ATG6 interacting with NPR1 increases Arabidopsis thaliana resistance to Pst DC3000/avrRps4 by increasing its nuclear accumulation and stability

Baihong Zhang
Shuqin Huang
Shuyu Guo
Yixuan Meng
Yuzhen Tian
Yue Zhou
Hang Chen
Xue Li
Jun Zhou author has email address
Wenli Chen author has email address

MOE Key Laboratory of Laser Life Science & Institute of Laser Life Science, College of Biophotonics, South China Normal University, Guangzhou 510631, China; Guangdong Provincial Key Laboratory of Laser Life Science, College of Biophotonics, South China Normal University, Guangzhou 510631, China
State Key Laboratory of Reproductive Regulation and Breeding of Grassland Livestock, College of Life Sciences, Inner Mongolia University, Hohhot, 010070, PR China; Key Laboratory of Herbage and Endemic Crop Biotechnology, and College of Life Sciences, Inner Mongolia University, Hohhot, 010070, China

https://doi.org/10.7554/eLife.97206.1

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Figures and data

Physical interaction between NPR1 and ATG6.
(a). Interaction of NPR1 with ATG6 in yeast. The CDS of ATG6, NPR1, NPR1-N (1∼984 bp), NPR1-C (984∼1782 bp) and SnRK2.8 were fused to pGADT7 (AD) and pGBKT7 (BD), respectively. Co-transformation of NPR1-BD + AD, BD + ATG6-AD, BD + SnRK2.8-AD, NPR1-N-BD + AD, NPR1-C-BD + AD were used as negative controls. The interaction of NPR1-BD and SnRK2.8-AD was used as a positive control. Yeast growth on SD/-Trp-Leu-His-Ade media represents interaction. Numbers represent the dilution fold of yeast. 0, -1 (10 fold dilution), -2 (100 fold dilution), -3 (1000 fold dilution). (b). In vitro pull-down assays of NPR1-His with GST-ATG6 fusion protein. NPR1-His prokaryotic proteins were incubated with GST-tag Purification Resin conjugated with GST-ATG6, GST and SnRK2.8-GST. Western blotting analysis with anti-GST and anti-His. Black asterisk indicate SnRK2.8-GST bands. Red asterisk indicate GST-ATG6 bands. (c). Co-immunoprecipitation of NPR1 with ATG6 in vivo. Total protein was extracted from N. benthamiana transiently transformed with ATG6-mCherry + GFP and ATG6-mCherry + NPR1-GFP, followed by IP with GFP-Trap. Western blots analysis with ATG6 and GFP antibodies. (d). Co-localization of NPR1-GFP and ATG6-mCherry in N. benthamiana under normal and SA treatment conditions. NPR1-GFP were co-expressed with ATG6-mCherry in N. benthamiana for 2 d followed by confocal observation. Scale bar, 100 μm. All experiments were performed with three biological replicates.

ATG6 is localized in the cytoplasm and nucleus.
(a). The nuclear localization of ATG6-mCherry in N. benthamiana. Scale bar, 100 μm. (b). Co-localization of ATG6-GFP and nls-mCherry in N. benthamiana. Scale bar, 100 μm. (c). Subcellular fractionation of ATG6-mCherry in N. benthamiana after 1 mM SA treatment. Black asterisk (*) indicate ATG6-mCherry bands. (d). Subcellular fractionation of ATG6-GFP in N. benthamiana after 1 mM SA treatment. Black asterisk (*) indicate ATG6-GFP bands. (e). Subcellular fractionation of ATG6-GFP in ATG6-GFP Arabidopsis after 0.5 mM SA treatment. (f). Subcellular fractionation of ATG6-mCherry in ATG6-mCherry Arabidopsis after 0.5 mM SA treatment. In (c-f), ATG6-mCherry (c and f) and ATG6-GFP (d and e) were detected using ATG6 or GFP antibody. Actin and H3 were used as cytoplasmic and nucleus internal reference, respectively. Numerical values indicate quantitative analysis of ATG6-mCherry and ATG6-GFP using image J. All experiments were performed with three biological replicates.

ATG6 increases the nuclear accumulation of NPR1 under SA treatment.
(a). Confocal images of NPR1-GFP nuclear localization in 7-day-old seedlings of NPR1-GFP and ATG6-mCherry × NPR1-GFP under normal and 0.5 mM SA spray for 3 h. Scale bar, 50 μm. (b). Nuclear localization numbers of NPR1-GFP (per section) in (a), n > 10. (c). Subcellular fractionation of NPR1-GFP in 7-day-old seedlings of NPR1-GFP and ATG6-mCherry × NPR1-GFP after 0.5 mM SA treatment for 0, 3 and 6 h. (d). The ration of NPR1 in the nucleus/total NPR1 in (c). (e). Subcellular fractionation of NPR1-GFP in N. benthamiana after 1 mM SA treatment for 0, 8 and 20 h. (f). The ration of NPR1 in the nucleus/total NPR1 in (e). In (c and e), cytoplasmic and nuclear proteins were extracted from Arabidopsis or N. benthamiana. NPR1-GFP were detected using GFP antibody. Actin and H3 were used as cytoplasmic and nucleus internal reference, respectively. Numerical values indicate quantitative analysis of NPR1-GFP using image J. All experiments were performed with three biological replicates.

ATG6 increases endogenous SA levels and promotes the expression of NPR1 downstream target genes
(a). Level of free SA in 3-week-old NPR1-GFP and ATG6-mCherry × NPR1-GFP after Pst DC3000/avrRps4 for 12 h. (b-c). Expression of PR1 (b), PR5 (c) under normal and SA treatment conditions. * or ** indicates that the significant difference compared to the control is at the level of 0.05 or 0.01 (Student t test p value, * p< 0.05 or ** p< 0.01). All experiments were performed with three biological replicates.

ATG6 increases the NPR1 protein levels and the formation of SINCs-like condensates.
(a). NPR1-GFP protein levels in 7-day-old seedlings of NPR1-GFP and ATG6-mCherry × NPR1-GFP after 0.5 mM SA treatment for 0, 3, 6 and 9 h. Numerical values indicate quantitative analysis of NPR1-GFP protein using image J. (b). NPR1-GFP protein levels in N. benthamiana. ATG6-mCherry + NPR1-GFP, NPR1-GFP + mCherry were co-expressed in N. benthamiana. After 2 days, leaves were treated with 1 mM SA for 8, 20, 24 h. Total proteins were extracted and analyzed. Numerical values indicate quantitative analysis of NPR1-GFP protein using image J. (c). ATG6 promotes the formation of SINCs-like condensates. ATG6-mCherry + NPR1-GFP, NPR1-GFP + mCherry were co-expressed in N. benthamiana. After 2 days, leaves were treated with 1 mM SA for 24 h. Confocal images obtained at excitation with wavelengths of 488 nm, scale bar = 50 μm. (d). SINCs-like condensates numbers of per section in (c), n > 10 sections. ** indicates that the significant difference compared to the control is at the level of 0.01 (Student t test p value, ** p< 0.01). All experiments were performed with three biological replicates.

ATG6 improves the protein stability of NPR1.
(a). NPR1-GFP degradation assay in Arabidopsis. Total proteins from 7-day-old seedlings of NPR1-GFP and ATG6-mCherry × NPR1-GFP were extracted, using Actin as an internal reference. “M” indicates MG115 treatment. (b). Quantification of NPR1-GFP degradation rates in (a) using Image J. In (a and b), the extracts were incubated for 0∼180 min at room temperature (25℃), the degradation rate of NPR1-GFP was analyzed. (c). NPR1-GFP protein turnover. 7-day-old NPR1-GFP and ATG6-mCherry × NPR1-GFP seedlings were treated with 100 μM cycloheximide (CHX) for different times. Total proteins were analyzed, Actin was used as an internal reference. (d). Quantification of NPR1-GFP protein turnover rates in (c) using Image J. (e). NPR1-GFP protein turnover. 7-day-old NPR1-GFP and NPR1-GFP/atg5 seedlings were treated with 100 μM cycloheximide (CHX) for different times. Total proteins were analyzed, Actin was used as an internal reference. (f). Quantification of protein levels of NPR1-GFP in (e) using Image J. All experiments were performed with three biological replicates.

ATG6 and NPR1 jointly inhibit the growth of Pst DC3000/avrRps4.
(a). Expression of ATG6 under Pst DC3000/avrRps4 infiltration in 3-week-old Col leaves. (b). Expression of ATG6 in the presence of 0.5 mM SA in 3-week-old Col leaves. (c). The protein levels of ATG6 after 0.5 mM SA in 3-week-old Col leaves. Total leaf proteins from Arabidopsis were analyzed, Actin was used as an internal reference. Numerical values indicate quantitative analysis of ATG6 protein using image J. (d). Growth of Pst DC3000/avrRps4 in Col/silencing ATG6 and Col/negative control (NC). (e). Phenotypes of 16-day-old amiRNA^ATG6 # 1 and amiRNA^ATG6 # 2. Bar, 1 cm. (f). Phenotypes of 23-day-old amiRNA^ATG6 # 1 and amiRNA^ATG6 # 2. Bar, 3 cm. (g). Expression of ATG6 in Col, amiRNA^ATG6 # 1 and amiRNA^ATG6 # 2 under infiltration treatment of 100 μM β-estradiol. (h). Growth of Pst DC3000/avrRps4 in Arabidopsis leaves of amiRNA^ATG6# 1, amiRNA^ATG6 # 2 and Col. (i). Growth of Pst DC3000/avrRps4 in NPR1-GFP/silencing ATG6 and NPR1-GFP/NC. (j). Growth of Pst DC3000/avrRps4 in Arabidopsis leaves of Col, amiRNA^ATG6 # 1, amiRNA^ATG6 # 2, npr1, NPR1-GFP, ATG6-mCherry and ATG6-mCherry × NPR1-GFP. In (d, h-j), a low dose of Pst DC3000/avrRps4 (OD600 = 0.001) was infiltrated. After 3 days, the growth of Pst DC3000/avrRps4 was counted. * or ** indicates that the significant difference compared to the control is at the level of 0.05 or 0.01 (Student t test p value, * p< 0.05 or ** p< 0.01). All experiments were performed with three biological replicates.

Working model for NPR1 regulation by ATG6.
ATG6 interacts directly with NPR1 to increase NPR1 protein level and stability, thereby promoting the formation of SINCs-like condensates and increasing the nuclear accumulation of NPR1. ATG6 synergistically activates PRs expression with NPR1 to jointly enhance resistance to inhibit Pst DC3000/avrRps4 invasion in Arabidopsis.

Physical interaction between NPRs and ATGs in yeast.
The CDS of NPR1, NPR3, NPR4, ATG6 and ATG8d-g were fused to the AD and BD domains, respectively, and co-expressed with yeast cells. Yeast cell growth on SD/-Trp-Leu-His-Ade media represents interaction. Add different concentrations of SA to SD/-Tro-Leu-His-Ade medium to verify the effect of SA on their interactions. All experiments were performed with three biological replicates.

Bimolecular fluorescence complementation assay of NPR1 with ATG6 in N. benthamiana.
Agrobacterium carrying ATG6-nYFP and NPR1-cYFP was co-expressed in leaves of Nicotiana benthamiana for 3 days. As a positive control, NPR1-nYFP and SnRK2.8-cYFP were co-expressed. As negative controls, nYFP and ATG6-cYFP, NPR1-nYFP and cYFP, nYFP and SnRK2.8-cYFP were co-expressed. Confocal images were obtained from chloroplast (Chl), YFP, Bright field. Scale bar = 20 pm. Experiment was performed with three biological replicates.

The nuclear localization of ATG6 in Arabidopsis. Fig. S4 Identification of ATG6-mCherry × NPR1-GFP plants.
(a). The nuclear localization of ATG6-GFP in ATG6-GFP under normal condition. Scale bar, 20 Mm. (b). The nuclear localization of ATG6-mCherry in ATG6-mCherry × NPR1-GFP. Scale bar, 100 um. (c). Predicted subcellular localization of ATG6 by Arabidopsis database (https://suba.live/). (d). ATG6-GFP and free GFP protein levels in ATG6-GFP Arabidopsis. (e). ATG6-GFP and free GFP protein levels in N. benthamiana. Black asterisk (*) indicate ATG6-GFP bands. All experiments were performed with three biological replicates.

Identification of ATG6-mCherry × NPR1-GFP plants.
(a). Total proteins from 7-day-old seedlings were extracted. Western blots analysis with ATG6 and GFP antibodies. Actin was used as an internal reference. Black asterisk (*) indicate ATG6-mCherry bands. (b). NPR1-GFP and free FP protein levels in 7-day-old seedlings of NPR1-GFP and ATG6-mCherry × NPR1-GFP plants after 0.5 mM SA treatment for 0, 3, 6 and 9 h. Numerical values indicate the ration of NPR1-GFP/free FP. All experiments were performed with three biological replicates.

Subcellular fractionation of endogenous ATG6 in Col after 0.5 mM SA treatment for 0, 3, 6 and 20 h.
Cytoplasmic and nuclear proteins were extracted from Arabidopsis. Endogenous ATG6 were detected using ATG6 antibody. Actin and H3 were used as cytoplasmic and nucleus internal reference, respectively. Numerical values indicate quantitative analysis of ATG6 using image J.

Overexpression of ATG6 delayed dark-induced leaf senescence. Fig. S7 Expression of ICS1 under normal and SA treatment conditions.
(a). Phenotypes of detached rosette leaves from 3-week-old of Col, amiRNAATG6 # 1, amiRNAATG6 # 2, ATG6-mCherry, ATG6-GFP and atg5 under constant dark treatment for 4 days. Bar = 1 cm. (b). Relative chlorophyll content in (a). ** indicates that the significant difference compared to the Col is at the level of 0.01 (Student t test p-value, ** p < 0.01).

Expression of ICS1 under normal and 0.5 mM SA treatment conditions.
** indicates that the significant difference compared to the control is at the level of 0.01 (Student t test p value, ** p< 0.01). Experiment was performed with three biological replicates.

Expression of PR1 and PR5 in Col and ATG6-mCherry under normal and Pst DC3000/avrRps4 treatment.
** indicates that the significant difference compared to the control is at the level of 0.01 (Student t test o value, ** p< 0.01). Experiment was performed with three biological replicates.

The protein level of NPR1-GFP in NPR1-GFP/silencing ATG6 and NPR1-GFP/Negative control.
The mixture of AuNPs-amiRNAATG6 or AuNPs-amiRNA^{Ngeative control} was performed by pressure infiltration through the abaxial leaf surface. After 3 days, NPR1-GFP protein levels were detected by treating with 0.5 mM SA for 0, 3, and 6 h.

Expression of NPR1 in Col and ATG6-mCherry under normal and Pst DC3000/avrRps4 treatment.
** indicates that the significant difference compared to the control is at the level of 0.01 (Student t test p value, ** p< 0.01). Experiment was performed with three biological replicates.

ATG6 improves the protein stability of NPR1 in N. benthamiana.
(a). NPR1-GFP degradation assay in N. benthamiana. Total proteins from N. benthamiana co-transfected with Cherry + NPR1-GFP and ATG6-mCherry + NPR1-GFP were extracted. CBB was used as a control. (b). Quantification of NPR1-GFP degradation rates in (a) using Image J. All experiments were performed with three biological replicates.

Structural analysis of acidic activation domains in ATG6.
Acidic (red) and hydrophobic (blue) amino acid residues in AADs.

NPR1-GFP degradation assay in ATG6-mCherry x NPR1-GFP Arabidopsis.
(a). Trypan blue staining showing cell death in the leaves of Col, amiRNAATG6 # 1, amiRNAATG6 # 2, npr1, NPR1-GFP, ATG6-mCherry and ATG6-mCherry × NPR1-GFP. A low dose of Pst DC3000/avrRps4 (OD600 = 0.001) was infiltrated. After 3 days, Trypan blue staining was performed, Bar, 0.2 cm. (b). Number of dead cells per section in the leaves of Col, amiRNA^ATG6 # 1, amiRNA^ATG6 # 2, npr1, NPR1-GFP, ATG6-mCherry and ATG6-mCherry × NPR1-GFP in (a). ** indicates that the significant difference compared to the control is at the level of 0.01 (Student t test p value, ** p< 0.01).

NPR1-GFP degradation assay in ATG6-mCherry × NPR1-GFP Arabidopsis.
Total proteins from 7-day-old seedlings of ATG6-mCherry × NPR1-GFP were extracted. These extracts were then incubated at room temperature (25°C) for 0~120 minutes to analyze the degradation rate of NPR1-GFP. To inhibit the proteasome pathway, 100 MM MG115 was utilized. Additionally, autophagy was inhibited using 5 uM concanamycin A and 30 uM Wortmannin. The analysis of NPR1-GFP was quantitatively performed using Image J software, and the corresponding numerical values were determined.

Verification of ATG6 antibody specificity.
(a). Prokaryotic expression of the GST-ATG6 fusion protein was used to verify the specificity of the ATG6 antibody, and GST and GST-SnRK2.8 were used as negative controls. GST-ATG6 bands was marked with a black asterisk. (b). The levels of ATG6 protein. Levels of ATG6-mCherry and endogenous ATG6 in Col, amiRNA^ATG6 # 1, amiRNA^ATG6 # 2 and ATG6-mCherry were detected after 100 uM estradiol treatment for 24 h.

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