The artificial amino acid change in the sialic acid-binding domain of the hemagglutinin neuraminidase of newcastle disease virus increases its specificity to HCT 116 colorectal cancer cells and tumor suppression effect

Bo-Kyoung Jung; Yong Hee An; Sung Hoon Jang; Jin-Ju Jang; Seonhee Kim; Joo Hee Jeon; Jinju Kim; Jason Jungsik Song; Hyun Jang

doi:10.1186/s12985-023-02276-9

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The artificial amino acid change in the sialic acid-binding domain of the hemagglutinin neuraminidase of newcastle disease virus increases its specificity to HCT 116 colorectal cancer cells and tumor suppression effect

Authors: Bo-Kyoung Jung ; Yong Hee An ; Sung Hoon Jang ; Jin-Ju Jang ; Seonhee Kim ; Joo Hee Jeon ; Jinju Kim ; Jason Jungsik Song ; Hyun Jang

Citation: VIROLOGY JOURNAL, Vol.21 : 7, 2024-01

Journal Title: VIROLOGY JOURNAL

Issue Date: 2024-01

MeSH: Animals ; Colorectal Neoplasms* / therapy ; Disease Models, Animal ; HCT116 Cells ; HN Protein / genetics ; HN Protein / metabolism ; Hemagglutinins ; Humans ; Membrane Proteins ; Mice ; N-Acetylneuraminic Acid / metabolism ; Neuraminidase / genetics ; Neuraminidase / metabolism ; Newcastle disease virus / genetics ; Newcastle disease virus / metabolism ; Oncolytic Viruses* / genetics

Keywords: Colorectal cancer ; Directed evolution ; Haemagglutinin ; Newcastle Disease virus (NDV) ; Oncolytic virus

Abstract: Background: Oncolytic viruses are being studied and developed as novel cancer treatments. Using directed evolution technology, structural modification of the viral surface protein increases the specificity of the oncolytic virus for a particular cancer cell. Newcastle disease virus (NDV) does not show specificity for certain types of cancer cells during infection; therefore, it has low cancer cell specificity. Hemagglutinin is an NDV receptor-binding protein on the cell surface that determines host cell tropism. NDV selectivity for specific cancer cells can be increased by artificial amino acid changes in hemagglutinin neuraminidase HN proteins via directed evolution, leading to improved therapeutic effects.

Methods: Sialic acid-binding sites (H domains) of the HN protein mutant library were generated using error-prone PCR. Variants of the H domain protein were screened by enzyme-linked immunosorbent assay using HCT 116 cancer cell surface molecules. The mutant S519G H domain protein showed the highest affinity for the surface protein of HCT 116 cells compared to that of different types of cancer cells. This showed that the S519G mutant H domain protein gene replaced the same part of the original HN protein gene, and S519G mutant recombinant NDV (rNDV) was constructed and recovered. S519G rNDV cancer cell killing effects were tested using the MTT assay with various cancer cell types, and the tumor suppression effect of the S519G mutant rNDV was tested in a xenograft mouse model implanted with cancer cells, including HCT 116 cells.

Results: S519G rNDV showed increased specificity and enhanced killing ability of HCT 116 cells among various cancer cells and a stronger suppressive effect on tumor growth than the original recombinant NDV. Directed evolution using an artificial amino acid change in the NDV HN (S519G mutant) protein increased its specificity and oncolytic effect in colorectal cancer without changing its virulence.

Conclusion: These results provide a new methodology for the use of directed evolution technology for more effective oncolytic virus development.