A small chemical change – shifting the position of two hydrogen atoms – makes the difference between mice that are healthy and mice with insulin resistance and fatty liver, major risk factors for diabetes and heart disease. Making the change prevented the onset of these symptoms in mice fed a high-fat diet and reversed prediabetes in obese mice.
The scientists changed the trajectory of metabolic disease by deactivating an enzyme called dihydroceramide desaturase 1 (DES1). Doing so stopped the enzyme from removing the final hydrogens from a fatty lipid called ceramide, having an effect of lowering the total amount of ceramides in the body.
The finding highlights a role for ceramides in metabolic health and pinpoints DES1 as a “druggable” target that could be used to develop new therapies for metabolic disorders such as prediabetes, diabetes and heart disease – that affect the health of hundreds of millions of Americans. Scientists at University of Utah Health and Merck Research Laboratories led the research, publishes online in Science on July 4, 2019.
“We have identified a potential therapeutic strategy that is remarkably effective, and underscores how complex biological systems can be deeply affected by a subtle change in chemistry,” says Scott Summers, chair of Nutrition and Integrative Physiology at U of U Health, who was co-senior author on the study with David Kelley, formerly of Merck Research Laboratories.
“Our work shows that ceramides have an influential role in metabolic health,” says Summers. “We’re thinking of ceramides as the next cholesterol.”
This isn’t the first time that Summers’ group has found that lowering ceramides could reverse signs of diabetes and metabolic disease. However, techniques used in previous experiments caused severe side effects, showing the approach would not be suitable for therapeutic applications.
This time, rather than taking a sledgehammer to the problem, they fine-tuned their approach. They reasoned that making the smallest change possible and at a precise time and place might yield better results.
To lower ceramides, the investigators blocked the final step of ceramide synthesis in two ways. Summers’ group genetically engineered mice in which the gene coding for DES1 could be switched off during adulthood and deactivated the gene from tissues throughout the body, or alternatively from either liver or fat cells. Kelley’s group injected short hairpin RNA into the adult liver, a method that selectively lowered production of DES1 by destroying the RNA precursor.
The scientists tested the new approaches first by placing adult mice on a high-fat diet – one that resembled cookie dough with plenty of sugar and six times the fat of a normal rodent diet. The mice gained two times their body weight within three months. Along with obesity came a strain on their metabolic health. They developed insulin resistance and fat accumulated in the liver, both signs of metabolic disease.
Within weeks after lowering ceramides using either technique, there were significant changes. Mice remained obese but their metabolic health improved. Fat cleared from the liver and they responded to both insulin and glucose like healthy, skinny mice. In contrast to previous interventions, mice remained healthy during the two-month investigation. Long-term effects on health are currently under investigation.
“Their weight didn’t change but the way they handled nutrients did,” says Summers. “The mice were fat but they were happy and healthy.”
In another paradigm, lowering ceramides before putting the mice on a high-fat diet prevented weight gain and insulin resistance.
Although the impact of lowering ceramides in humans is still unknown, there is evidence that ceramides are linked to metabolic disease, says Summers. He points out that clinics are already performing ceramide screening tests to gauge an individual’s risk for developing heart disease.
Summers and Kelley are now developing drugs that inhibit DES1 with a goal of making new therapeutics. “This project provides substantial validation that this is a discreet and highly effective point of intervention,” says Kelley.
When the good goes bad
If ceramides cause poor health, why do we have them in the first place? Summers’ group addressed the question by measuring how the lipid affects metabolism. They found that ceramides trigger a number of mechanisms that promote the storage of fat in cells. They also impair cells’ ability to use glucose, a type of sugar, as fuel.
The evidence for these effects includes activation of a molecular pathway, Akt/PKB, that inhibits both the ability of cells to synthesize sugars and to take them up from the bloodstream. At the same time, ceramides slow the turnover of fatty acids in part by causing cells in the liver to increase fatty acid storage and adipose tissue to burn less fat.
The shift in how cells use fuel is an advantage in the short-term, says Summers. This is because ceramides have another role in stiffening the cell membrane and promoting fat storage increases production of ceramides. These data suggest that one benefit of ceramides is to protect the cell. When food is plentiful and cells engorge with fat, increasing ceramide levels strengthens the cells’ outer membrane, preventing ruptures.
“Serving in this role is usually good but it can potentially be bad,” explains Trevor Tippetts, a graduate student in Summers’ lab. He, U of U Health research assistant professor Bhagirath Chaurasia, and two of their Merck colleagues, Rafael Mayoral Moñibas, and Jinqi Liu, share lead authorship.
Tippetts explains that problems arise in times of chronic overabundance, such as during obesity, when there are persistently high levels of ceramides. The sustained shift toward fat storage and away from using sugar as fuel leads to fatty liver disease and insulin resistance.
“We think our results are telling us that ceramides evolved to become a nutritional sensor,” saysChaurasia. He says that ceramidesserve as a signal, helping the body to cope when the amount of fat coming into cells exceeds energetic needs and storage capacity.
These findings are leading to a deep understanding of how cells in the body assess nutrient status and adjust their behavior accordingly.