The Experiment
I've received several e-mails from readers about a recent experiment by nutrition professor Mark Haub at Kansas State university (thanks to Josh and others). He ate a calorie-restricted diet in which 2/3 of his calories came from junk food: Twinkies, Hostess and Little Debbie cakes, Dorito corn chips and sweetened cereals (1). On this calorie-restricted junk food diet (800 calorie/day deficit), he lost 27 pounds in two months.
Therefore, junk food doesn't cause fat gain and the only thing that determines body fatness is how much you eat and exercise. Right?
Discussion
Let's start with a few things most people can agree on. If you don't eat any food at all, you will lose fat mass. If you voluntarily force-feed yourself with a large excess of food, you will gain fat mass, whether the excess comes from carbohydrate or fat (2). So calories obviously have something to do with fat mass.
But of course, the situation is much more subtle in real life. Since a pound of body fat contains roughly 3,500 calories, eating an excess of 80 calories per day (1 piece of toast) should lead to a weight gain of 8 lbs of fat per year. Conversely, if you're distracted and forget to eat your toast, you should lose 8 lbs of fat per year, which would eventually be dangerous for a lean person. That's why we all record every crumb of food we eat, determine its exact calorie content, and match that intake precisely with our energy expenditure to maintain a stable weight.
Oh wait, we don't do that? Then how do so many people maintain a stable weight over years and decades? And how do wild animals maintain a stable body fat percentage (except when preparing for hibernation) even in the face of food surpluses? How do lab rats and mice fed a whole food diet maintain a stable body fat percentage in the face of literally unlimited food, when they're in a small cage with practically nothing to do but eat?
The answer is that the body isn't stupid. Over hundreds of millions of years, we've evolved sophisticated systems that maintain "energy homeostasis". In other words, these systems act to regulate fat mass and keep it within the optimal range. The evolutionary pressures operating here are obvious: too little fat mass, and an organism will be susceptible to starvation; too much, and an organism will be less agile and less efficient at locomotion and reproduction. Energy homeostasis is such a basic part of survival that even the simplest organisms regulate it.
Not only is it clear that we have an energy homeostasis system, we even know a thing or two about how it works. Early studies showed that lesioning a part of the brain called the ventromedial hypothalamus causes massive obesity (3; this is also true in humans, when a disruption results from cancer). Investigators also discovered several genetic mutations in rats and mice that result in massive obesity*. Decades-long research eventually demonstrated that these models have something in common: they all interfere with an energy homeostasis circuit that passes information about fat mass to the hypothalamus via the hormone leptin.
The leptin system is a classic negative feedback loop: the more fat mass accumulates, the more leptin is produced. The more leptin is produced, the more the hypothalamus activates programs to reduce hunger and increase energy expenditure, which continues until fat mass is back in the optimal range. Conversely, low fat mass and low leptin lead to increased hunger and energy conservation by this same pathway**.
So if genetic mutants can become massively obese, I guess that argues against the idea that voluntary food intake and energy expenditure are the only determinants of fat mass. But a skeptic might point out that these are extreme cases, and such mutations are so rare in humans that the analogy is irrelevant.
Let's dig deeper. There are many studies in which rodents are made obese using industrial high-fat diets made from refined ingredients. The rats eat more calories (at least in the beginning), and gain fat rapidly. No big surprise there. But what may come as a surprise to the calorie counters is that rodents on these diets gain body fat even if their calorie intake is matched precisely to lean rodents eating a whole food diet (4, 5, 6). In fact, they sometimes gain almost as much fat as rodents who are allowed to eat all the industrial food they want. This has been demonstrated repeatedly.
How is this possible? The answer is that the calorie-matched rats reduce their energy expenditure to a greater degree than those that are allowed free access to food. The most logical explanation for this behavior is that the "set point" of the energy homeostasis system has changed. The industrial diet causes the rodents' bodies to "want" to accumulate more fat, therefore they will accomplish that by any means necessary, whether it means eating more, or if that's not possible, expending less energy. This shows that a poor diet can, in principle, dysregulate the system that controls energy homeostasis.
Well, then why did Dr. Haub's diet allow him to lose weight? The body can only maintain body composition in the face of a calorie deficit up to a certain point. After that, it has no choice but to lower fat mass. It will do so reluctantly, at the same time increasing hunger, and reducing lean mass***, muscular strength and energy dedicated to tissue repair and immune function. However, I hope everyone can agree that a sufficient calorie deficit can lead to fat loss regardless of what kind of food is eaten. Dr. Haub's 800 calorie deficit qualifies. I think only a very small percentage of people are capable of maintaining that kind of calorie deficit for more than a few months, because it is mentally and physically difficult to fight against what the hypothalamus has decided is in your best interest.
My hypothesis is that, in many people, industrial food and an unnatural lifestyle lead to gradual fat gain by dysregulating the energy homeostasis system. This "breaks" the system that's designed to automatically keep our fat mass in the optimal range by regulating energy intake, energy expenditure and the relative partitioning of energy resources between lean and fat tissue. This system is not under our conscious control, and it has nothing to do with willpower.
I suspect that if you put a group of children on this junk food diet for many years, and compared them to a group of children on a healthy diet, the junk food group would end up fatter as adults. This would be true if neither group paid any attention to calories, and perhaps even if calorie intake were identical in the two groups (as in the rodent example). The result of Dr. Haub's experiment does not contradict that hypothesis.
So do calories matter? Yes, but in a healthy person, all the math is done automatically by the hypothalamus and energy balance requires no conscious effort. In 2010, many people have already accumulated excess fat mass. How that may be sustainably lost is another question entirely, and a more challenging one in my opinion. As they say, an ounce of prevention is worth a pound of cure. There are many possible strategies, with varying degrees of efficacy that depend highly on individual differences, but I think overall the question is still open. I discussed some of my thoughts in a recent series on body fat regulation (7, 8, 9, 10, 11).
* ob/ob and db/db mice. Zucker and Koletsky rats. Equivalent mutations in humans also result in obesity.
** Via an increase in muscular efficiency and perhaps a decrease in basal metabolism. Thyroid hormone activity drops.
*** Loss of muscle, bone and connective tissue can be compensated for by strength training during calorie restriction. Presumed loss of other non-adipose tissues (liver, kidney, brain, etc.) is probably not affected by strength training.
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