Developing an optimized PCR protocol for microsatellite analysis in Vaccinium myrtillus

Wreth, Cajsa

January 2024

In the future, food security will face significant challenges due to climate change and a growing world population. One approach to make agriculture more sustainable is to preserve biodiversity by utilizing crop wild relatives as a source of genetic material. These crop wild relatives are closely related to today’s cultivated crops and can be an important asset to combat food insecurity. Gaining more knowledge about a species’ genetic diversity through microsatellite analysis is an important step for future conservation and potential utilization in crop improvement. However, before these studies can take place the microsatellite markers have to be optimized for PCR. In this study, eleven microsatellite markers were optimized for bilberry individuals. Optimized annealing temperatures were found for all markers and most of them had amplification in three or more of the individuals tested from Sweden, Finland and Iceland. Ten out of the eleven tested markers were regarded suitable for future genetic diversity analyses. The eleventh, VCB-C00694, was considered unsuitable due to formation of primer dimers and not amplifying in several individuals. By assessing the genetic diversity of bilberry, Vaccinium myrtillus, it opens up the possibility to enrich their domesticated relative the American blueberry, Vaccinium corymbosum, by introducing new genetic variety. In relation to this, the increased knowledge about genetic diversity among bilberries in the Nordic can lead to better understanding of their need for conservation.

Agriculture

bilberry

Crop wild relatives

microsatellites

PCR

species conservation

Biochemistry and Molecular Biology

Biokemi och molekylärbiologi

Elargissement de la base génétique de l'arachide cultivée (Arachis hypogaea) : applications pour la construction de populations, l'identification de QTL, et l'amélioration de l'espèce cultivée / Broadening the gene pool of cultivated peanut (Arachis hypogaea) : application for population development, QTLs mapping and breeding

Fonceka, Daniel

10 December 2010

L'arachide (Arachis hypogaea L.) est une plante allotétraploïde (2n = 4x = 40) issue d'un événement récent d'hybridation entre deux espèces sauvages suivi d'un doublement spontané des chromosomes. La variabilité génétique existant dans le compartiment cultivé est faible. Les espèces diploïdes sauvages apparentées à l'arachide cultivée représentent un important réservoir d'allèles nouveaux utilisables pour élargir le pool génique du cultigène. L'objectif général de cette thèse est d'augmenter les marges de progression en amélioration de l'arachide par recours aux ressources génétiques sauvages. Nous avons développé une population BC1F1 à partir du croisement entre Fleur11 et un amphidiploïde synthétique (A. ipaensis x A. duranensis)x4 qui associe les génomes des plus probables progéniteurs sauvages de l'espèce cultivée. Nous avons d'abord construit une carte génétique comprenant 298 loci positionnés sur 21 groupes de liaison avec une taille totale de 1843.7 cM. Nous avons ensuite conduit une analyse AB-QTL pour plusieurs caractères impliqués dans la productivité, l'adaptation et la domestication de l'arachide. Au total, nous avons cartographié 95 QTL. Pour plusieurs QTL, les effets positifs sont associés aux allèles provenant des espèces sauvages. Nous avons aussi identifié trois régions du génome qui portent des empreintes de la domestication. Nous avons enfin développé une population de 122 lignées d'introgression à l'aide d'une stratégie de sélection assistée par marqueurs. L'ensemble des groupes de liaison sont couverts avec des frag ments chevauchants, issus des donneurs sauvages, d'une taille moyenne de 39.2 cM et chaque lignée comprend en moyenne 1.2 fragments. Nous avons par ailleurs discuté l'utilisation de cette collection de lignées d'introgression pour des applications de sélection et de recherche. Nos résultats ouvrent de nouvelles perspectives pour l'amélioration de l'arachide par croisement avec les espèces sauvages apparentées. / Peanut (Arachis hypogaea L.) is considered to be an allotetraploid (2n = 4x = 40) originated from a single hybridization event between two wild diploids followed by spontaneous chromosomes duplication. Cultivated peanut harbours a limited genetic diversity. Peanut wild relatives represent an important source of novel alleles that could be used to broaden the gene pool of the cultigen. The general objective of this work is to enhance the rate of progress in peanut breeding using wild species resources.We developed a BC1F1 population from the cross between Fleur11 and a synthetic amphidiploid (A. ipaensis x A. duranensis)x4 that combines the genomes of the most probable wild progenitors of the cultigen. We first developed a SSR based genetic map of 298 loci on 21 linkage groups, spanning a total map distance of 1843.7 cM. We then conducted a detailed AB-QTL analysis for several traits involved in peanut productivity and adaptation as well as in the domestication syndrome. We mapped a total of 95 QTLs. About half of the QTL positive effects were associated with alleles of the wild parents and several QTLs involved in yield components were specific to the water-limited treatment. We identified three genomic regions which bear footprints of domestication. We finally developed, through a marker assisted backcross strategy, an exotic introgression library of 122 lines. This population, which has in average 1.2 fragments per line, allows covering all linkage groups with overlappi ng wild donor fragments of in average 39.2 cM length. The utilization of the exotic introgression lines library for breeding and research is discussed. Our findings open new avenues for peanut improvement using wild relatives.

Arachis hypogaea

Cartographie de QTL

Domestication

Ressources génétiques sauvages

Polyploïde

Amélioration

Arachis hypogaea

QTL mapping

Domestication

Wild relatives

Polyploid

Breeding

Ecogeographical Surveying For IN SITU Conservation Of Wild Relatives Of Cultivated Plants In Uttara Kannada District Of Karnataka State, India

Singh, Shri Niwas

07 1900

No description available.

Botany - Ecology - Uttara Kannada

Plants - Conservation

Plant Crops

Plants - Ecology

Cultivated Plants - Uttara Kannada

Myristica Swamps

Plant Ecology

Genetic analysis of Helosciadium repens (Jacq.) W.D.J.Koch populations in Germany - Fundamental research for conservation management

Herden, Tobias

03 February 2020

Crop wild relatives (CWR) are an indispensable and at the same time threatened genetic resources for plant breeding. The study uses wild species related to celery to demonstrate how genetic resources of CWRs can be actively maintained in their natural surroundings (in-situ). Genetic reserves should be designated for long term conservation of selected occurrences. The study presents the selection procedure in detail, aiming at the identification of occurrences and sites suitable for the designation of genetic reserves, the spatial model of a genetic reserve and first practical results of the project. The overall aim of the project is the establishment of a nationwide network of genetic reserves for Apium graveolens, Helosciadium repens, H. nodiflorum and H. inundatum, the four wild celery species native to Germany. Helosciadum repens (Jacq.) W.D.J.Koch is threatened by genetic erosion due to a decline in population numbers and sizes. The loss of any population is an irretrievable loss of diversity and opportunity to enhance crops in the future. Genetic reserves are one way to conserve these populations and their genetic potential. Twenty-seven populations were selected for the analysis in a decision process based on site information. Microsatellites (SSR) were used to elucidate the genetic diversity of German populations. A cluster analysis was performed to see if the individuals form clusters of similarity. For that, a discriminate analysis of principal components (DAPC) was conducted, as the inbreeding index indicated a high number of inbreeding events in the populations and thus discordance with HWE (Hardy-Weinberg equilibrium). The analysis identified six genetic groups, which coincide well with the geographic origin of the analysed plants. The allelic richness (mean counts of alleles per individual per population) was higher in the southern populations compared to the northern ones. This North-South discrepancy was also visible as a high heterogeneity in the cluster assignments in the DAPC analysis. These differences in genetic diversity might be a result of the biogeographic history of Europe, especially the last glacial maximum. For the establishment of genetic reserves, two populations were considered as most important: The population that differs the most from the average genetic composition and the population that represents the average genetic composition of a population the best. The two extremes of differentiation were interpreted as such that the former has a specific adaptation to its local environment, and the latter represents all populations the best. DifferInt was used to analyse the SSR data and validate the differentiation of all populations compared to a pool of populations. However, SSRs are not capable of detecting adaptive traits. Populations were additionally chosen from different eco-geographic units (EGU), to increase the chance of capturing different traits. EGUs (Naturräume) are areas of specific abiotic and biotic features. These features may influence selection pressures and induce local adaptations. Based on site parameters and genetic data, 14 most appropriate wild populations (MAWP) were identified for genetic reserves establishment. For H. repens, two eco-forms are known and described in the literature. Besides their different habitats (terrestrial/semi-terrestrial and aquatic) they can be differentiated by morphological traits. Leave and stolon sizes and flowering behaviour differ significantly. Furthermore, the roots of the aquatic forms do not anchor in soil but on other aquatic plants, wood or roots of trees, while the terrestrial form exhibits a shallow root system network similar to other perennial species. To this end, no genetic analysis was conducted to clarify the phylogenetic status of the putative forms and authors avoided the usage of any specific noun rather than form. The SSR data from the previous study was evaluated, particularly with regards to the two forms. Additionally, an ISSR analysis was conducted, and the data was used to perform a PCA. There was no genetic clustering regarding the two forms neither in the SSR nor in the ISSR data. Nonetheless, the North-South discrepancy in the genetic diversity that was visible in the DAPC plot was confirmed in the PCA of the ISSR data. However, markers may fail to detect quantitative variation for adaptively important traits. As the most obvious difference in the two habitats was the water availability, the adaptation of both forms to drought stress was studied by measuring the relative water content of leaves, system water content and water loss during drought stress conditions. The stomatal index was measured for different water treatment levels. The results indicate that phenotypic plasticity rather than genotypic adaptation is responsible for different H. repens phenotypes.

Helosciadium repens

ecotypes

phenotypic plasticity

Apiaceae

genetic reserve

crop wild relatives

celery

SSR

DAPC

ISSR

genetics

population analysis

conservation

42.47 - Spezielle Botanik: Allgemeines

ddc:570

Distribution des parents sauvages du quinoa cultivé en lien avec les pratiques et usages des communautés andines dans la région de Puno au Pérou / Distribution of quinoa crop wild relatives linked to practices and uses in Andean communities of the Puno region of Peru

Fagandini ruiz, Francesca

09 January 2019

Dans les hauts plateaux des Andes entre le Pérou et la Bolivie, à 3 800 mètres d’altitude s’étend le lac Titicaca, berceau des civilisations précolombiennes et l’un des principaux centres mondiaux de domestication des espèces végétales cultivées pour l’agriculture. Cette région est reconnue comme le centre d’origine du quinoa, C. quinoa Willd. Elle concentre la plus grande diversité génétique du quinoa, tant pour les variétés paysannes cultivées que pour les espèces sauvages apparentées. Notre recherche a été conduite dans la région de Puno, Pérou, qui reste l’une des principales régions productrices de quinoa au monde. Le quinoa y présente une distribution spatiale selon un gradient climatique nord-sud et une différenciation en zones agroécologiques liée à l’altitude. Actuellement, sept principales espèces de parents sauvages du quinoa y sont présentes : C.ambrosioides L., C.incisum Poiret, C.pallidicaule Aellen, C.petiolare Kunth, C.hircinum Schrad., C.quinoa ssp. melanospermum Hunz. et C.carnosolum Moq. Cette diversité de ressources génétiques a une grande valeur pour l’évolution adaptative du quinoa notamment face aux effets du changement climatique. Notre thèse s’inscrit dans l’importance économique et culturelle du quinoa, étant à la fois une ressource alimentaire des régions andines et l’objet des marchés internationaux du fait de ses qualités nutritives. Cette opportunité économique peut avoir des impacts en termes de sécurité alimentaire, d’agrobiodiversité, et de gestion de l’agroécosystème. Cette thèse a analysé comment les communautés agricoles andines intègrent la présence des espèces de parents sauvages dans leurs pratiques de gestion et leurs pratiques agricoles autour du quinoa. Des cartographies participatives et des enquêtes ethnobotaniques ont été réalisées avec les membres de six villages choisis selon des critères biogéographiques. La modélisation chorématique a été appliquée à deux périodes, avant et après 1970, année charnière au Pérou pour l’agriculture, dans le but de montrer comment les dynamiques socio-spatiales du milieu andin se modifient, notamment en lien avec l’évolution de la culture du quinoa. La distribution des espèces de parents sauvages du quinoa apparaît fortement liée à l’organisation socio-spatiale de l’agroécosystème. Ces espèces sont maintenues par les villageois pour leurs multiples usages alimentaires, médicinaux et culturels, dans des espaces naturels, des zones pâturées, aux abords et également à l’intérieur des champs cultivés. Ceci est à la fois le résultat de la gestion dynamique organisée par les communautés rurales et des savoirs liés à ces espèces qui se transmettent de génération en génération. Cependant cette gestion est en train de changer sous la pression d’enjeux globaux liés au marché international du quinoa, dont les exigences impliquent de réduire la présence de parents sauvages dans les champs cultivés. En conclusion, la thèse aborde la durabilité des pratiques de gestion et des pratiques agricoles dans un objectif de conservation dynamique in situ de la biodiversité sauvage et cultivée. Une mise en perspective historique des résultats nous a permis de questionner l’évolution des pratiques de gestion de ces différentes espèces par les communautés locales. En termes d’implication, deux types de projets pourraient être réfléchis. Le développement de projets prenant en compte le maintien de la présence des parents sauvages du quinoa dans le champ cultivé est favorable à l’introduction de gènes d’intérêt pour aider le quinoa à s’adapter à des conditions écologiques changeantes sous les effets du changement climatique. Egalement, des projets spécifiques de conservation in situ de l’agrobiodiversité, qui considèrent l’espace naturel et l’espace cultivé comme un ensemble cohérent, représentent une voie de gestion de pools de gènes importante pour l’agriculture et l’alimentation mondiale / Lake Titicaca, the cradle of pre-Columbian civilizations and one of the world’s main centres of domestication for farmed plant species, lies 3,800 m above sea level in the central Andean Highlands between Peru and Bolivia. The region is acknowledged as the centre of origin of quinoa, Chenopodium quinoa Willd. The greatest genetic diversity of quinoa and its wild relatives is concentrated there. Our research was conducted in the Puno region (Peru), which remains one of the main quinoa producing regions in the world. Quinoa displays spatial distribution along a North-South climate gradient in the region, with differentiation into mostly elevation-related, agro-ecological zones that explain its genetic diversity. Seven main quinoa crop wild relatives currently exist there: C. ambrosioides L., C. incisum Poiret, C. pallidicaule Aellen, C. petiolare Kunth, C. hircinum Schrad., C. quinoa ssp. melanospermum Hunz. and C. carnosolum Moq. This diversity of plant genetic resources is of great value for the adaptive evolution of quinoa, especially under the effect of climate change. This PhD thesis deals with the economic and cultural importance of quinoa, which is both a food resource in the Andean regions and an international commodity due to its exceptional nutritional qualities (protein-rich). This economic opportunity may have impacts on local food security, agrobiodiversity and agro-ecosystem management. One way of investigating this issue is to examine how the distribution of crop wild relatives is linked to the way quinoa cultivation is spatially organized. The thesis analysed how Andean farming communities incorporate the presence of wild relatives in their quinoa-related management and farming practices. Participatory mapping and ethnobotanical surveys were carried out with members of six villages chosen according to biogeographical criteria along a North South gradient, combined with data related to elevation and the proximity to Lake Titicaca. In order to show how the socio-spatial dynamics of the Andean environment are changing, notably linked to changes in quinoa growing, chorematic modelling was applied to two periods, before and after 1970, which was a pivotal year for Peruvian farming (agrarian reform, territorial rights of indigenous communities). The distribution of quinoa crop wild relatives seems to be closely linked to how the agro-ecosystem is spatially organized. Local communities keep these species for their multiple food, medicinal and cultural uses in natural areas, grazing areas, around and in farmed fields. This results from the dynamic management organized by rural communities, and from knowledge of those species passed down through the generations, by both women and men. However, management is changing under the pressure of global challenges arising from the international quinoa market, which calls for fewer wild parents in farmed fields. To conclude, the thesis looks at the sustainability of management and farming practices with a view to dynamic in situ conservation of wild and cultivated biodiversity. Choremes are used to place the results in historical perspective, to see how the management of these different species by local communities is evolving. In terms of implications, two types of project could be considered. Developing projects that keep quinoa crop wild relatives in farmed fields promotes the introduction of genes of interest, helping quinoa to adapt to ecological conditions being modified by climate change. Likewise, specific projects for in situ conservation of agrobiodiversity, which consider natural and cultivated areas as a coherent whole, are a way of managing gene pools that is important for agriculture and for feeding the world.

Chenopodium quinoa Willd..

Parents sauvages

Pratiques agricoles

Biodiversité

In situ

Altiplano

Pérou

Cartographie participative

Chorèmes

Chenopodium quinoa Willd..

Crop wild relatives

Farming practices

Biodiversity

In situ

Altiplano

Peru

Participatory mapping

Choremes

338.162

Linking Genetic Resources, Genomes and Phenotypes of Solanaceus Crops

Alonso Martín, David

30 November 2024

[ES] El impacto del cambio climático en los cultivos hortícolas es cada vez más evidente, lo que ha llevado a la pérdida y erosión de diversidad genética de manera drástica. Esto plantea importantes desafíos para la mejora de los cultivos, que requiere la exploración de los recursos fitogenéticos conservados en los bancos de germoplasma y el desarrollo de tecnologías que permitan evaluar el valor fenotípico y genotípico de estos materiales. Sin embargo, la situación actual de las colecciones de germoplasma es la existencia de duplicados no identificados entre colecciones, errores en la clasificación taxonómica, documentación insuficiente y no disponible para investigadores y mejoradores, añadido a la falta de financiación para la conservación y gestión adecuadas. Esto dificulta enormemente la utilización de estos recursos. En la presente Tesis se aborda este problema comenzando por la unificación de datos de pasaporte, fenotipado e imágenes de las principales colecciones de tomate, pimiento y berenjena en un mismo repositorio en el primer capítulo. El segundo capítulo se centra en el desarrollo y optimización de un método de extracción de ADN genómico de alta calidad, rápido y económico que combina las ventajas del método de extracción basado en el CTAB, añadido a la purificación de los ácidos nucleicos en una matriz de sílice. Es un método universal que puede utilizarse para diferentes especies y tejidos. Se ha evaluado la eficiencia del ADN genómico resultante en diferentes plataformas de secuenciación como SPET (Single Primer Enrichment Technology) y Oxford Nanopore, generando resultados muy prometedores. Esto facilita el paso previo al genotipado de las colecciones que es la extracción de ADN. En el tercer capítulo se aborda el genotipado de las colecciones. El elevado número de accesiones de cada cultivo, en particular el tomate, supone un problema de tipo económico, en ocasiones irresoluble. Por ello, el tercer capítulo está orientado a la evaluación del potencial de la tecnología de secuenciación SPET, más económica que otras conocidas, para el genotipado de alto rendimiento de colecciones de germoplasma de tomate y berenjena. Los resultados revelan que el genotipado SPET es una tecnología robusta y de alto rendimiento para estudios genéticos, incluyendo la posibilidad de identificación de duplicados y errores de clasificación taxonómica en las entradas conservadas en los bancos. Con la información generada en los primeros tres capítulos se establecieron las colecciones nucleares para cada cultivo, abarcando la máxima diversidad genética y fenotípica en un conjunto de 450 individuos. Finalmente, en el cuarto capítulo, se analiza y describe la colección nuclear de tomate a nivel genético y fenotípico, mediante un enfoque basado en el establecimiento de grupos genéticos basados en su proximidad genética. El análisis de la diversidad genética y fenotípica reveló patrones de variación distintos entre diferentes grupos genéticos, contradiciendo afirmaciones anteriores que proponían una disminución en la diversidad genética como consecuencia de la mejora genética y descubriendo correlaciones entre rasgos morfológicos únicas dentro de los diferentes grupos. En resumen, esta tesis aumenta el conocimiento y accesibilidad a las colecciones de Solanaceae en bancos de germoplasma y proporciona herramientas moleculares. Destaca la importancia de estos bancos como reservorios de diversidad genética, aunque enfrenten desafíos como datos limitados y duplicados. Estos avances sientan las bases para la conservación y programas de mejora futuros. / [CA] L'impacte del canvi climàtic en els cultius hortícoles és cada vegada més evident, la qual cosa ha portat a la dràstica pèrdua i erosió de la diversitat genètica. La reduïda diversitat genètica planteja importants reptes per a la millora dels cultius. Sent necessari l'exploració dels recursos genètics vegetals conservats en els bancs de germoplasma i el desenvolupament de tecnologies que permeten avaluar el valor fenotípic i genotípic d'aquests materials. Pel que fa a les col·leccions de germoplasma presenten duplicats no identificats entre col·leccions, errors en la classificació taxonòmica, falta de finançament per a la conservació i gestió adequades a banda de documentació insuficient i no disponible (investigadors i milloradors vegetals). En la present tesi doctoral en el primer capítol s'aborda aquest problema unificant les dades de passaport, fenotipat i imatges de les principals col·leccions de tomaca, pebre i albergínia en un mateix repositori. El segon capítol es focalitza en el desenvolupament i optimització d'un mètode d'extracció de ADN genòmic d'alta qualitat, ràpid i econòmic que combina els avantatges del mètode d'extracció basat en el CTAB amb l'ús de matrius de sílice. El mètode desenvolupat pot utilitzar-se de manera universal per a diferents espècies i teixits vegetals. S'ha avaluat l'eficiència del ADN genòmic resultant en diferents plataformes de seqüenciació com SPET (Single Primer Enrichment Technology) i Oxford Nanopore, generant resultats molt prometedors. Això facilita el pas previ al genotipat de les col·leccions que és l'extracció d'ADN. En el tercer capítol aborda l'optimització del procés de genotipat de les col·leccions generades. L'elevat nombre d'accessions de cada cultiu, en particular la tomaca, suposa un problema de tipus econòmic, a vegades irresoluble. Per això, aquest capítol està orientat a l'avaluació del potencial de la tecnologia de seqüenciació SPET per al genotipat d'alt rendiment de col·leccions de germoplasma de tomaca i albergínia a un preu econòmic. Els resultats revelen que el genotipat SPET és una tecnologia robusta i d'alt rendiment per a estudis genètics, incloent-hi la possibilitat d'identificació de duplicats i errors de classificació taxonòmica en les entrades conservades en els bancs de germoplasma. La informació generada va permetre establir col·leccions nuclears per a cada cultiu, abastant la màxima diversitat genètica i fenotípica en un conjunt de 450 individus. Finalment, en el quart capítol, s'analitza i descrigué la col·lecció nuclear de tomaca a nivell genètic i fenotípic, focalitzant-se en l'establiment de grups genètics basats en la seua proximitat genètica. L'anàlisi de la diversitat genètica i fenotípica va revelar patrons de variació diferents entre diferents grups genètics, contradient afirmacions anteriors que proposaven una disminució en la diversitat genètica a conseqüència de la millora genètica. També és descobriren noves correlacions entre trets morfològics únics dins dels diferents grups. L'estudi destaca la importància d'abordar les iniciatives de millora de la tomaca tenint en compte tant la diversitat genètica com la fenotípica, amb especial èmfasi en aspectes com la grandària, la forma, el color i la qualitat del fruit. En definitiva, els treballs realitzats en aquesta tesi doctoral augmenten, d'una banda, el coneixement i l'accessibilitat a les principals col·leccions de solanàcies conservades en els bancs de germoplasma. Per un altre, generen eines moleculars que permeten l' avaluació genotípica de les col·leccions analizades. En resum, aquests avanços suposen una base per al futur, proporcionant informació valuosa per a la pròpia conservació de les col·leccions i el seu ús en programes de millora. / [EN] The impact of climate change on horticultural crops is increasingly evident, leading to drastic loss and erosion of genetic diversity. This poses significant challenges for crop improvement, which requires the exploration of plant genetic resources conserved in germplasm banks and the development of technologies. However, the current situation of germplasm collections is characterized by the existence of unidentified duplicates among collections, taxonomic mislabelling, insufficient and unavailable documentation for researchers and breeders, and a lack of funding for proper conservation and management. This greatly hampers the utilization of these resources. This thesis addresses this problem by starting with the unification of passport, phenotyping, and image data from the main collections of tomato, pepper, and eggplant. Genotyping these collections enables the creation of core collections, enhancing knowledge of genotypic and phenotypic variability for researchers and breeders. In the first chapter, an inventory of available passport and phenotypic data of tomato, pepper, and eggplant accessions conserved in major European and non-European germplasm banks were conducted to improve the efficiency of plant genetic resource management. The second chapter focuses on the development and optimization of a high-quality, fast, and cost-effective genomic DNA extraction method that combines the advantages of the CTAB-based extraction method with nucleic acid purification on a silica matrix. The efficiency of the resulting genomic DNA was evaluated on different sequencing platforms, such as Single Primer Enrichment Technology (SPET) and Oxford Nanopore, yielding promising results. This facilitates the prerequisite step of DNA extraction before genotyping the collections. Chapter three addresses the genotyping of the collections. The high number of accessions for each crop, particularly tomato, poses an often insurmountable economic problem. Therefore, chapter three is focused on evaluating the potential of SPET sequencing technology, which is more cost-effective than other known methods, for high-throughput genotyping of tomato and eggplant germplasm collections. The results reveal that SPET genotyping is a robust and high-performance technology for genetic studies, including the identification of duplicates and taxonomic misclassifications in the accessions stored in the germplasm banks. Based on the information generated in the first three chapters, core collections were established for each crop, encompassing maximum genetic and phenotypic diversity in a set of 450 individuals. Finally, in the fourth chapter, the genetic and phenotypic analysis of the tomato core collection is examined and described using an approach based on establishing genetic groups based on their genetic proximity. Genetic and phenotypic diversity analysis revealed distinct patterns of variation among different genetic groups, contradicting previous claims of a decrease in genetic diversity due to genetic improvement and uncovering unique correlations between morphological traits within different groups. The study highlights the importance of considering both genetic and phenotypic diversity in tomato breeding initiatives, with a particular emphasis on aspects such as fruit size, shape, color, and quality. In conclusion, this thesis enhances knowledge and accessibility to major Solanaceae collections in germplasm banks, while providing molecular tools for genotypic evaluation. It underscores germplasm banks' role as genetic diversity reservoirs, despite challenges such as data limitations and inaccuracies, emphasizing the importance of data standardization and maintenance. These advancements lay a foundation for conservation and breeding programs in the future. / This work was supported by grants CIPROM/2021/020 from Conselleria d’Innovació, Universitats, Ciència i Societat Digital (Generalitat Valenciana, Spain), PID2021-128148OB-I00 funded by MCIN/AEI/10.13039/501100011033/ and by “ERDF A way of making Europe”, PDC2022-133513-I00 funded by MCIN/AEI/10.13039/501100011033/, and by “European Union NextGenerationEU/PRTR”, by Grant Agreement No. 677379 (G2P-SOL project: Linking genetic resources, genomes and phenotypes of Solanaceous crops) from European Union’s Horizon 2020 Research and Innovation Programme, by the Grant Agreement No. 101094738 (PRO-GRACE project: Promoting a Plant Genetic Resource Community for Europe) from the European Union’s Horizon Europe programme, as well as by the initiative "Adapting Agriculture to Climate Change: Collecting, Protecting and Preparing Crop Wild Relatives", which is supported by the Government of Norway. This later project is managed by the Global Crop Diversity Trust with the Millennium Seed Bank of the Royal Botanic Gardens, Kew and implemented in partnership with national and international gene banks and plant breeding institutes around the world. For further information, see the project website: htp://www.cwrdiversity.org/. The overall work also partially fulfils some goals of the Agritech National Research Center and received funding from the European Union Next-Generation EU (PIANO NAZIONALE DI RIPRESA E RESILIENZA (PNRR)–MISSIONE 4 COMPONENTE 2, INVESTIMENTO 1.4—D.D. 1032 17/06/2022, CN00000022). David Alonso is grateful to Universitat Politècnica de València for a predoctoral (PAID-01-16) / Alonso Martín, D. (2023). Linking Genetic Resources, Genomes and Phenotypes of Solanaceus Crops [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/201550

Eggplant

Tomato

Pepper

Germplasm bank

Genomic

Genetic resources

Solanacea

Wild relatives

Solanum melongena

Solanum lycopersicum

G2P-SOL

SILEX

DNA extraction

SPET

Extracción de ADN

Recursos genéticos

Genoma

Banco de germoplasma

Pimiento

Tomate

Berenjena

GENETICA

Vilda kulturväxtsläktingar : för framtidens föda / Crop Wild Relatives : for the food of the future

Druid, Linnea, Thiele, David

January 2022

Jordbruket står inför många utmaningar. Grödorna behöver bland annat anpassas till ett förändrat klimat. Här är grödornas vilda släktingar, kulturväxtsläktingar viktiga, då de bär på stor genetisk variation. För att kulturväxtsläktingarna ska kunna användas i arbetet med att anpassa och utveckla dagens grödor är det av största vikt att de bevaras. Denna litteraturstudie syftar till att göra en kartläggning av bevarandearbetet som gjorts och behöver göras samt presentera Sveriges bevarandearbete. Litteraturstudien visar att flera internationella konventioner, bevarandestrategier och samarbeten har haft betydelse för bevarandearbetet. Vissa stora fröinsamlingsprojekt har gjorts och på vissa platser har skyddade områden för kulturväxtsläktingar upprättats. Dock krävs fortfarande ett omfattande bevarandearbete. Planer måste omsättas i praktiken, projekt finansieras och politiskt engagemang öka. I Sverige är arbetet på ett tidigt stadie, men vissa framsteg har gjorts och arbete pågår. Att öka kännedomen om kulturväxtsläktingar kan vara ett sätt att ge bevarandearbetet högre status och mer resurser. Där kan biologilärare göra en viktig insats genom att inkludera kulturväxtsläktingar och dess betydelse i undervisningen, till exempel att eleverna får arbeta med frågor om hur framtidens mattillgång kan säkras. / Agriculture is facing several great challenges. The crops need, among other things, to be adapted to a changing climate. Here, the wild relatives of the crops, the crop wild relatives, are important since they carry a vast amount of genetic diversity. For the crop wild relatives to be used in the process of adapting and improving today’s crops, it is essential that they are conserved. This literature review aims to make a survey of the previous conservation efforts and the work that remains, as well as presenting the conservation efforts in Sweden. The review shows that several international conventions, conservation strategies, and collaborations have been significant for the conservation efforts. Some large seed collecting projects have been completed and, in some places, protected areas for crop wild relatives have been established. However, extensive conservation efforts are still required. Plans need to be actualized, projects funded, and political incentive increased. The Swedish conservation efforts are still at an early stage, but some progress has been made and work is in ongoing. Increasing awareness about crop wild relatives could result in their conservation receiving a higher status and increased funds. Biology teachers can make an important contribution to this by including crop wild relatives and their significance in class, for example by letting students work with questions concerning the security of the futures food production.

biology teaching

conservation

crop wild relatives

Europe

ex situ

in situ

strategies

Sweden

bevarandearbete

biologiundervisning

Europa

ex situ

in situ

kulturväxtsläktingar

strategier

Sverige

Botany

Botanik

Environmental Sciences

Miljövetenskap

Ecology

Ekologi

Climate Research

Klimatforskning

Pedagogical Work

Pedagogiskt arbete

Pedagogy

Pedagogik

Learning

Lärande