An international research collaborative has determined that a promising
anti-malarial compound tricks the immune system to rapidly destroy red
blood cells infected with the malaria parasite but leave healthy cells
unharmed. St. Jude Children's Research Hospital scientists led the
study, which appears in the current online early edition of the Proceedings of the National Academy of Sciences (PNAS).
A new report says that the rapid action of (+)-SJ733 will likely slow malaria drug resistance.
Credit: Peter Barta, St. Jude Children's Research Hospital
The compound, (+)-SJ733, was developed from a molecule identified in a
previous St. Jude-led study that helped to jumpstart worldwide
anti-malarial drug development efforts. Malaria is caused by a parasite
spread through the bite of an infected mosquito. The disease remains a
major health threat to more than half the world's population,
particularly children. The World Health Organization estimates that in
Africa a child dies of malaria every minute.
In this study, researchers determined that (+)-SJ733 uses a novel
mechanism to kill the parasite by recruiting the immune system to
eliminate malaria-infected red blood cells. In a mouse model of malaria,
a single dose of (+)-SJ733 killed 80 percent of malaria parasites
within 24 hours. After 48 hours the parasite was undetectable.
Planning has begun for safety trials of the compound in healthy adults.
Laboratory evidence suggests that the compound's speed and mode of
action work together to slow and suppress development of drug-resistant
parasites. Drug resistance has long undermined efforts to treat and
block malaria transmission.
"Our goal is to develop an affordable, fast-acting combination
therapy that cures malaria with a single dose," said corresponding
author R. Kiplin Guy, Ph.D., chair of the St. Jude Department of
Chemical Biology and Therapeutics. "These results indicate that SJ733
and other compounds that act in a similar fashion are highly attractive
additions to the global malaria eradication campaign, which would mean
so much for the world's children, who are central to the mission of St.
Jude."
Whole genome sequencing of the Plasmodium falciparum, the deadliest
of the malaria parasites, revealed that (+)-SJ733 disrupted activity of
the ATP4 protein in the parasites. The protein functions as a pump that
the parasites depend on to maintain the proper sodium balance by
removing excess sodium.
The sequencing effort was led by co-author Joseph DeRisi, Ph.D., a
Howard Hughes Medical Institute investigator and chair of the University
of California, San Francisco Department of Biochemistry and Biophysics.
Investigators used the laboratory technique to determine the makeup of
the DNA molecule in different strains of the malaria parasite.
Researchers showed that inhibiting ATP4 triggered a series of changes
in malaria-infected red blood cells that marked them for destruction by
the immune system. The infected cells changed shape and shrank in size.
They also became more rigid and exhibited other alterations typical of
aging red blood cells. The immune system responded using the same
mechanism the body relies on to rid itself of aging red blood cells.
Another promising class of antimalarial compounds triggered the same
changes in red blood cells infected with the malaria parasite,
researchers reported. The drugs, called spiroindolones, also target the
ATP4 protein. The drugs include NITD246, which is already in clinical
trials for treatment of malaria. Those trials involve investigators at
other institutions.
"The data suggest that compounds targeting ATP4 induce physical
changes in the infected red blood cells that allow the immune system or
erythrocyte quality control mechanisms to recognize and rapidly
eliminate infected cells," DeRisi said. "This rapid clearance response
depends on the presence of both the parasite and the investigational
drug. That is important because it leaves uninfected red blood cells,
also known as erythrocytes, unharmed."
Laboratory evidence also suggests that the mechanism will slow and
suppress development of drug-resistant strains of the parasite,
researchers said.
Planning has begun to move (+)-SJ733 from the laboratory into the
clinic beginning with a safety study of the drug in healthy adults. The
drug development effort is being led by a consortium that includes
scientists at St. Jude, the Swiss-based non-profit Medicines for Malaria
Venture and Eisai Co., a Japanese pharmaceutical company.
Journal Reference:
- María Belén Jiménez-Díaz, Daniel Ebert, Yandira Salinas, Anupam Pradhan, Adele M. Lehane, Marie-Eve Myrand-Lapierre, Kathleen G. O’Loughlin, David M. Shackleford, Mariana Justino de Almeida, Angela K. Carrillo, Julie A. Clark, Adelaide S. M. Dennis, Jonathon Diep, Xiaoyan Deng, Sandra Duffy, Aaron N. Endsley, Greg Fedewa, W. Armand Guiguemde, María G. Gómez, Gloria Holbrook, Jeremy Horst, Charles C. Kim, Jian Liu, Marcus C. S. Lee, Amy Matheny, María Santos Martínez, Gregory Miller, Ane Rodríguez-Alejandre, Laura Sanz, Martina Sigal, Natalie J. Spillman, Philip D. Stein, Zheng Wang, Fangyi Zhu, David Waterson, Spencer Knapp, Anang Shelat, Vicky M. Avery, David A. Fidock, Francisco-Javier Gamo, Susan A. Charman, Jon C. Mirsalis, Hongshen Ma, Santiago Ferrer, Kiaran Kirk, Iñigo Angulo-Barturen, Dennis E. Kyle, Joseph L. DeRisi, David M. Floyd, R. Kiplin Guy. ( )-SJ733, a clinical candidate for malaria that acts through ATP4 to induce rapid host-mediated clearance ofPlasmodium. Proceedings of the National Academy of Sciences, 2014; 201414221 DOI: 10.1073/pnas.1414221111
Courtesy: ScienceDaily
No comments:
Post a Comment