586: Parasitology Triple genome triumph : Nature
Parasitology Triple genome triumph : Nature:
There is welcome news for scientists working on sleeping sickness, Chagas' disease and visceral leishmaniasis: the genomes of the three trypanosome parasites responsible for these devastating illnesses have now been cracked. The sequences from Trypanosoma brucei, Trypanosoma cruzi and Leishmania major were published in last week's Science by an array of international research teams (Science 309, 416−422, 409−415, 436−442; 2005).Understanding the evolution of these parasites reveals new paths to immunization and treatment.
In the terminology of global public health, these diseases don't even fall into the category of 'neglected diseases' such as malaria and tuberculosis. Rather, they are classed as 'most neglected diseases' — which nonetheless kill millions. But those affected have little means of paying for treatment, making drug development unprofitable. Consequently, there are no vaccines, and medicines are few, expensive and usually toxic.
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The three parasites share around 6,200 'core' genes, so the proteins these encode might provide targets for drugs that are effective against all three. The parasites make a large and diverse set of kinase and phosphatase enzymes. This means that there could well be regulatory and other processes used by the organisms that could be vulnerable to disruption by drugs.
Many species-specific genes were also identified in the genome sequences, providing potential species- and stage-specific targets. Although the three parasites share many subcellular structures, such as kinetoplasts and glycosomes, the organisms are very different. They are spread by different insects, attack different tissues and cause different pathologies. The specimens of L. major pictured are in the form that is transmitted to humans by sand flies.
Each parasite also has its own mechanism for evading the human immune system: T. brucei does not enter its victim's cells, and evades the immune system by constantly changing its main surface proteins; T. cruzi holes up inside cells, but uses a similar strategy to hide from the immune system; and L. major infects certain immune cells and interferes with their function.
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