Fertilization discovery makes vaccine possible.

PositionMalaria

International investigations of an organism that one researcher calls a "silly little green scum" have led to key insights into the basic mechanisms of reproduction. The findings may help explain why species almost never can interbreed, and point to a possible way to thwart the spread of malaria, a disease that kills about 1,000,000 people each year, primarily children in sub-Saharan Africa.

In a study by the University of Texas Southwestern Medical Center, Dallas, researchers have found that sexual reproduction begins with two genetically different steps: first, two reproductive cells must latch onto each other with one protein; second, they must fuse their membranes to form a single cell using a different protein. The scientists collaborated with malaria experts at Imperial College London and found that the parasite causing the disease also uses this two-step process. When they blocked "male" and "female" malarial cells from fusing, spread of the mosquito-borne disease was stopped.

Their work started with a single-celled green alga nicknamed Chlamy (pronounced "clammy"), short for Chlamydomonas. This harmless organism, widely found in soil and water, is easy to grow and study under laboratory conditions. "A silly little green scum has led us to an exciting new vaccine target for malaria," exudes William Snell, professor of cell biology.

Understanding fertilization in microorganisms may lead to a new type of vaccine known as "altruistic." There is no vaccine to prevent malaria but, in the future, vaccinating an infected person to prevent the parasitic cells from completing the fusion step might stop the disease from passing to others.

Although the study involved only single-celled organisms, Snell indicates that the use of two different proteins in the two-step fertilization process may be the case in all species. The gene controlling whether egg and sperm can bind would be unique to each species, while the gene for the second step--fusing into a single cell--could be more universal. For example, the researchers found that HAP2, the gene that controlled whether cells fused, also is present in agriculturally important crops such as corn and wheat. For the parasite...

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