A leafhopper saliva protein mediates horizontal transmission of viral pathogens from insect vectors into rice phloem

• Published in: Communications biology Vol. 5; no. 1; p. 204
• Main Authors: Wu, Wei, Yi, Ge, Lv, Xinwei, Mao, Qianzhuo, Wei, Taiyun
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 04.03.2022; Nature Portfolio
• Subjects: 13/1; 13/89; 14/19; 14/28; 14/34; 38/23; 38/77; 45/23; 45/29; 631/326/596/2563; 631/601/1466; Animals; Biomedical and Life Sciences; Hemiptera - metabolism; Hydrogen Peroxide; Insect Proteins - metabolism; Insect Vectors; Life Sciences; Oryza - metabolism; Phloem; Saliva - metabolism
• ISSN: 2399-3642; 2399-3642
• DOI: 10.1038/s42003-022-03160-y

Numerous insects transmit viruses together with saliva to plant phloem, but the roles of saliva components remain elusive. Here, we report that calcium-binding protein (CBP), a universal insect saliva protein, is modified to benefit horizontal transmission of a devastating rice reovirus into plant phloem. CBP effectively competes with virus-induced filaments to target and traverse actin-based apical plasmalemma into saliva-stored cavities in salivary glands of leafhopper vector. Thus, the inhibition of CBP expression by viral infection facilitates filament-mediated viral secretion into salivary cavities and then into plant phloem. Furthermore, virus-mediated reduction of CBP secretion causes an increase of cytosolic Ca 2+ levels in rice, triggering substantial callose deposition and H 2 O 2 production. Thus, viruliferous vectors encounter stronger feeding barriers, probe more frequently, and secrete more saliva into plants, ultimately enhancing viral transmission. We thus conclude that the inhibition of CBP secretion facilitates viral secretion and increases host defense response to benefit viral transmission. CBP, a calcium binding protein found in insect saliva, allows for the transmission of the devastating rice gall dwarf virus into plant phloem. This interaction with CBP is compounded by stronger feeding barriers, more frequent probing behavior, and increased saliva secretion into plants by insect vectors, all increasing the likelihood of viral transmission.