Molecule of the Month: Dihydrofolate Reductase

DHFR is a target for cancer chemotherapy and bacterial infection

Dihydrofolate reducase with NADP (green) and folic acid (magenta).
Dihydrofolate reducase with NADP (green) and folic acid (magenta).
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Dihydrofolate reductase is a small enzyme that plays a supporting role, but an essential role, in the building of DNA and other processes. It manages the state of folate, a snaky organic molecule that shuttles carbon atoms to enzymes that need them in their reactions. Of particular importance, the enzyme thymidylate synthase uses these carbon atoms to build thymine bases, an essential component of DNA. After folate has released its carbon atoms, it has to be recycled. This is the job performed by dihydrofolate reductase.

A Protein Jig

Dihydrofolate reductase, shown here from PDB entry 7dfr , juggles two relatively large molecules in its reaction. It has a long groove that binds to folate at one end, shown here in purple, and to NADPH at the other end, shown here in green. As you can see, the protein wraps sidechains around the two molecules, positioning them tightly next to one another. Then, the enzyme transfers hydrogen atoms from NADPH to the folate, converting folate to a useful reduced form.

A Target in the Fight Against Cancer

Enzymes with essential roles are sensitive targets for drug therapy. Dihydrofolate reductase was the first enzyme to be targeted for cancer chemotherapy. The first drug used for cancer chemotherapy was aminopterin. It binds to dihydrofolate reductase a thousand times more tightly than folate, blocking the action of the enzyme. Today, methotrexate and other variations on aminopterin are used, because of their tighter binding and better clinical characteristics. Since these drugs attack a key step in the production of DNA, they tend to kill cells that are actively growing rather than cells that are not growing. Since cancer cells are often the most rapidly reproducing cells in a patient, the drug will have the strongest effect on the cancer cells. The side effects of chemotherapy, however, are the result of the drug on other normally-growing tissues, such as hair follicles and the lining of the stomach.

Bacterial (left) and human (right) dihydrofolate reductase.
Bacterial (left) and human (right) dihydrofolate reductase.
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Taking Advantage of Differences

Dihydrofolate reductase is used in all organisms, but each organism makes a slightly different version. Over the course of the evolution of life, the plans for dihydrofolate reductase have slowly mutated, making small changes but keeping the essential function the same. As a result, the version from bacteria, shown on the left from PDB entry 3dfr , is smaller and more streamlined than the version in our own cells, shown on the right from PDB entry 1dls . As seen in these structures, both bind similarly to NADPH, shown in green, and to the drug methotrexate, shown in purple. Researchers, however, have developed drugs that take advantage of the differences. For instance, the drug trimethoprim binds about 30,000 times more tightly to the bacterial enzyme. So, it is effective as an antibiotic drug. A low dose of trimethoprim will attack bacteria while leaving the dihydrofolate reductase in our own cells relatively untouched.

Exploring the Structure

The drug methotrexate is designed to mimic a folate molecule, so that it will bind in the active site of the enzyme and block its action. Methotrexate is about the same size as folate, with similar chemical composition. In these two early crystal structures, PDB entries 7dfr and 3dfr , researchers confirmed that the drug does in fact mimic folate, binding in a very similar position. In these pictures, the carbon atoms in NADPH are colored green, and carbon atoms in the drug are white. Notice how the nicotinamide ring at the lower end of the nucleotide packs tightly against flat rings of methotrexate and folate. During the chemical reaction, hydrogen atoms (which are unfortunately not seen in crystal structures) are transferred from the nicotinamide to these large, flat rings. You can explore these structures in more detail by clicking on the accession codes and picking one of the options for 3D viewing.


October 2002, David Goodsell

http://doi.org/10.2210/rcsb_pdb/mom_2002_10
About Molecule of the Month
The RCSB PDB Molecule of the Month by David S. Goodsell (The Scripps Research Institute and the RCSB PDB) presents short accounts on selected molecules from the Protein Data Bank. Each installment includes an introduction to the structure and function of the molecule, a discussion of the relevance of the molecule to human health and welfare, and suggestions for how visitors might view these structures and access further details.More
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