Researchers discover method to unravel malaria’s genetic secrets
January 25, 2012 Editor 0
The parasite that causes malaria is a genetic outlier, which has prevented scientists from discovering the functions of most of its genes. Researchers at National Jewish Health and Yale University School of Medicine have devised a technique to overcome the genetic oddity of Plasmodium falciparum, the major cause of human malaria. This new approach led them discover a new gene involved in lipid synthesis, and opens the door to further genetic discovery for the entire organism. This should foster a much greater understanding of the parasite, and facilitate discovery of new medications for a disease that infects more than 200 million people and kills nearly 700,000 every year.
“The malarial genome has been a black box. Our technique allows us to open that box, so that we can learn what genes in the most lethal human parasite actually do,” said Dennis Voelker, PhD, Professor of Medicine at National Jewish Health and senior author on the paper that appeared in the January 2, 2012 , issue of the Journal of Biological Chemistry. “This could prove tremendously valuable in the fight against a disease that has become increasingly drug-resistant.”
The genome of P. falciparum was sequenced in 2002, but the actual functions of many of the organism’s genes have remained elusive. One of the primary methods for discovering gene function is to copy a specific gene, insert it into a model organism that is easy to grow, often the yeast Saccharomyces cerevisiae, then draw on the incredible knowledge base about yeast and its abundant genetic variants to discover how that inserted gene changes the organism’s biology.
DNA is composed of building blocks with the shorthand designations A,T,C and G. The genome of P. falciparum is odd because it is particularly rich in A’s and T’s. Because of this A-T-rich nature, P. falciparum genes generally do not function when they are inserted into other organisms. As a result, scientists have been largely stymied when trying to understand the functions of P. falciparum‘s genes.
It turns out, however, that P. falciparum has a close cousin, P. knowlesi, which shares almost all its genes with P. falciparum, but with fewer A’s and T’s. As a result, P. knowlesi genes function well when inserted into yeast. Scientists can now insert P. knowlesi genes into yeast, discover their function, and then match them to corresponding genes in P. falciparum, which reveals the function of the malarial parasite’s genes.
“This technique could lead to an explosion in knowledge about malaria and the parasite that causes it.” said Dr. Voelker.
The researchers used the technique to discover a new gene involved in the synthesis of lipids in cell membranes of P. falciparum. The gene, phosphatidylserine decarboxylase, directs the formation of a protein unique to malarial parasites and is a potential therapeutic target. For example, selective disruption of lipid synthesis in P. falciparum, would prevent the organism from making new cell membranes, growing and reproducing in human hosts.
- Sporadic mutations may be responsible for half of schizophrenia cases
- Study is first to explain type of antimalarial drug resistance
- New whole plant therapy shows promise as an effective and economical treatment for malaria
- Hidden layer of genome unveils how plants may adapt to environments throughout the world
- Malaria vaccines: The long war
- Benin: Scientists Unveil Enhanced Malaria Test
Subscribe to our stories
- Prize-winning projects promote healthier eating, smarter crop investments June 28, 2018
- Reliable energy for all June 28, 2018
- Making marble from bottles: plastic waste’s second life in Kenya June 28, 2018
- A regional enterprise to commercialize an integrated technology for waste water treatment and biowaste conversion in eastern Africa May 27, 2018
- Dr Peggy Oti-Boateng May 27, 2018