that make up genes. These one-letter differences are known as single-nucleotide polymorphisms, or SNPs.
The research involved more than 80 scientists at 71 institutions in 8 countries. Many researchers are needed for such a study in order to put together the large samples, or cohorts, of people whose genetic makeup is to be investigated, to measure the hippocampus from magnetic resonance pictures of the brain and for the labor-intensive statistical analysis of the findings.
The study used a very large assemblage of genetic and disease data called the Cohorts for Heart and Aging Research in Genomic Epidemiology Consortium, or CHARGE. The consortium brings together several population-based cohorts in the United States and Europe.
The cohort was made up of 9,232 dementia-free volunteers with an average age of 67. The study identified four different gene variants associated with hippocampus volume decline. One, known as rs7294919, showed a particularly strong link to a reduced hippocampus volume, suggesting that this gene is very important to hippocampus development or health.
The findings were then assessed in two other cohorts. One, including both normal and cognitively compromised people with an average age of 40, showed that three of the suspect SNPs were linked to reduced hippocampus volume. Analysis of results from the third group, comprised primarily of older people, showed a significant association between one of the SNPs and accelerated memory loss.
"With this study, we have new evidence that aging, the hippocampus and memory are influenced by specific genes," DeCarli said. "Understanding how these genes affect the development and aging of the hippocampus may give us new tools to delay memory loss with advanced age and possibly reduce the impact of such diseases as Alzheimer's disease."
Genetic variants of Intracranial-volume study
While the first study deals with the genetic associations with brain shrinkage, the second deals with associations impacting intracranial volume, which is an indirect measure of the size of the brain at full development.
Though brain volume and intracranial volume are both highly heritable, the genetic influences on these measures may differ. To assess the genetic influence on these two measures, researchers in the second study performed a genome-wide association study on cross-sectional measures of intracranial volume and brain volume in 8,175 elderly in the CHARGE consortium.
They found no associations for brain volume, but they did discover that intracranial volume was significantly associated with two loci: rs4273712, a known height locus on chromosome 6q22, and rs9915547, tagging the inversion on chromosome 17q21.
"Since geneticists are already familiar with the other functions of these same genes, associating these particular genes with intracranial volume may help us better understand brain development in general," said DeCarli. "For instance, we know that one of these genes has played a unique evolutionary role in human development, and perhaps we as a species are selecting this gene as a way of providing further advances in brain development."
Both studies involved international teams representing scores of institutions, funded by a variety of NIH grants as well as grants from agencies around the world. Please refer to the papers for complete lists of authors, affiliations, and funding sources.
The UC Davis Alzheimer's Disease Center is one of only 29 research centers designated by the National Institutes of Health's National Institute on Aging. The center's goal is to translate research advances into improved diagnosis and treatment for patients while focusing on the long-term goal of finding a way to prevent or cure Alzheimer's disease. Also funded by the state of California, the center allows researchers to study the effects of the disease on a uniquely diverse population. For more information, visit alzheimer.ucdavis.edu
Carole Gan | EurekAlert!
New study: How does Europe become a leading player for software and IT services?
03.04.2017 | Fraunhofer-Institut für System- und Innovationsforschung (ISI)
Reusable carbon nanotubes could be the water filter of the future, says RIT study
30.03.2017 | Rochester Institute of Technology
The world's highest gain high power laser amplifier - by many orders of magnitude - has been developed in research led at the University of Strathclyde.
The researchers demonstrated the feasibility of using plasma to amplify short laser pulses of picojoule-level energy up to 100 millijoules, which is a 'gain'...
Staphylococcus aureus is a feared pathogen (MRSA, multi-resistant S. aureus) due to frequent resistances against many antibiotics, especially in hospital infections. Researchers at the Paul-Ehrlich-Institut have identified immunological processes that prevent a successful immune response directed against the pathogenic agent. The delivery of bacterial proteins with RNA adjuvant or messenger RNA (mRNA) into immune cells allows the re-direction of the immune response towards an active defense against S. aureus. This could be of significant importance for the development of an effective vaccine. PLOS Pathogens has published these research results online on 25 May 2017.
Staphylococcus aureus (S. aureus) is a bacterium that colonizes by far more than half of the skin and the mucosa of adults, usually without causing infections....
Physicists from the University of Würzburg are capable of generating identical looking single light particles at the push of a button. Two new studies now demonstrate the potential this method holds.
The quantum computer has fuelled the imagination of scientists for decades: It is based on fundamentally different phenomena than a conventional computer....
An international team of physicists has monitored the scattering behaviour of electrons in a non-conducting material in real-time. Their insights could be beneficial for radiotherapy.
We can refer to electrons in non-conducting materials as ‘sluggish’. Typically, they remain fixed in a location, deep inside an atomic composite. It is hence...
Two-dimensional magnetic structures are regarded as a promising material for new types of data storage, since the magnetic properties of individual molecular building blocks can be investigated and modified. For the first time, researchers have now produced a wafer-thin ferrimagnet, in which molecules with different magnetic centers arrange themselves on a gold surface to form a checkerboard pattern. Scientists at the Swiss Nanoscience Institute at the University of Basel and the Paul Scherrer Institute published their findings in the journal Nature Communications.
Ferrimagnets are composed of two centers which are magnetized at different strengths and point in opposing directions. Two-dimensional, quasi-flat ferrimagnets...
24.05.2017 | Event News
23.05.2017 | Event News
22.05.2017 | Event News
29.05.2017 | Physics and Astronomy
29.05.2017 | Physics and Astronomy
29.05.2017 | Earth Sciences