Quantcast

COVID virus kills pain, possibly explaining why many unaware they are sick

SARS-CoV-2, the virus that causes COVID-19, can relieve pain, according to a new study by University of Arizona Health Sciences researchers.

The finding may explain why nearly half of all people who get COVID-19 experience few or no symptoms, even though they are able to spread the disease, according to the study’s corresponding author Rajesh Khanna, PhD, a professor in the UArizona College of Medicine – Tucson’s Department of Pharmacology.

Rajesh Khanna, PhD. (Photo: Kris Hanning/University of Arizona Health Sciences)Rajesh Khanna, PhD. (Photo: Kris Hanning/University of Arizona Health Sciences)“It made a lot of sense to me that perhaps the reason for the unrelenting spread of COVID-19 is that in the early stages, you’re walking around all fine as if nothing is wrong because your pain has been suppressed,” said Dr. Khanna. “You have the virus, but you don’t feel bad because your pain is gone. If we can prove that this pain relief is what is causing COVID-19 to spread further, that’s of enormous value.”

The paper, “SARS-CoV-2 Spike protein co-opts VEGF-A/Neuropilin-1 receptor signaling to induce analgesia,” was published today in PAIN, the journal of the International Association for the Study of Pain.

View an animated video of how SARS-CoV-2 reduces pain, and a video of Dr. Rajesh Khanna explaining how his team identified the phenomenon.

The U.S. Centers for Disease Control and Prevention released updated data Sept. 10 estimating that 50% of COVID-19 transmission occurs prior to the onset of symptoms and 40% of COVID-19 infections are asymptomatic.

“This research raises the possibility that pain, as an early symptom of COVID-19, may be reduced by the SARS-CoV-2 spike protein as it silences the body’s pain signaling pathways,” said UArizona Health Sciences Senior Vice President Michael D. Dake, MD. “University of Arizona Health Sciences researchers at the Comprehensive Pain and Addiction Center are leveraging this unique finding to explore a novel class of therapeutics for pain as we continue to seek new ways to address the opioid epidemic.”

Doctoral student Lisa Boinon prepares buffers under the watchful eye of Dr. Khanna, her faculty mentor. (Photo: Kris Hanning/University of Arizona Health Sciences)Doctoral student Lisa Boinon prepares buffers under the watchful eye of Dr. Khanna, her faculty mentor. (Photo: Kris Hanning/University of Arizona Health Sciences)Viruses infect host cells through protein receptors on cell membranes. Early in the pandemic, scientists established that the SARS-CoV-2 spike protein uses the angiotensin-converting enzyme 2 (ACE2) receptor to enter the body. But in June, two papers posted on the preprint server bioRxiv pointed to neuropilin-1 as a second receptor for SARS-CoV-2.

“That caught our eye because for the last 15 years my lab has been studying a complex of proteins and pathways that relate to pain processing that are downstream of neuropilin,” said Dr. Khanna, who is affiliated with the UArizona Health Sciences Comprehensive Pain and Addiction Center and a member of the UArizona BIO5 Institute. “So we stepped back and realized this could mean that maybe the spike protein is involved in some sort of pain processing.”

Many biological pathways signal the body to feel pain. One is through a protein named vascular endothelial growth factor-A (VEGF-A), which plays an essential role in blood vessel growth but also has been linked to diseases such as cancer, rheumatoid arthritis and, most recently, COVID-19.

Like a key in a lock, when VEGF-A binds to the receptor neuropilin, it initiates a cascade of events resulting in the hyperexcitability of neurons, which leads to pain. Dr. Khanna and his research team found that the SARS-CoV-2 spike protein binds to neuropilin in exactly the same location as VEGF-A.

See a 3D rendering of neuropilin with VEGF-A (left), spike protein (middle) and small molecule inhibitor (right) in the binding pocket here.

Kimberley Gomez, PhD, locates cells to record. (Photo: Kris Hanning/University of Arizona Health Sciences)Kimberley Gomez, PhD, locates cells to record. (Photo: Kris Hanning/University of Arizona Health Sciences)

With that knowledge, they performed a series of experiments in the laboratory and in rodent models to test their hypothesis that the SARS-CoV-2 spike protein acts on the VEGF-A/neuropilin pain pathway. They used VEGF-A as a trigger to induce neuron excitability, which creates pain, then added the SARS-CoV-2 spike protein.

“The spike protein completely reversed the VEGF-induced pain signaling,” Dr. Khanna said. “It didn’t matter if we used very high doses of spike or extremely low doses – it reversed the pain completely.”

Dr. Khanna is teaming up with UArizona Health Sciences immunologists and virologists to continue research into the role of neuropilin in the spread of COVID-19.

In his lab, he will be examining neuropilin as a new target for non-opioid pain relief. During the study, Dr. Khanna tested existing small molecule neuropilin inhibitors developed to suppress tumor growth in certain cancers and found they provided the same pain relief as the SARS-CoV-2 spike protein when binding to neuropilin.

“We are moving forward with designing small molecules against neuropilin, particularly natural compounds, that could be important for pain relief,” Dr. Khanna said. “We have a pandemic, and we have an opioid epidemic. They’re colliding. Our findings have massive implications for both. SARS-CoV-2 is teaching us about viral spread, but COVID-19 has us also looking at neuropilin as a new non-opioid method to fight the opioid epidemic.”

Co-authors on the paper from the Department of Pharmacology are: Aubin Moutal, PhD; Lisa Boinon; Kimberly Gomez, PhDDongzhi Ran, PhDYuan ZhouHarrison Stratton, PhDSong Cai, PhDShizhen LuoKerry Beth Gonzalez; and Samantha Perez-Miller, PhD. Co-authors from the Department of Anesthesiology, with additional affiliations with the Comprehensive Pain and Addiction Center, are Amol Patwardhan, MD, PhD, and Mohab Ibrahim, MD, PhD.

This research was funded by the National Institute of Neurological Disorders and Stroke, a unit of the National Institutes of Health (NIH), under Award No. NS098772; and the National Institute on Drug Abuse, also an NIH unit, under Award No. DA042852.

 




The material in this press release comes from the originating research organization. Content may be edited for style and length. Want more? Sign up for our daily email.