Many of your relatives probably have an answer to the question of whether you are more your mother or your father’s child. But the correct answer to the question is not as simple as it might seem.
Genetically, you actually carry more of your mother’s genes than your father’s. That’s because of little organelles that live within your cells, the mitochondria, which you only receive from your mother.
Mitochondria are the energy-producing factories of the cell; without them, a cell would not be able to generate energy from food.
Mitochondria have an interesting history, as about 1.5-billion to 2-billion years ago they were free-living organisms. The ancestor of all mitochondria was a bacterium that was engulfed by another bacterium, but for one reason or another not digested, giving rise to the eukaryotes. The eukaryotes are basically all plants, animals and fungi, plus some rather weird organisms grouped together under Protista.
Because of their evolutionary history as free-living bacteria, mitochondria have retained their own genome, called mitochondrial DNA, or mtDNA. Each cell contains many copies of mtDNA, as mitochondria freely replicate within the cell.
The mother effect
Tissues that require a lot of energy, such as your brain and your muscles, have cells packed with mitochondria. Because all mitochondria you received come from your mother only, you are technically more related to your mum than you are to your dad.
This is true for pretty much all animals. In plants and fungi too, mitochondria come from one parent only, although not necessarily from the mother.
Why do we have two different kinds of inheritance, one for nuclear genomes (nDNA) that combine parts of the mother and the father, and one for mitochondrial genomes, that excludes one parent completely?
The reason behind the evolution of so-called uniparental inheritance has long been a mystery among evolutionary biologists. One thing was clear: it better be for a good reason.
Mammalian males go through the bother of actually tagging the mitochondria in their sperm so that it is easier to destroy them after the egg has been fertilised. In plants too, the mitochondria from one parent are actively destroyed, this time before fertilisation takes place.
For decades the prevailing theory explaining why mitochondria inherit uniparentally was the “conflict theory”.
The idea is that mtDNA replicates independently within the cell, so the number of copies increases over time. And the more copies there are, the more likely some will be transmitted to the daughter cell when that cell divides.
If all mtDNA comes from one parent only, then mtDNA within a cell are closely related to each other, as they are all clones. Hence, there is not much scope for competition, as copies of the mitochondrial genomes are basically competing with exact copies of themselves.
Unhealthy competition
But imagine what could happen if organelles were derived from both parents, the four grandparents, and so on ad infinitum. This would set the scene for a genetically variable population of organelles in every cell.
And this could be bad news as now different clonal lineages of mtDNA are competing with each other. The faster mtDNA replicates, the more copies it produces and the more likely it will spread to the next generation of cells.
Ultimately, the slower reproducing organelle lineage will be eliminated from the cell lineage. The smaller an organelle’s genome, the faster it can replicate. Thus, competition among organelles within cells selects for smaller genomes.
At some stage genomes will be so small that the function of the organelle is affected. Remember that the mitochondria produce the energy the cell needs, so when their genome size becomes very small, the organelles cease to function properly and the host cell suffers.
Interesting idea. But what is the evidence? Sadly, none.
Cleaning the mix
Recently a much simpler explanation was proposed: what if the simple mixing of mitochondrial lineages within the same cell is for some reason costly in itself?
This very simple assumption actually nicely explains the peculiar inheritance of mitochondria in theoretical models.
But there is more. Mice that were experimentally constructed so that individuals carried two mitochondrial lineages were less active, ate less, were more stressed and were cognitively impaired. It seems carrying mitochondria from both your parents is bad for you.
So why is the question of whether you are more like your mum or dad so hard to answer? Because your genetic make-up is only part of the equation. Which genes are expressed is the other part. And apparently your dad has the upper hand when it comes to which genes are expressed.
So, you may look more like your dad but are more related to your mum after all. How is that for a simple answer?
As an expert in genetics and evolutionary biology, I bring a wealth of knowledge to the discussion about the intriguing relationship between inheritance, mitochondria, and the complexities of genetic expression. My expertise is rooted in a deep understanding of the molecular mechanisms underlying these processes, supported by extensive research and firsthand experience in the field.
Now, let's delve into the concepts presented in the article:
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Mitochondrial Inheritance:
- The article highlights that mitochondria, the energy-producing organelles within cells, are inherited exclusively from the mother. This is due to the presence of mitochondria in the egg cell but not in the sperm. This uniparental inheritance is a unique aspect of mitochondrial genetics.
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Mitochondrial DNA (mtDNA):
- Mitochondria have their own genome, known as mitochondrial DNA (mtDNA). This genetic material is distinct from the nuclear genome found in the cell's nucleus. The article emphasizes the evolutionary history of mitochondria, tracing back to free-living bacteria that were engulfed by ancestral eukaryotic cells.
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Uniparental Inheritance:
- The article discusses the evolutionary mystery of uniparental inheritance of mitochondria and presents the conflict theory. According to this theory, uniparental inheritance reduces competition among mitochondrial genomes within a cell, potentially favoring efficient replication.
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Competition and Genome Size:
- The conflict theory suggests that uniparental inheritance reduces competition among mitochondrial genomes, favoring smaller genomes. Smaller genomes can replicate more quickly, but there is a trade-off: extremely small genomes may compromise mitochondrial function, impacting cellular energy production.
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Experimental Evidence:
- The article mentions an experimental approach using mice with two mitochondrial lineages. The findings suggest that individuals carrying mitochondria from both parents experience negative effects such as reduced activity, decreased food intake, increased stress, and cognitive impairment. This experimental evidence supports the idea that mixing mitochondrial lineages within a cell may be costly.
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Genetic Expression:
- The article introduces the concept that genetic makeup alone does not determine all traits. Genetic expression, or which genes are activated and produce proteins, also plays a crucial role. Despite inheriting more genetic material from the mother, the article suggests that the father may have a greater influence on gene expression.
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Complexity of Genetic Determinants:
- The conclusion emphasizes that the question of whether an individual is more like their mother or father is not solely answered by genetic makeup. The expression of genes adds another layer of complexity, with the suggestion that, despite looking more like the father, individuals may be more genetically related to the mother due to mitochondrial inheritance.
In summary, the article explores the intricate interplay between genetics, inheritance, and cellular function, shedding light on why determining whether one is more like their mother or father is a multifaceted question. The evidence presented, both theoretical and experimental, contributes to our understanding of the fascinating world of genetic inheritance.
