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Tuesday, October 10, 2017

Menopause Triggers Metabolic Changes in Brain That May Promote Alzheimer’s

NEUROSCIENCE NEWS   OCTOBER 10, 2017

Summary: Weill Cornell Medicine researchers may have answered why women are more likely to develop Alzheimer’s disease than men. In a new PLOS ONE study, researchers reveal menopause can cause metabolic changes in the brain that appear to increase the risk of Alzheimer’s disease.

Source: Weill Cornell Medicine.

The scan to the left shows brain activity (e.g., metabolism) in a premenopausal woman; the scan to the right shows brain activity in a postmenopausal woman. The color scale reflects brain activity, with brighter colors indicating more activity, and darker colors indicating lower activity. The scan to the right (menopause) looks ‘greener’ and overall darker, which means that the woman’s brain has substantially lower brain activity (more than 30 percent less) than the one to the left (no signs of menopause). NeuroscienceNews.com image is credited to WCM.


Menopause causes metabolic changes in the brain that may increase the risk of Alzheimer’s disease, a team from Weill Cornell Medicine and the University of Arizona Health Sciences has shown in new research.

The findings, published today in PLoS One, could help solve a longstanding mystery about Alzheimer’s, namely, why women get this fatal neurodegenerative disorder more often than men — even accounting for the fact that women on average live longer. The investigators say the results also eventually may lead to the development of screening tests and early interventions to reverse or slow the observed metabolic changes.

Alzheimer’s afflicts more than 5 million Americans, including one-third of Americans older than 85, and the disease process is known to begin several decades before dementia sets in.

“This study suggests there may be a critical window of opportunity, when women are in their 40s and 50s, to detect metabolic signs of higher Alzheimer’s risk and apply strategies to reduce that risk,” said lead author Dr. Lisa Mosconi, who was recruited to Weill Cornell Medicine as an associate professor of neuroscience in neurology.

For the study, Dr. Mosconi and her colleagues, including senior author Dr. Roberta Brinton from the University of Arizona Health Sciences in Tucson, used the imaging test positron emission tomography (PET) to measure the use of glucose–a principal fuel source for cellular activity–in the brains of 43 healthy women ages 40 to 60. Of those, 15 were pre-menopausal, 14 were transitioning to menopause (peri-menopause) and 14 were menopausal.

The tests revealed the women who had undergone menopause or were peri-menopausal had markedly lower levels of glucose metabolism in several key brain regions than those who were pre-menopausal. Scientists in prior studies have seen a similar pattern of “hypometabolism” in the brains of patients in the earliest stages of Alzheimer’s — and even in mice that model the disease.

In addition, menopausal and peri-menopausal patients showed lower levels of activity for an important metabolic enzyme called mitochondrial cytochrome oxidase, as well as lower scores on standard memory tests. The strong contrast with pre-menopausal patients remained even when accounting that the menopausal and peri-menopausal women were older.

“Our findings show that the loss of estrogen in menopause doesn’t just diminish fertility,” said Dr. Mosconi, associate director of the Alzheimer’s Prevention Clinic at Weill Cornell Medicine and NewYork-Presbyterian. “It also means the loss of a key neuroprotective element in the female brain and a higher vulnerability to brain aging and Alzheimer’s disease. We urgently need to address these problems because, currently, 850 million women worldwide are entering or have entered menopause. Our studies demonstrate that women need medical attention in their 40s, well in advance of any endocrine or neurological symptoms.”

The findings add to mounting evidence that there is physiological connection between menopause and Alzheimer’s. Dr. Mosconi and colleagues published a study in Neurology in September that linked menopause to increased accumulation of the Alzheimer’s-associated protein amyloid beta in the brain. The investigators also observed reduced volumes of gray matter (brain cells) and white matter (nerve fiber bundles) in brain regions that are strongly affected in Alzheimer’s.

Menopause long has been known to cause brain-related symptoms, including depression, anxiety, insomnia and cognitive deficits. Scientists widely believe they are caused largely by declines in estrogen levels. Estrogen receptors are found on cells throughout the brain and evidence suggests that reduced signaling through these receptors due to low estrogen levels can leave brain cells generally more vulnerable to disease and dysfunction.

More specifically, the authors suggest that the menopausal fall in estrogen may trigger a shift to a “starvation reaction” in brain cells — a metabolic state that is beneficial in the short term but can be harmful in the long term.

“Our work indicates that women may need antioxidants to protect their brain activity and mitochondria in combination with strategies to maintain estrogen levels,” Dr. Mosconi said, noting that exercise and foods that are rich in antioxidants, such as flaxseeds, also may help boost estrogen production. “We believe that more research is needed to test efficacy and safety of hormonal-replacement therapies at the very early stages of menopause, and to correlate hormonal changes with risk of Alzheimer’s. This is a major priority at our Alzheimer’s Prevention Clinic.”

Dr. Mosconi and her colleagues now plan to expand their patient group, and also hope to perform longer-term, more comprehensive analyses of neural and metabolic markers during and after menopause. This work may lead to the development of biomarkers that could help investigators identify at-risk patients.

“We really need to follow larger groups of women over long periods to see how this menopausal change in metabolism relates to Alzheimer’s,” she said.
Said Dr. Brinton, a leading neuroscientist in the field of Alzheimer’s, the aging female brain and regenerative therapeutics: “Outcomes of this study will provide critical evidence for early changes in the aging female brain that are relevant to the two-fold greater lifetime risk in Alzheimer’s disease. Importantly, these results indicate that we know when to intervene in the aging process to divert the potential for developing this devastating disease.”
ABOUT THIS NEUROSCIENCE RESEARCH ARTICLE
Source: Jen Gundersen – Weill Cornell Medicine
Image Source: NeuroscienceNews.com image is credited to WCM.
Original Research: Full open access research for “Perimenopause and emergence of an Alzheimer’s bioenergetic phenotype in brain and periphery” by Lisa Mosconi, Valentina Berti, Crystal Guyara-Quinn, Pauline McHugh, Gabriella Petrongolo, Ricardo S. Osorio, Christopher Connaughty, Alberto Pupi, Shankar Vallabhajosula, Richard S. Isaacson, Mony J. de Leon, Russell H. Swerdlow, and Roberta Diaz Brinton in PLOS ONE. Published online October 10 20110 doi:10.1371/journal.pone.0185926


Abstract

Perimenopause and emergence of an Alzheimer’s bioenergetic phenotype in brain and periphery
After advanced age, female sex is the major risk factor for Alzheimer’s disease (AD). The biological mechanisms underlying the increased AD risk in women remain largely undetermined. Preclinical studies identified the perimenopause to menopause transition, a neuroendocrine transition state unique to the female, as a sex-specific risk factor for AD. In animals, estrogenic regulation of cerebral glucose metabolism (CMRglc) falters during perimenopause. This is evident in glucose hypometabolism and decline in mitochondrial efficiency which is sustained thereafter. This study bridges basic to clinical science to characterize brain bioenergetics in a cohort of forty-three, 40–60 year-old clinically and cognitively normal women at different endocrine transition stages including premenopause (controls, CNT, n = 15), perimenopause (PERI, n = 14) and postmenopause (MENO, n = 14). All participants received clinical, laboratory and neuropsychological examinations, 18F-fluoro-deoxyglucose (FDG)-Positron Emission Tomography (PET) FDG-PET scans to estimate CMRglc, and platelet mitochondrial cytochrome oxidase (COX) activity measures. Statistical parametric mapping and multiple regression models were used to examine clinical, CMRglc and COX data across groups. As expected, the MENO group was older than PERI and controls. Groups were otherwise comparable for clinical measures and distribution of APOE4 genotype. Both MENO and PERI groups exhibited reduced CMRglc in AD-vulnerable regions which was correlated with decline in mitochondrial COX activity compared to CNT (p’s<0.001). A gradient in biomarker abnormalities was most pronounced in MENO, intermediate in PERI, and lowest in CNT (p<0.001). Biomarkers correlated with immediate and delayed memory scores (Pearson’s 0.26≤r≤0.32, p≤0.05). These findings validate earlier preclinical findings and indicate emergence of bioenergetic deficits in perimenopausal and postmenopausal women, suggesting that the optimal window of opportunity for therapeutic intervention in women is early in the endocrine aging process.

“Perimenopause and emergence of an Alzheimer’s bioenergetic phenotype in brain and periphery” by Lisa Mosconi, Valentina Berti, Crystal Guyara-Quinn, Pauline McHugh, Gabriella Petrongolo, Ricardo S. Osorio, Christopher Connaughty, Alberto Pupi, Shankar Vallabhajosula, Richard S. Isaacson, Mony J. de Leon, Russell H. Swerdlow, and Roberta Diaz Brinton in PLOS ONE. Published online October 10 20110 doi:10.1371/journal.pone.0185926

http://neurosciencenews.com/menopause-metabolic-alzheimers-7711/

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