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Molecular Models: Exploring the Structure of tRNA

In this activity you will make a paper model of a biological molecule - tRNA. You can use an online interactive display of tRNA's atomic model and the paper model to learn about the structure and function of this molecule. The activity is presented in 3 sections:

  1. What is tRNA? - An introduction to the molecule
  2. Build a paper model of tRNA - Template and instructions for making the paper model
  3. Explore the atomic structure of tRNA - Interactive display of the atomic model of tRNA and details about its structure

1. What is tRNA?

During protein synthesis in cells, transfer RNA (tRNA) "translates" the genetic code in the messenger RNA (mRNA) into the language of proteins. Each tRNA molecule binds to a specific amino acid on the acceptor arm, recognizes its corresponding codon in the mRNA through the anticodon loop region, and delivers the amino acid to a growing peptide chain in the ribosome for protein synthesis.

To learn more, see the Molecule of the Month features on tRNA and Ribosome.

2. Build a Paper Model of tRNA

Use this PDF to build a paper model of the tRNA. As you build the model, you will see the primary structure, secondary structure and a simplified version of the tertiary structure of tRNA.

Template (PDF)

Primary Structure

Secondary Structure

Tertiary Structure (paper model)

The tRNA is a polymer which has alternating sugar and phosphate units forming a backbone for the entire molecule. Each sugar in the backbone has a base attached to it which in turn interacts with other bases in the molecule.

The yeast phenylalanine tRNA has 76 bases which provide points of interaction between various parts of the molecule. In addition to standard bases such as adenine (A), cytosine (C), uracil (U) and guanine (G), tRNA has several modified bases such as pseudouridine (Ψ) and ribothymidine (T). These modifications are a hallmark of tRNA molecules and have been studied very carefully.

Although many of the details are still unknown, the modified bases are thought to tune the function of the tRNA, for instance, in optimizing the interaction of the anticodon with the mRNA codon.

Folding Instructions

Follow the instructions in the slide show to create your own model.

Model limitations

In this paper model, base pairing between G19 and C56 is used to show the tertiary structure of tRNA. However, the actual molecule has many more interactions between these and other bases that stabilize the tertiary structure. These interactions can not be easily shown in the paper model. Explore the atomic model of tRNA to view in detail some of these interactions.

3. Explore the Atomic Structure of tRNA

The atomic structure of tRNA can be visualized using coordinates from the Protein Data Bank. Here the structure from PDB ID 4tna is shown in a Jmol interactive view. Use the buttons to change the color and representation, and look closely at a few unusual representations between bases. For example bases C13, G22, m7G46 display a base triplet interaction (highlighted here as 13-22-46). Another unusual interaction occurs where base G57 stacks between the base pairs G18:(Ψ)55 and G19:C56 (highlighted here as 18-19 and 55-57).

Topics for further exploration

  1. Many different types of base pairs are formed when tRNA folds. These include typical A-U and C-G base pairs in the four stems, and some more unusual interactions when the whole thing folds into the final L shape. Use the model to find a non-standard base pair in one of the four stems, and use the Jmol to explore some unusual base interactions in the folded tRNA.
  2. What is the sequence of the anticodon in this tRNA? What codon would it read?