HIGH SALT PREVENTS WEIGHT GAIN IN MICE ON A HIGH FAT DIET
In a study that seems
to defy conventional dietary wisdom, University of Iowa scientists have found
that adding high salt to a high-fat diet actually prevents weight gain in mice.
As exciting as this
may sound to fast food lovers, the researchers caution that very high levels of
dietary salt are associated with increased risk for cardiovascular disease in
humans. Rather than suggest that a high salt diet is suddenly a good thing, the
researchers say these findings really point to the profound effect non-caloric
dietary nutrients can have on energy balance and weight gain.
"People focus on
how much fat or sugar is in the food they eat, but [in our experiments]
something that has nothing to do with caloric content -- sodium -- has an even
bigger effect on weight gain," say Justin Grobe, PhD, assistant professor
of pharmacology at the UI Carver College of Medicine and co-senior author of
the study, which was published in the journalScientific Reports on
June 11.
The UI team started
the study with the hypothesis that fat and salt, both being tasty to humans,
would act together to increase food consumption and promote weight gain. They
tested the idea by feeding groups of mice different diets: normal chow or
high-fat chow with varying levels of salt (0.25 to 4 percent). To their
surprise, the mice on the high-fat diet with the lowest salt gained the most
weight, about 15 grams over 16 weeks, while animals on the high-fat, highest
salt diet had low weight gain that was similar to the chow-fed mice, about 5
grams.
"We found out
that our 'french fry' hypothesis was perfectly wrong," says Grobe, who
also is a member of the Fraternal Order of Eagles Diabetes Research Center at
the UI and a Fellow of the American Heart Association. "The findings also
suggest that public health efforts to continue lowering sodium intake may have
unexpected and unintended consequences."
To investigate why the
high salt prevented weight gain, the researchers examined four key factors that
influence energy balance in animals. On the energy input side, they ruled out
changes in feeding behavior -- all the mice ate the same amount of calories
regardless of the salt content in their diet. On the energy output side, there
was no difference in resting metabolism or physical activity between the mice
on different diets. In contrast, varying levels of salt had a significant
effect on digestive efficiency -- the amount of fat from the diet that is
absorbed by the body.
"Our study shows
that not all calories are created equal," says Michael Lutter, MD, PhD,
co-senior study author and UI assistant professor of psychiatry. "Our
findings, in conjunction with other studies, are showing that there is a wide
range of dietary efficiency, or absorption of calories, in the populations, and
that may contribute to resistance or sensitivity to weight gain."
"This suppression
of weight gain with increased sodium was due entirely to a reduced efficiency
of the digestive tract to extract calories from the food that was
consumed," explains Grobe.
It's possible that
this finding explains the well-known digestive ill effects of certain fast
foods that are high in both fat and salt, he adds.
Through his research
on hypertension, Grobe knew that salt levels affect the activity of an enzyme
called renin, which is a component in the renin- angiotensin system, a hormone
system commonly targeted clinically to treat various cardiovascular diseases.
The new study shows that angiotensin mediates the control of digestive
efficiency by dietary sodium.
The clinical
usefulness of reducing digestive efficiency for treating obesity has been
proven by the drug orlistat, which is sold over-the-counter as Alli. The
discovery that modulating the renin-angiotensin system also reduces digestive
efficiency may lead to the developments of new anti-obesity treatments.
Lutter, who also is an
eating disorders specialist with UI Health Care, notes that another big
implication of the findings is that we are just starting to understand complex
interactions between nutrients and how they affect calorie absorption, and it
is important for scientists investigating the health effects of diet to analyze
diets that are more complex than those currently used in animal experiments and
more accurately reflect normal eating behavior.
"Most
importantly, these findings support continued and nuanced discussions of public
policies regarding dietary nutrient recommendations," Grobe adds.
In addition to Grobe
and Lutter, the UI research team included Benjamin Weidemann; Susan Voong;
Fabiola Morales-Santiago; Michael Kahn; Jonathan Ni; Nicole Littlejohn; Kristin
Claflin; Colin Burnett; and Nicole Pearson. The study was funded in part by
grants from the National Heart, Lung and Blood Institute, the American Diabetes
Association, and American Heart Association.
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