The Whole History of the Earth and Life 　Part3:Birth of Proto-life

Hadean Bioscience

4 Jun 201704:10

Summary

TLDRThe script narrates the hypothesis of early life's emergence on Earth, suggesting life began underground in geysers' caves shielded from sunlight. Uranium ore radiation fostered biomolecule formation, protected by reductive underground and oxidizing surface conditions. Wet-dry cycles were pivotal, leading to the encapsulation of proto-life molecules by fatty acids, forming ribozymes capable of self-replication. These eventually enclosed in lipid membranes, marking the dawn of primitive cellular life.

Takeaways

🌏 The early Earth had an atmosphere that blocked sunlight from reaching the surface, suggesting an environment conducive to the emergence of primitive life underground.
💡 The cave of a geyser, rich in uranium ore, emitted radiation that contributed to the creation of diverse materials and early building blocks of life.
🌡 The temperature in the geyser water remained below 100 degrees Celsius, which was critical for protecting the newly formed biomolecules from destruction.
🌊 Water circulation between the underground and the surface, driven by the geyser, facilitated the synthesis of biomolecules in both reductive and oxidizing conditions.
🌀 Tidal forces on early Earth were significantly stronger than today, leading to wet and dry cycles that were essential for the formation of life's building blocks.
🧬 Fatty acids encapsulated proto life molecules, and polymerization occurred under the influence of wet and dry cycles, leading to the creation of protein-like materials.
🔬 These protein-like materials acted as catalysts and circulated between the geyser caves and the surface, interacting to form more complex biomolecules.
🧬 Proto RNA combined with enzyme-like materials to evolve into ribozymes, which had the ability to replicate themselves, marking a significant step towards life's reproduction.
💧 The enclosure of these replicating molecules within lipid membranes led to the formation of primitive proto cellular life, a crucial stage in the origin of life.
🚀 The described process in the script outlines a hypothesis for the beginning of life on Earth, highlighting the importance of geological and environmental factors.

Q & A

What was the condition of the early Earth's atmosphere that affected sunlight penetration?
-The early Earth's atmosphere was dense, which prevented sunlight from reaching the surface.
Where did primitive life begin to emerge according to the script?
-Primitive life began to emerge underground in the cave of a geyser.
What role did uranium ore play in the formation of early life's building blocks?
-Uranium ore emitted large amounts of radiation, which helped create a diverse range of materials and eventually produced the early building blocks of life.
Why did the water from the geyser boil and rise to the surface?
-The boiling and rising of water to the surface were part of the natural nuclear reactor process within the geyser.
How did the temperature of the geyser water affect the formation of biomolecules?
-The temperature of the geyser water remained below 100 degrees, which protected the newly formed biomolecules from being destroyed by high heat.
What was the environmental condition of the underground compared to the surface?
-The underground environment was reductive, while the surface environment was oxidizing, both of which were necessary for the synthesis of biomolecules.
What were the Hadiya tidal forces and how did they contribute to life's emergence?
-The Hadiya tidal forces were pronounced on early Earth, even causing significant urban flow of water in lakes, creating wet and dry cycles that were crucial for producing the building blocks of life.
How did fatty acids contribute to the development of proto life?
-Fatty acids came together to encase proto life molecules, allowing polymerization to progress under wet and dry cycles, eventually leading to the production of protein-like basic materials that could act as catalysts.
What interaction led to the formation of more complex biomolecules?
-The circulation of materials between the geyser caves and the surface environment led to interactions that resulted in the formation of more complex biomolecules.
How did proto RNA evolve into a form capable of self-replication?
-Proto RNA combined with enzyme-like basic materials and evolved into ribozymes, which had the ability to replicate themselves, laying the groundwork for life to reproduce.
What was the final step in the formation of primitive proto cellular life?
-The final step was the enclosure of these self-replicating molecules within lipid membranes, forming primitive proto cellular life.