The plant pathogen Pseudomonas aeruginosa triggers a DELLA-dependent seed germination arrest in Arabidopsis

To anticipate potential seedling damage, plants block seed germination under unfavorable conditions. Previous studies investigated how seed germination is controlled in response to abiotic stresses through gibberellic and abscisic acid signaling. However, little is known about whether seeds respond to rhizosphere bacterial pathogens. We found that Arabidopsis seed germination is blocked in the vicinity of the plant pathogen Pseudomonas aeruginosa. We identified L-2-amino-4-methoxy-trans-3-butenoic acid (AMB), released by P. aeruginosa, as a biotic compound triggering germination arrest. We provide genetic evidence that in AMB-treated seeds DELLA factors promote the accumulation of the germination repressor ABI5 in a GA-independent manner. AMB production is controlled by the quorum sensing system IQS. In vitro experiments show that the AMB-dependent germination arrest protects seedlings from damage induced by AMB. We discuss the possibility that this could serve as a protective response to avoid severe seedling damage induced by AMB and exposure to a pathogen.


Introduction
Seeds are remarkable structures promoting plant dispersal by preserving the plant embryo in a desiccated and highly resistant state. Their appearance in the course of land plant evolution is regarded as a cornerstone of the striking spread and diversification of angiosperms among terrestrial plants.
Seed imbibition with water is the necessary first step to permit germination, transforming the embryo into a fragile juvenile seedling. However, upon imbibition, the seed is also exposed to potentially fatal environmental conditions for the future seedling. To avoid premature death, plants have evolved control mechanisms that block germination under unfavorable conditions to maintain the highly protected embryonic state (Lopez-Molina et al., 2001;2002).
Historically, studies focused on how seeds respond to abiotic stresses such as high temperature, canopy light -unfavorable for photosynthesis-or high salinity (Baskin and Baskin, 1998;Reynolds and Thompson, 1971;Negbi et al., 1968). In Arabidopsis, perception of abiotic factors leads to changes in seed endogenous levels of gibberellic acid (GA) and abscisic acid (ABA), two phytohormones playing a central role to control germination (Cutler et al., 2010;Lau and Deng, 2010;Nonogaki, 2014;Davière and Achard, 2016). Under favorable conditions, GA synthesis increases, which is necessary to initiate germination. GA induces proteolysis of DELLA factors repressing germination, which are encoded by a family of five genes: RGL2, GAI, RGA, RGL1 and RGL3.
DELLA factors collectively repress germination by promoting the accumulation of ABA and ABAresponse transcription factors (TFs) ultimately repressing seed germination such as ABI3 and ABI5 (Lee et al., 2002;Penfield et al., 2006;Lee et al., 2010a;Lopez-Molina and Chua, 2000;Lopez-Molina et al., 2001;2002;Finkelstein and Lynch, 2000;Piskurewicz et al., 2008;. RGL2 can play a prominent role among DELLAs to stimulate ABA signaling and thus repress germination. Indeed, only rgl2 mutants can germinate when seeds are treated with a GA synthesis inhibitor (Lee et al., 2002;Piskurewicz et al., 2008). This is likely due to the positive regulation of RGL2 mRNA levels by ABA, which generates a positive feedback loop sustaining high RGL2 accumulation relative to other DELLAs (Piskurewicz et al., 2008(Piskurewicz et al., , 2009. How DELLA factors stimulate ABA signaling in seeds remains to be understood. DELLAs are unable to directly bind to DNA and thus are more likely to interact with TFs or other factors regulating ABA signaling. Recent work has shown that DELLA protein activity is regulated through phosphorylation, SUMOylation, O-GlcNAcylation, or O-fucosylation (Conti et al., 2014;Qin et al., 2014;Zentella et al., 2016Zentella et al., , 2017. Along with abiotic factors, seeds are also continuously confronted to bacteria, fungi and animals (e.g. nematodes) present in soil and potentially acting as pathogens or commensals (Silby et al., 2011). Little is known about whether biotic factors released by non-plant organisms induce seed germination responses in plants. To address this question in the model plant Arabidopsis, we considered the case of Pseudomonas, a genus of Gram-negative bacteria having pathogenic and commensal interactions with both animals and plants (Silby et al., 2011).
We confronted Arabidopsis seeds to different Pseudomonas species and found a strong germination repressive activity (GRA) released by Pseudomonas aeruginosa. Strikingly, P. aeruginosa did not repress the germination of Arabidopsis mutant seeds lacking DELLA factors or ABA signaling eLife digest The plant embryo within a seed is well protected. While it cannot stay within the seed forever, the embryo can often wait for the right conditions before it develops into a seedling and continues its life cycle. Indeed, plants have evolved several ways to time this process -which is known as germination -to maximize the chances that their seedlings will survive. For example, if the environment is too hot or too dark, the seed will make a hormone that stops it from germinating.
In addition to environmental factors like light and temperature, a seed in the real word is continuously confronted with soil microbes that may harm or benefit the plant. However, few researchers have asked whether seeds control their germination in response to other living organisms.
The bacterium Pseudomonas aeruginosa lives in a wide spectrum of environments, including the soil, and can cause diseases in both and plants and animals. Chahtane et al. now report that seeds of the model plant Arabidopsis thaliana do indeed repress their germination when this microbe is present. Specifically, the seeds respond to a molecule released from the bacteria called L-2-amino-4methoxy-trans-3-butenoic acid, or AMB for short. Like the bacteria, AMB is harmful to young seedlings, but Chahtane et al. showed that the embryo within the seed is protected from its toxic effects.
Further experiments revealed that the seed's response to the bacterial molecule requires many of the same signaling components that repress germination when environmental conditions are unfavorable. However, Chahtane et al. note that AMB activates these components in an unusual way that they still do not understand.
The genes that control the production of AMB are known to also control how bacterial populations behave as they accumulate to high densities. It is therefore likely that Pseudomonas aeruginosa would make AMB if it reached a high density in the soil. This raises the possibility that plants have specifically evolved to stop germination if there are enough microbes nearby to pose a risk of disease. This hypothesis, however, is only one of several possible explanations and remains speculative at this stage; further work is now needed to evaluate it. Nevertheless, identifying how AMB interferes with the signaling components that control germination and plant growth may guide the design of new herbicides that could, for example, control weeds in the farming industry.
components. Metabolomic and bioguided biochemical fractionation approaches led us to identify the oxyvinylglycine L-2-amino-4-methoxy-trans-3-butenoic acid (also referred as methoxyvinylglycine or AMB) as the main GRA released by P. aeruginosa. AMB production and release is dependent on the five-gene operon ambABCDE controlling the newly identified quorum-sensing IQS in P. aeruginosa (Lee et al., 2010b(Lee et al., , 2013a. Using synthetic AMB, we provide genetic evidence that the activity of DELLAs to stimulate ABA-dependent responses is enhanced in seed exposed to AMB. Whether this reflects a mechanistic link between AMB and DELLAs is not known. Furthermore, AMB induces severe developmental defects in juvenile seedlings. In contrast, germination-arrested seeds are capable to produce viable plants when no longer exposed to AMB or P. aeruginosa. Oxyvinylglycines are known to inhibit irreversibly pyridoxal phosphate (PLP)-dependent enzymes (Berkowitz et al., 2006). Furthermore, AMB is a methionine analog. Our results suggest that AMB does not block germination by interfering with ethylene, auxin or methionine synthesis. Rather, our results indicate that AMB interferes with an unknown and GA-independent mechanism promoting DELLA-dependent germination arrest, which involves DELLA-dependent stimulation of ABA signaling. We discuss possible interpretations of our findings, including the possibility that the germination arrest could serve as a protective response to avoid severe seedling damage induced by AMB and exposure to a pathogen.

Arabidopsis seed germination is repressed by Pseudomonas aeruginosa
We explored whether Pseudomonas bacteria release compounds inhibiting Arabidopsis seed germination as follows: (1) individual Pseudomonas species were propagated for 3 days on germination agar medium supplemented with a carbon source; (2) thereafter Arabidopsis seeds were sown on the germination medium at various distances from the bacteria; (3) germination was scored after culturing seeds for 3 days (Materials and methods, Figure 1-figure supplement 1A). Germination was not markedly repressed by P. fluorescens, P. putida, P. syringae or Escherichia coli (used as a Gram-negative non-Pseudomonas species control) ( Figure 1A and B). In marked contrast, germination was strongly repressed by P. aeruginosa (WT strains PAO1 and PA14) ( Figure 1A and B). The percentage of germination increased with increasing distance separating seeds and P. aeruginosa ( Figure 1A and Figure 1-figure supplement 1B). Furthermore, germination arrest did not occur in absence of germination medium separating bacteria and seeds ( Figure 1-figure supplement 1C).
From these observations, we conclude that P. aeruginosa releases a germination repressive activity (GRA) that diffuses in the germination medium.
The GRA released by P. aeruginosa stimulates GA and ABA signaling pathways to repress seed germination Upon imbibition seeds respond to unfavorable abiotic conditions by blocking GA synthesis, which promotes DELLA factors accumulation. In turn, DELLA factors collectively repress seed germination by stimulating ABA signaling including the accumulation of the germination repressor TF ABI5 (Piskurewicz et al., 2008(Piskurewicz et al., , 2009. We studied whether GA and ABA signaling pathways play a role to repress germination in seeds exposed to P. aeruginosa. GA signaling mutant seeds, lacking one or several DELLA factors and particularly Ddella mutant seeds lacking all five DELLA factors, had a higher percentage of seed germination in presence of WT P. aeruginosa (PAO1) (Figure 2A). Furthermore, Arabidopsis mutant seeds deficient in ABA synthesis (aba1) or signaling (abi3, abi5) also had a higher percentage of seed germination in presence of P. aeruginosa (PAO1) ( Figure 2B). We also exposed seeds to lyophilized extracts of P. aeruginosa liquid culture medium (Materials and methods, Figure 2-figure supplement 1A). These bacteria-free extracts (thereafter referred as 'extracts') also elicited DELLA-dependent germination arrest responses (Figure 2-figure supplement 1B, C and D).
We monitored the accumulation of the DELLA factor RGL2 and the ABA response TF ABI5 in seeds exposed to P. aeruginosa. In absence of bacteria, RGL2 and ABI5 were detectable during the first 44 hr upon seed imbibition but their accumulation decreased thereafter, which was associated with increasing germination percentage, consistent with previous reports (  after sowing WT seeds in germination medium lacking bacteria (MS) or containing a given Pseudomonas species as indicated. Escherichia coli was included as a Gramnegative non-Pseudomonas species control. Note that seeds in close proximity of P. aeruginosa strains mostly did not germinate. Red arrows indicate distance used to calculate germination percentage in B. (B) Same experiment as in A. Representative pictures of plants 4 days after sowing seeds in germination medium in absence (MS) or presence of bacteria as indicated. Histograms show seed germination percentage 4 days upon sowing seeds in absence (MS) or presence of bacteria as indicated. Data represent mean ± standard deviation (nine replicates, n = 300-350). Lower case letters above histograms are used to establish whether two seed germination percentage values are statistically significantly different as assessed by one-way ANOVA followed by a Tukey HSD test (p<0.05): different letters denote statistically different values. DOI: https://doi.org/10.7554/eLife.37082.003  (Lee et al., 2002;Piskurewicz et al., 2008). However, WT seeds exposed to P. aeruginosa (PAO1) persistently accumulated RGL2 and ABI5 up to 148 hr upon imbibition, which was associated with low germination percentage ( Figure 2C). In contrast, Ddella mutant seeds exposed to P. aeruginosa extracts did not maintain ABI5 accumulation over time upon imbibition, which was associated with increasing germination percentage ( Figure 2D). These observations indicate that the GRA released by P. aeruginosa represses germination by promoting DELLA-dependent increase of the germination repressor ABI5, as previously shown with seeds unable to synthesize GA upon imbibition (Piskurewicz et al., 2008(Piskurewicz et al., , 2009).
The GRA released by P. aeruginosa elicits DELLA-dependent responses in a GA-independent manner However, and surprisingly, exogenous GA (10 mM) did not promote germination of WT seeds exposed to P. aeruginosa extracts ( Figure 3A). This was associated with persistent accumulation of RGL2 and ABI5 ( Figure 3B). In contrast, and expectedly, exogenous GA promoted the germination of WT seeds exposed to paclobutrazol (PAC), an inhibitor of GA synthesis, which was associated with downregulation of RGL2 and ABI5 protein levels, consistent with previous results ( Figure 3A, Figure 3-figure supplement 1 and Figure 5B). Thus, the GRA could elicit a DELLA-dependent germination arrest irrespective of GA levels in seeds.
To further study how the GRA triggers a DELLA-dependent germination arrest, we compared the early transcriptome of WT and Ddella seeds exposed to PAC or P. aeruginosa (PAO1) extract (Materials and methods, Figure 3C and D). We also included in the analysis the effect of exogenous GA (Materials and methods).
The expression of as many as 1103 genes was changed in PAC-treated WT seeds relative to untreated WT seeds (MS vs PAC, Figure 3C, Supplementary file 1). In contrast, only three genes had their expression affected in PAC-treated Ddella seeds relative to untreated Ddella seeds (MS vs PAC, Figure 3C, Supplementary file 1). Furthermore, only 36 and 2 genes had their expression changed when WT and Ddella seeds were treated with both PAC and GA (10 mM), respectively (MS vs PAC + GA, Figure 3C, Supplementary file 1). Thus, DELLA factors influence gene expression mainly when GA synthesis is compromised, consistent with previous reports (Cao et al., 2006).
In contrast to PAC-treated WT seeds, only 130 genes had their expression changed in WT seeds exposed to PAO1 extract relative to non-exposed WT seeds (MS vs PAO1 extract, Figure 3D, Supplementary file 2). Among the 130 genes, the expression of 87 genes was DELLA-dependent since it did not change in Ddella seeds exposed to PAO1 extract ( Figure 3D, Supplementary file 2). Strikingly, about a quarter of the 87 genes (24 genes) had their expression unchanged when GA was included in the medium together with PAO1 extract (MS vs PAO1 extract +GA, Figure 3D).
Altogether, these results show that the GRA released by P. aeruginosa is able to elicit gene expression responses in a DELLA-dependent and GA-independent manner.
Release of the GRA by P. aeruginosa requires functional LASI/RHLI and IQS quorum sensing systems We next sought to identify the GRA by first identifying P. aeruginosa genes that are necessary to its release.
Bacteria have a quorum sensing (QS) system regulating gene expression to mount coordinated behavioral responses when a bacterial population reaches high densities (Ng and Bassler, 2009). The P. aeruginosa QS has four QS subsystems influencing each other: 1) las, 2) rhl, 3) pqs and 4) the recently discovered IQS (for 'Integrating the QS network'). Each subsystem consists of genes or operons producing signaling molecules, referred as autoinducers, which interact with and activate . Arabidopsis plants include WT (Col-0) seeds and rgl2, rgl2/rga, rgl2/rga/gai (3D) and rgl2/rga/gai/rgl1/rgl3 (Ddella) mutant seeds as indicated. Seeds and P. aeruginosa cells were separated by 2 cm. Histograms show seed germination percentage 3 days upon sowing seeds in absence (MS) or presence (PAO1) of bacteria as shown. Seeds and P. aeruginosa cells were separated by 2 cm. Data represent mean ± standard deviation (five replicates, n = 200-250). Statistical treatment and lower case letters as in Figure 1B. (B) Same as in A. using ABA synthesis and signaling mutant seeds. Mutants included aba1 (deficient in ABA synthesis), abi3 and abi5 as indicated. Histograms show seed germination percentage 3 days upon sowing seeds in absence (MS) or presence (PAO1) of bacteria as indicated. Seeds and P. aeruginosa cells were separated by 2 cm. Data represent mean ± standard deviation (four replicates, n = 150-200). Statistical treatment and lower case letters as in Figure 1B. (C) Protein gel blot analysis of a time course of RGL2 and ABI5 protein levels upon WT (Col-0) seed imbibition in the absence (MS) or presence of P. aeruginosa (PAO1). Seeds and P. aeruginosa cells were separated by 2 cm. DS, dry seeds. UGPase protein levels are used as a loading control. Germination percentage at each time point is indicated. (D) Protein gel blot analysis of a time course of ABI5 protein levels upon WT (Col-0) and Ddella seed imbibition in the absence (MS) Figure 2 continued on next page cognate transcription factors controlling bacterial coordinated behavior (Lee and Zhang, 2015;Papenfort and Bassler, 2016;Moradali et al., 2017).
We asked whether the GRA released by P. aeruginosa is under QS control. We exposed WT seeds to P. aeruginosa mutant strains deficient in (1) the LASI and RHLI operons (DlasIDrhlI double mutants), which control the production of the homoserine lactones autoinducers, (2) the PQS operon (DpqsA and DpqsH mutants), which controls the production of the quinolones autoinducers and (3) the AMB operon (DambE mutant), which is necessary for the production of the autoinducer 2-(2hydroxyphenyl)-thiazole-4-carbaldehyde (IQS) (Lee et al., 2013a).
We observed markedly lower GRAs released by DlasIDrhlI and particularly with DambE mutants ( Altogether, these results show that the GRA released by P. aeruginosa is dependent on QS activity and particularly that of IQS. The importance of IQS is further suggested by the fact that P. aeruginosa is the only Pseudomonas species used in this study having the IQS QS ( Figure 1A L-2-amino-4-methoxy-trans-3-butenoic acid (AMB) is the main GRA released by P. aeruginosa.
We undertook an unbiased metabolomic approach complemented with biochemical purification procedures to identify the GRAs present in P. aeruginosa extracts (Figure 4-figure supplement 2).
In the metabolomic approach, untargeted UHPLC-HRMS 2 (Ultra-High-Performance Chromatography hyphenated to High-Resolution Tandem Mass Spectrometry) data were acquired from extracts of P. aeruginosa strains releasing a GRA (PAO1 and Dpqsa), not releasing a GRA (DambE and DlasI/ rhlI) or releasing a higher GRA (AMBox) (Materials and methods, We next used chromatographic methods to fractionate WT PAO1, AMBox and DambE extracts, which led to the identification of a GRA present in a polar fraction of WT PAO1 and AMBox extracts but absent in that of DambE extracts (Materials and methods, . AMB present in this purified fraction is hereafter referred as 'AMBi'. Altogether, these results point to AMB as being the main GRA. Consistent with this hypothesis synthetic AMB dose response for germination inhibition confirmed that AMB inhibits WT seed germination ( Figure 4C). Furthermore, mutant seeds deficient in GA signaling (Ddella), ABA biosynthesis (aba1) or ABA signaling (abi3,) had a higher percentage of seed germination in presence of synthetic AMB ( Figure 4D).
A concentration of 50 mM synthetic AMB had a GRA equivalent to that 0.8 mg/ml PAO1 extract in germination plates (see dashed red line in Figure 4C E). However, we estimated that this extract concentration provides only 16 mM of natural AMB (quantification by targeted UHPLC-HRMS 2 approach, Figure 4-figure supplement 8). This discrepancy could be explained as follows: (1) there are other compounds present in PAO1 extracts enhancing the GRA of AMB, (2) AMB is not the only compound released by P. aeruginosa having a substantial GRA. To test the first possibility, we supplemented DambE extracts, lacking AMB, with synthetic AMB so as to match the amount of AMB naturally present in PAO1 extracts. The GRA of the AMB-supplemented DambE extract was similar to that present in PAO1 extracts ( Figure 4E).
Furthermore, we also purified the natural AMB present in Pseudomonas extracts (Materials and methods, Figure  Taken together, these results strongly suggest that the GRA of synthetic AMB can be enhanced by the presence of other compounds present in P. aeruginosa extracts. We also tested the GRA of aminoethoxyvinylglycine (AVG), another oxyvinylglycine. As much as 200 mM of AVG of did not noticeably repress Arabidopsis seed germination, consistent with previous reports, indicating that AMB is an oxyvinylglycine specifically repressing Arabidopsis seed germination (Figure 4-figure supplement 10) (Wilson et al., 2014). AVG is known to inhibit ethylene synthesis, suggesting that AMB does not block germination by inhibiting ethylene synthesis (further discussed below) (Adams and Yang, 1979;Huai et al., 2001;Capitani et al., 2002).
We next verified whether AMB could recapitulate the effects of P. aeruginosa cells or WT PAO1 extracts on RGL2 and ABI5 protein accumulation. WT seeds exposed to AMB persistently accumulated RGL2 and ABI5 over time, unlike unexposed seeds ( Figure 5A). Persistent high ABI5 accumulation was not observed in AMB-treated Ddella mutant seeds ( Figure 5A). Furthermore, beyond 24 hr of imbibition in presence of AMB, PAC and GA, RGL2 protein levels persisted in seeds despite the presence of GA, unlike seeds treated with PAC and GA only ( Figure 5B). This was associated with persistent ABI5 accumulation and absence of seed germination ( Figure 5B). Thus, AMB induces changes in RGL2 and ABI5 accumulation in a manner similar to that observed with P. aeruginosa or WT PAO1 extracts (Figures 2C,D and 3B).
Altogether, these results conclusively show that AMB is the main GRA released by P. aeruginosa repressing germination in a DELLA-and ABA-signaling-dependent manner.  Figure 1B. (B) Protein gel blot analysis of RGL2 and ABI5 levels in WT (Col) seeds 24 hr and 64 hr after imbibition in the absence (MS) or presence of WT P. aeruginosa extract without (PAO1 extract) or with 10 mM GA (PAO1extract + GA) as indicated. UGPase protein levels are used as a loading control. Germination percentage at each time point is indicated. The asterisk (*) represents and unspecific banc detected by the RGL2 antibody. (C) Diagram describes the procedure to isolate seed RNA in order to compare early transcriptomes of WT and Ddella seed exposed to PAC or PAC with GA. Total RNA isolated from WT (Col-0) and Ddella seeds imbibed for 20 hr in the absence (MS) or presence of 5 mM paclobutrazol without (PAC) or with 10 mM GA (PAC + GA) was used for RNAseq analysis (two replicates). The red and green horizontal lines represent individual genes whose mRNA expression is significantly upregulated (red) or downregulated (green) by at least twofold under different seed treatments as follows: left column represents the 1103 genes whose expression is either upregulated or downregulated in PAC-treated seeds relative to non-treated seeds (MS) (blue asterisk indicates the genes whose expression does not change in PAC-treated Ddella seeds); middle column represents the expression of the 1103 genes in seeds treated with PAC and GA (PAC + GA) relative to non-treated WT seeds (MS); right column represents the expression of the 1103 genes in Ddella seeds treated with PAC relative to nontreated seeds (MS). The scale bar relates color with absolute fold changes. Black color represents no change in gene expression. (D) Same experiment as in C using WT and Ddella seed exposed to WT P. aeruginosa extract without (PAO1 extract) or with 10 mM GA (PAO1extract + GA) as indicated. 0.7 mg/ml of WT P. aeruginosa extract was used. Red asterisk indicates the genes whose expression does not change in Ddella seeds treated with PAO1 extract.  . The GRA is under the control of the P. aeruginosa LASI/RHLI and IQS QS systems. L-2-amino-4-methoxy-trans-3-butenoic acid (AMB) is the main GRA released by P. aeruginosa. (A) Histograms show seed germination percentage 4 days upon sowing seeds in absence (MS) or presence of WT P. aeruginosa (PAO1) or mutant P. aeruginosa strains as indicated. PAO1 is the reference WT P. aeruginosa strain from which all the QS mutant strains were derived. Seeds and P. aeruginosa cells were separated by 2 cm. Data represent mean ± standard deviation (four replicates, n = 150-200). Statistical treatment and lower case letters as in Figure 1B. (B) Same experiment as in A. using P. aeruginosa DambA-E mutants, as indicated, each affected in individual AMB operon genes. Data represent mean ± standard deviation (three replicates, n = 100-150). Statistical treatment and lower case letters as in Figure 1B. (C) AMB represses Arabidopsis seed germination in a DELLA-dependent manner. Pictures show representative Arabidopsis plants 4 days after sowing WT and Ddella seeds in presence of different AMB concentrations as indicated. The graph shows quantification of the germination percentage of WT and Ddella seeds exposed to AMB. The red dashed line indicates the concentration of synthetic AMB (50 mM) having the same GRA as that present in germination plates containing 0.8 mg/ml of PAO1 extracts (see Figure 4E). Data represent mean ± standard deviation (three replicates, n = 150-200). (D) AMB represses Arabidopsis seed germination in an ABA-dependent manner. Histograms show Figure 4 continued on next page Genetic experiments indicate that DELLA factor activity to stimulate ABA signaling is enhanced in AMB-treated seeds To better understand the genetic requirement of functional DELLA genes for the AMB-dependent germination arrest, we focused on the DELLA factors RGL2, GAI and RGA (Piskurewicz et al., 2008;. We asked whether GA-dependent DELLA protein degradation was perturbed in AMB-treated seeds. WT seeds were imbibed under normal (MS) conditions or in presence of PAC, AMB or ABA. As expected, RGL2, GAI and RGA protein levels markedly increased in presence of PAC, consistent with the notion that low GA stabilizes DELLA proteins ( Figure 6A, B and C, Figure 2-figure supplement 2C). In contrast, no marked increase in RGL2, GAI and RGA protein levels was observed in presence of AMB or ABA despite the fact that both treatments arrested seed germination as in PAC-treated seeds ( Figure 6A, B and C). germination percentage of WT, aba1, abi3 and Ddella 3 days after sowing seeds in absence (MS) or presence of 50 mM of synthetic AMB. Data represent mean ± standard deviation (two replicates, n = 100-150). Statistical treatment and lower case letters as in Figure 1B. (E) Synthetic AMB introduces a GRA in DambE extracts equivalent to that of PAO1 extracts. DambE extracts, which lack AMB, were supplemented with synthetic AMB so as to obtain the same amount of AMB naturally present in PAO1 extracts. Pictures show representative Arabidopsis plants 4 days after sowing WT seeds in absence (MS) or presence of WT P. aeruginosa extracts (PAO1extract) or DambE P. aeruginosa extracts (DambEextract) or AMB-supplemented DambE extracts (DambEextract + AMB). 0.8 mg/ml of WT P. aeruginosa extract was used. The graph shows quantification of the germination percentage of WT seeds exposed to the different extract concentrations as indicated. Note that the supplemented DambE extract (DambEextract + AMB) has a GRA equivalent, if not higher, than that of PAO1 extract. The red dashed line indicates the concentration of PAO1 extract (0.8 mg/ml) having the same GRA as that present in germination plates containing 50 mM synthetic AMB (see Figure 4C). Data represent mean ± standard deviation (six replicates, n = 250-300). We also monitored the extinction of RGL2, GAI and RGA protein accumulation upon exposure to GA in absence or presence of AMB ( Figure 6D, Figure 6-figure supplement 1A and B). WT seeds were first treated for 30 hr with PAC to allow for DELLA protein stabilization and high accumulation. After 30 hr seeds were further treated with AMB for 12 hr to ensure AMB presence within seed tissues prior to adding GA. Upon addition of GA to the medium RGL2, RGA and GAI protein levels decreased over 28 hr in a similar manner to that observed in control plates lacking AMB ( Figure 6D, Figure 6-figure supplement 1A and B). Penetrance of AMB within seeds was confirmed by the absence of seed germination of AMB-treated seeds despite the presence of GA ( Figure 6D).
Altogether, these results strongly suggest that GA-dependent DELLA protein degradation is not affected in AMB-treated seeds.
RGL2 persistently accumulated at late time points upon seed imbibition in presence of AMB despite the presence of GA ( Figure 5B). Furthermore, ABA signaling in seeds promotes RGL2 mRNA accumulation as well as that of ABI5 (Lopez-Molina et al., 2001;Piskurewicz et al., 2008;. We therefore hypothesized that the DELLA activity promoting ABA signaling in seeds is enhanced in AMB-treated seeds (Lopez-Molina et al., 2001;Piskurewicz et al., 2008;. In turn, this would explain the persistent RGL2 and ABI5 protein accumulation in AMB-treated seeds ( Figures 2C,4A B).
To test this hypothesis genetically, we measured RGL2 and ABI5 mRNA levels using total RNA isolated 30 hr and 44 hr upon imbibition from the same seed material used in Figure 5A. We also analyzed the expression of the ABA-responsive genes EM1 and NCED6 (Lopez-Molina and Chua,   Lefebvre et al., 2006;Martínez-Andújar et al., 2011). Upon 30 hr of imbibition, seed accumulated the same RGL2 levels in absence (MS) or presence of AMB (AMB) ( Figure 5A). Nevertheless, AMB-treated seeds accumulated markedly higher ABI5, EM1 and NCED6 mRNA levels relative to seeds imbibed in absence of AMB ( Figure 6E). In contrast, AMBtreated Ddella mutant seeds accumulated lower ABI5, EM1 and NCED6 mRNA expression at 30 hr ( Figure 6E). Upon 44 hr of imbibition, AMB-treated seeds further increased the expression of ABI5, EM1 and NCED6 mRNA as well as that of RGL2 ( Figure 6E).
Collectively, these genetic observations support the notion that the DELLA activity promoting ABA signaling in seeds is enhanced in AMB-treated seeds ( Figure 7E). Whether this is the result of a direct interaction between AMB and DELLAs is not known.
Interestingly, AMB could still mildly stimulate EM1, NCED6 and particularly ABI5 mRNA expression in Ddella mutant seeds ( Figure 6E). Accordingly, ABI5 protein accumulation, although diminishing, remained higher 44 hr and 68 hr after imbibition of AMB-treated Ddella seeds relative to nontreated seeds ( Figure 5A). These genetic observations suggest that a residual activity promoting ABA synthesis or signaling independently of DELLA factors is present in AMB-treated seeds.
Germination arrested seeds are protected from developmental abnormalities triggered by AMB The relative proportion of germinating seeds relative to non-germinating seeds depended on the distance separating seeds from P. aeruginosa cells or on the concentration of AMB used in the germination plate ( Figure 1A, Figure 1-figure supplement 1). Seeds that germinated in either presence of P. aeruginosa or AMB similarly produced pale seedlings whose growth was severely delayed bearing diminutive roots ( Figure 7A). These developmental defects diminished with increased distance between seeds and bacteria or decreased AMB concentrations. Furthermore, they were no longer observed in seeds exposed to DambE P. aeruginosa mutants, unable to produce AMB ( Figure 7A). Altogether, these observations show that AMB released by P. aeruginosa severely perturbs seedling development.
Remarkably, within a seed population exposed to P. aeruginosa, WT seeds that did not germinate germinated upon transfer to plates lacking P. aeruginosa and produced normal seedlings ( Figure 7B). The resulting WT seedlings produced a normal seed yield ( Figure 7C). In contrast, WT seeds that had germinated in presence of P. aeruginosa failed to recover ( Figure 7B). Furthermore, when WT and Ddella seeds were exposed for 3 days to P. aeruginosa prior to transfer to a bacteriafree medium, WT seeds had a higher survival rate relative to Ddella seeds ( Figure 7D).
These observations therefore strongly suggest that germination-arrested seeds in presence of AMB are able to retain their vitality unlike newly emerged seedlings.

Discussion
Whether biotic factors present in the soil affect seed germination responses is poorly understood. Here we show that Arabidopsis seeds respond when exposed to P. aeruginosa by blocking their germination. This involves perception of the oxyvinylglycine AMB released by P. aeruginosa, which triggers a DELLA-dependent seed germination arrest.

Oxyviniglycines differentially affect seed germination
Oxyvinylglycines are a class bacterially produced compounds whose biological function is unclear.
Oxyvinylglycines are known to inhibit irreversibly pyridoxal phosphate (PLP)-dependent enzymes (Berkowitz et al., 2006). Oxyvinylglycines had been previously associated with germination repressive activities (GRAs) after exposing graminaceous (Poaceae) seeds to bacterial culture filtrates. The best documented cases are those of AVG (aminoethoxyvinylglycine, produced by Streptomyces sp) and FVG (4-formylaminooxyvinylglycine, produced by Pseudomonas fluorescens strain WH6) that were directly and indirectly linked with a GRA, respectively (McPhail et al., 2010;Okrent et al., 2017). Only in the case of AVG a GRA could be established using a pure synthetic compound: 100 mM AVG inhibited the germination of Poa annua seeds. However, we found here that as much as 200 mM AVG did not inhibit Arabidopsis seed germination, consistent with previous reports (Wilson et al., 2014). More recently, using Poa seeds, Lee et al. also found a weak GRA in culture filtrates from P. aeruginosa strains overexpressing the AMB operon (AMBox) relative to that of AVG and FVG (Lee et al., 2013b). However, the concentrations of AMB or FVG in the germination assays were unspecified and no synthetic compound was used to directly test their intrinsic GRA. Furthermore, dicot seeds are less responsive to P. fluorescens culture filtrates than graminaceous monocot seed, suggesting that FVG is less active to repress the germination of dicot seeds including seeds of cabbage, which is a brassicaceae (Banowetz et al., 2008). We found that AMB-containing WT PAO1 extracts inhibited the germination of brassicaceae seeds, including cabbage seeds, unlike Altogether, these results indicate that oxyvinylglycines do not affect seed germination in the same manner. They also strongly suggest that AMB is an oxyvinylglycine able to repress the germination of several seed dicot species.
Furthermore, brassicaceae seeds that germinated in presence of WT PAO1 extracts developed developmental defects unlike those germinated in presence of DambE extracts ( Figure 7A, Figure 7-figure supplement 3). Germination arrested Capsella seeds in presence of WT PAO1 extracts were protected as they produced normal seedlings upon transfer to a normal medium (Figure 7-figure supplement 3E and F).
Since oxyvinylglycines inhibit irreversibly pyridoxal phosphate (PLP)-dependent enzymes their proposed GRA was interpreted as a toxic effect killing the seed, rendering these compounds potentially useful as herbicides (Rando, 1974;Lee et al., 2013b). However, whether oxyvinylglycines repress seed germination in a manner requiring functional DELLA genes, as shown here, was not previously investigated. It should be noted that a signaling role for oxyvinylglycines is not incompatible with toxic effects at high concentrations as in the case of auxin whose synthetic derivative 2,4-D is widely used as a systemic herbicide (Grossmann, 2007). of P.aeruginosa germinated 3 days after sowing (100%). Plants produced by seeds sown in presence of P. aeruginosa are shown according to their germination status 3 days after sowing: 82% (82%) did not germinate and 18% (18%) germinated. 3 days after sowing, plant material was transferred to a medium lacking P. aeruginosa (MS) and cultured for 1 week. Bottom panel shows representative pictures of plants 1 week after the transfer. (C) Histograms show the seed yield (expressed in mg) from plants produced by seeds never exposed to P. aeruginosa (MS) or from plants produced by seeds that did not germinate for 3 days in presence of P. aeruginosa and then transferred to medium lacking P. aeruginosa. Average seed yield was calculated from seeds produced by five and nine individual plants from seeds sown in absence or presence of P. aeruginosa, respectively. Data represent mean ± standard deviation. Statistical treatment and lower case letters as in Figure 1B. (D) WT and Ddella seeds were exposed for three days to WT P. aeruginosa (PAO1) prior to transfer to a bacteria-free medium. Histograms show percent of survival one week after transfer. Data represent mean ± standard deviation (three replicates, n = 60). Statistical treatment and lower case letters as in Figure 1B. AVG is a well-known inhibitor of 1-aminocyclopropane-1-carboxylic acid (ACC) synthase, a PLPdependent enzyme catalyzing the synthesis of ACC, a precursor of ethylene, from S-adenosylmethionine (Adams and Yang, 1979;Huai et al., 2001;Capitani et al., 2002). AVG was also shown to inhibit auxin synthesis (Soeno et al., 2010). AMB may also inhibit ACC synthase as suggested by a report showing that AMB decreases ethylene levels in apples; however, whether AMB can inhibit ACC synthase in vitro was not shown (Mattoo et al., 1979).
Wilson et al. previously reported that 5 mM AVG, a widely used inhibitor of ACC synthase, lowers ethylene synthesis in Arabidopsis seeds and does not inhibit germination (Wilson et al., 2014).
Here, we report that as much as 200 mM AVG did not noticeably inhibit seed germination, further confirming the results of Wilson et al. (Figure 4-figure supplement 10). Furthermore, heptuple acs mutant seeds, deficient several in ACS biosynthetic genes, germinated similarly to WT seeds (Figure 7-figure supplement 4A and B). Seeds deficient in ACS biosynthetic genes would be expected to respond more strongly to AMB-containing WT PAO1 extracts if AMB represses germination by inhibiting ethylene biosynthesis. However, this is not what we observed (Figure 7-figure supplement 4A and B).
We also treated seeds with silver nitrate (AgNO3), which induces ethylene insensitivity, and did not observe an inhibition of seed germination (Figure 7-figure supplement 4C) (Rodríguez et al., 1999;McDaniel and Binder, 2012). Altogether, these experiments show that inhibition of ethylene biosynthesis upon seed imbibition is not sufficient to block germination and therefore are not consistent with the hypothesis that AMB blocks germination because it blocks ethylene biosynthesis.
This could suggest that the effect of AMB to block germination results from its inhibition of auxin or methionine synthesis. The former possibility is unlikely because (1) auxin promotes ABA-dependent repression of seed germination and (2) low auxin levels may facilitate seed germination since ABA-dependent inhibition of radicle elongations involves enhancement of auxin signaling in the radicle elongation zone (Belin et al., 2009;Liu et al., 2013). We found that tir1 mutants, deficient in the auxin receptor TIR1, germinate normally, consistent with the report of Liu et al. showing that tir1/ afb2 and tir1/afb3 double mutants, deficient in the auxin receptors TIR1 and AFB1 or TIR1 and AFB3, germinate normally and are less dormant (Figure 7-figure supplement 5A and B, Liu et al., 2013). Furthermore, WT seeds treated with 500 mM of yucasin, a potent inhibitor of the YUCCA proteins, which are flavin mono-oxygenases oxidizing indole-3-pyruvic acid to indole-3-acetic acid (auxin), did not prevent their germination (Figure 7-figure supplement 5C) (Nishimura et al., 2014). These data indicate that low auxin signaling or synthesis upon seed imbibition does not prevent seed germination. In addition, tir1 mutant seed germination responses to AMB-containing WT PAO1 extracts was similar to that of WT seeds, indicating that AMB-dependent responses in seeds do not require auxin signaling (Figure 7-figure supplement 5A and B).
Concerning methionine, previous reports showed that methionine biosynthesis is essential for seed germination (Gallardo et al., 2002). We explored whether AMB could block germination by inhibiting methionine synthesis. DL-Propargylgylcine (PAG) is an active site-directed inhibitor of cystathionine g-synthase, which is necessary for methionine synthesis (Thompson et al., 1982). WT seeds treated with 1 mM PAG were unable to germinate, consistent with previous reports (Gallardo et al., 2002). As expected and consistent with previous reports, exogenously added methionine in the germination medium fully restored germination in PAG-treated seeds (Figure 7figure supplement 6) (Gallardo et al., 2002). However, exogenous methionine did not rescue the germination of PAO1 treated WT seeds. These observations are not consistent with the hypothesis that AMB prevents germination by limiting methionine synthesis.
Altogether, these results are not supporting the view that AMB exerts its DELLA-dependent seed germination arrest by inhibiting ethylene, auxin or methionine synthesis.
How AMB invokes a DELLA-dependent germination arrest remains to be understood Here, we unambiguously identify AMB as the main if not only GRA released by P. aeruginosa affecting Arabidopsis seed germination. AMB, unlike AVG, represses Arabidopsis seed germination and this requires functional DELLA genes.
Our results strongly suggest that AMB does not interfere with GA synthesis. Rather, they suggest that AMB can regulate seed gene expression in both a DELLA-dependent and GA-independent manner (Figure 3 and 5B). Our results with RGL2, GAI and RGA suggest that AMB does not interfere with GA-dependent DELLA degradation ( Figures 4B,6A-D and Figure 6-figure supplement  1).
We rather provide genetic evidence that DELLA activity to promote ABA-dependent seed germination arrest is stimulated in presence of AMB (Piskurewicz et al., 2009(Piskurewicz et al., , 2008. The mechanism through which AMB enhances DELLA activity to promote ABA-dependent responses in seeds remains to be understood. In particular, whether it is the result of a direct interaction between AMB and DELLAs is not known. Exogenous GA cannot overcome germination repression triggered by P. aeruginosa or AMB (Figures 3,4B,6D and Figure 6-figure supplement 1). Thus, genes whose expression is DELLAdependent and GA-independent in response to P. aeruginosa or synthetic AMB might provide clues about the potential mode of action of AMB. In this respect, our transcriptome analysis identified 87 genes whose expression is regulated by DELLA factors in seeds exposed to P. aeruginosa extracts ( Figure 3D, Supplementary file 2). Among them, 24 genes had their expression unchanged when GA was included in the medium together with P. aeruginosa extracts ( Figure 3D, Supplementary file 2). Interestingly, the expression of 18 of them was not significantly changed in seeds exposed to paclobutrazol (PAC), an inhibitor of GA synthesis, further suggesting these genes are not regulated by GA. In this set of genes, those related to karrikin signaling were overrepresented (Nelson et al., 2009;Waters et al., 2012). Karrikins are a class of compounds found in the smoke of burning plant material, which are known to promote germination and to break seed dormancy (Nelson et al., 2009). Furthermore, seeds lacking the karrikin receptor KAI2 are dormant (Waters et al., 2012). The karrikin signaling genes KUF1 and BBX20/STH7 are strongly repressed in WT seeds exposed to P. aeruginosa but not in Ddella mutant seeds, lacking all DELLA factors (Supplementary file 2). Thus, our data suggest that AMB could repress germination by repressing karrikin signaling through the DELLAs. However, karrikins share common signaling components with strigolactones, a class of plant hormones also promoting germination (De Cuyper et al., 2017;Toh et al., 2012). Strigolactones were recently proposed to regulate GA signaling in rice (Ito et al., 2017). SLR1, a rice DELLA factor, was found to interact with the strigolactone receptor DWARF14 fused to its ligand (Nakamura et al., 2013). Thus, AMB could also potentially regulate strigolactone signaling in seeds.
AMB production and release is under the control of P. aeruginosa's quorum sensing IQS Beyond the question of how AMB affects Arabidopsis developmental responses, its biological significance in Pseudomonas has recently attracted much attention.
Indeed, genetic experiments have shown that IQS, the autoinducer of the recently discovered quorum sensing (QS) subsystem named IQS in P. aeruginosa, is controlled by the five-gene operon ambABCDE (Lee et al., 2013a). Although the IQS receptor remains unknown it also remains to be determined what is the link between ambABCDE and IQS synthesis. Indeed, Lee et al. first proposed that ambABCDE gene products are directly responsible for IQS synthesis and therefore activity of the quorum sensing IQS (Lee et al., 2013a). However, the link between ambABCDE and IQS synthesis remains to be clarified. Indeed Lee et al. showed that ambABCDE is also necessary for AMB production and Rojas Murcia et al. proposed that ambABCDE gene products rather synthesize and export AMB (Rojas Murcia et al., 2015;reviewed in Moradali et al., 2017;Lee et al., 2010bLee et al., , 2013a. In any case, there is no genetic controversy regarding the need of a functional ambABCDE operon for (1) IQS production and signaling and (2) AMB synthesis and release by P. aeruginosa.
In this study, we further confirm that presence of the ambABCDE operon is necessary for AMB production (Figure 4-figure supplement 5, Supplementary file 3). Furthermore, we show that AMB is also abolished in DlasIDrhlI P. aeruginosa mutants lacking the las and rhl QS subsystems (Figure 4-figure supplement 5A, Supplementary file 3). This is in agreement with a previous report showing that expression of amb operon is strongly downregulated in DlasIDrhlI mutants (Schuster et al., 2003). The genes of the ambABCDE operon were also singled out as quorumdependent genes in chronic cystic fibrosis patients infected with P. aeruginosa (Chugani et al., 2012).
Thus, these reports leave little doubt that the ambABCDE operon, which is necessary for AMB production, is being intimately linked to the activity of QS in P. aeruginosa.

Potential ecological and evolutionary significance of an AMBdependent germination arrest
Publicly available genomic sequences show that the ambABCDE operon is not only present in the P. aeruginosa PAO1 strain used in this study but is also present in numerous other P. aeruginosa strains (Figure 4-figure supplement 11). This raises the question of the biological significance of the AMB-dependent germination arrest involving DELLA factors described here. The biological significance can be divided in two broad categories.
Firstly, AMB could exert its effect fortuitously, that is in an accidental manner that bears no ecological or evolutionary significance. This does not preclude the potential biological interest of the effect of AMB on seeds. Indeed, we provided evidence that the AMB-and DELLA-dependent germination arrest cannot be readily explained by an AMB-dependent inhibition of ethylene, auxin or methionine synthesis. Furthermore, AMB does not appear to prevent GA-dependent DELLA degradation. Given that oxyvinylglycines were reported to inhibit PLP-dependent enzymes and that AMB is a methionine analog, our results could indicate that AMB interferes with an unknown mechanism present in Arabidopsis that is linking PLP-dependent enzymes or amino acid metabolism with DELLA factors. Alternatively, AMB could interfere with an unknown and GA-independent mechanism involving DELLA factors to control germination.
Secondly, the effect of AMB on seeds could indeed be ecologically and evolutionary significant. We hereafter discuss this possibility.
Arabidopsis produces high seed numbers, which could contradict the need of evolving protective germination arrest responses since one successful germination event is sufficient to maintain the size of the population. However, Arabidopsis is not a long distance seed dispersal species and the majority of seeds is expected to fall in the vicinity of the mother plant. Furthermore, Arabidopsis seedlings are small and fragile and poor dispersion would increase their chance of being killed at the same time whenever faced by a local threat. It is therefore expected that early development is tightly regulated in Arabidopsis to enhance plant survival. Indeed, Arabidopsis has evolved elaborate germination arrest control mechanisms that are widely regarded as being protective. These include seed dormancy, believed to prevent germination out of season, and control of seed germination of nondormant seeds in response to abiotic factors, which is also considered to protect the plant (Kami et al., 2010;Penfield and King, 2009).
Here, we described laboratory conditions where the AMB-dependent germination arrest protects the plant from the potentially fatal effect of AMB on seedlings (Figure 7). This could indicate that this response has evolved as an adaption to counteract damage induced by biotic harmful compounds similarly to what is proposed for abiotic stresses. More generally, it is also consistent with the notion that it could correspond to a protection mechanism against pathogenic bacteria in the environment. Given the link between AMB and QS activity in P. aeruginosa, it is tempting to speculate that evolving a germination arrest response to AMB could be doubly advantageous: (1) it could protect the plant from the AMB toxin and (2) it could reveal the presence of the plant pathogen P. aeruginosa.
However, presently these considerations remain highly speculative. Indeed, the GRAs released by P. aeruginosa reported here are observed after culturing P. aeruginosa to high densities that trigger IQS QS activity. Whether bacteria such as P. aeruginosa proliferate to such high densities in the rhizosphere is unclear. The number of P. aeruginosa cells building up in the environment is subject to controversy. Green et al. were able to detect P. aeruginosa in 24% of soil samples studied and reported that it multiplied in lettuce and bean under conditions of high temperature and high humidity (Green et al., 1974). On the other hand, Deredjian et al. reported that P. aeruginosa has low occurrence in agricultural soils. However, they were able to detect them in high amounts in various manures, consistent with previous reports (Deredjian et al., 2014). These results could suggest that P. aeruginosa could only be found in high densities in the rhizosphere where food is available, including near decaying fruit or animal droppings, together with the proper moisture or temperature conditions. This could limit the ecological significance of controlling seed germination responses to biotic factors.
On the other hand, high densities of bacteria in the rhizosphere may not be obligatory to elicit seed germination responses. The Quorum Sensing is usually invoked to describe situations when high densities of cells trigger coordinated responses after autoinducers reach high concentrations in the environment. However, a given individual bacterium can only detect the autoinducer concentration present in its immediate proximity, which can include the autoinducer molecules that the same bacterium releases. In the rhizosphere, there could be situations limiting autoinducer diffusion, altering autoinducer advection, reducing autoinducer degradation or altering autoinducer spatial distribution, which could lead to high local concentrations of autoinducer even in absence of high densities of bacteria. Thus, a given bacteria cannot distinguish among the various scenarios leading to high autoinducer concentration. These considerations lead to the proposal that autoinducers fulfill a role beyond that of detecting high densities of bacteria (Redfield, 2002). They could allow bacteria to sense whether diffusion of molecules in their immediate environment is limited (Diffusion Sensing -DS-). In turn, this would allow a given bacteria to determine whether a given effector would diffuse efficiently or not (Hense et al., 2007).
Clearly, testing the model that the AMB-dependent germination arrest fulfills an adaptive function in plants will require future investigations. These include (1) a better understanding of the ecology of P. aeruginosa in real field settings, (2) identifying AMB's interacting targets in Arabidopsis responsible to convey the AMB-dependent germination arrest and (3) studying the fitness in the field of Arabidopsis mutants lacking those targets.
Undoubtedly, the findings reported here offer a very narrow sample of interactions that could take place between seeds and living organisms in the rhizosphere.

Pseudomonas material
The Pseudomonas strains used in this study are listed in Supplementary file 5.

Preparation of germination plates containing P. aeruginosa
Bacteria were cultured with agitation in 5 ml LB medium for 16 hr at 37˚C (with the exception of P. fluorescens, grown at 30˚C). Bacteria density was controlled by OD 600 (Ultrospec 2000, Pharmabiotec) and stocks were made for each bacteria strain when OD 600 reached 1.2. A volume of 25 mL of liquid culture containing approx. 7 Â 10 8 CFU was streaked on a square plate (120 Â 120 mm, Huberlab) containing Murashige and Skoog (MS) medium (4.3 g/L), 2-(N-morpholino)ethanesulfonic acid (MES) (0.5 g/L), 0.8% (w/v) Bacto-Agar (Applichem) and 20 mM succinate. Plates were incubated for 3 days in the dark in plant growth chambers (22˚C, 70% humidity). The resulting plates were used for germination tests as described in Figure 1-figure supplement 1. All experiments were repeated independently several times with similar results.

Preparation of germination plates containing bacteria-free extracts
Bacteria were cultured with agitation in a liquid solution (0.215 g/L MS, 20 mM succinate) for 24 hr at 37˚C and the saturated culture was centrifuged at 4˚C for 30 min (HiCen XL, Herolab) to pellet bacteria. The supernatant was then filtrated (0.22 mm filter) and lyophilized (Freeze-dryer Alpha 2-4 LD plus, Christ) as described in Figure 2-figure supplement 2. The resulting bacteria-free lyophilizate (also referred as 'extract' in the main text) was stored at À20˚C. To perform germination assays, the lyophilizate was resuspended in water at 40 mg/ml and used at different concentrations as shown and described in the figures and figure legends. All experiments were repeated independently several times with similar results.

RNA extraction and RT-qPCR
Total RNA was extracted as described (Piskurewicz and Lopez-Molina, 2016). RNAs were treated with RQ1 RNase-Free DNAse treatment (Promega) and cDNAs were made from 1 ug of RNA using ImProm-II reverse transcriptase (Promega). Amplification was done using GoTaq qPCR Master mix (Promega) and reaction was performed on QuantStudio 5 Real-Time PCR equipment (Thermo Fisher Scientific) according to manufacturer instructions. Relative transcript levels were calculated using the comparative Ct method and normalized to PP2A (AT1G69960) gene transcript levels. qPCR experiment were performed in biological triplicate. Primers used in this study are listed in Supplementary file 5.

RNAseq
Surface-sterilized WT (Col-0) and Ddella seeds were sown in germination plates in absence or presence of (PAC 5 mM), P. aerurinosoa (PAO1) extracts (0.7 mg/mL) or GA (10 mM) and cultured for 20 hr prior to total seed RNA extraction. cDNA libraries from two independent biological replicates were normalized and sequenced using HiSeq4000 (Illumina) with single-end 50 bp reads. Reads were mapped to Col-0 genome (TAIR10) with the TopHat program. Differential gene expression analysis was performed with the Cuffdiff program calculated by pooling the biological replicates. Differentially expressed genes were selected according to their significance in fold-change expression (false discovery rate, FDR < 0.05) and a threshold level of at least two-fold change between samples (log 2 ratio !1 and À1). All RNAseq analysis were performed on GALAXY website. For data visualization, clustering analysis were done with Gene Cluster 3.0 using average linkage method and visualized with Java Treeview version 1.1 6r4, were expression levels were color coded as following: red color for overexpressed, black color for unchanged expression and green color for underexpressed genes. All data are publicly available through the GEO database with accession number GSE115272.

Metabolomic analysis
With the aim to obtain preliminary information about the chemical nature of the GRA, bacterial extracts containing or not containing the GRA were analyzed by comprehensive UHPLC-HRMS 2 metabolite profiling and data were mined by differential untargeted metabolomics (see below Appendix 1, part '1. Metabolomic analysis informations' for details). Data were acquired on extracts from strains releasing (PAO1 WT and DpqsA) or not releasing a GRA (DambE and DlasIDrhlI). After the appropriate data treatment, all MS signals recorded were gathered as peak lists of individual features (mass and retention time were annotated as follow: m/z @ RT) each strain for subsequent multivariate data analysis to identify biomarkers. After alignment, the resulting peak list (Supplementary file 3) was then mined for differential features using unsupervised PCA (principal component analysis) and supervised statistical analysis approaches OPLS-DA (orthogonal partial least squares discriminant analysis). The PCA already allowed to clearly separate the four different bacteria extracts according to their MS features (Figure 4-figure supplement 3A). An OPLS-DA was carried constructing two 'active' vs. 'non-active' groups namely (PAO and DpqsA ('active') vs DambE and DlasI/rhlI ('non-active') ( Figure 4-figure supplement 3B). This analysis afforded a list of biomarkers responsible for the metabolic differences between strains (Supplementary file 4). The annotation of the most significant MS features was done using exact mass information and search against a database of natural products taxonomically restricted to the genus Pseudomonas. The bioactive compound was known to be a polar compound since activity was observed to be present in the H 2 O eluted fraction of all GRA-containing extracts when eluted through reversed phase chromatography ( Figure 4-figure supplement 6). Taking all this information into account one specific MS feature m/z 327.12 eluting at a retention time of 0.46 min (m/z = 327.12 @ RT 0.46 min) could be highlight when filtering the discriminant loadings of the OPLS-DA analysis for the most polar compounds (Supplementary file 4). This exact mass corresponded to a molecular formula (MF) of C 11 H 22 N 2 O 7 S, which did not yield any hit when querying the whole Dictionary of Natural Products (http://dnp.chemnetbase.com/). In order to gain information on this specific feature, a molecular network (MN) was constructed based on MS fragmentation similarities between extracts constituents using the untargeted MS/MS data acquired on PAO, DpqsA, DambE and DlasIDrhlI mutants and bioactivity data were mapped on this MN. The MN generated allows grouping compounds with structural similarities in clusters (Wang et al., 2016). The MN was searched for the feature m/z = 327.12 @ RT 0.46 min which was found to be related to a cluster of 3 ions (Figure 4-figure supplement 5). As expected the ion m/z 327.12 was only found in the 'active' labelled species. Surprisingly, one of the related ion at m/z 196.06 (C 6 H 13 NO 4 S) was found in both active and non-active samples but also in the culture media. Using the CSI:FingerID in silico fragmentation platform (https://www.csifingerid.uni-jena. de/, Dührkop et al., 2015), it was identified as 2-(N-morpholino)ethanesulfonic acid) or MES, a known constituent of the used culture media. Since MES in known to readily form coordination complexes we focused on the mass difference between ion m/z 327.12 and m/z 196.06, which was found to correspond to a mass difference of 131.1 Da. and a MF of C 5 H 9 NO 3 . Searching this MF within reported metabolites of Pseudomonas sp. permitted to annotate this compound, possibly responsible for the GRA, as L-2-amino-4-methoxy-trans-3-butenoic acid (also referred as methoxyvinylglycine or AMB). PCA analysis (Figure 4-figure supplement 4A) followed by an OPLS-DA was also carried between biological replicates of P. aeruginosa extract DambE and AMBox (Figure 4-figure supplement 4B). This analysis indicated that m/z 327.12 was found between the most discriminant features (Figure 4-figure supplement 5B, Supplementary file 4). Comparison of the extracted MS ion trace intensities of m/z 327.12 among the mutants indicated that this ion was indeed over-expressed in AMBox (ca. 20 fold between AMBox and PAO1 WT, Figure 4-figure supplement 5B). Additional informations can be found below in the section Appendix 1. All raw data have been deposited under the Massive Dataset ID MSV000082463, available at the following address: ftp://massive.ucsd.edu/MSV000082463.

Biochemical purification procedures
WT PAO1 and DambE extracts were separately fractionated by a reversed phase semi-preparative HPLC (High Performance Liquid Chromatography) into four fractions. The conditions for fractionation were obtained by a gradient chromatographic transfer of the metabolite profiling after optimization at the analytical level (see below Appendix 1, part '2. Bioguided biochemical purification analysis' for details). A GRA was found to be present in the polar fraction F1 from WT PAO1 extracts only. The NMR analysis of this fraction allowed detecting the presence of characteristic proton signals of the AMB molecule (data not shown). In order to confirm the structure of this compound and assess its biological properties, the crude extract of the strain AMBox was fractionated at large scale using RP-MPLC (Reversed Phase Medium Pressure Chromatography, C18) followed by semi-preparative HPLC purification using an amide stationary phase for efficient selectivity (Figure 4-figure supplement 6B). The structure of AMB was finally confirmed by extensive 1D and 2D NMR and HRMS analyses (Appendix 1-figures 1 and 2). For AMB quantification and NMR analysis, see below Appendix 1 part '3. AMB quantification' and part.4 'Chemical identity of the isolate AMB' for details. Data availability Sequencing data have been deposited publicly through the GEO database under accession number GSE115272. Metabolomic data have been deposited under the Massive Dataset ID MSV000082463, available at the following address: ftp://massive.ucsd.edu/MSV000082463 The generated molecular network is accessible at the following address: https://gnps.ucsd.edu/ProteoSAFe/status.jsp?task= 98375138ca634aa2827d693d3235ebe5 Source data files have been provided for Figures 1, 2, 3, 4 and 7.
The following datasets were generated:

Molecular Network Analysis
The MS 2 data were converted from the. RAW (Thermo) or. d (Agilent) standard data-format to. mzXML format using the MSConvert software, part of the ProteoWizard package. Chambers et al., 2012 The molecular network was created using the online workflow at GNPS (http://gnps.ucsd.edu). The data was then clustered with MS-Cluster with a parent mass tolerance of 0.08 Da and a MS/MS fragment ion tolerance of 0.05 Da to create consensus spectra. Further, consensus spectra that contained less than two spectra were discarded. A network was then created where edges were filtered to have a cosine score above 0.65 and more than six matched peaks. Further edges between two nodes were kept in the network if and only if each of the nodes appeared in each other's respective top 10 most similar nodes. The spectra in the network were then searched against GNPS' spectral libraries. All matches kept between network spectra and library spectra were required to have a score above 0.6 and at least six matched peaks. The generated molecular network is accessible at the following address: https://gnps.ucsd. edu/ProteoSAFe/status.jsp?task=98375138ca634aa2827d693d3235ebe5 MS data treatment and multivariate data analysis For the (PAO1 and DpqsA) vs. (DambE and DlasIDrhlI) analysis, this data treatment was led on two biological replicates and led to a peaklist of 1382 individual features (m/z@RT) (Supplementary file 3). For the DambE vs. AMBox analysis, this data treatment was led on three biological replicates and led to a peaklist of 1049 individual features (m/z@RT) (Supplementary file 3). PCA and supervised multivariate data analysis was done using the ropls R package available at (https://doi.org/10.18129/B9.bioc.ropls). Mean-centering and pareto scaling were applied. Significance of the respective models was depicted in the Bioguided biochemical purification analysis HPLC-PDA-ELSD analysis HPLC-PDA-ELSD analyses for the profiling the Pseudomonas extracts prior to isolation were conducted on a HP 1260 system equipped with a photodiode array detector (Agilent Technologies, Santa Clara, CA, USA) connected to an ELSD Sedex 85 (Sedere, Oliver, France). The HPLC conditions were as follows: Interchim PF10 C18 column (250 Â 4.6 mm i.d., 10 mm, Montluç on, France); solvent system MeOH (B) and H 2 O (A). Flow rate 1 mL/min; injection volume 20 mL; sample concentration 10 mg/mL in the mobile phase. The UV absorbance was measured at 210, 254, 280 and 366 nm and the UV-PDA spectra were recorded between 190 and 600 nm (step 2 nm). The ELSD detection parameters were: pressure 3.5 bar, 40˚C, gain 8.

Semi prep HPLC-UV fractionation of the PAO1 extract
The fractionation of the crude ethanol extract using the semi-preparative HPLC-UV (High Performance Liquid Chromatography hyphenated to Ultra-Violet detector) was performed with an X-Bridge RP C18 column (5 mm, 250 Â 21.2 i.d., mm; Waters, Milford MA, USA). The flow rate was set at 17 mL/min and the injection volume was of 500 mL (30 mg of the crude extract). The solvent system used was (A) H 2 O and (B) MeOH. The separation was performed using the follow conditions: 3% of B between 0 and 15 min, follow by gradient step of 3% of B to 100% of B in 45 min. The column was washed for 10 min with 100% B. 75 fractions of 12 ml were collected (see separation in Figure 4-figure supplement 6A). Eight consecutive injections were performed (240 mg of the crude extract in total). After collection, each fraction was evaporated to dryness using a SpeedVac (HT-4X Genevac, Stone Ridge, NY, USA). In order to obtain a rough fractionation and identify the zone of the chromatogram containing bioactive constituents, the fractions were combined in four main fractions (F1-F4) with the following yield F1 (142.2 mg), F2 (9.88 mg), F3 (6.76 mg) and F4 (18.91 mg). The GRA activity of the four fractions was evaluated in the germination assay. Fraction F1 presented a strong GRA and proton NMR signals corresponding to AMB.

Isolation of the germination inhibitor principle from the AMBox extract
The lyophilized supernatant (4.2 g) of the AMBox strain was fractionated using medium pressure liquid chromatography (MPLC-UV) with a Zeoprep C18 column (40-63 m, 460 Â 49 mm i.d.; Zeochem, Uetikon am See, Switzerland). These conditions were first optimized on an analytical HPLC column (250 Â 4.6 mm i.d., 15-25 mm, Zeochem, Uetikon am See, Switzerland) packed with the same stationary phase and then chromatographic conditions were geometrically transferred to the preparative scale (Challal et al., 2015). The extract was introduced in the MPLC column by dry injection. For this, 4.2 g of the extract were mixed with 20 g of Zeoprep C18 stationary phase. The mixture was conditioned in a dry load cell (11.5 Â 2.7 cm i.d.). The dry load cell was connected between the pump and the MPLC column. The flow rate was 30 mL/min, and the UV absorbance was detected at 210, 254 and 366 nm. The solvent system used was (A) H 2 O and (B) MeOH. The separation was performed using the following conditions: 3% of B between 0 and 69 min, 3% to 40% of B in 162 min, 40% of B during 63 min, and a final step of 40% to 100% of B in 126 min. 46 fractions of 250 ml were