Scientists have developed experimental compounds that prompt the mitochondria inside cells to use more energy and burn additional calories. This early research suggests a possible new path toward treating obesity while also supporting better metabolic health.
Obesity affects people worldwide and raises the risk of serious conditions such as diabetes and cancer. Many current weight loss medications require injections and can lead to unwanted side effects. A safer method for increasing calorie burn could therefore have major benefits for public health.
The study was led by Associate Professor Tristan Rawling of the University of Technology Sydney (UTS) and was recently published in Chemical Science, the flagship journal of the UK Royal Society of Chemistry. The research was also recognized as a "pick of the week."
How Mitochondrial Uncouplers Work
The research team, which included scientists from UTS and Memorial University of Newfoundland in Canada, focused on compounds known as "mitochondrial uncouplers." These molecules cause cells to use fuel less efficiently, releasing some of that energy as heat instead of converting it into usable power.
"Mitochondria are often called the powerhouses of the cell. They turn the food you eat into chemical energy, called ATP or adenosine triphosphate. Mitochondrial uncouplers disrupt this process, triggering cells to consume more fats to meet their energy needs," said Associate Professor Rawling.
He compared the process to a hydroelectric system. "It's been described as a bit like a hydroelectric dam. Normally, water from the dam flows through turbines to generate electricity. Uncouplers act like a leak in the dam, letting some of that energy bypass the turbines, so it is lost as heat, rather than producing useful power."
A Dangerous History of Weight Loss Chemicals
Substances that interfere with mitochondrial energy production were first identified about a century ago. However, the earliest versions were extremely dangerous and caused severe overheating that could be fatal.
"During World War I, munitions workers in France lost weight, had high temperatures and some died. Scientists discovered this was caused by a chemical used at the factory, called 2,4-Dinitrophenol or DNP," said Associate Professor Rawling.
"DNP disrupts mitochondrial energy production and increases metabolism. It was briefly marketed in the 1930's as one of the first weight-loss drugs. It was remarkably effective but was eventually banned due to its severe toxic effects. The dose required for weight loss and the lethal dose are dangerously close," he said.
Designing Safer Mild Uncouplers
In the new study, researchers aimed to overcome these risks by creating safer versions known as "mild" mitochondrial uncouplers. They carefully modified the chemical structure of experimental molecules, allowing them to control how strongly the compounds increased energy use inside cells.
Some of these experimental drugs successfully raised mitochondrial activity without damaging cells or interfering with ATP production. Others behaved more like the older toxic compounds, producing dangerous levels of uncoupling.
By comparing these outcomes, the researchers were able to identify why the safer molecules acted differently. Mild mitochondrial uncouplers slow the process to a level that cells can tolerate, reducing the risk of harmful side effects.
Beyond Weight Loss Potential Benefits
Mild mitochondrial uncouplers also appear to lower oxidative stress within cells. This reduction could support healthier metabolism, slow certain aging-related processes, and help protect against neurodegenerative conditions such as dementia.
Although the research is still in its early stages, the findings provide a roadmap for developing a new generation of drugs. These future treatments could harness the advantages of mild mitochondrial uncoupling while avoiding the dangers that plagued earlier approaches.
Reference:
Ethan Pacchini, Daniel A. McNaughton, Aaron Pye, Katie A. Wilson, Philip A. Gale, Tristan Rawling. The role of transmembrane proton transport rates in mild mitochondrial uncoupling by arylamide substituted fatty acids. Chemical Science, 2026; DOI: 10.1039/D5SC06530E
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