%0 Figure %A Bi, Ji’an %A Yang, Yong %A Chen, Binghua %A Zhao, Jinping %A Chen, Zhuo %A Song, Baoan %A Chen, Jianping %A Yan, Fei %D 2019 %T Image_2_Retardation of the Calvin Cycle Contributes to the Reduced CO2 Assimilation Ability of Rice Stripe Virus-Infected N. benthamiana and Suppresses Viral Infection.TIF %U https://frontiersin.figshare.com/articles/figure/Image_2_Retardation_of_the_Calvin_Cycle_Contributes_to_the_Reduced_CO2_Assimilation_Ability_of_Rice_Stripe_Virus-Infected_N_benthamiana_and_Suppresses_Viral_Infection_TIF/7866533 %R 10.3389/fmicb.2019.00568.s002 %2 https://frontiersin.figshare.com/ndownloader/files/14650439 %K rice stripe virus %K phosphoribulokinase %K glucose %K the Calvin cycle %K viral infection %X

Rice stripe virus (RSV) is naturally transmitted by the small brown planthopper and infects plants of the family Poaceae. Under laboratory conditions, RSV can infect Nicotiana benthamiana by mechanical inoculation, providing a useful system to study RSV–plant interactions. Measurements of CO2 assimilation ability and PSII photochemical efficiency showed that these were both reduced in N. benthamiana plants infected by RSV. These plants also had decreased expression of the N. benthamiana Phosphoribulokinases (NbPRKs), the key gene in the Calvin cycle. When the NbPRKs were silenced using the TRV-Virus Induced Gene Silencing system, the plants had decreased CO2 assimilation ability, indicating that the downregulated expression of NbPRKs contributes to the reduced CO2 assimilation ability of RSV-infected plants. Additionally, NbPRKs-silenced plants were more resistant to RSV. Similarly, resistance was enhanced by silencing of either N. benthamiana Rubisco small subunit (NbRbCS) or Phosphoglycerate kinase (NbPGK), two other key genes in the Calvin cycle. Conversely, transgenic plants overexpressing NbPRK1 were more susceptible to RSV infection. The results suggest that a normally functional Calvin cycle may be necessary for RSV infection of N. benthamiana.

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