Molecule of the Month: Malaria Parasite PTEX

The parasite that causes malaria exports hundreds of proteins to remodel the cells that it infects.

PTEX core complex. The parasite membrane is shown schematically in gray. Note that some of PTEX150 is not resolved in this structure, so there are several disconnected segments in the structure.
PTEX core complex. The parasite membrane is shown schematically in gray. Note that some of PTEX150 is not resolved in this structure, so there are several disconnected segments in the structure.
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The parasites that cause malaria have an unusual multi-step life cycle. They are carried by infected mosquitoes and are injected into the bloodstream when they bite. The parasite then infects liver cells and multiplies. Finally, the parasite escapes into the bloodstream, invading red blood cells and reproducing inside them. Most of the symptoms of malaria is caused at this final step, as the parasite bursts red blood cells and moves on to attack more cells.

Effective Effectors

When the malaria parasite is inside a red blood cell, it secretes hundreds of different proteins that remodel the cell. These effector proteins do many things. They help the parasite absorb nutrients and get rid of wastes. They also make the cell act in ways that are beneficial to the parasite, but not necessarily beneficial to the infected person, such as evading the immune system and gluing the infected red blood cell to the wall of the blood vessel. The PTEX complex (Plasmodium translocon of exported proteins) pumps these effector proteins out of the parasite and into the red blood cell.

Parasite Pump

The core of PTEX is composed of three parts, as seen in PDB ID 6e10. HSP101 is an AAA+ motor that uses ATP to unfold effector proteins and thread them through the center of PTEX. EXP2 forms a transmembrane pore, providing a path for the unfolded protein through the parasite membrane. PTEX150 holds the motor and the pore together. This structure also includes a short piece of the cargo protein inside HSP101, which is better seen in the interactive JSmol below.
VAR2CSA (red) and a small piece of its target molecule chondroitin sulfate A (blue). VAR2CSA is attached to the surface of a red blood cell with a transmembrane segment, not included in the structure.
VAR2CSA (red) and a small piece of its target molecule chondroitin sulfate A (blue). VAR2CSA is attached to the surface of a red blood cell with a transmembrane segment, not included in the structure.
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Sticky Cells

PTEX exports a family of proteins, termed erythrocyte membrane protein 1, that are displayed on the surface of red blood cells, radically changing their properties. Instead of circulating normally in the bloodstream, these proteins adhere infected red blood cells to the wall of the circulatory system, fixing them in one place. This is a great advantage to the parasite, since it allows them to evade mechanisms used by the spleen for finding and removing infected cells. VAR2CSA, shown here from PDB ID 7jgh and 7nnh, is one of this family of parasite proteins. It binds to molecules on cells in the placenta, causing severe problems both in the mother and the growing fetus. Researchers are currently exploring VAR2CSA as a target for vaccines to fight malaria in pregnant women.

Exploring the Structure

PTEX Dynamics

PTEX is a dynamic protein that changes shape as it pumps effector proteins across the membrane. Two PDB structures capture different states in this process. PDB ID 6e10 captures the AAA+ motor in an asymmetric state that is typical of actively pumping motors. In this image, ATP is shown in white. PDB ID 6e11 captures a more symmetrical state that may represent a resting form of the protein. To explore these structures in more detail, click on the JSmol tab for an interactive JSmol.

Topics for Further Discussion

  1. The core assembly of PTEX is assisted by several proteins. For example, thioredoxin 2 helps with unfolding proteins that have cysteine amino acids. You can explore it in PDB ID 3ul3.

Related PDB-101 Resources

References

  1. 7jgh: Ma, R., Lian, T., Huang, R., Renn, J.P., Petersen, J.D., Zimmerberg, J., Duffy, P.E., Tolia, N.H. (2021) Structural basis for placental malaria mediated by Plasmodium falciparum VAR2CSA. Nat Microbiol 6: 380-391
  2. 7nnh: Wang, K., Dagil, R., Lavstsen, T., Misra, S.K., Spliid, C.B., Wang, Y., Gustavsson, T., Sandoval, D.R., Vidal-Calvo, E.E., Choudhary, S., Agerbaek, M.O., Lindorff-Larsen, K., Nielsen, M.A., Theander, T.G., Sharp, J.S., Clausen, T.M., Gourdon, P., Salanti, A. (2021) Cryo-EM reveals the architecture of placental malaria VAR2CSA and provides molecular insight into chondroitin sulfate binding. Nat Commun 12: 2956-2956
  3. 6e10, 6e11: Ho, C.M., Beck, J.R., Lai, M., Cui, Y., Goldberg, D.E., Egea, P.F., Zhou, Z.H. (2018) Malaria parasite translocon structure and mechanism of effector export. Nature 561: 70-75
  4. Koning-Ward, T.F., Dixon, M.W.A., Tilley, L., Gilson, P.R. (2016) Plasmodium species: master renovators of their host cells. Nat Rev Microbiol 14: 494-507

November 2024, David Goodsell

http://doi.org/10.2210/rcsb_pdb/mom_2024_11
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