Characterization of a Fatal Feline Panleukopenia Virus Derived from Giant Panda with Broad Cell Tropism and Zoonotic Potential

Overview

Journal Front Immunol

Specialty Allergy & Immunology

Date 2023 Sep 4

PMID 37662912

Authors

Shan Zhao

Huanyuan Hu

Jingchao Lan

Zhisong Yang

Qianling Peng

Liheng Yan

Li Luo

Lin Wu

Yifei Lang

Qigui Yan

Affiliations

Soon will be listed here.

Abstract

Represented by feline panleukopenia virus (FPV) and canine parvovirus (CPV), the species has a worldwide distribution through continuous ci13rculation in companion animals such as cats and dogs. Subsequently, both FPV and CPV had engaged in host-to-host transfer to other wild animal hosts of the order . In the present study, we emphasized the significance of cross-species transmission of parvoviruses with the isolation and characterization of an FPV from giant panda displaying severe and fatal symptoms. The isolated virus, designated pFPV-sc, displayed similar morphology as FPV, while phylogenetic analysis indicated that the nucleotide sequence of pFPV-sc clades with Chinese FPV isolates. Despite pFPV-sc is seemingly an outcome of a spillover infection event from domestic cats to giant pandas, our study also provided serological evidence that FPV or other parvoviruses closely related to FPV could be already prevalent in giant pandas in 2011. Initiation of host transfer of pFPV-sc is likely with association to giant panda transferrin receptor (TfR), as TfR of giant panda shares high homology with feline TfR. Strikingly, our data also indicate that pFPV-sc can infect cell lines of other mammal species, including humans. To sum up, observations from this study shall promote future research of cross-host transmission and antiviral intervention of , and necessitate surveillance studies in thus far unacknowledged potential reservoirs.

Citing Articles

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