Codes for killers: knowledge of microbes could lead to cures.Scientists have deciphered the DNA of the parasites responsible for three deadly diseases: African sleeping sickness sleeping sickness: see encephalitis; trypanosomiasis., Chagas' disease Chagas' disease, disease of South and Central America caused by the parasite Trypanosoma Trypanosoma /Try·pano·so·ma/ (tri?pan-o-so´mah) a genus of protozoa parasitic in the blood and lymph of invertebrates and vertebrates, including humans. T. bru´cei gambien´se and T. bru´cei rhodesien´se cause types of African trypanosomiasis and T. cru´zi causes Chagas' disease. cruzi. It usually affects children and young adults and is transmitted by the feces of infected insects, typically the assassin bug. Most of those infected have mild symptoms, such as fever and swelling and redness around the eyes, but from 10% to 30% develop chronic disease that may result in serious or fatal inflammation of the brain and heart tissues., and leishmaniasis American leishmaniasis any of the types of cutaneous or visceral leishmaniasis occurring in South America, Central America, or Mexico. cutaneous leishmaniasis an endemic granulomatous disease, divided into two forms: an Old World form caused by Leishmania major, L. tropica or L. aethiopica and a New World form caused by L. mexicana or L. viannia. . This information could open new routes to preventing and treating these conditions, which collectively kill more than 1 million people worldwide each year. The diseases are caused by related protozoa Protozoa /Pro·to·zoa/ (-zo´ah) a subkingdom comprising the simplest organisms of the animal kingdom, consisting of unicellular organisms ranging in size from submicroscopic to macroscopic. It comprises the Sarcomastigophora, Labyrinthomorpha, Apicomplexa, Microspora, Acetospora, Myxozoa, and Ciliophora. in a group known as trypanosomatids--single-celled organisms that are transmitted back and forth between at least two hosts, often a blood-eating insect and a person. African sleeping sickness, caused by Trypanosoma brucei, gradually brings on devastating neurological symptoms that affect the sleep cycle. Chagas' disease, caused by Trypanosoma cruzi Trypanosoma cru·zi (kr   z )n. , critically damages the heart, stomach, and brain. Leishmaniasis, caused by various species of Leishmania protozoa, can lethally enlarge the spleen and liver. "These are neglected diseases that afflict deeply impoverished people in the developing world," says Najib El-Sayed of the Institute for Genomic Research in Rockville, Md. As such, he adds, they have traditionally been unattractive research projects for pharmaceutical companies hoping to turn a profit. No vaccine exists to prevent these conditions, and the drugs that are currently available are considered inadequate because of their toxicity or the parasites' acquired resistance. After procuring grants in the late 1990s to study the organisms that cause these conditions, several groups collaborated to sequence the parasites' genomes. The teams were El-Sayed's group at the Institute for Genomic Research and groups at the Wellcome Trust Sanger Frederick Born 1918. British biochemist. He won a 1958 Nobel Prize for determining the order of amino acids in the insulin molecule and shared a 1980 Nobel Prize for developing methods for mapping DNA structure and function. Sanger, Margaret Higgins 1883-1966. Institute in Hinxton, England, the Seattle Biomedical Research Institute, and the Karolinska Institute in Stockholm. After examining the sequences of T. brucei, T. cruzi, and Leishmania major, the researchers made several surprising discoveries. For example, says Matthew Berriman of the Wellcome Trust Sanger Institute, the three parasites have a common core of 6,200 genes arranged ill a similar order. By creating drugs that interfere with proteins produced by these shared genes, but not proteins produced by people, scientists may be able to treat all three diseases with few or no side effects. Berriman also notes that the differences between the three parasites' genomes provide clues to why these organisms are so deadly. For example, the research teams identified more than 800 genes for surface proteins that T. brucei mixes and matches to evade immune system detection. "This gives us more information on why vaccines are going to be difficult to design for this organism," Berriman says. The results of the genome studies, published together in the July 15 Science, are important not only for their potential impact on treating these diseases but also for setting a positive example for collaborative research, notes Thomas Brewer of the Bill & Melinda Gates Foundation in Seattle. "These are not only good science, but they're good in terms of synergism synergism /syn·er·gism/ (sin´er-jizm) synergy. syn·er·gism (s  n," he says. John Kelly, who studies these and related protozoa at the University of London, notes that the next step will be to figure out which parasite proteins make the best targets for drug design. He predicts that the three genome studies will provide "a whole sea of targets that we can look at in detail." |
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