FUNCTIONAL CHARACTERIZATION OF TOMATO PROSYSTEMIN AND PROSYSTEMIN REGIONS: NOVEL TOOLS FOR PLANT DEFENSE

Prosystemin (ProSys) is a pro-hormone of 200 aminoacidic residues which releases a bioactive peptide hormone of 18 amino acids called Systemin (Sys) involved in the activation of a complex signaling cascade that leads to the production of defense compounds. The tomato genome contains only one copy of Prosys gene; it is composed of 4176 bp and is structured into 11 exons, of which the last one codes for Sys. Sys peptide was traditionally considered as the principal actor that confers protection against both biotic and abiotic environmental challenges observed in tomato plant overexpressing the ProSys. Thus, a single peptide hormone is capable of eliciting multiple defense pathways to counteract a wide range of unfavourable conditions for the plant. So far, it was unknown whether ProSys had any biological function other than being an intermediate in the synthesis of Sys. However, recent evidences suggest that Prosys devoid of the Sys sequence contributes to defense responses. This observation prompted us to investigate the biochemical and structural features of the ProSys protein. To this purpose ProSys has been expressed in BL21 (DE3) E. coli cells and purified. A detailed characterization of this pro-hormone by means of multidisciplinary approach revealed for the first time that this precursor behaves like an intrinsically disordered protein (IDP) possessing intrinsically disordered regions (IDRs) within the sequence. However, to find out an alternative delivery strategy not relying on transgenic plants, we decided to investigate the effects of exogenous application of the recombinant pro-hormone on the defense responses and its potential use as a plant protection tool in tomato. In particular, plant assays revealed that ProSys direct treatment of leaves is biologically active being very effective in the induction, both locally and systemically, of tomato defense-related genes, conferring protection against different pests. To our knowledge, this is the first biotic stress related IDP identified in plants, suggesting new interesting insights on the role of IDPs. into plant response against biotic stressors. IDPs are functionally important proteins lacking a stable or ordered three-dimensional structure. Despite being highly flexible, it has been demonstrated that IDPs have crucial roles in signal transduction process, cell-cycle regulation, gene expression and molecular recognition. The role of IDPs in these processes has been systematically studied in the animal kingdom. In contrast, less reports of these proteins from the plant kingdom are available in the scientific literature. In plant biology, IDPs play crucial roles among plant stress responses, signaling, and molecular recognition pathways, that resemble the functional roles of ProSys in the tomato defense pathways activated upon several biotic and abiotic stresses. These evidences aimed our study focused on the establishment of a relationship between ProSys structure and its biological activity. To this purpose different regions of ProSys have been expressed in BL21 (DE3) E. coli cells, purified and then characterized by a biophysical and biochemical point of view. Results showed that the recombinant fragments are disordered in agreement with what previously shown for the whole precursor. It was subsequently investigated whether the recombinant ProSys Fragments had any biological activity in activating defense responses upon biotic or abiotic attacks. In particular, by using a combination of gene expression analysis and bioassays, we proved that the exogenous supply of the recombinant ProSys Fragments to tomato plants promotes early and late plant defense genes, but only two fragments (namely Fragment I and III, encompassing the N-terminal part of the protein) were found to be the most promising. In addition, it was observed that the latter ones counteracted the development of Spodoptera littoralis larvae and the fungal leaf colonization. These results suggest that the direct application of these recombinant products, which are safe to humans and no-target organisms, may represent an exploitable tool for crop protection

GENETICS AND GENOMICS OF CULTIVATED EGGPLANTS AND WILD RELATIVES

Tesis por compendioAlimentar a la futura población en crecimiento en un contexto de cambio climático exige nuevos enfoques y herramientas de mejora genética para desarrollar nuevas variedades de cultivos que sean resilientes y eficientes en el uso de los recursos. Entre las hortalizas, la berenjena (Solanum melongena) es reconocida como un cultivo importante y como tal está incluida en el Anexo 1 del Tratado Internacional sobre los Recursos Fitogenéticos para la Alimentación y la Agricultura, que incluye 34 cultivos considerados como los más relevantes para la humanidad. Antes del inicio de esta tesis, se disponía de pocas herramientas genéticas y genómicas para la mejora genética de la berenjena, las cuales se revisan en un capítulo introductorio. Asimismo, hemos reconocido la importancia de los parientes silvestres de la berenjena, que apenas se han utilizado en la mejora genética de la misma. A este respecto, para hacer un uso más eficiente de los parientes silvestres en la mejora genética, propusimos un enfoque ambicioso, llamado "introgressiomics", que consiste en un desarrollo sistemático y masivo de materiales que lleven introgresiones de parientes silvestres (CWR), los cuales generalmente son una fuente inexplorada e desaprovechada de variación genética. Los trabajos realizados en esta tesis están relacionados con la aplicación de este enfoque a la berenjena. En este marco, los objetivos generales de la tesis son el desarrollo de la información y herramientas genéticas y genómicas en el acervo genético de la berenjena, utilizando un enfoque multidisciplinario y multifacético para la mejora genética en el desarrollo de nuevas variedades mejoradas y resistentes usando especies relacionadas como fuente de variación. Concretamente, en el primer capítulo de esta tesis, secuenciamos el transcriptoma de dos especies relacionadas con la berenjena, la silvestre Solanum incanum y la especie cultivada africana S. aethiopicum, que tienen un gran interés en la mejora genética de la berenjena. Los transcriptomas se ensamblaron en 83,905 y 87,084 unigenes para S. incanum y S. aethiopicum respectivamente, los cuales fueron extensivamente anotados estructuralmente y funcionalmente. La busqueda de variantes alélicas identificó decenas de miles de polimorfismos intraespecíficos e interespecíficos, así como alrededor de un millar de SSRs en cada especie. En el segundo capítulo, un subconjunto de esos marcadores (11 SSRs y 35 SNPs) se analizaron para confirmar su utilidad para la huella genética, la evaluación de la diversidad y el establecimiento de relaciones entre las berenjenas cultivadas (común, escarlata y gboma). Observamos que los SSRs y los SNPs proporcionaron resultados diferentes en el establecimiento de las relaciones, lo que sugiere que cada tipo de marcador muestreó diferentes niveles de variación genética. Sin embargo, aunque ambos marcadores proporcionaron un nivel similar de información, los SNPs parecen proporcionar una mejor resolución que los SSRs para materiales filogenéticamente más distantes. En el tercer capítulo, para ampliar la estimación de la diversidad genética y las relaciones genéticas entre y dentro de las especies silvestres y cultivadas pertenecientes al complejo berenjena, realizamos un genotipado masivo, mediante un enfoque de genotipado por secuenciación, de 76 accesiones pertenecientes a 17 especies del acervo genético primario, secundario y terciario de la berenjena común. De los 75,399 sitios polimórficos identificados, 12,859 se asociaron a regiones CDS y se usaron para establecer una evaluación exhaustiva y detallada de la diversidad alélica natural y las relaciones genéticas en el acervo genético de la berenjena utilizando tres enfoques diferentes (estructura jerárquica de la población, dendrograma basado en UPGMA y análisis de PCoA). En el cuatro capítulo, desarrollamos un mapa genético interespecífico entre S. incanum y S. melongena, vinculado a otrosFeeding the future burgeoning population in a climate change scenario demands new breeding approaches and tools to develop new resource-efficient and resilient crop varieties. Among vegetable crops, eggplant (Solanum melongena) is recognized as an important food crop and as such is included in the Annex 1 of the International Treaty on Plant Genetic Resources for Food and Agriculture, which includes 34 crops considered as most relevant for mankind. Before the start of this thesis, few genetic and genomic tools and resources for eggplant breeding, which are reviewed in an introductory chapter, were available. We have recognized the importance of wild eggplant relatives, which have been barely used in eggplant breeding. In this respect, in order to make a more efficient use of wild relatives in plant breeding, we proposed an ambitious approach, called "introgressiomics", consisting of a systematic and massive development of materials carrying introgressions from crop wild relatives (CWRs), which usually are an unexplored and unexploited source of genetic variation for breeding traits. The works done in this thesis are related to the application of the introgressiomics approach to eggplant. In this framework, the general objectives of the thesis are the development of genetic and genomic information and tools in eggplant genepool, using a multidisciplinary and multi-pronged approach to assist eggplant breeding in the development of new improved and resilient varieties using eggplant relatives as a source of variation. Specifically, in the first chapter of this thesis, we sequenced the transcriptome of two eggplant related species, the wild Solanum incanum and the cultivated S. aethiopicum, that have a great interest in eggplant breeding. The transcriptomes were assembled in 83,905 and 87,084 unigenes for S. incanum and S. aethiopicum respectively, which were extensively structurally and functionally annotated. The variant call analysis identified tens of thousands intraspecific and interspecific polymorphisms, as well as around a thousand of SSRs in each species. In the second chapter, a subset of those markers (11 SSRs and 35 SNPs) was tested for confirming their usefulness for genetic fingerprinting, diversity evaluation and the establishment of relationships in cultivated eggplant (common, scarlet and gboma) genepools. We observed that SSRs and SNPs provided different results in the establishment of the relationships, suggesting that each marker type sampled different levels of genetic variation. However, although both markers provided a similar level of information, SNPs seem to provide a better resolution than SSRs for materials phylogenetically more distant. In the third chapter, in order to broaden the estimation of the genetic diversity and genetic relationships among and within wild and cultivated species belonging to eggplant complexes, we performed a massive genotyping, by a genotype-by-sequencing approach, of 76 accessions belonging to 17 species from the primary, secondary and tertiary genepool of common eggplant. Out of 75,399 polymorphic sites identified, 12,859 were associated to CDS regions and used to establish an exhaustive and detailed evaluation of the natural allelic diversity and genetic relationships in eggplant genepool using three different approaches (hierarchical population structure, UPGMA-based dendrogram, and PCoA analysis). In the four chapter, we developed an interspecific genetic map between S. incanum and S. melongena, linked to four previous eggplant maps and to one tomato map. A total of 243 molecular markers were successfully mapped consisting of 42 COSII, 99 SSRs, 88 AFLPs, 9 CAPS, 4 SNPs and one morphological polymorphic markers encompassed 1085 cM distributed in 12 linkage groups. Based on the syntheny with tomato, the candidate genes involved in the core chlorogenic acid synthesis pathway in eggplant (PAL, C4H, 4CL, HCT, C3¿H, HQT), five polyphenol oxidase genes (PPO1, PPO2, PPO3, PPAlimentar la futura població en creixement en un context de canvi climàtic exigeix nous enfocaments i eines de millora genètica per desenvolupar noves varietats de cultius que siguin resilients i eficients en l'ús dels recursos. Entre les hortalisses, l'albergínia (Solanum melongena) és reconeguda com un cultiu important i com a tal està inclosa en l'Annex 1 del Tractat Internacional sobre els Recursos Fitogenètics per a l'Alimentació i l'Agricultura, que inclou 34 cultius considerats com els més rellevants per a la humanitat. Abans de l'inici d'aquesta tesi, es disposava de poques eines genètiques i genòmiques per a la millora genètica de l'albergínia, les quals es revisen en un capítol introductori. Així mateix, hem reconegut la importància dels parents silvestres de l'albergínia, que tot just s'han utilitzat en la millora genètica de la mateixa. Referent a això, per fer un ús més eficient dels parents silvestres a la millora genètica, vam proposar un enfocament ambiciós, anomenat "introgressiomics", que consisteix en un desenvolupament sistemàtic i massiu de materials que portin introgresions de parents silvestres (CWR), els quals generalment són una font inexplorada i desaprofitada de variació genètica. Els treballs realitzats en aquesta tesi estan relacionats amb l'aplicació d'aquest enfocament a l'albergínia. En aquest marc, els objectius generals de la tesi són el desenvolupament de la informació i eines genètiques i genòmiques en el patrimoni genètic de l'albergínia, utilitzant un enfocament multidisciplinari i multifacètic per a la millora genètica en el desenvolupament de noves varietats millorades i resistents emprent spècies relacionades com a font de variació. Concretament, en el primer capítol d'aquesta tesi, seqüenciem el transcriptoma de dues espècies relacionades amb l'albergínia, la silvestre Solanum incanum i l'espècie cultivada africana S. aethiopicum, que tenen un gran interès en la millora genètica de l'albergínia. Els transcriptomes s'ensamblaren en 83,905 i 87,084 unigenes per S. incanum i S. aethiopicum respectivament, els quals van ser extensivament anotats estructuralment i funcionalment. La recerca de variants al·lèliques va identificar desenes de milers de polimorfismes intraespecífics i interespecífics, així com al voltant d'un miler de SSRs en cada espècie. En el segon capítol, un subconjunt d'aquests marcadors (11 SSRs i 35 SNPs) es van analitzar per confirmar la seva utilitat per l'empremta genètica, l'avaluació de la diversitat i l'establiment de relacions entre les albergínies conreades (comú, escarlata i gboma). Observem que els SSRs i els SNPs van proporcionar resultats diferents en l'establiment de les relacions, el que suggereix que cada tipus de marcador va mostrejar diferents nivells de variació genètica. No obstant això, encara que tots dos marcadors van proporcionar un nivell similar d'informació, els SNPs semblen proporcionar una millor resolució que els SSRs per materials filogenèticament més distants. En el tercer capítol, per a ampliar l'estimació de la diversitat genètica i les relacions genètiques entre i dins de les espècies silvestres i conreades pertanyents al complex albergínia, vam realitzar un genotipat massiu, mitjançant un enfocament de genotipat per seqüenciació, de 76 accessions pertanyents a 17 espècies del patrimoni genètic primari, secundari i terciari de l'albergínia comuna. Dels 75,399 llocs polimòrfics identificats, 12,859 es van associar a regions CDS i es van usar per a establir una avaluació exhaustiva i detallada de la diversitat al·lèlica natural i les relacions genètiques en el patrimoni genètic de l'albergínia utilitzant tres enfocaments diferents (estructura jeràrquica de la població, dendrograma basat en UPGMA i anàlisi de PCoA). En el quart capítol, desenvolupem un mapa genètic interespecífic entre S. incanum i S. melongena, vinculat a altres quatre mapes anteriorGramazio, P. (2018). GENETICS AND GENOMICS OF CULTIVATED EGGPLANTS AND WILD RELATIVES [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/104605TESISCompendi

Revitalizing agriculture: next-generation genotyping and -omics technologies enabling molecular prediction of resilient traits in the Solanaceae family

This review highlights -omics research in Solanaceae family, with a particular focus on resilient traits. Extensive research has enriched our understanding of Solanaceae genomics and genetics, with historical varietal development mainly focusing on disease resistance and cultivar improvement but shifting the emphasis towards unveiling resilience mechanisms in genebank-preserved germplasm is nowadays crucial. Collecting such information, might help researchers and breeders developing new experimental design, providing an overview of the state of the art of the most advanced approaches for the identification of the genetic elements laying behind resilience. Building this starting point, we aim at providing a useful tool for tackling the global agricultural resilience goals in these crops

Development of Biotechnological Tools for the Genetic Improvement of Pepino (Solanum Muricatum) and Tree Tomato (S.betaceum)

Tesis por compendio[ES] El pepino dulce (Solanum muricatum) y el tomate de árbol (S. betaceum) pertenecen al grupo de cultivos de la familia Solanaceae. Estos dos cultivos son originarios de América del Sur y actualmente se cultivan en varios países con climas tropicales, subtropicales y mediterráneos. Han sido infrautilizados durante mucho tiempo y han cobrado relevancia solo en los últimos años debido a su alta calidad nutricional. El pepino dulce exhibe niveles significativos de potasio, vitamina C y carotenoides y se informa que presenta propiedades antioxidantes, antidiabéticas, antiinflamatorias y antitumorales. Sus frutos se pueden consumir tanto como postre o en ensaladas. El tomate de árbol también destaca por su alto contenido en compuestos bioactivos como carotenoides, antocianinas, flavonoides y vitaminas. Varios productos como jugos, mermeladas, salsas y productos farmacéuticos son elaborados a partir de sus frutos. Debido a que estos cultivos se han introducido en nuevas regiones, donde pueden estar expuestos a estreses bióticos y abióticos que pueden amenazar su producción, y dado que el pepino dulce se ve especialmente afectado por la escasez de agua, fue necesario realizar un estudio para determinar la respuesta de siete cultivares de pepino dulce a parámetros fisiológicos y bioquímicos al estrés por sequía. Este trabajo puede ayudar a desarrollar programas de selección y mejoramiento que permitan generar nuevas variedades más tolerantes a la sequía. Por otro lado, en los países de clima mediterráneo, el pepino dulce se cultiva como cultivo protegido, aplicando las mismas técnicas agrícolas que otras solanáceas como el tomate y el pimiento. Estos sistemas agrícolas también brindan condiciones óptimas para el desarrollo de enfermedades como Fusarium oxysporum f. sp. lycopersici (FOL), Verticillium dahliae (VE), virus del mosaico del pepino (PepMV) y virus del mosaico del tomate (ToMV), que potencialmente podrían causar grandes daños a los cultivos de pepino dulce. Por tal motivo, se realizó un estudio para evaluar la respuesta de una colección de pepino dulce y sus parientes silvestres contra estas cuatro enfermedades, y encontrar fuentes de resistencia/tolerancia a estos patógenos. Aunque el tomate de árbol es un cultivo frutal importante debido a su valor nutricional y efectos beneficiosos para la salud, actualmente no hay información genómica y transcriptómica disponible públicamente. Por lo tanto, fue fundamental secuenciar el transcriptoma de dos cultivares de tomate de árbol con frutos morados (A21) y frutos anaranjados (A23). Estos dos cultivares han sido ampliamente utilizados y cultivados comercialmente en países de la región andina como Ecuador y Colombia. La obtención del primer transcriptoma de tomate de árbol ha permitido realizar un estudio comparativo entre el tomate de árbol y sus especies cercanas, tomate y patata, identificar genes implicados en la ruta de biosíntesis de carotenoides y desarrollar marcadores de polimorfismo de nucleótido único (SNP). En general, esta Tesis Doctoral aporta información relevante sobre la respuesta del pepino a diversos estreses ambientales, que puede ser utilizada para el desarrollo de nuevas variedades de pepino resistentes a múltiples estreses. Mientras que en tomate de árbol, el desarrollo de herramientas genómicas acelerará los programas de mejoramiento.[CA] El cogombre dolç (Solanum muricatum) i tomata d'arbre (S. betaceum) pertanyen al grup de cultius de la família Solanaceae. Aquests dos cultius són originaris d'Amèrica del Sud i actualment es cultiven en diversos països amb climes tropicals, subtropicals i mediterranis. Han sigut infrautilitzats durant molt de temps i han cobrat rellevància només en els últims anys a causa de la seua alta qualitat nutricional. El cogombre dolç exhibeix nivells significatius de potassi, vitamina C i carotenoides i s'informa que presenta propietats antioxidants, antidiabètiques, antiinflamatòries i antitumorals. Els seus fruits es poden consumir tant com postres o en ensalades. La tomaca d'arbre també destaca pel seu alt contingut en compostos bioactivos com carotenoides, antocianinas, flavonoides i vitamines. Dels seus fruits s'elaboren diversos productes com a sucs, melmelades, salses i productes farmacèutics. Pel fet que aquests cultius s'han introduït en noves regions on poden estar exposats a estressos biòtics i abiòtics que poden amenaçar la seua producció, atés que el cogombre es veu especialment afectat per l'escassetat d'aigua, va ser necessari realitzar un estudi per a determinar la resposta de set cultivars de cogombre dolç a paràmetres fisiològics i bioquímicos a l'estrés per sequera. Aquest treball pot ajudar a desenvolupar programes de selecció i millorament que permeten generar noves varietats més tolerants a la sequera. D'altra banda, als països de clima mediterrani, el cogombre dolç es cultiva com a cultiu protegit, aplicant les mateixes tècniques agrícoles que unes altres solanáceas com la tomaca i el pimentó. Aquests sistemes agrícoles també brinden condicions òptimes per al desenvolupament de malalties com Fusarium oxysporum f. sp. lycopersici (FOL), Verticillium dahliae (VE), virus del mosaic del cogombre (PepMV) i virus del mosaic de la tomaca (ToMV), que potencialment podrien causar grans danys als cultius de cogombre dolç. Per tal motiu, es va realitzar un estudi per a avaluar la resposta d'una col·lecció de cogombre dolç i els seus parents silvestres contra aquestes quatre malalties, i trobar fonts de resistència/tolerància a aquests patògens. Encara que la tomaca d'arbre és un cultiu fruiter important a causa del seu valor nutricional i efectes beneficiosos per a la salut, actualment no hi ha informació genòmica i transcriptómica disponible públicament. Per tant, va ser fonamental seqüenciar el transcriptoma de dues cultivars de tomaca d'arbre amb fruits morats (A21) i fruits ataronjats (A23). Aquestes dues cultivars han sigut àmpliament utilitzats i cultivats comercialment en països de la regió andina com l'Equador i Colòmbia. L'obtenció del primer transcriptoma de tomaca d'arbre ha permés realitzar un estudi comparatiu entre la tomaca d'arbre i les seues espècies pròximes, tomaca i creïlla, identificar gens implicats en la ruta de biosíntesi de carotenoides i desenvolupar marcadors de polimorfisme de nucleòtid únic (SNP). En general, aquesta Tesi Doctoral aporta informació rellevant sobre la resposta del cogombre a diversos estressos ambientals, que pot ser utilitzada per al desenvolupament de noves varietats de cogombre resistents a múltiples estressos. Mentre que en tomaca d'arbre, el desenvolupament d'eines genòmiques accelerarà els programes de millorament.[EN] Pepino (Solanum muricatum) and tree tomato (S. betaceum) belong to the group of crops of the Solanaceae family. These two crops are native to South America and currently are grown in various countries with tropical, subtropical and Mediterranean climates. They have been underutilized for a long time and have become relevant only in recent years due to their high nutritional quality. Pepino exhibit significant levels of potassium, vitamin C and carotenoids and it is reported to present antioxidant, antidiabetic, anti-inflammatory and antitumor properties. Its fruits can be consumed both as a dessert or in salads. Tree tomato also highlights high content of bioactive compounds such as carotenoids, anthocyanins, flavonoids and vitamins. Severals products such as juices, jams, sauces and pharmaceutical products are made from its fruits. Due to these crops have been introduced into new regions, where they may be exposed to biotic and abiotic stresses that can threaten their production, and since pepino is specially affected by water scarcity, a study was needed to determine the response of seven pepino cultivars to physiological and biochemical parameters to drought stress. This work can help develop selection and improvement programs that allow the generation of new varieties that are more tolerant to drought. On the other hand, in countries with a Mediterranean climate, pepino is grown as a protected crop, applying the same agricultural techniques as other solanaceous plants such as tomato and pepper. These agricultural systems also provide optimal conditions for the development of diseases such as Fusarium oxysporum f. sp. lycopersici (FOL), Verticillium dahliae (VE), pepino mosaic virus (PepMV) and tomato mosaic virus (ToMV), which could potentially cause great damage to pepino crops. For this reason, a study was performed to evaluate the response of a collection of pepino and their wild relatives against these four diseases, and find sources of resistance/tolerance to those pathogens. Although tree tomato is an important fruit crop due to its nutritional value and beneficial health effects, there is currently no publicly available genomic and transcriptomic information. Therefore, it was essential to sequence the transcriptome of two tree tomato cultivars with purple fruits (A21) and orange fruits (A23). These two cultivars have been widely used and cultivated commercially in countries of the Andean region such as Ecuador and Colombia. Obtaining the first tree tomato transcriptome has made it possible to perform a comparative study between tree tomato and its close species, tomato and potato, identify genes involved in the carotenoid biosynthesis pathway, and develop single nucleotide polymorphism (SNP) markers. In general, this Doctoral Thesis provides relevant information on the response of pepino to various environmental stresses, which can be used for the development of new varieties of pepino resistant to multiple stresses. While in tree tomato, the development of genomic tools will accelerating up breeding programs.Pacheco Toabanda, JE. (2022). Development of Biotechnological Tools for the Genetic Improvement of Pepino (Solanum Muricatum) and Tree Tomato (S.betaceum) [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/189205Compendi

Isolation and characterization of potato homologues of Arabidopsis thaliana genes operating in defense signal transduction

An increasing number of pathogen-defense related genes are being identified and characterized in Arabidopsis thaliana. So far, it is not known whether and which structural and functional homologues of these Arabidopsis genes have any role in natural variation of resistance to pathogens in crops. Using sequence database mining and PCR-based approaches, potato (Solanum tuberosum L.) gene fragments with high sequence similarity to 16 Arabidopsis defense signal transduction genes were obtained, sequenced and genetically positioned on potato molecular maps. Of 16 novel loci, five were positional candidates for known potato pathogen resistance QTL. One of the candidate loci, StAOS2 co-localizing with QTL for resistance to P. infestans and E. carotovora on linkage group XI, was further characterized in more detail. StAOS2 encodes a gene for allene oxide synthase, a cytochrome P450-enzyme, acting upstream in the jasmonic acid biosynthesis pathway. A metabolic block at the level of AOS completely abolishes JA production, which affects plant development (e.g. sterile pollen production) and various abiotic and biotic stress responses (e.g. P. infestans resistance in tomato, E. carotovora resistance in Arabidopsis). The chloroplastic localization of StAOS2-GFP was confirmed by confocal microscopy and functionality of the potato protein was proven by complementation of the male-sterile Arabidopsis aos mutant. StAOS2-RNAi transgenic lines in potato were generated in order to test role of StAOS2 in P. infestans resistance. The measurements of endogenous OPDA and JA in the silenced lines after wounding treatment revealed drastic decrease in the levels of above mentioned compounds (up to 25 folds less than in wild type plants). In addition, natural variation of StAOS2 locus was characterized. Sequencing of the locus across 38 potato chromosomes revealed high polymorphism. Thirteen distinct alleles were found, and four of them showed highly significant (P=0.000, R2=14%) linkage to P. infestans and E. carotovora QTL. Five alleles of StAOS2 were cloned. Sequence analyses revealed a substantial polymorphism on amino acid level, including non-conservative substitutions and an insertion/deletion within the cytochrome P450 domain. Currently, an ongoing quantitative complementation of the Ataos mutant with the five different StAOS2 alleles fused to the native AtAOS promoter, followed by OPDA and JA levels measurements in the transgenic lines, will possibly provide direct evidence for StAOS2 being the first plant resistance QTL identified

Advances in Molecular Breeding of Vegetable Crops

Vegetable crops provide valuable minerals and vitamins that are indispensible for human health. Scientists have been working on the genetics of vegetable crops, deciphering the molecular bases of agronomically important traits. These genetic bases and variations in vegetable traits will greatly facilitate vegetable genetic improvement. Therefore, the genes of and genetic research on vegetable crops are of great importance. This Special Issue is a collection of 13 important research papers addressing the genes, genetics, and breeding of major vegetable crops. In the present book, the authors described the genes and QTLs responsible for stress tolerance, disease resistance, vegetable yield, and quality. The 13 research papers cover germplasm enhancement and evaluation, QTL mapping, gene isolation, marker development, and gene expression as well as gene editing in a wide range of vegetable species, including broccoli, pepper, eggplant, onion, and Cucurbita species. Readers from all over the globe are expected to greatly benefit from this Special Issue collection regarding their own work and the goal of improving breeding efficiency with molecular breeding to generate environment-adaptive, high-yield, and high-quality vegetable crops with which to feed the global population of 9.7 billion in an extreme climate by 2050

Identification of Candidate Genes Associated With Tolerance to Apple Replant Disease by Genome-Wide Transcriptome Analysis

Apple replant disease (ARD) is a worldwide economic risk in apple cultivation for fruit tree nurseries and fruit growers. Several studies on the reaction of apple plants to ARD are documented but less is known about the genetic mechanisms behind this symptomatology. RNA-seq analysis is a powerful tool for revealing candidate genes that are involved in the molecular responses to biotic stresses in plants. The aim of our work was to find differentially expressed genes in response to ARD in Malus. For this, we compared transcriptome data of the rootstock ‘M9’ (susceptible) and the wild apple genotype M. ×robusta 5 (Mr5, tolerant) after cultivation in ARD soil and disinfected ARD soil, respectively. When comparing apple plantlets grown in ARD soil to those grown in disinfected ARD soil, 1,206 differentially expressed genes (DEGs) were identified based on a log2 fold change, (LFC) ≥ 1 for up– and ≤ −1 for downregulation (p < 0.05). Subsequent validation revealed a highly significant positive correlation (r = 0.91; p < 0.0001) between RNA-seq and RT-qPCR results indicating a high reliability of the RNA-seq data. PageMan analysis showed that transcripts of genes involved in gibberellic acid (GA) biosynthesis were significantly enriched in the DEG dataset. Most of these GA biosynthesis genes were associated with functions in cell wall stabilization. Further genes were related to detoxification processes. Genes of both groups were expressed significantly higher in Mr5, suggesting that the lower susceptibility to ARD in Mr5 is not due to a single mechanism. These findings contribute to a better insight into ARD response in susceptible and tolerant apple genotypes. However, future research is needed to identify the defense mechanisms, which are most effective for the plant to overcome ARD. Copyright © 2022 Reim, Winkelmann, Cestaro, Rohr and Flachowsky

Identification of candidate genes associated with tolerance to apple replant disease by genome-wide transcriptome analysis

Apple replant disease (ARD) is a worldwide economic risk in apple cultivation for fruit tree nurseries and fruit growers. Several studies on the reaction of apple plants to ARD are documented but less is known about the genetic mechanisms behind this symptomatology. RNA-seq analysis is a powerful tool for revealing candidate genes that are involved in the molecular responses to biotic stresses in plants. The aim of our work was to find differentially expressed genes in response to ARD in Malus. For this, we compared transcriptome data of the rootstock ‘M9’ (susceptible) and the wild apple genotype M. ×robusta 5 (Mr5, tolerant) after cultivation in ARD soil and disinfected ARD soil, respectively. When comparing apple plantlets grown in ARD soil to those grown in disinfected ARD soil, 1,206 differentially expressed genes (DEGs) were identified based on a log2 fold change, (LFC) ≥ 1 for up– and ≤ −1 for downregulation (p < 0.05). Subsequent validation revealed a highly significant positive correlation (r = 0.91; p < 0.0001) between RNA-seq and RT-qPCR results indicating a high reliability of the RNA-seq data. PageMan analysis showed that transcripts of genes involved in gibberellic acid (GA) biosynthesis were significantly enriched in the DEG dataset. Most of these GA biosynthesis genes were associated with functions in cell wall stabilization. Further genes were related to detoxification processes. Genes of both groups were expressed significantly higher in Mr5, suggesting that the lower susceptibility to ARD in Mr5 is not due to a single mechanism. These findings contribute to a better insight into ARD response in susceptible and tolerant apple genotypes. However, future research is needed to identify the defense mechanisms, which are most effective for the plant to overcome ARD

Investigation on the role of plant defensin proteins in regulating plant-Verticillium longisporum interactions in Arabidopsis thaliana

The hemibiotrophic pathogen Verticillium longisporum infects rapeseed (Brassica napus) and poses a real threat to its cultivation. Conventional approaches are limited and are based primarily on the availability of a wide gene pool to identify suitable genotypes for breeding in order to improve resistance, e.g. against abiotic stress or pathogens. In order to achieve this goal also in crop plants with a very narrow gene pool like rapeseed, new strategies have to be developed. One solution could be the expression of plant defensins (PDFs), which are known for their anti-fungal effects. In our laboratory, compatibility factors (CF) were identified in Arabidopsis, the loss of which led to a highly increased expression of AtPDF2.2. There are already numerous examples of how overexpression of such PDFs in model and crop plants led to improved and lasting resistance. This thesis work demonstrated the antifungal role of two AtPDF genes that contribute to the regulation of the Arabidopsis-Verticillium interaction. GUS expression under the AtPDF2.2 promoter showed that AtPDF2.2 was suppressed in Arabidopsis roots 6 days after infection (dpi) and later in leaves (9 dpi). This was confirmed by a transcript analysis that showed strong suppression of the AtPDF2.2 expression and two other Arabidopsis genes of PDF class II. Transgenic lines for AtPDF2.2 overexpression (OE-PDF2.2) and for knockdown (KD-pdf2.2) also showed an increased expression of AtPDF2.3 and AtPDF2.5 in the OE-PDF2.2 line, while a corresponding suppression in the KD-pdf2.2 line was recorded. Another important observation in the KD-pdf2.2 line was an enhanced jasmonic acid (JA) response, accompanied by upregulation of ethylene (ET) and salicylic acid (SA) -dependent genes, an effect that also in other infections with hemibiotrophic pathogens was observed. Therefore, based on available data, it can be assumed that V. longisporum uses host compatibility factors during the early phase of infection to suppress AtPDF2.2 to bypass plant defense. This also suppresses the expression of the closely related genes AtPDF2.3 and 2.5, which enables the fungus to establish a successful infection process. However, the suppression of these three PDFs, in turn, triggers the JA response which subsequently activates ET and SA signaling to mediate the reprogramming of defense response. To investigate the antifungal effect of AtPDF2.2, the OE-PDF2.2 line was analyzed, which showed increased resistance to two fungal (V. longisporum and Sclerotinia sclerotiorum) and one bacterial pathogen (Pseudomonas syringae). In contrast, the KD-pdf2.2 line showed a higher susceptibility to these fungal and bacterial pathogens. However, Verticillium longisporum induces the expression of AtPDF1.2a at 6 dpi in Arabidopsis wild type Col-0. Transcript study in the AtPDF1.2a overexpression (OE-PDF1.2a) and knockout (KO-pdf1.2a) plants revealed that AtPDF1.2a expression positively correlates with Class-I and III AtPDF genes, but negatively to AtPDF2.2, 2.3 and 2.5. Moreover, OE-PDF1.2a plants did not upregulate the expression of JA, ET or SA marker genes but KO-pdf1.2a plants showed induced expression of all the three pathways responsive genes. Possibly, low expression of AtPDF1.2a in KO-pdf1.2a plants during ongoing infection works as a concentration-specific signal. Since OE-PDF1.2a plants did not show significant changes in the expression of upstream JA, ET, and SA responsive genes it might rather be that upon V. longisporum attack AtPDF1.2a positively co-regulates several AtPDF genes from Class-I and III, while suppressing the expression of AtPDF2.2, 2.3 and 2.5 to reprogram the plant defense response. The antifungal activity has already been demonstrated for AtPDF1.2a, but its exact role in plant defense is still unclear. Therefore, OE-PDF1.2a lines were used, AtPDF1.2a seems to have an antifungal effect only on fungal pathogens; V. longisporum and Sclerotinia sclerotiorum but not on the bacterial pathogen