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Sanford-Burnham Science Blog

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Diabetic fruit flies support buzz about dietary sugar dangers

by Heather Buschman, Ph.D. on January 17, 2013 at 5:33 am | 1 comment
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Cardiac fibrosis (shown in purple), a hallmark of heart disease, is clearly increased in fruit flies on a high-sugar diet (right), as compared to flies on a normal diet (left).

Cardiac fibrosis (shown in purple), a hallmark of heart disease, is clearly increased in fruit flies on a high-sugar diet (right), as compared to flies on a normal diet (left).

First fruit fly model of diet-induced type 2 diabetes shows how high-sugar diet affects the heart and reveals new therapeutic opportunities

Regularly consuming sucrose—the type of sugar found in many sweetened beverages—increases a person’s risk of heart disease. In a study published January 10 in the journal PLOS Genetics, researchers at Sanford-Burnham Medical Research Institute and Mount Sinai School of Medicine used fruit flies, a well-established model for human health and disease, to determine exactly how sucrose affects heart function. In addition, the researchers discovered that blocking this cellular mechanism prevents sucrose-related heart problems.

“Our study reveals a number of specific sugar-processing enzymes that could be targeted with therapies aimed at reducing sucrose’s unhealthy effects on the heart,” said Karen Ocorr, Ph.D., research assistant professor at Sanford-Burnham and the study’s corresponding author.

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Marching to the same beat

by Ana Miletic Sedy on August 4, 2011 at 11:23 am | 0 Comments
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heart muscle in a fruit fly (image courtesy of the Bodmer lab)

heart muscle in a fruit fly (image courtesy of the Bodmer lab)

Heart disease is the leading cause of death in the United States, accounting for more than 25 percent of all deaths each year. While many factors work together to contribute to heart disease—including environment, lifestyle, and genetics—we only have control over the first two. To address the third factor (genetics), researchers at Sanford-Burnham recently turned to fruit flies.

Fly and human genes are so closely related that the sequences of newly discovered human genes, including many that contribute to disease, can often be matched up with fly counterparts. Since fruit flies are relatively easy to work with (they’re small, breed quickly, and don’t require a lot of maintenance), they often give scientists clues to the functions of human genes and helps them develop drugs that target them.

As Dr. Rolf Bodmer, director of Sanford-Burnham’s Development and Aging Program, explains in the Journal of Cell Biology, “We use fruit flies to learn about the fundamental genetic mechanisms that are important for the development and function of the heart.”

Dr. Bodmer himself discovered early in his career that flies lacking Tinman, a protein that regulates the expression of other genes, fail to develop heart tissue during embryonic development. If Tinman is removed later during fly development, the flies’ hearts don’t function properly.

Now researchers in Dr. Bodmer’s lab, led by postdoctoral researcher Dr. Li Qian, uncovered a genetic network that controls heart development and function in fruit flies and mice, with additional clues that it might also play a role in human heart health.

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A different path to fat-related heart disease

by Heather Buschman, Ph.D. on January 18, 2011 at 3:09 pm | 2 Comments
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Heart disease is the leading cause of death for both men and women in the United States. But heart disease is more than just one disease; there are many different ‘flavors’ that can result from a heart attack, high blood pressure, diabetes or other causes. In lipotoxic cardiomyopathy, for example, heart function is disrupted by fat accumulation in heart cells. Obesity and high-fat diets are major risk factors for lipotoxic cardiomyopathy, but scientists recently unraveled an alternative pathway to lipotoxic cardiomyopathy in fruit flies – a genetic mechanism that occurs independently of a diet high in fat. Their study lays the foundation for the development of new ways to combat lipotoxic cardiomyopathy and other types of heart disease.

“It’s a well-accepted notion that if you eat too much fatty food and your body can’t metabolize it properly, you can become obese and this can lead to lipotoxic cardiomyopathy. Our study shows that there is also an alternative cause of obesity and associated heart problems – an imbalance in the fats that normally make up the basic structure of our cells,” explained Dr. Hui-Ying Lim, post-doctoral researcher and lead author of the study.

In this study, the researchers analyzed mutant fruit flies (called easily shocked mutants) that have abnormally low levels of phosphatidylethanolamine (PE), a type of fat that makes up a major component of cellular membranes in both flies and mammals. They found that these flies compensate for low PE levels by initiating a mechanism for synthesizing fat. In this mechanism, a protein called sterol regulatory element-binding protein (SREBP) turns on genes encoding metabolic enzymes that synthesize more fat.

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Super-sized Fruit Flies

by Heather Buschman, Ph.D. on November 2, 2010 at 1:13 pm | 0 Comments
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It’s no secret that being overweight is hard on the heart – many studies have shown that heavier people are more likely to suffer from heart disease. But why, exactly? What does fat have to do with your heart?

There are numerous causes of obesity and other risk factors for heart disease, making it difficult to tease them apart. So a team led by Drs. Sean Oldham, Rolf Bodmer and Ryan Birse created a simple model to study the genes linking high-fat diet, obesity and heart dysfunction. Using fruit flies, they discovered that a protein called TOR influences fat accumulation in the heart. Their study, published November 3 in the journal Cell Metabolism, also demonstrates that manipulating TOR protects the hearts of obese flies from damage caused by high-fat diets.

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Heart team gets pumped up

by Heather Buschman, Ph.D. on September 28, 2010 at 8:21 am | 0 Comments
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A collaborative team led by Dr. Gabriel Haddad at the University of California, San Diego (UCSD), which includes Sanford-Burnham’s Dr. Rolf Bodmer, Dr. Pilar Ruiz-Lozano, Dr. Karen Ocorr and Dr. Giovanni Paternostro, was awarded a $10 million grant from the National Heart, Lung, and Blood Institute, part of the National Institutes of Health. The team will research the molecular response to low oxygen levels – a condition known as hypoxia– in heart, lung and brain cells.

“This funding will allow us to develop powerful predictions of how the human heart and other organs can be protected from hypoxia-inflicted injury by studying both fruit flies, which are very tolerant to low oxygen, and mice, which are less tolerant,” explains Dr. Bodmer, professor and director of Sanford-Burnham’s Development and Aging Program.

According to Dr. Paternostro, adjunct assistant professor, ”This grant will allow us to continue our work on the systems biology and metabolomics of hypoxia, an ongoing collaboration with Dr. Haddad and with the other scientists participating in the funded project.”

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Mapping Heart Disease

by Josh Baxt on April 8, 2010 at 7:21 am | 0 Comments
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fruit fly

Drosophila, a fruit fly used in Dr. Bodmer's research. Picture by Muhammad Mahdi Karim.

Heart disease remains the leading cause of death in the United States and Europe, but little is understood about its genetic causes. Recently, an international team of scientists at Sanford-Burnham, the Institute of Molecular Biotechnology of the Austrian Academy of Sciences (IMBA), and other organizations uncovered important information about how genes influence heart development and function. Studying Drosophila (fruit flies), the team investigated 7,061 genes and built a detailed map that illustrates how some of these genes contribute to heart disease. The team also identified many genes that had not previously been associated with heart disease.

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