The function of the phytoplasma effector SWP12 depends on the properties of two key amino acids.

Phytoplasmas are insect-borne bacterial pathogens capable of secreting effectors into host cells and interfering with host plant defense response processes. Previous studies have found that the Candidatus Phytoplasma tritici effector SWP12 binds to and destabilizes the wheat transcription factor TaWRKY74, increasing wheat susceptibility to phytoplasmas. Here, we used a Nicotiana benthamiana transient expression system to identify two key functional sites of SWP12 and screened a series of truncated mutants and amino acid substitution mutants to determine whether they inhibit Bax-induced cell death. Using a subcellular localization assay and online structure analysis websites, we found that structure rather than intracellular localization probably affects the function of SWP12. D33A and P85H are two inactive substitution mutants, neither of which interacts with TaWRKY74, and P85H does not inhibit Bax-induced cell death, suppress flg22-triggered reactive oxygen species (ROS) bursts, degrade TaWRKY74, or promote phytoplasma accumulation. D33A can weakly suppress Bax-induced cell death and flg22-triggered ROS bursts and degrade a portion of TaWRKY74 and weakly promote phytoplasma accumulation. S53L, CPP, and EPWB are three SWP12 homolog proteins from other phytoplasmas. Sequence analysis revealed that D33 was conserved in these proteins, and they exhibited the same polarity at P85. Transient expression in N. benthamiana showed that these proteins could inhibit Bax-induced cell death and suppress ROS bursts. Our findings clarified that P85 and D33 of SWP12 play critical and minor roles, respectively, in suppressing the plant defense response and that they play a preliminary role in determining the functions of homologous proteins.

[Isolation, prokaryotic expression and activity analysis of thymidylate kinase (tmk) gene from Phytoplasma of wheat blue dwarf].

OBJECTIVE: Wheat blue dwarf (WBD) is an important disease in winter wheat district, which causes serious losses in wheat production. Thymidylate kinase (TMK) catalyses the phosphorylation of dTMP to dTDP in the de novo and salvage pathways of dTTP synthesis in both prokaryotes and eukaryotes. In order effectively control this phytoplasma, we isolated the thymidylate kinase gene of WBD phytoplasma, and analyzed the catalytic activity of TMK protein. METHODS: tmk gene was amplified from the phytoplasma of WBD, the amplicons were digested with EcoR I and Hind III and then inserted into expression vector pET-30a(+). The polyHis-tagged TMK was expressed in E. coli BL21 (DE3) and fusion protein was obtained and purified by Ni-NTA column. The TMK activities were measured by the method of en-zyme-coupled assay involving Mg2+, dTMP and ATP. RESULTS: Two genes, tmk-1 and tmk-2 were obtained, with the molecular weight of 630 bp and 624 bp. Both of them encoded an amino acid sequence with three conserved functional motifs which related with binding NTP/NMP. The fusion protein, TMK-2 had a higher catalytic activity (112.41 U/mg) than TMK-1 (16.4 U/mg), and its optimum catalytic conditions were 32 degrees C, pH7.3, 1.5 mmol/L Mg2+ and 1 mmol/L ATP. CONCLUSION: TMK-1 and TMK-2 had conserved functional motifs in their primary sequence, and suggested that they may function as TMK enzymes. But, the TMK-1-polyHis fusion protein had very low catalytic activity, the possible reason was that two highly conserved regions were absent in TMK-1, and it might function as another type of kinase in WBD phytoplasma. This experiment lay a foundation for further study of the TMK function in infection and reproduction of WBD phytoplasma.