Two new studies originating from the Roy Blunt NextGen Precision Health building provide promise for diabeticsPeer-Reviewed Publication
UNIVERSITY OF MISSOURI-COLUMBIA
New research at the Roy Blunt NextGen Precision Health building has discovered a potential treatment for an underlying cause of cardiovascular disease in people with Type 2 diabetes.
More than 30 million Americans live with Type 2 diabetes. One common feature of diabetes is the hardening and inflexibility of blood vessels caused by damage to the endothelial cells in the vascular system. Over time, this can lead to the development and progression of cardiovascular disease, which is the number one cause of death in diabetics. Because endothelial dysfunction is causally linked to cardiovascular disease, there is a considerable need to identify new therapeutic targets to improve endothelial function in Type 2 diabetics.
A research team from the University of Missouri has found that neuraminidase activity is elevated in the circulation of Type 2 diabetic mice and humans. In a series of mechanistic experiments in cultured endothelial cells and isolated blood vessels, they were able to link increased neuraminidase to endothelial dysfunction.
“Because we know that Type 2 diabetics have this increased neuraminidase circulating in their blood, and that the presence of it promotes endothelial dysfunction, it is important to target it as a means of addressing the cardiovascular complications faced by those with Type 2 diabetes,” said Luis Martinez-Lemus, DVM, PhD, James O. Davis distinguished professor in cardiovascular research at the University of Missouri School of Medicine.
The team also found that neuraminidase inhibition using zanamivir, an oral inhalation drug used to treat the flu virus, improved endothelial function in diabetic mice.
“This research lays out the molecular mechanisms by which neuraminidase promotes endothelial dysfunction and these mechanisms can be exploited therapeutically,” said Jaume Padilla, PhD, an associate professor of nutrition and exercise physiology at MU. “Improving vascular function in people with Type 2 diabetes can help them live longer and better lives, which is why this research is so important.”
“Neuraminidase inhibition improves endothelial function in diabetic mice” and “Neuraminidase-induced externalization of phosphatidylserine activates ADAM17 and impairs insulin signaling in endothelial cells” were recently published in the American Journal of Physiology-Heart and Circulatory Physiology. In addition to Martinez-Lemus and Padilla, the research team at MU includes Camila Manrique-Acevedo, MD, distinguished professor in diabetes and director of faculty research at the School of Medicine; Larissa Ferreira-Santos, PhD, Thaysa Ghiarone, PhD and Francisco Ramirez-Perez, PhD, postdoctoral fellows at NextGen Precision Health; Christopher Foote, PhD, assistant research professor of medical pharmacology and physiology; James Smith, Marc Augenreich, Neil McMillan, and Gavin Power, doctoral students in Nutrition and Exercise Physiology; Andrew Wheeler, MD, surgeon, MU Health Care Weight Management Center; Katherine Burr, senior research specialist at the School of Medicine; Annayya Aroor, MD, assistant research professor at the School of Medicine; Shawn Bender, PhD, associate professor, College of Veterinary Medicine; Mariana Morales-Quinones, PhD, senior research specialist at NextGen Precision Health; Morgan Williams and Juan Gonzalez-Vallejo, NextGen Precision Health.
DOI
10.1152/ajpheart.00337.2023
METHOD OF RESEARCH
Experimental study
SUBJECT OF RESEARCH
People
ARTICLE TITLE
Neuraminidase-induced externalization of phosphatidylserine activates ADAM17 and impairs insulin signaling in endothelial cells
ARTICLE PUBLICATION DATE
1-Jan-2024
COI STATEMENT
The authors declare the following financial interests/personal relationships which may be considered as potential competing interests: Pending US patent Application, Serial No. 16/754,814. Entitled: Neuraminidase Inhibition to Improve Glycocalyx Volume and Function to Ameliorate Cardiovascular Diseases in Pathologies Associated with Glycocalyx Damage (filed, 9 April 2020; Ref. No. 17UMC103).
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