8-O-(E-p-methoxycinnamoyl)harpagide Inhibits Influenza A Virus Infection by Suppressing Intracellular Calcium.

Eun-Bin Kwon,Wei Li,Jang-Gi Choi,Young-Soo Kim,Hye-Jin Yang

doi:10.3390/molecules26041029

Eun-Bin Kwon, Wei Li + Show 3 more

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https://doi.org/10.3390/molecules26041029

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Abstract

Calcium (Ca2+) dependent signaling circuit plays a critical role in influenza A virus (IAV) infection. The 8-O-(E-p-methoxycinnamoyl)harpagide (MCH) exhibits pharmacological activities that exert neuroprotective, hepatoprotective, anti-inflammatory and other biological effects. However, not have reports of antiviral effects. To investigate the antiviral activity of MCH on IAV-infected human lung cells mediated by calcium regulation. We examined the inhibitory effect of MCH on IAV infections and measured the level of viral proteins upon MCH treatment using Western blotting. We also performed molecular docking simulation with MCH and IAV M2 protein. Finally, we analyzed MCH’s suppression of intracellular calcium and ROS (reactive oxygen species) in IAV-infected human lung cells using a flow cytometer. The results shown that MCH inhibited the infection of IAV and increased the survival of the infected human lung cells. The levels of IAV protein M1, M2, NS1 and PA were inhibited in MCH-treated human lung cells compared to that in infected and untreated cells. Also, docking simulation suggest that MCH interacted with M2 on its hydrophobic wall (L40 and I42) and polar amino acids (D44 and R45), which formed intermolecular contacts and were a crucial part of the channel gate along with W41. Lastly, MCH inhibited IAV infection by reducing intracellular calcium and mitochondrial Ca2+/ROS levels in infected human lung cells. Taken together, these data suggest that MCH inhibits IAV infection and increases the survival of infected human lung cells by suppressing calcium levels. These results indicate that MCH is useful for developing IAV treatments.

Highlights

IntroductionInfluenza A virus (IAV) continues to circulate in the human population despite pre-immune responses by vaccines and the resulting annual influenza outbreak is associated with up to 500,000 deaths worldwide [1]
Influenza A virus (IAV) is a significant pathogen that infects the respiratory tract and causes influenza, characterized by fever, headache, muscle pain and other conditions.IAV continues to circulate in the human population despite pre-immune responses by vaccines and the resulting annual influenza outbreak is associated with up to 500,000 deaths worldwide [1]
(approximately 87% versus the control group), so we proceeded with concentrations of

Summary

Introduction

IAV continues to circulate in the human population despite pre-immune responses by vaccines and the resulting annual influenza outbreak is associated with up to 500,000 deaths worldwide [1]. These vaccines cannot protect against arising influenza pandemic and currently used antiviral drugs have limitations due to resistance and side effects [1]. Viruses aid the viral life cycle by intercepting calcium channels or pumps and inhibiting T cell responses, anti-apoptosis and other persistent functions by interfering with host cells’ Ca2+ homeostasis [2]. Recent reports have shown that voltage-dependent Ca2+ channels are crucial for IAV entry into host cells [3].

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