How the amino acid leucine helps our cells produce energy


Mitochondria are responsible for maintaining the cell’s supply of energy.

Mitochondria are responsible for maintaining the cell’s supply of energy.
| Photo Credit: Image created with AI

Proteins in the cells in our body perform functions of value to the sustenance and growth of organs. There are more than 20 amino acids, which are the building blocks of proteins, and the sequence of these amino acid chains generates the structure and function of each protein in the cells.

Several of these amino acids play vital roles in specific functions. For example, an amino acid called glycine is vital for blood cells. Leucine is an essential amino acid involved in muscle growth, tissue repair, and energy production. The body has eight other essential amino acids that the body cannot produce on its own. They need to be supplied to the organs from outside for them to function.

The energy for each organ is generated by cellular components called the mitochondria (in Ancient Greek, ‘mito’ means thread-like and ‘chondrion’ means granule). These are unique, thread-like organelles present in the thousands per cell. They are the gatekeepers of energy in most organs in our body.

Mitochondria are responsible for maintaining the cell’s supply of energy, by producing the molecule adenosine triphosphate (ATP), which is the energy currency of the cell. Mitochondria are thus the battery of the cell, charging it using ATP. The connection between the mitochondrion and the parent cell is vital, since during oxidation and respiration, the membrane of this cellular organelle can be degraded, causing a loss in cellular function.

For example, the adult human heart has more than 2 billion muscle cells that work non-stop, and each of these cells has 5,000-8,000 mitochondria. Most of the energy required for the pumping of the heart comes from these mitochondria.

Every organ in the body needs adequate energy to function normally. When an organ needs more energy, new mitochondria are made, while at the same time increased wear and tear necessitates the degradation of some mitochondria.

The proteins that make up mitochondria are degraded during the process. Critically, the outer mitochondrial membrane proteins should not be lost, and methods should be found to prevent excessive degradation. Scientists have been searching for ways to prevent these outer walls from breaking down completely under stress, as this can lead to metabolic and age-related diseases.

Role of leucine in protecting cells

A ball and stick model of a leucine molecule. The black orbs are carbon atoms, white orbs are hydrogen, red orbs are oxygen, and the blue ball is a nitrogen atom.

A ball and stick model of a leucine molecule. The black orbs are carbon atoms, white orbs are hydrogen, red orbs are oxygen, and the blue ball is a nitrogen atom.
| Photo Credit:
Public domain

It is here that the essential amino acid leucine becomes valuable. It belongs to the family of branched chain amino acids (BCAA) such as isoleucine and valine, which are needed for the growth and functioning of organs such as muscles, nervous system, the heart, and the brain.

BCAAs are not made in the body and need to be supplied from our diet. Without them, the outer membrane of the mitochondrion cannot be properly constructed or maintained. A study last year (Nature Cell Biology, 1889-1901, November 27, 2025)by a group from the University of Cologne Centre for Excellence Cluster on Aging and Aging-Associated Diseases, Germany, used the small roundworm Caenorhabditis elegansas the model organism to work with. Their results showed that the BCAA leucine acts like a protective shield and inhibits the premature degradation of outer mitochondrial membrane proteins. This is done by leucine interacting with a protein called SEL1L, which has a role in recognising and pulling out damaged or misfolded proteins.

Thus, leucine offers both protection and more energy to cells and organs. Whether other BCAAs also play such valuable roles in cell protection will be worth studying.

 dbala@lvpei.org

  • Related Posts

    Finerenone helps slow kidney disease in patients without diabetes

    In chronic kidney disease, the kidneys gradually lose their ability to filter waste from the blood. While diabetes is one of its leading causes, many patients develop the condition because…

    Continue reading
    Financial services AI dangers highlighted by UK regulator’s review

    Britain’s financial regulator has been urged to ‌consider regulation of large language models such as ChatGPT, Claude and Gemini because ​of their growing influence on consumer financial decisions. In a…

    Continue reading

    Leave a Reply

    Your email address will not be published. Required fields are marked *