It’s not just how much you eat, how much you exercise, or what specific diet plan you choose to use—appetite and consequently weight management is also controlled by hormones. Some of these you may have heard of—others probably are new to you.
These “hunger hormones,” as they are often called, include leptin, ghrelin, peptide YY, neuropeptide YY, cortisol, adiponectin, glucagon-like peptide-1(GLP-1), and cholecystokinin. The “major” players—at least based on what we know now—are leptin, ghrelin, cholecystokinin, GLP-1, and adiponectin.
Defining Hormones
Hormones are a type of chemical messenger between cells, tissues, and organs and generally are the regulatory actors for the complex physiological actions of plants and multicellular organisms. There are three types of hormones—the protein or polypeptide (or peptide) hormones, the steroid hormones, and those derived from amino acids—the basic building block of proteins. These hormones may couple with a receptor on the surface of a cell or actually enter a cell and interact with an intracellular receptor—these may then either activate or de-activate a gene within the cell’s nucleus.
The Brain’s Role in Controlling Appetite
The brain(1) is the ultimate controller of appetite. Various regions of the brain interact in complex ways to control behavior, decision-making, reward, sensory influences (e.g., smell or taste), and learning around appetite. Satiety is the sense that you are full.
Regions of the brain such as the thalamus, hypothalamus, and brainstem detect the energy available to the body and help regulate both hunger and appetite. Hunger is the physical feeling that you need to eat, while appetite is the desire to eat something and how much of that something you are going to put away. Hunger is based on body processes, while appetite may be influenced by emotional, social, and other environmental factors.
The Most Important Hormones Controlling Appetite (As We Know It Now…)
As the science progresses, there may be new hormones added to the list—and potentially, some may be more critical as we learn of their role in controlling appetite. For now, here is a description of the most important active hormones(2) in appetite control.
Leptin: Leptin sends the signal of “I have no appetite” to the brain and brainstem. It is primarily made by adipose (fat) cells, with some produced by intestinal cells. Leptin inhibits hunger by acting on cells found in various regions of the brain including the hypothalamus—that is why it is often called the “satiety hormone”. Its primary role is to regulate fat cell storage, but leptin can also affect the immune system, new vascular growth, both male and female fertility, male and female puberty, and bone mass.
Perhaps confusingly, leptin levels tend to be high in obese individuals and lower in thin individuals. Obese individuals are considered to be leptin resistant—this is similar to the insulin resistance seen in pre-diabetes and diabetes. Leptin resistance indicates that the cells of the body have lost the responsiveness to leptin—in obesity, the fat cells keep on making leptin, but the brain cells don’t seem to respond by decreasing hunger. Leptin resistance results in constant hunger and increased food intake—usually leading to MORE weight gain and MORE adipocytes producing MORE leptin—it becomes a sort of vicious weight-gain cycle. This scenario may also explain why diets—especially demanding diets—don’t work for the long term. Leptin resistance combined with behavioral reactions seems to make it all seem impossible!
In thin or normal weight people, leptin levels tend to be directly based on the amount of fat cells in the body—and thin or normal weight people tend to be sensitive to the levels of leptin produced by the fat cells, resulting in more appropriate hunger signals.
Ghrelin is produced by the stomach, with some synthesized by the pancreas, small intestine, and brain. Ghrelin is called the “hunger hormone” because it stimulates appetite, food intake, and the growth of fat storage. It acts on the hypothalamus but also appears to act in the brain’s reward processing—further enhancing food intake. Ghrelin(3) production is regulated by meal routines and food intake—ghrelin levels increase when hungry or during times of fasting and decrease by eating. Ghrelin is also involved in insulin secretion and the control of blood sugar levels.
Cholecystokinin, or CCK, is produced by the small intestine and increases the release of digestive enzymes. However, it also acts as an appetite suppressant by binding to cells in various areas of the brain. CCK is released at especially high levels when you eat a fatty meal—this may be why eating fatty meals is often seen as a pleasant experience—by activating reward centers in the brain. CCK(4) can also slow down digesting, increasing the sense of feeling full.
Adiponectin is involved in regulating blood sugar levels and in the breakdown of fatty acids. It is made by adipocytes—and the human placenta. Adiponectin(5) can increase insulin sensitivity and can act in concert with leptin, including increasing weight loss.
Glucagon-like peptide-1, or GLP-1, is produced by cells in the small intestine and by neurons within the brainstem. Most effects of GLP-1 may be particularly important in diabetes because it can promote the secretion of insulin and helps support the body’s synthesis of insulin by the pancreatic beta cells. It also promotes satiety or the sense of having had enough to eat. Finally (well, again for now…), GLP-1(6) reduces appetite by slowing down digestion.
Putting All this Information into a Weight Loss Plan
The complex interaction of these (and other) hormones makes weight loss—and importantly—weight maintenance a long-term and sometimes difficult process. There is no single, easy solution, but it is clear that long-term weight maintenance depends on controlling appetite, eating healthy foods, and increasing activity levels…also known as exercising!
What we DO know is if you try the following—mixed as works for you—you should have some success in controlling your appetite and hunger, losing weight and maintaining that weight loss.
Use Natural Appetite Inhibitors
To see if you are REALLY hungry as opposed to looking for comfort food, or seeing the ice cream truck drive past, or feeling bored, angry, or anxious, test yourself by asking these three questions(7):
- Is your stomach grumbling, rumbling, or just making noise?
- Do you feel low energy?
- Are you feeling cranky or dealing with brain fog?
- Stick with whole foods with lots of fiber—this includes vegetables, fruits, grains with the bran (e.g., brown rice instead of white rice), nuts, and seeds.
- Avoid red meats and increase leaner meats, poultry, and fish.
- More of your plate should contain vegetables, non-refined carbohydrates, fruit, nuts and seeds than meat.
- Avoid fast foods, junk foods and processed foods.
- Cook from “scratch” whenever you can!
If any of those things apply, you probably need to eat. If so, then try these approaches. General guidelines are listed in the box.
- Foods that contain healthy fats and high protein tend to suppress the appetite.
- High-protein foods include lean meats, yogurt, eggs, beans, peas and legumes, and soy products
- Eat high-fiber foods. These fill you up faster, take longer to digest, AND helps regulate bowel movements. High fiber foods include whole grains, beans, peas and legumes, fruit especially with the skin on, vegetables, nuts, and seeds.
- Drink plenty of water before, during, and after meals, but especially before your meal.
- Don’t try to change everything you eat in one day—take your time adjusting your food intake and dietary choices to minimize the chance of turning to binge eating, or getting frustrated and giving up.
- Eat smaller, more frequent meals
There are LOTS of fads and established diets out there—avoid the ones that seem difficult to you—you are less likely to stick to them than to others. Keep the guidelines listed in the box in mind no matter which diet plan you choose.
Other approaches
- OK—this definitely comes under the heading of “Easier said than done,” but do try and keep your stress levels to a minimum. To reduce stress, consider professional therapy giving you options to control stress, meditation, prayer, increasing both relaxation time and rest time, and trying to get more sleep!
- Exercise—especially high-intensity workouts(8), suppresses ghrelin secretion and can help control appetite.
That’s it for now!
Resources:
- Ahn BH, Kim M, Kim SY. Brain circuits for promoting homeostatic and non-homeostatic appetites. Experimental & Molecular Medicine. 2022 Apr;54(4):349-57. https://www.nature.com/articles/s12276-022-00758-4
- Montégut L, Lopez-Otin C, Magnan C, Kroemer G. Old paradoxes and new opportunities for appetite control in obesity. Trends in Endocrinology & Metabolism. 2021 May 1;32(5):264-94. https://endocrinologia.org.mx/pdf_socios/20_Old_Paradoxes_NewOpportunities_appetite_control_obesity.pdf
- Pradhan G, Samson SL, Sun Y. Ghrelin: much more than a hunger hormone. Curr Opin Clin Nutr Metab Care. 2013 Nov;16(6):619-24. doi: 10.1097/MCO.0b013e328365b9be. PMID: 24100676; PMCID: PMC4049314. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4049314/
- Warrilow A, Turner M, Naumovski N, Somerset S. Role of cholecystokinin in satiation: a systematic review and meta-analysis. British Journal of Nutrition. 2022 Feb 14:1-25. https://www.cambridge.org/core/journals/british-journal-of-nutrition/article/role-of-cholecystokinin-in-satiation-a-systematic-review-and-metaanalysis/116421BC63C927C05C53A33860B95C09
- Khoramipour K, Chamari K, Hekmatikar AA, Ziyaiyan A, Taherkhani S, Elguindy NM, Bragazzi NL. Adiponectin: Structure, physiological functions, role in diseases, and effects of nutrition. Nutrients. 2021 Apr 2;13(4):1180. https://www.mdpi.com/2072-6643/13/4/1180/pdf
- Drucker DJ. GLP-1 physiology informs the pharmacotherapy of obesity. Molecular Metabolism. 2021 Oct 6:101351. https://www.sciencedirect.com/science/article/pii/S2212877821001988
- https://iamherbalifenutrition.com/healthy-weight/control-hunger/
- Schubert, M.M., Sabapathy, S., Leveritt, M. et al. Acute Exercise and Hormones Related to Appetite Regulation: A Meta-Analysis. Sports Med 44, 387–403 (2014). https://doi.org/10.1007/s40279-013-0120-3 https://link.springer.com/article/10.1007/s40279-013-0120-3