In the year 2150, in the ultra-advanced Bio-Lab, young scientist Ashton and his AI assistant Z embark on a mission to synthesize a protein that could cure a rare space disease. They must follow the exact steps of protein synthesis to succeed.


With a microscpe, Ashton examines a single nucleotide. He carefully labels its sugar, phosphate, and base. He then examines a 9-base pair DNA molecule, ensuring each nitrogenous base has the correct complementary partner (A-T, C-G). Through the microscope, He sees the DNA’s double helix structure.
Inside the cell

Ashton zooms in on a cell model projected on his lab screen. He identifies and labels the nucleus, cell membrane, and ribosome, understanding their roles in protein synthesis. Inside the nucleus, He locates the DNA, the master blueprint of life.

Using a specialized enzyme, RNA polymerase, Ashton watches as a single strand of mRNA is transcribed from the DNA. The base sequence appears, but instead of thymine (T), uracil (U) is used. The strand is exactly 9 bases long, matching the DNA’s template
The mRNA blueprint, now complete, exits the nucleus through a membrane portal and heads toward the ribosome, the protein-building factory located in the cytoplasm.

The ribosome locks onto the mRNA strand and begins reading it in groups of three nucleotides (codons). Ashton highlights the codons by marking every three bases.

Three tRNA molecules arrive at the ribosome, each carrying a specific amino acid. The anticodons on tRNA match perfectly with the codons on mRNA.

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In the year 2150, in the ultra-advanced Bio-Lab, young scientist Ashton and his AI assistant Z embark on a mission to synthesize a protein that could cure a rare space disease. They must follow the exact steps of protein synthesis to succeed.


With a microscpe, Ashton examines a single nucleotide. He carefully labels its sugar, phosphate, and base. He then examines a 9-base pair DNA molecule, ensuring each nitrogenous base has the correct complementary partner (A-T, C-G). Through the microscope, He sees the DNA’s double helix structure.
Inside the cell

Ashton zooms in on a cell model projected on his lab screen. He identifies and labels the nucleus, cell membrane, and ribosome, understanding their roles in protein synthesis. Inside the nucleus, He locates the DNA, the master blueprint of life.

Using a specialized enzyme, RNA polymerase, Ashton watches as a single strand of mRNA is transcribed from the DNA. The base sequence appears, but instead of thymine (T), uracil (U) is used. The strand is exactly 9 bases long, matching the DNA’s template
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