The genes you don't get from your parents (but can't live without) - Devin Shuman

TED-Ed

5 Oct 202105:03

Summary

TLDRThe script delves into the unique nature of mitochondria, our cells' second genome, which originated from an ancient symbiotic event. Mitochondria, essential for converting food and oxygen into ATP, possess their own DNA and vary significantly across species. In humans, mitochondrial DNA is maternally inherited and undergoes a dynamic replication process, affecting cellular health. Understanding mitochondria's evolution and function can offer insights into both our health and evolutionary history.

Takeaways

🧬 Mitochondria contain a distinct set of genes separate from the chromosomes inherited from our parents.
🌏 This secondary genome is found in all animals, plants, fungi, and most multicellular organisms on Earth.
🕵️‍♂️ Mitochondria are thought to have originated from a single-celled organism engulfing its ancestor about 1.5 billion years ago.
🔋 They are crucial for converting food and oxygen into ATP, the energy currency of the cell.
🩸 Mature red blood cells are an exception, lacking mitochondria to ensure oxygen delivery efficiency.
🧬 Mitochondrial DNA varies significantly across species, with mammals typically having 37 genes, plants like cucumbers up to 65, and some fungi only 1.
🧬 Mitochondria possess their own DNA, which is subject to evolution, both alongside and separate from their host organisms.
👶 Mitochondrial DNA is maternally inherited, with the sperm's mitochondria dissolving after conception.
🧬 The number of mitochondrial DNA copies inherited from our mothers can exceed 150,000, each with potential slight variations.
🧬 Mitochondrial DNA distribution within the body is random and can change throughout life due to the independent replication process of mitochondria.
🔬 Mitochondria are dynamic entities that, while influenced by their environment, also require instructions from our nuclear DNA for replication and regulation.

Q & A

What is the significance of mitochondria in our cells?
-Mitochondria are organelles within our cells that play a crucial role in converting energy from food and oxygen into ATP, a molecule that our cells can use for energy. Without this energy conversion, our cells would begin to die.
How are mitochondria different from other parts of our body?
-Mitochondria contain their own DNA, separate from the nuclear DNA inherited from our parents, and they have a unique evolutionary history, believed to have originated from an ancient engulfed single-celled organism.
Why do mitochondria have their own DNA?
-Mitochondria are thought to have evolved from a symbiotic relationship with an ancient single-celled organism, which has resulted in them retaining their own distinct genetic material.
How does the number of genes in mitochondria vary across different organisms?
-The number of genes in mitochondria can vary significantly. For example, in mammals, there are usually 37 genes, while in plants like cucumbers, there can be up to 65, and some fungal mitochondria may have only 1 gene.
Why don't mature red blood cells contain mitochondria?
-Mature red blood cells do not contain mitochondria because their primary function is to transport oxygen, and having mitochondria would consume oxygen before it could be delivered to other parts of the body.
How is mitochondrial DNA inherited?
-In almost all species, mitochondrial DNA is inherited solely from the mother. The sperm's mitochondria, which are present in small numbers, dissolve after conception, and the egg contributes thousands of mitochondria with multiple copies of mitochondrial DNA.
How does the distribution of mitochondrial DNA vary within an individual?
-The mitochondrial DNA inherited from the mother is distributed randomly throughout the body's cells as the fertilized egg divides and differentiates into tissues and organs.
What is the replication process of mitochondria in relation to our cells?
-Mitochondria have a separate replication process from the cells they inhabit. As cells divide, mitochondria are distributed to new cells, and they also undergo fusion and division on their own timeline.
How do mitochondria maintain their function and genetic integrity?
-Mitochondria can sequester faulty DNA or non-functional mitochondria for removal, ensuring that they maintain their ability to produce energy and preserve their genetic integrity.
What role do mitochondria play in our evolution and health?
-Mitochondria are still evolving and can influence our health by affecting cellular energy production. Understanding their function and evolution can provide insights into human health and our evolutionary history.
How do mitochondria interact with the nuclear DNA of the cell?
-Although mitochondria have their own genome and replicate separately, they rely on instructions from the host cell's nuclear DNA to function properly. Additionally, genes involved in building and regulating mitochondria come from both parents.