Posts tagged monozygotic twins
Articles and news from the latest research reports.
After death, twin brains show similar patterns of neuropathologic changes
Despite widespread use of a single term, Alzheimer’s disease is actually a diverse collection of diseases, symptoms and pathological changes. What’s happening in the brain often varies widely from patient to patient, and a trigger for one person may be harmless is another.
In a unique study, an international team of researchers led by USC psychologist Margaret Gatz compared the brains of twins where one or both died of Alzheimer’s disease. They found that many of the twin pairs not only had similar progressions of Alzheimer’s disease and dementia prior to death, but they also had similar combinations of pathologies — two-or-more unconnected areas of damage to the brain.
The paper is part of Gatz’s landmark body of work on aging and cognition with the Swedish Twin Registry, a large cohort study of more than 14,000 Swedish twins, now over the age of 65. Across nearly 30 years, Gatz’s work with twins — including genetically identical pairs — has shifted the study of Alzheimer’s disease to include the entire lifespan, including the effects of developmental exposure, periodontal disease, mental health, obesity and diabetes on later-life Alzheimer’s risk.
The current paper provides more evidence that there may not be a single smoking-gun cause of Alzheimer’s, but rather a range of potential causes to which we may be susceptible largely depending on our genetics. It appears in the current issue of the journal Brain Pathology.
“We try to make inferences based on tests and diagnoses, but we have to assume that what we’re seeing is a manifestation of what’s going on in these twins’ brains,” said Gatz, professor of psychology, gerontology and preventive medicine in USC Dornsife College. “For this reason, we wanted to compare the brains of twins to ask whether identical twins’ brains are actually more identical?”
The researchers had the rare opportunity to directly autopsy the brains of seven pairs of twins who both died after being receiving diagnostic evaluations over many years, including a pair of identical twins who were both diagnosed with Alzheimer’s and died within a year of one another at the age of 98.
“There may be risk factors that start to accumulate but don’t lead to a clinical diagnosis,” explained lead author Diego Iacono of the Karolinska Institute in Sweden and the Biomedical Research Institute. “We found that the presence of Alzheimer’s disease doesn’t preclude the presence of other damage. Looking at co-pathologies in twin pairs may present new areas for research aside from the typical factors.”
For example, while there’s wide consensus among experts about the course of Alzheimer’s disease and the presence of amyloid plaques and tangles in the brain, what starts the process going is less clear, including the role of lesions, Lewy bodies and vascular or ventricle damage, more often associated with specific types of dementia such as Parkinson’s disease.
“Identical twins tended to have similar combinations of pathologies. We looked not just at the hallmark indicators of Alzheimer’s, but at all the other damage in the brain. Across the whole array of neuropathological changes, the identical twins appeared to have more similar pathologies,” Gatz said. “This is fascinating: it’s not just a key pathology related to the twins’ diagnoses but the combination of things happening in their brains. We’re going to keep looking for what these combinations are.”
(Image: Getty)
Epigenetic changes shed light on biological mechanism of autism
Scientists from King’s College London have identified patterns of epigenetic changes involved in autism spectrum disorder (ASD) by studying genetically identical twins who differ in autism traits.
The study, published in Molecular Psychiatry, is the largest of its kind and may shed light on the biological mechanism by which environmental influences regulate the activity of certain genes and in turn contribute to the development of ASD and related behaviour traits.
ASD affects approximately 1 in 100 people in the UK and involves a spectrum of disorders which manifest themselves differently in different people. People with ASD have varying levels of impairment across three common areas: deficits in social interactions and understanding, repetitive behaviour and interests, and impairments in language and communication development.
Evidence from twin studies shows there is a strong genetic component to ASD and previous studies suggest that genes that direct brain development may be involved in the disorder. In approximately 70% of cases, when one identical twin has ASD, so does the other. However, in 30% of cases, identical twins differ for ASD. Because identical twins share the same genetic code, this suggests non-genetic, or epigenetic, factors may be involved.
Epigenetic changes affect the expression or activity of genes without changing the underlying DNA sequence – they are believed to be one mechanism by which the environment can interact with the genome. Importantly, epigenetic changes are potentially reversible and may therefore provide targets for the development of new therapies.
The researchers studied an epigenetic mechanism called DNA methylation. DNA methylation acts to block the genetic sequences that drive gene expression, silencing gene activity. They examined DNA methylation at over 27,000 sites across the genome using samples taken from 50 identical twin pairs (100 individuals) from the UK Medical Research Council (MRC) funded Twins Early Development Study (TEDS): 34 pairs who differed for ASD or autism related behaviour traits, 5 pairs where both twins have ASD, and 11 healthy twin pairs.
Dr Chloe Wong, first author of the study from King’s College London’s Institute of Psychiatry, says: “We’ve identified distinctive patterns of DNA methylation associated with both autism diagnosis and related behaviour traits, and increasing severity of symptoms. Our findings give us an insight into the biological mechanism mediating the interaction between gene and environment in autism spectrum disorder.”
DNA methylation at some genetic sites was consistently altered for all individuals with ASD, and differences at other sites were specific to certain symptom groups. The number of DNA methylation sites across the genome was also linked to the severity of autism symptoms suggesting a quantitative relationship between the two. Additionally, some of the differences in DNA methylation markers were located in genetic regions that previous research has associated with early brain development and ASD.
Professor Jonathan Mill, lead author of the paper from King’s College London’s Institute of Psychiatry and the University of Exeter, says: “Research into the intersection between genetic and environmental influences is crucial because risky environmental conditions can sometimes be avoided or changed. Epigenetic changes are potentially reversible, so our next step is to embark on larger studies to see whether we can identify key epigenetic changes common to the majority of people with autism to help us develop possible therapeutic interventions.”
Dr Alycia Halladay, Senior Director of Environmental and Clinical Sciences from Autism Speaks who funded the research, says: “This is the first large-scale study to take a whole genome approach to studying epigenetic influences in twins who are genetically identical but have different symptoms. These findings open the door to future discoveries in the role of epigenetics – in addition to genetics – in the development of autism symptoms.”
(Source: kcl.ac.uk)