Identification of the amino acids residues involved in hemagglutinin-neuraminidase of Newcastle disease virus binding to sulfated Chuanmingshen violaceum polysaccharides

Xu Song; Lin Liu; Wei Hu; Xiaoxia Liang; Changliang He; Lizi Yin; Gang Ye; Yuanfeng Zou; Lixia Li; Huaqiao Tang; Renyong Jia; Zhongqiong Yin

doi:10.1016/j.psj.2021.101255

Identification of the amino acids residues involved in hemagglutinin-neuraminidase of Newcastle disease virus binding to sulfated Chuanmingshen violaceum polysaccharides

Poult Sci. 2021 Aug;100(8):101255. doi: 10.1016/j.psj.2021.101255. Epub 2021 May 13.

Authors

Xu Song¹, Lin Liu¹, Wei Hu¹, Xiaoxia Liang¹, Changliang He¹, Lizi Yin¹, Gang Ye¹, Yuanfeng Zou¹, Lixia Li¹, Huaqiao Tang¹, Renyong Jia¹, Zhongqiong Yin²

Affiliations

¹ Natural Medicine Research Center, College of Veterinary Medicine, Sichuan Agricultural University, Chengdu, 611130 China.
² Natural Medicine Research Center, College of Veterinary Medicine, Sichuan Agricultural University, Chengdu, 611130 China. Electronic address: yinzhongq@163.com.

Abstract

The antiviral mechanism of sulfated polysaccharides is supposed to prevent virus entry, which is mediated by the interactions of anionic charges on sulfated polysaccharides with positively charged domains of viral envelope glycoproteins, leading to shielding of the functional domain involved in virus attachment to cell surface receptors. But, few direct evidences were reported. In the previous study, we found that sulfated Chuanmingshen violaceum polysaccharides (sCVPS) possessed remarkable inhibitory effect against Newcastle disease virus (NDV) through inhibition of NDV attachment to host cells. Whether sCVPS bound to hemagglutinin-neuraminidase (HN) leading to inhibition of NDV attachment needs to be further clarified. The present study conducted site-directed mutagenesis of possible positively charged residues of HN, and found that mutants R197G, H199G, R363G, and R523G could significantly decrease the inhibitory effects of sCVPS on receptor binding ability through hemadsorption assay, especially R363G which suggested that binding to R363 is more effective to shield the sialic acid binding sites. Dual mutants (R363G/R197G, R363G/H199G and R363G/R523G) induced more decreased inhibitory effect of sCVPS than single mutants. The immunofluorescence study using FITC-labeled sCVPS found that the fluorescence intensity of mutants R363G and R363G/H199G were significantly decreased. The binding kinetics of sCVPS to HN measured by surface plasmon resonance indicated that sCVPS had a higher binding affinity for wild-type HN than mutants R363G and R363G/H199G. Plaque reduction study was performed using recombinant NDV with mutant HN_R363G and HN_R363G/H199G, which showed significantly decreased inhibitory effects of sCVPS against mutant NDV adsorption to BHK-21 cells. These results suggested that the residues R197, H199, R363, and R523 were the binding sites for sCVPS, especially R363 act as the main interaction site. The present study provided direct evidence for the theory that antiviral mechanism of sulfated polysaccharides attributed to anionic groups binding to the positively charged residues of viral proteins which led to the shielding of receptor binding sites.

Keywords: Newcastle disease virus; hemagglutinin-neuraminidase; interaction sites; sulfated Chuanmingshen violaceum polysaccharides.

MeSH terms

Amino Acids
Animals
Chickens
Hemagglutinins
Neuraminidase
Newcastle Disease*
Newcastle disease virus* / genetics
Polysaccharides
Sulfates
Viral Envelope Proteins

Substances

Amino Acids
Hemagglutinins
Polysaccharides
Sulfates
Viral Envelope Proteins
Neuraminidase