Lesson: Chapter - 6

Protein Synthesis

Now that we’ve described DNA and RNA, it’s time to take a look at the process of protein synthesis. The synthesis of proteins takes two steps: transcription and translation. Transcription takes the information encoded in DNA and encodes it into mRNA, which heads out of the cell’s nucleus and into the cytoplasm.During translation, the mRNA works with a ribosome and tRNA to synthesize proteins.

Video Lesson - Transcription

The first step in transcription is the partial unwinding of the DNA molecule so that the portion of DNA that codes for the needed protein can be transcribed. Once the DNA molecule is unwound at the correct location, an enzyme called RNA polymerase helps line up nucleotides to create a complementary strand of mRNA. Since mRNA is a single-stranded molecule,only one of the two strands of DNA is used as a template for the new RNA strand.

• DNA cytosine pairs with RNA guanine
• DNA guanine pairs with RNA cytosine
• DNA thymine pairs with RNA adenine
• DNA adenine pairs with RNA uracil

Example

The mRNA complement to the DNA sequence TTGCAC is AACGUG. The SAT II Biology frequently asks about the sequence of mRNA that will be produced from a given sequence of DNA.For these questions, don’t forget that RNA uses uracil in place of thymine.

After transcription, the new RNA strand is released and the two unzipped DNA strands bind together again to form the double helix. Because the DNA template remains unchanged after transcription, it is possible to transcribe another identical molecule of RNA immediately after the first one is complete. A single gene on a DNA strand can produce enough RNA to make thousands of copies of the same protein in a very short time.

Translation

In translation, mRNA is sent to the cytoplasm, where it bonds with ribosomes, the sites of protein synthesis. Ribosomes have three important binding sites:one for mRNA and two for tRNA. The two tRNA sites are labeled the A site and P site.

Video Lesson - The Process of Translation

Once the mRNA is in place, tRNA molecules, each associated with specific amino acids, bind to the ribosome in a sequence defined by the mRNA code. tRNA molecules can perform this function because of their special structure. tRNA is made up of many nucleotides that bend into the shape of a cloverleaf. At its tail end, tRNA has an acceptor stem that attaches to a specific amino acid. At its head, tRNA has three nucleotides that make up an anticodon.

An anticodon pairs complementary nitrogenous bases with mRNA. For example if mRNA has a codon AUC, it will pair with tRNA’s anticodon sequence UAG. tRNA molecules with the same anticodon sequence will always carry the same amino acids, ensuring the consistency of the proteins coded for in DNA.

The Process of Translation

Translation begins with the binding of the mRNA chain to the ribosome. The first codon, which is always the start codon methionine, fills the P site and the second codon fills the A site. The tRNA molecule whose anticodon is complementary to the mRNA forms a temporary base pair with the mRNA in the A site. A peptide bond is formed between the amino acid attached to the tRNA in the A site and the methionine in the P site.

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