High throughput sequencing unravels tomato- pathogen interactions towards a sustainable plant breeding

Tomato (Solanum lycopersicum) is one of the most economically important vegetables throughout the world. It is one of the best studied cultivated dicotyledonous plants, often used as a model system for plant research into classical genetics, cytogenetics, molecular genetics, and molecular biology. Tomato plants are affected by different pathogens such as viruses, viroids, fungi, oomycetes, bacteria, and nematodes, that reduce yield and affect product quality. The study of tomato as a plant-pathogen system helps to accelerate the discovery and understanding of the molecular mechanisms underlying disease resistance and offers the opportunity of improving the yield and quality of their edible products. The use of functional genomics has contributed to this purpose through both traditional and recently developed techniques, that allow the identification of plant key functional genes in susceptible and resistant responses, and the understanding of the molecular basis of compatible interactions during pathogen attack. Nextgeneration sequencing technologies (NGS), which produce massive quantities of sequencing data, have greatly accelerated research in biological sciences and offer great opportunities to better understand the molecular networks of plant–pathogen interactions. In this review, we summarize important research that used high-throughput RNA-seq technology to obtain transcriptome changes in tomato plants in response to a wide range of pathogens such as viruses, fungi, bacteria, oomycetes, and nematodes. These findings will facilitate genetic engineering efforts to incorporate new sources of resistance in tomato for protection against pathogens and are of major importance for sustainable plant-disease management, namely the ones relying on the plant’s innate immune mechanisms in view of plant breeding

Identification of host-specific effectors mediating pathogenicity of the vascular wilt pathogen Verticillium dahliae

In order to establish disease, many plant pathogens secrete so-called effector molecules to support host colonization, frequently through the modulation of host physiology. Accordingly, many effector molecules have been shown to be pivotal for microbial pathogenesis. Upon infection of its hosts, vascular wilt fungal pathogen Verticillium dahliae secretes effectors to enable host colonization. The aim of the research described in this thesis is to gain more insight into molecular mechanisms of V. dahliae pathogenesis, with a specific focus on the discovery of novel effectors that contribute to the establishment of V. dahliae infections on diverse host plants. Interestingly, we found that pathogenicity of V. dahliae on various plant hosts depends on relatively few effectors, and for some host species even on a single one. Such knowledge is essential for designing and developing novel and effective Verticillium wilt disease management strategies.</p

Functional analysis of the tomato Ve resistance locus against Verticillium wilt

Verticillium dahliae, V. albo-atrum and V. longisporum are soil-borne plant pathogens that are responsible for Verticillium wilt diseases in temperate and subtropical regions. Collectively they can infect over 200 hosts, including many economically important crops. Chapter 1 is a “pathogen profile” which describes the most important aspects of the biology of the Verticillium wilt pathogens. They colonize the xylem vessels of their host plants and cause symptoms such as wilting, chlorosis, stunting, necrosis and vein clearing. Verticillium species are notoriously difficult to control as there are no fungicides available to cure plants once they are infected. Therefore, genetic resistance is the preferred method for disease control. Chapter 2 describes the functional characterization of the tomato (Solanum lycopersicum) Ve locus. This locus is responsible for resistance against race 1 strains of V. dahliae and V. albo-atrum and comprises two closely linked inversely oriented genes, Ve1 and Ve2. Both genes encode cell surface receptor proteins of the extracellular leucine-rich repeat (eLRR) receptor-like protein (RLP) class of disease resistance proteins. In chapter 2, it is demonstrated that Ve1, but not Ve2, provides resistance in tomato against race 1 but not against race 2 strains of V. dahliae and V. albo-atrum. Using virus-induced gene silencing in tomato, the signaling cascade downstream of Ve1 was shown to require both EDS1 (enhanced disease susceptibility1) and NDR1 (non-race-specific disease resistance1). In addition, also NRC1 (NB-LRR protein required for hypersensitive response-associated cell death1), ACIF (Avr9/Cf-9–induced F-box1), MEK2 (MAP/ERK kinase2), and SERK3/BAK1 (somatic embryogenesis receptor kinase 3/brassinosteroid-associated kinase 1) act as positive regulators of Ve1 in tomato. In conclusion, Ve1-mediated resistance signaling only partially overlaps with signaling mediated by Cf proteins, type members of the eLRR-RLP-class of resistance proteins. In chapter 3 an attempt to introduce Nicotiana benthamiana as a model to facilitate the study of Ve1-mediated resistance is described. Challenge of wild type plants with several race 1 and race 2 strains of V. dahliae and V. albo-atrum demonstrated that N. benthamiana is susceptible to both Verticillium species. To obtain Verticillium wilt resistant plants, N. benthamiana was engineered to express the tomato Ve1 coding sequence. However, out of thirteen transgenic lines, six showed clear phenotypic aberrancies that included severe stunting and malformed leaves when compared to wild type plants. The seven Ve1-transgenic lines that did not show any phenotypic alterations were challenged with race 1 and race 2 strains. Although the pathogenicity assays indicated that in few lines Ve1 expression temporarily reduced disease development, most lines were as susceptible as wild type parental line. In conclusion, in chapter 3 it is demonstrated that the Ve1-transgenic N. benthamiana lines could not be used to study Ve1-mediated resistance signaling. In chapter 4, the use of Arabidopsis (Arabidopsis thaliana) as model to facilitate the study of Ve1-mediated resistance is presented. To this end, tomato Ve1 was expressed in susceptible Arabidopsis plants. Upon challenge with race 1 strains of V. dahliae or V. albo-atrum, Ve1-expressing plants were found to be resistant. In contrast, Ve1-expressing plants were susceptible to race 2 strains of both V. dahliae and V. albo-atrum. Furthermore, expression of Ve1 in Arabidopsis plants did not prevent colonization by V. longisporum strains. Through Ve1-expression in Arabidopsis defense signaling mutants, it was demonstrated that signaling downstream of Ve1 is highly conserved between tomato and Arabidopsis. In previous chapters it was shown that the receptor kinase SERK3/BAK1 is required for Ve1-mediated resistance in tomato as well as in Arabidopsis. In Arabidopsis, SERK3/BAK1 belongs to a gene family consisting of five members. In chapter 5, the requirement of the different SERK family members in Ve1-mediated resistance in Arabidopsis is investigated, revealing the requirement of SERK1 and, although to a lesser extent, SERK4 for resistance. Using virus-induced gene silencing, it was subsequently shown that SERK1 is also required for Ve1-mediated resistance in tomato. In conclusion, the results of chapter 5 demonstrate that Arabidopsis can be used as model to unravel the molecular mechanisms of Ve1-mediated resistance. In chapter 6, the recognition specificity of Ve1 was further investigated by performing domain-swaps with Ve2 and expressing the chimeric Ve proteins in Arabidopsis. Various domain swaps in which eLRRs from Ve1 were replaced by those of Ve2 suggest that the region between eLRR22 and eLRR35 is required for full Ve1-mediated resistance. However, plants expressing a Ve chimera in which eLRR1 to eLRR30 of Ve1 was replaced with those of Ve2 were resistant against Verticillium. Overall, these results suggest that Ve2 may still bind the elicitor in the eLRR domain, but its C-terminal domain is not able to activate a successful defense response. Finally in Chapter 7, highlights of this thesis are discussed and placed in a broader perspective. </p

Analysis of the JA-Ile-independent function of COI1 in Arabidopsis thaliana upon infection with Verticillium longisporum

CORONATINE INSENSITIVE 1 (COI1) perceives the plant hormone jasmonoyl-isoleucine (JA-Ile) together with proteins of the JASMONATE ZIM-domain (JAZ) family. JA-Ile induces signalling cascades in defence and developmental processes. It has been shown that in Arabidopsis thaliana, COI1 without its ligand conveys susceptibility to the soil-born vascular pathogen Verticillium longisporum. Grafting experiments have shown that presence of COI1 in roots mediates susceptibility to the pathogen. Root transcriptome analysis has revealed that a number of salicylic acid defence-associated genes are constitutively expressed in coi1. The observation that COI1 acts as a JA-Ile-independent repressor of root gene expression led us to postulate that this novel COI1 function operates independently of the canonical JA signalling machinery. In this thesis, we show that coi1 plants complemented with a COI1 protein, that was severely impaired in its interaction with JAZ proteins (COI1AA), were compromised in wound-induced induction of the JA-signalling marker gene VEGETATIVE STORAGE PROTEIN 2 (VSP2). Moreover, COI1AA could not restore fertility in sterile coi1 plants. In contrast, COI1AA was able to repress gene expression in roots. Hence, in roots, COI1 has a second function other than its role in JA-Ile perception, in which it acts as a suppressor of defence gene expression independently of JA-Ile and most likely independently of JAZ proteins. We furthermore show that after infection with V. longisporum, approximately half of the COI1-repressed genes in roots are induced to similar levels as in coi1. We hence postulate that COI1-mediated repression is inactivated upon infection with V. longisporum leading to induction of these genes. Gene induction requires the transcription factor SYSTEMIC ACQUIRED RESISTANCE DEFICIENT 1 (SARD1) which is itself repressed by COI1. Equally, constitutive expression of genes in coi1 was abolished by mutations in SARD1 and its close homologue CALMODULIN BINDING PROTEIN 60-LIKE G. In contrast, overexpression of SARD1 in wild-type roots did not lead to activation of gene expression, likely because the repressive effect of COI1 on gene expression could not be overcome. The repressor function of COI1 was only observed in roots and not in shoots. As roots need to balance perception of microbe-associated molecular patterns with maintaining an intact rhizosphere, we speculate that COI1 acts as a regulator of the onset of defence responses in roots.2021-09-3

Regulation of proteinaceous effector expression in phytopathogenic fungi

Effectors are molecules used by microbial pathogens to facilitate infection via effector-triggered susceptibility or tissue necrosis in their host. Much research has been focussed on the identification and elucidating the function of fungal effectors during plant pathogenesis. By comparison, knowledge of how phytopathogenic fungi regulate the expression of effector genes has been lagging. Several recent studies have illustrated the role of various transcription factors, chromosome-based control, effector epistasis, and mobilisation of endosomes within the fungal hyphae in regulating effector expression and virulence on the host plant. Improved knowledge of effector regulation is likely to assist in improving novel crop protection strategies

A Thioredoxin Domain-Containing Protein Interacts with Pepino mosaic virus Triple Gene Block Protein 1

Pepino mosaic virus (PepMV) is a mechanically-transmitted tomato pathogen of importance worldwide. Interactions between the PepMV coat protein and triple gene block protein (TGBp1) with the host heat shock cognate protein 70 and catalase 1 (CAT1), respectively, have been previously reported by our lab. In this study, a novel tomato interactor (SlTXND9) was shown to bind the PepMV TGBp1 in yeast-two-hybrid screening, in vitro pull-down and bimolecular fluorescent complementation (BiFC) assays. SlTXND9 possesses part of the conserved thioredoxin (TRX) active site sequence (W__PC vs. WCXPC), and TXND9 orthologues cluster within the TRX phylogenetic superfamilyclosesttophosducin-likeprotein-3. InPepMV-infectedandhealthyNicotianabenthamiana plants,NbTXND9mRNAlevelswerecomparable,andexpressionlevelsremainedstableinbothlocal and systemic leaves for 10 days post inoculation (dpi), as was also the case for catalase 1 (CAT1). To localize the TXND9 in plant cells, a polyclonal antiserum was produced. Purified α-SlTXND9 immunoglobulin (IgG) consistently detected a set of three protein bands in the range of 27–35 kDa, in the 1000 and 30,000 g pellets, and the soluble fraction of extracts of healthy and PepMV-infected N. benthamiana leaves, but not in the cell wall. These bands likely consist of the homologous protein NbTXND9 and its post-translationally modified derivatives. On electron microscopy, immuno-gold labellingofultrathinsectionsofPepMV-infectedN.benthamianaleavesusingα-SlTXND9IgGrevealed particle accumulation close to plasmodesmata, suggesting a role in virus movement. Taken together, this study highlights a novel tomato-PepMV protein interaction and provides data on its localization in planta. Currently, studies focusing on the biological function of this interaction during PepMV infection are in progress