Newswise — August 17, 2023—(BRONX, NY)—Researchers at Albert Einstein College of Medicine have found that the virus responsible for chikungunya fever can spread directly from cell to cell—perhaps solving the longstanding mystery of how the virus, now emerging as a major health threat, can manage to escape antibodies circulating in the bloodstream. The findings, published today in Nature Microbiology, could help in developing effective vaccines or treatments for chikungunya fever, a debilitating and increasingly common mosquito-borne disease.
A Possible Explanation for Prolonged Infections
“Previously, chikungunya virus was thought to spread in the body by infecting a cell, replicating within that cell, and then sending new copies of the virus into the bloodstream that then infect new cells,” said study leader Margaret Kielian, Ph.D., professor of cell biology and the Samuel H. Golding Chair in Microbiology at Einstein. “However, we’ve found that the virus can also hijack a host cell’s cytoskeleton—the proteins that support cells and maintain their shape. The virus causes the infected cell to send out long thin extensions that make contact with uninfected neighboring cells, enabling the virus to safely and efficiently travel from one cell to another.”
Dr. Kielian and her colleagues have named these virus-induced structures intercellular long extensions, or ILEs. “This mode of viral transmission may not only shield some copies of the virus from the host’s immune response, but it may also explain why symptoms of chikungunya infection can persist for many months or years,” added first author Peiqi Yin, Ph.D., a postdoctoral fellow in Dr. Kielian’s lab.
In addition to fever, chikungunya infections often lead to chronic and debilitating arthritis. The virus is spread to humans by the bite of infected mosquitoes, which become infected by feeding on people who already have the virus. Over the past 15 years, chikungunya virus has become an important and increasingly widespread human pathogen. Multiple outbreaks have caused millions of human infections in numerous areas including the Americas, Africa, Asia, Europe, and the Caribbean. The National Institute of Allergy and Infectious Diseases lists chikungunya virus as a Category B Pathogen, the second-highest priority for organisms posing threats to national security and public health.
Confirming a Cell Structure’s Role
Dr. Kielian and colleagues discovered the presence of ILEs in chikungunya-infected cells several years ago, but it wasn’t clear whether the structures facilitated cell-to-cell viral transmission. The study described in the Nature Microbiology paper was designed to answer that question.
The first part of the study involved the use of cultured mouse cells. The researchers exposed the cells to chikungunya virus that expressed a fluorescent reporter protein, allowing them to observe that infectious virus particles were indeed being transmitted from cell to cell via ILEs. Cell-to-cell transmission occurred even in the presence of high quantities of neutralizing antibodies that were added to the culture medium.
To confirm this mode of cell-to-cell transmission in living animals, the researchers studied chikungunya infection in mice. Mice that were first inoculated with neutralizing antibodies and were then directly injected with chikungunya virus did not become infected. However, antibody-treated mice that were then injected with virus-infected cells (rather than just the virus) did develop chikungunya infections that were resistant to the neutralizing antibodies.
“Together, these studies show that ILEs shield chikungunya virus from neutralizing antibodies and promote intercellular virus transmission, both in vitro and in vivo,” said Dr. Yin. The mouse studies were conducted by Thomas E. Morrison, Ph.D., and his group at the University of Colorado School of Medicine in Aurora.
Short-Circuiting the Connections
In a final set of studies, the researchers determined that certain antiviral antibodies were able to block ILEs from forming and to prevent cell-to-cell transmission. “If we can generate the production of such antibodies in human patients, or develop other methods to stop ILE formation, that could be especially helpful in combatting the chronic symptoms of chikungunya infection,” said Dr. Kielian. “We’re currently studying different ways to do this.”
The study is titled “Chikungunya virus cell-to-cell transmission is mediated by intercellular extensions in vitro and in vivo.” Other Einstein authors were Jonathan R. Lai, Ph.D., M.D./Ph.D. student Karen Tong, and Judy J. Wan, Ph.D. Other contributors include Bennett J. Davenport, Ph.D., and Ph.D. student Brian C. Ware at the University of Colorado School of Medicine, Aurora, CO; Michael S. Diamond, M.D., Ph.D., and Arthur S. Kim, Ph.D., at Washington University School of Medicine, Saint Louis, MO; Thérèse Couderc, Ph.D., at Institut Pasteur, Université de Paris, Paris, France; and Marc Lecuit, M.D., Ph.D., at Institut Pasteur, Université de Paris, and Necker-Enfants Malades University Hospital, APHP, Institut Imagine, Paris, France.
The research was supported by grants from the National Institutes of Health (R01GM057454, R01AI141436, R01AI125462 and R01AI143673) and by an NCI Cancer Center Support Grant (P30CA013330).
Competing interests: Dr. Lai is a paid consultant for Celdara Medical, LLC. Dr. Diamond is a consultant for Inbios, Vir Biotechnology, Senda Biosciences, Ocugen, Moderna, and Immunome. The Diamond laboratory has received unrelated funding support in sponsored research agreements from Vir Biotechnology, Moderna, Generate Biomedicine, and Emergent BioSolutions. The other authors declare no competing interests.
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Albert Einstein College of Medicine is one of the nation’s premier centers for research, medical education and clinical investigation. During the 2022-23 academic year, Einstein is home to 740 M.D. students, 194 Ph.D. students, 118 students in the combined M.D./Ph.D. program, and approximately 225 postdoctoral research fellows. The College of Medicine has more than 1,900 full-time faculty members located on the main campus and at its clinical affiliates. In 2022, Einstein received more than $202 million in awards from the National Institutes of Health. This includes the funding of major research centers at Einstein in cancer, aging, intellectual development disorders, diabetes, clinical and translational research, liver disease, and AIDS. Other areas where the College of Medicine is concentrating its efforts include developmental brain research, neuroscience, cardiac disease, and initiatives to reduce and eliminate ethnic and racial health disparities. Its partnership with Montefiore, the University Hospital and academic medical center for Einstein, advances clinical and translational research to accelerate the pace at which new discoveries become the treatments and therapies that benefit patients. For more information, please visit einsteinmed.edu, follow us on Twitter, Facebook, Instagram, LinkedIn, and view us on YouTube.
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R01GM057454; R01AI141436; R01AI125462; R01AI143673; P30CA013330; Nature Microbiology