Salicylic Acid Signaling in Disease Resistance

Kumar, Dhirendra

01 November 2014

Salicylic acid (SA) is a key plant hormone that mediates host responses against microbial pathogens. Identification and characterization of SA-interacting/binding proteins is a topic which has always excited scientists studying microbial defense response in plants. It is likely that discovery of a true receptor for SA may greatly advance understanding of this important signaling pathway. SABP2 with its high affinity for SA was previously considered to be a SA receptor. Despite a great deal work we may still not have true a receptor for SA. It is also entirely possible that there may be more than one receptor for SA. This scenario is more likely given the diverse role of SA in various physiological processes in plants including, modulation of opening and closing of stomatal aperture, flowering, seedling germination, thermotolerance, photosynthesis, and drought tolerance. Recent identification of NPR3, NPR4 and NPR1 as potential SA receptors and α-ketoglutarate dehydrogenase (KGDHE2), several glutathione S transferases (GSTF) such as SA binding proteins have generated more interest in this field. Some of these SA binding proteins may have direct/indirect role in plant processes other than pathogen defense signaling. Development and use of new techniques with higher specificity to identify SA-interacting proteins have shown great promise and have resulted in the identification of several new SA interactors. This review focuses on SA interaction/binding proteins identified so far and their likely role in mediating plant defenses.

NPR1

NPR3

SA-binding protein 2 (SABP2)

salicylic acid (SA)

syystemic acquired resistance (SAR)

Biological Sciences

Identification of Likely Orthologs of Tobacco Salicylic Acid-Binding Protein 2 and Their Role in Systemic Acquired Resistance in Arabidopsis Thaliana

Vlot, Anna, Liu, Po Pu, Cameron, Robin K., Park, Sang Wook, Yang, Yue, Kumar, Dhirendra, Zhou, Fasong, Padukkavidana, Thihan, Gustafsson, Claes, Pichersky, Eran, Klessig, Daniel F.

01 November 2008

Salicylic acid-binding protein 2 (SABP2) is essential for the establishment of systemic acquired resistance (SAR) in tobacco; SABP2's methyl salicylate (MeSA) esterase activity is required in healthy systemic tissues of infected plants to release the active defense phytohormone SA from MeSA, which serves as a long-distance signal for SAR. In the current study, we characterize a new gene family from Arabidopsis thaliana encoding 18 potentially active α/β fold hydrolases that share 32-57% identity with SABP2. Of 14 recombinant AtMES (MES for methyl esterase) proteins tested, five showed preference for MeSA as a substrate and displayed SA inhibition of MeSA esterase activity in vitro (AtMES1, -2, -4, -7, and -9). The two genes encoding MeSA esterases with the greatest activity, AtMES1 and -9, as well as AtMES7 were transcriptionally upregulated during infection of Arabidopsis with avirulent Pseudomonas syringae. In addition, conditional expression of AtMES1, -7, or -9 complemented SAR deficiency in SABP2-silenced tobacco, suggesting that these three members of the AtMES family are SABP2 functional homologs (orthologs). Underexpression by knockout mutation and/or RNAi-mediated silencing of multiple AtMES genes, including AtMES1, -2, -7, and -9, compromised SAR in Arabidopsis and correlated with enhanced accumulation of MeSA in the systemic tissue of SAR-induced plants. Together, the data show that several members of the AtMES gene family are functionally homologous to SABP2 and redundant for MeSA hydrolysis and probably SAR. These data suggest that MeSA is a conserved SAR signal in Arabidopsis and tobacco.

arabidopsis

defense signal

methyl esterase

methyl salicylate

salicylic acid-binding protein 2

systemic acquired resistance

The Search for the Salicylic Acid Receptor LED to Discovery of the SAR Signal Receptor

Kumar, Dhirendra, Klessig, Daniel F.

01 January 2008

Systemic acquired resistance (SAR) is a state of heightened defense which is induced throughout a plant by an initial infection; it provides long-lasting, broad-spectrum resistance to subsequent pathogen challenge. Recendy we identified a phloem-mobile signal for SAR which has been elusive for almost 30 years. It is methyl salicylate (MeSA), an inactive derivative of the defense hormone, salicylic acid (SA). This discovery resulted from extensive characterization of SA-binding protein 2 (SABP2), a protein whose high affinity for SA and extremely low abundance suggested that it might be the SA receptor. Instead we discovered that SABP2 is a MeSA esterase whose function is to convert biologically inactive MeSA in the systemic tissue to active SA. The accumulated SA then activates or primes defenses leading to SAR. SABP2's esterase activity is inhibited in the initially/primary infected tissue by SA binding in its active site; this facilitates accumulation of MeSA, which is then translocated through the phloem to systemic tissue for perception and processing by SABP2 to SA. Thus, while SABP2 is not the SA receptor, it can be considered the receptor for the SAR signal. This study of SABPs not only illustrates the unexpected nature of scientific discoveries, but also underscores the need to use biochemical approaches in addition to genetics to address complex biological processes, such as disease resistance.

methyl salicylate

methyl salicylate esterase

salicylic acid

salicylic acid-binding proteins

systemic acquired resistance

Biological Sciences

The ssDNA Theory of BRCAness and Genotoxic Agents

Panzarino, Nicholas J.

02 April 2021

Cancers that are deficient in BRCA1 or BRCA2 are thought to be hypersensitive to genotoxic agents because they cannot prevent or repair DNA double strand breaks, but observations in patients suggest this dogma may no longer agree with experiment. Here, we propose that single stranded DNA underlies the hypersensitivity of BRCA deficient cancers, and that defects in double strand break repair and prevention do not. Specifically, in BRCA deficient cells, ssDNA gaps developed because replication was not effectively restrained in response to stress. In addition, we observed gaps could be suppressed by either restored fork restraint or by gap filling, both of which conferred therapy resistance in tissue culture and BRCA patient tumors. In contrast, restored double strand break repair and prevention did not confer therapy resistance when gaps were present. Critically, double strand breaks were not detected after therapy when apoptosis was inhibited, supporting a framework in which double strand breaks are not directly induced by genotoxic agents, but instead are created by cell death nucleases and are not fundamental to genotoxic agents. Together, these data indicate that ssDNA replication gaps underlie the BRCA cancer phenotype, "BRCAness," and we propose are fundamental to the mechanism-of-action of genotoxic chemotherapy.

Cancer

BRCAness

ssDNA

Genotoxin

PARPi

Acquired Resistance

Cancer Biology

Cell Biology

Characterization of the Pathway Leading to the Synthesis of Salicylic Acid in Plants Resisting Pathogen Infection.

Eddo, Alexander

12 August 2008

Salicylic acid is a plant hormone that accumulates with plant-pathogen interaction. This accumulation corresponds to the plant being resistant to infection and without it the plant is susceptible. In this study, primers of genes involved in the normal synthesis of SA were used in RT-PCR to compare gene expression levels in susceptible and resistant plants challenged with tobacco mosaic virus. Because SA synthesis shares chorismate as a common substrate with the synthesis of aromatic amino acids, HPLC was used to determine whether the increase in SA could be attributed to a decrease in amino acid levels. The results suggest that genes of the shikimate pathway are up-regulated in both plant lines but much more quickly in the resistant plant, making differential gene expression a possible cause of SA accumulation. Additionally, results showed a more pronounced decrease in amino acid levels in resistant plants compared to susceptible plants.

Tobacco mosaic virus

Shikimate pathway

Systemic acquired resistance

Salicylic acid

Life Sciences

Plant Pathology

Plant Sciences

EXAMINING THE ROLES OF DIR1 AND DIR1-LIKE DURING SYSTEMIC ACQUIRED RESISTANCE IN ARABIDOPSIS AND CUCUMBER

Isaacs, Irene Marisa

16 December 2014

<p>Systemic Acquired Resistance (SAR) is a plant defense response induced by an initial infection in one part of the plant that leads to broad-spectrum resistance to normally virulent pathogens in distant naïve leaves. As part of the Cameron research team, I contributed to demonstrating that the lipid transfer protein, DIR1 is required for SAR long distance signaling in <em>Arabidopsis</em> and travels from induced to distant tissues during SAR. A highly similar<em> Arabidopsis</em> protein DIR1-like was identified and is thought to be responsible for the occasional SAR-competent phenotype observed in the <em>dir1-1</em> mutant. This work provides evidence for the idea that DIR1 and DIR1-like are paralogs created by a recent duplication event and that similar to DIR1, DIR1-like may travel to distant tissues during SAR. To better understand DIR1 and DIR1-like contribution during SAR, <em>dir1-1dir1-like</em> double mutant transgenic plants were created as well as transgenic plants expressing epitope- (HA and FLAG) and fluorescent- (iLOV and phiLOV) tagged DIR1 and DIR1-like to facilitate visualization of movement during SAR. Several putative DIR1 orthologs were identified in crop plants and cucumber CucDIR1 was shown to be functionally equivalent to AtDIR1 in <em>dir1-1</em> complementation studies providing further evidence that DIR1 plays an important role in SAR across plant species. By analyzing conservation between DIR1, DIR1-like and the putative DIR1 orthologs, several protein residues were identified that may be important for DIR1 function during SAR. DIR1 proteins were modified at these sites and the importance of these residues was supported by the reduced binding of the TNS hydrophobic probe in these DIR1 variants. Taken together, this thesis suggests that DIR1 and DIR1-like both participate in SAR in <em>Arabidopsis</em>, that DIR1 crop orthologs are also important for the SAR response and that DIR1 possesses several sites that are critical for its function in long distance SAR signaling.</p> / Doctor of Philosophy (PhD)

Systemic Acquired Resistance

DIR1

DIR1-like

Arabidopsis

Cucumber

Pseudomonas syringae pv. tomato

Biology

Plant Sciences

Biology

Investigation of SAR-associated small molecules as inducers of resistance in cucumber and biofilm formation by Pseudomonas syringae pv. tomato in Arabidopsis

Fufeng, Angela B.

13 June 2019

Greenhouse environments often promote bacterial and fungal infections in important crop plants. Exogenous application of chemical inducers could help reduce the severity of infection, or even prevent infection. Small molecules such as glycerol, azelaic acid and pipecolic acid have been implicated as being important signaling molecules during Systemic Acquired Resistance (SAR). To examine if these small molecules could be used to induce resistance in crop plants, exogenous treatment assays were developed in cucumber. Glycerol spray and azelaic acid infiltration induced modest resistance at locally treated leaves. Pipecolic acid soil treatment induced modest resistance in aerial tissue of cucumber plants, and strong resistance when plants were treated weekly. This knowledge may be useful in promoting the commercialization of SAR-associated compounds to protect important crop plants against disease. Plants possess multiple defense pathways that include an SA signaling component to initiate resistance to microbial pathogens. However, during Age-Related Resistance (ARR) in Arabidopsis, a number of studies support that SA acts as an anti-microbial and anti-biofilm agent against Pseudomonas syringae pv. tomato (Pst) in the plant intercellular space. Little is known about the role of Pst biofilm formation during infection of young plants or if other defense responses act to suppress bacterial biofilm formation. Therefore Pst biofilm formation and the effect of PAMP Triggered Immunity (PTI) on bacterial biofilm formation was examined. PTI was induced with flg22 in wild-type Col-0, fls2, bak1-3 (PTI mutants) and sid2-2 (SA biosynthesis mutant). In vivo bacterial biofilm-like aggregate formation was monitored using Pst DC3000 PDSK-GFPuv and epifluorescence microscopy. Pst aggregate occurrence and size were positively correlated with bacterial success in susceptible plants (wild-type Col-0, fls2, bak1-3, sid2-2), while fewer and smaller bacterial aggregates were observed in Col-0 undergoing PTI. To determine if the extracellular polysaccharide, alginate was a major contributor to biofilm formation, in vivo bacterial aggregate formation was monitored using alginate deficient Pst-GFP. Alginate deficient Pst-GFP and wild-type Pst grew to similar levels in wild-type plants suggesting that the ability to produce alginate was not necessary for Pst pathogenicity and success in planta. Fewer alginate-deficient Pst aggregates were observed compared to wild-type Pst in inoculated plants, suggesting that the ability to produce alginate was modestly important for aggregate formation. These data provide novel insights into how biofilms form in planta, the association between pathogen virulence and biofilm formation, and how plant defense responses such as PTI not only reduce bacterial growth, but also target biofilms. / Thesis / Master of Science (MSc)

Pseudomonas syringae

Biofilm

Cucumber

Arabidopsis

Systemic Acquired Resistance

PAMP-triggered immunity

Harnessing Systems Bioengineering Approaches to Study Microbe-Microbe and Host-Microbe Interactions in Health and Disease

Datla, Udaya Sree

22 March 2024

The core of the dissertation lies in developing two novel systems bioengineering approaches, a synthetic Escherichia coli killer-prey microecology, and a combined infection-inflammation NET-array system, to investigate the role of the mechanochemical complexity of the microenvironment in driving the microbe-microbe and host-microbe interactions, respectively. Herein, the first part of the dissertation includes designing and engineering a synthetic E. coli killer-prey microecological system where we quantified the quorum-sensing mediated interactions between the engineered killer and prey E. coli bacterial strains plated on nutrient-rich media. In this work, we developed the plate assay followed by plasmid sequencing and computational modeling that emphasizes the concept of the constant evolution of species or acquired resistance in the prey E. coli, in the vicinity of the killer strain. We designed the microecological system such that the killer cells (dotted at the center of the plate) constitutively produce and secrete AHL quorum-sensing molecules into the microenvironment. AHL then diffuses into the prey cells (spread throughout the plate) and upregulates the expression of a protein that lyses the prey. Through time-lapse imaging on petri plates automated using a scanner, we recorded the "kill wave" that originates outside the killer colony and travels outward as the prey dies. We found that the prey population density surrounding the killer decreased in comparison to other locations on the plate far from the killer. However, some of the prey colonies evolve to be resistant to the effects of AHL secreted by the killer. These prey colonies resistant to the killer were then selected and confirmed by plasmid sequencing. Using this empirical data, we developed the first ecological model emphasizing the concept of the constant evolution of species, where the survival of the prey species is dependent on the location (distance from the killer) or the evolution of resistance. The importance of this work lies in the context of the evolution of antibiotic-resistant bacterial strains and in understanding the communication between the microbial consortia, such as in the gut microbiome. Further, the second part of the dissertation includes quantifying the interactions between immune cells (primary healthy human neutrophils) and motile Pseudomonas aeruginosa bacteria in an inflammation-rich microenvironment. Neutrophils, being the first responding immune cells to infection, defend by deploying various defense mechanisms either by phagocytosing and killing the pathogen intracellularly or through a suicidal mechanism of releasing their DNA to the extracellular space in the form of Neutrophil Extracellular Traps (NETs) to trap the invading pathogens. Although the release of NETs is originally considered a protective mechanism, it is shown to increase the inflammation levels in the host if unchecked, ultimately resulting in end-organ damage (especially lung and kidney damage), as with the severe cases of sepsis and COVID-19. In our work, we developed a combined infection-inflammation NET-array system integrated with a live imaging assay to quantify the spatiotemporal dynamics of NET release in response to P. aeruginosa infection in an inflammatory milieu at a single-cell resolution. Importantly, we found increased NET release to P. aeruginosa PAO1 when challenged with inflammatory mediators tumor necrosis factor-α (TNF-α) and interleukin-6 (IL-6), but not leukotriene B4 (LTB4), compared to the infection alone. Our device platform is unique in that the nanoliter well-assisted individual neutrophil trapping enables us to quantify NET release with single-cell precision. Besides, incorporating confined side loops in the device helped us study the role of mechanical confinement on NET release, showing reduced NET release from neutrophils confined in the side loops compared to the relatively wider chambers of our microsystem. In summary, our work emphasizes the importance of studying the heterogeneity of NET release in host defense and inflammation. In the future, our system can be used for screening novel neutrophil-based immunotherapies and serve as a valuable research tool in precision medicine. / Doctor of Philosophy / The microenvironment plays a vital role in shaping the interactions within microbes and between the host and the microbes. Microbes use quorum-sensing-based chemical signaling to adapt to the environmental stresses in a microecology (be it a soil microecology or the gut microbiome). They communicate with each other with the help of these chemicals to regulate their population density (to mutual benefit in the case of a biofilm formation or to compete for resources in the case of a predator-prey model). In the first part of the dissertation, we utilize this quorum-sensing approach to study the spatiotemporal dynamics of the interactions between two engineered killer and prey Escherichia coli bacterial strains on a nutrient-rich agar plate in real-time. We designed the microecological system such that the killer cells (dotted at the center of the plate) constitutively produce and secrete AHL quorum-sensing molecules into the microenvironment. AHL then diffuses into the prey cells (spread throughout the plate) and upregulates the expression of a protein that lyses the prey. We found that the prey population density surrounding the killer decreased in comparison to other locations on the plate far from the killer. Further, through sequencing, we found that some of the prey colonies acquired resistance to the effects of AHL secreted by the killer. We then developed a computational model that recapitulates our experimental results, emphasizing the concept of the constant evolution of species or acquired resistance. The importance of this work lies in using experimental and computational approaches to better understand the evolution of multidrug-resistant (MDR) bacterial strains. Next, we investigated the interactions between primary human neutrophils (first responding immune cell type to infection) and motile Pseudomonas aeruginosa bacteria in the second part of the dissertation, explicitly focusing on quantifying neutrophil extracellular traps (NETs) release. With increasing concerns regarding the role of the dysregulated NET release in exaggerated inflammatory responses in the host, it is imperative to quantify NET release precisely at a single-cell level in a controlled microenvironment. To this end, we engineered a combined infection-inflammation NET-array device with 1024 nanoliter wells per device and achieved single-cell level trapping of neutrophils in these wells. Our device platform is unique in that the individual wells of the device have constricted side loops, which helps us better understand the role of mechanical confinement on NET release from an engineering standpoint. We then used the NET-array system to quantify the spatiotemporal dynamics of NET release to P. aeruginosa in an inflammatory mediator-rich microenvironment. Importantly, we found heightened NET release to Pseudomonas aeruginosa PAO1 when challenged with inflammatory mediators tumor necrosis factor-α (TNF-α) and interleukin-6 (IL-6), but not leukotriene B4 (LTB4), compared to the infection alone. We also demonstrated reduced NET release from neutrophils confined in the side loops compared to the relatively wider chambers of our combined infection-inflammation microsystem. Especially with the increasing complexity of the intercellular cues at the site of infection, by integrating our microfluidic method with the conventional reductionist approaches, we can better solve the intricate puzzles of the immune cell decision-making processes at a single-cell level. Our study highlights the importance of fine-tuning NET release in controlling pathological neutrophil-driven inflammation.

Synthetic microecology

Acquired resistance

Escherichia coli

Pseudomonas aeruginosa

Neutrophil extracellular traps

NET-array device

Infection

Inflammation

Molecular and Biochemical Signaling Underlying Arabidopsis-Bacterial/Virus/Fungal Interactions

El-Shetehy, Mohamed H.

01 January 2016

Systemic acquired resistance (SAR) is a form of inducible defense response triggered upon localized infection that confers broad-spectrum disease resistance against secondary infections. Several factors are known to regulate SAR and these include phenolic phytohormone salicylic acid (SA), phosphorylated sugar glycerol-3-phosphate (G3P), and dicarboxylic acid azelaic acid (AzA). This study evaluated a role for free radicals nitric oxide (NO) and reactive oxygen species (ROS) in SAR. Normal accumulation of both NO and ROS was required for normal SAR and mutations preventing NO/ROS accumulation and/or biosynthesis compromised SAR. A role for NO and ROS was further established using pharmacological approaches. Notably, both NO and ROS conferred SAR in a concentration dependent manner. This was further established using genetic mutants that accumulated high levels of NO. NO/ROS acted upstream of G3P and in parallel to SA. Collectively, these results suggest that NO and ROS are essential components of the SAR pathway.

Systemic acquired resistance

Azelaic acid

Glycerol-3-phosphate

Nitric oxide

Reactive oxygen species

Bacteriology

Biochemistry

Biotechnology

Microbiology

Molecular Biology

Virology

Global changes in Brassica napus gene activity in response to Sclerotinia sclerotiorum and the biocontrol agent Pseudomonas chlororaphis PA23

Duke, Kelly

15 September 2016

The biological control agent Pseudomonas chlororaphis PA23 is effective at protecting Brassica napus (canola) from the necrotrophic fungus Sclerotinia sclerotiorum via direct antagonism. Despite the growing importance of biocontrol bacteria in protecting crop plants from fungal pathogens, little is known about how the host plant responds to bacterial priming on the leaf surface and certainly nothing about global changes in gene activity in the presence and absence of S. sclerotiorum. PA23 priming of mature canola plants reduced the number of lesion-forming petals by 90%. Global RNA sequencing of canola tissue at the host-pathogen interface showed a 16-fold reduction in the number of genes uniquely upregulated in response to S. sclerotiorum when pretreated with PA23. Upstream defense-related gene patterns suggest MAMP-triggered immunity via surface receptors detecting PA23 flagellin and peptidoglycans. Although systemic acquired resistance (SAR) was induced in all treatment groups, a response centered around a glycerol-3-phosphate (G3P)-mediated pathway was exclusively observed in canola plants treated with PA23 alone. Activation of these defense mechanisms by PA23 involved production of reactive oxygen species as well as pronounced thylakoid membrane structures and plastoglobule formation in leaf chloroplasts. PA23 therefore primes defense responses in the plant through the induction of unique local and systemic regulatory networks. / October 2016

Biocontrol

Sclerotinia sclerotiorum

Brassica napus

Chloroplast

Pseudomonas chlororaphis PA23

RNA-seq

Reactive oxygen species

Systemic acquired resistance