The yellow molecule is messanger RNA (mRNA); it leaves the nucleus; at the ribosome, ribosomal RNA (rRNA) binds to mRNA; transfer RNA or tRNA (in green) can read the three letter code on mRNA or codon; each codon codes for one animo acid (red molecule attached to tRNA); the sequence of codons on the mRNA determines the sequence of amino acids in the protein, which in turn determines the structure and function of the protein.
Duration: 3 minutes, 3 seconds
The job of this mRNA is to carry the genes message from the DNA out of the nuceus to a ribosome for production of the particular protein that this gene codes for. There can be several million ribosomes in a typical eukaryotic cell these complex catalytic machines use the mrna copy of the genetic information to assemble amino acid building blokes into the three dimensional proteins that are essential for life. Lets see how it works. The ribosome is composed of one large and one small sub-unit that assemble around the messenger RNA, which then passes through the ribosome like a computer tape. The amino acid building blocks (that's the small glowing red molecules) are carried into the ribosome attached to specific transfer RNAs. That's the larger green molecules also referred to as tRNA. The small sub-unit of the ribosome positions the mRNA so that it can be read in groups of three letters known as a codon. Each codon on the mRNA matches a corresponding anti-codon on the base of a transfer RNA molecule.The larger sub-unit of the ribosome removes each amino acid and join it onto the growing protein chain. As the mRNA is ratcheted through the ribosome, the mRNA sequence is translated into an amino acid sequence. There are three locations inside the ribosome, designated the A-site, the P-site and the E-site. The addition of each amino acid is a three step cycle: First, the tRNA enters the ribosome at the A-site and is tested for a codon/anti-codon match with the mRNA. Next, provided there is a correct match, the tRNA is shifted to the P-site and the amino acid it carries is added to the end of the amino acid chain. The mRNA is also ratcheted on three nucleotides or one codon. Thirdly, the spent tRNA is moved to the E-site and then ejected from the ribosome to be recycled. As the protein synthesis proceeds, the finished chain emerges from the ribosome. It folds up into a precise shape, determined by the exact order of amino acids. Thus the Central Dogma explains how the four letter DNA code is - quite literally - turned into flesh and blood.
messanger rna, protein translation, ribosomal rna, sequence of amino acids, codons, trna, rrna, structure and function, molecule
Translation: RNA to protein, 3D animation with no audio
3D animation of translation: RNA to protein.
Francis Crick describes RNA and its role and Paul Zamecnick explains protein synthesis.
Several researchers crack the genetic code.
After decoding the "easy" codons, Marshall Nirenberg talks about his strategy for decoding the rest.
In this section learn that in the cytoplasm, the messenger RNA is released from its carrier proteins and binds to a protein assembly complex called a ribosome.
What happens in protein synthesis?
The Central Dogma is the flow of genetic information from DNA, to RNA, to protein.
An animation shows how the DNA genetic "code" is made into protein.
Small image depicting translation.