The effect of germline variants on the genesis of early somatic events in cancer explored via Cas9 genome editing

Stringa, Blerta

14 October 2019

Although the understanding of genetic predisposition to prostate cancer (PCa) has been improved through genome-wide association studies (GWAS), little is known about the biological implication of germline variants residing in coding or non-coding regions in cancer development and progression. Our hypothesis is that inherited variants may predispose to specific early recurrent genomic events observed in PCa adenocarcinomas, possibly in the context of variable androgen receptor (AR) signaling that changes during a man’s lifetime. Recent in silico analysis by our group on potential association between germline variants and PCa specific somatic lesions identified a non-coding polymorphic regulatory element at the 7p14.3 locus associated with DNA repair and hormone regulated transcript levels and with an early recurrent prostate cancer specific somatic mutation in the Speckle-Type POZ protein (SPOP) gene (OR=5.54, P=1.22e-08) in human prostate tissue data. In order to functionally characterize the polymorphic 7p14.3 locus (rs1376350, single nucleotide polymorphism, G>A), we set up to establish isogenic cell lines harboring the minor allele by using the CRISPR/Cas9 system. In parallel, CRISPR/Cas9 system was used to knock out different portion of the region encompassing the 7p14.3 variant and to eliminate transcription factors (TFs) binding sites that were identified from previous in silico analysis (i.e. AR and CCAAT/Enhancer Binding Protein (C/EBP) beta (CEBPβ)). The transcriptomes of edited pools and edited single clones from macrodeletion (731 bp), microdeletion (50 bp) and alterations of TFs binding sites were analyzed and compared to the transcriptomes of isogenic cells heterozygous (A/G) and homozygous (A/A) for the minor allele A of the risk variant rs1376350 (with or without AR overexpression). These data identified a set of genes scattered throughout the genome with the same pattern of deregulation suggesting the implication of the variant on the regulation of genes residing in different chromosomes. Additionally, ChIP-qPCR experiments for histone modification supported the identification of the 7p14.3 locus with enhancer activity. Furthermore, ChIP-qPCR of histone mark associated with transcriptional activation or repression in isogenic cells harboring the minor allele A upon AR overexpression showed that the activity of the locus is higher for the minor allele A compared to G, independently from AR activation. Despite the limitations of our model and the current lack of validation in other cells, we confirmed that some of the differentially expressed genes that emerged from the comparative analysis of edited cells are deregulated in human normal and tumor prostate samples as well. This work is a proof of concept of germline predisposition to molecularly distinct cancer subclasses and has the potential to nominate new mechanisms of cancer development. Future work aims to elucidate the mechanisms implicated in the deregulation of the transcriptome by combining the information obtained until now with potential new players that we expect to identify by Mass Spectrometry experiments. To clarify the link between the 7p14.3 variant and the somatic mutations in SPOP, we plan to express mutant SPOP in isogenic cells harboring the minor allele and to asses DNA damage response upon overexpression or silencing of TFs binding at and around the rs1376350 variant. My work is an example of how the CRISPR/Cas9 system can be used to develop a technical framework with convergent approaches to functionally characterize polymorphic regulatory regions including but not limited to the establishment of isogenic cells upon single nucleotide editing.

Settore BIO/11 - Biologia Molecolare

Dual CRISPR-Cas3 system for inducing multi-exon skipping in DMD patient-derived iPSCs / DMD患者由来iPS細胞におけるマルチエクソンスキッピング誘導に向けたDual CRISPR-Cas3システム

Kita, Yuto

23 January 2024

付記する学位プログラム名: 京都大学卓越大学院プログラム「メディカルイノベーション大学院プログラム」 / 京都大学 / 新制・課程博士 / 博士(医科学) / 甲第25007号 / 医科博第154号 / 新制||医科||10(附属図書館) / 京都大学大学院医学研究科医科学専攻 / (主査)教授 遊佐 宏介, 教授 萩原 正敏, 教授 齋藤 潤 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

genetic disorder

Duchenne muscular dystrophy

genome editing

CRISPR-Cas system

CRISPR-Cas3

491

Development of Novel Genome Editing in Avian Species: Functional Genomic Studies for Melanophilin and Myostatin Genes

Lee, Joonbum

15 September 2022

No description available.

Genetics

Animal Sciences

CRISPR/Cas9

genome editing

avian species

adenovirus

melanophilin

myostatin

Decoding novel virulence strategies in Fusobacterium invasion and survival

Nguyen, Tam

08 June 2022

Fusobacterium nucleatum is an anaerobic, Gram-negative, oral bacterium that disseminates from the mouth, and contributes to preterm birth, tissue infections, and acceleration of multiple cancers including colorectal and pancreatic. It is well-established that most Fusobacterium species exhibit genetic recalcitrance, which has led to hindrance in the understanding of their biology and molecular pathogenesis. Though the association of Fusobacterium in diseases is well-established, the majority of our experimental work stems from the strain F. nucleatum ATCC 23726 because it is genetically tractable. Here, in this dissertation, we show that we are able to enhance our existing molecular tools for genome editing to introduce the first mutants in a clinically relevant strain, F. nucleatum ATCC 25586, a feat that was never accomplished in decades of trying. Furthermore, we created a deletion library of genes predicted to be involved in host cellular invasion and survival. In this work, we identified a novel small adhesin, FadA2, that played a significant role in the invasive ability of F. nucleatum ATCC 25586 to colorectal cancer cells. This dissertation also sheds the first insight into the roles of the type 5a autotransporters. Using a deletion library of genes encoding for the type 5a autotransporter proteins in F. nucleatum ATCC 23726, we systemically characterized altogether 12 type 5a proteins with a focus on the invasion of colorectal cancer cells. Most notably, we found that a wide assortment of type 5a proteins contributing to binding and invasion of F. nucleatum to HCT116 cancer cells. Furthermore, we identified that RadD was not directly involved in inducing secretions of the cytokines IL-8 and CXCL1 while confirmed the specific association of Fap2 in bacterial-induced cytokine secretion. Thus, our findings provided the first comparative and functional analysis of Fusobacterium type 5a autotransporter proteins in colorectal cancer cells which will be crucial to the understanding of Fusobacterium involvement in cancer progression. Finally, this dissertation reported on the first ever observation on the survival strategy of Fusobacterium inside the host cells. We uncovered a novel protein that contributed to enhanced survival of Fusobacterium residing in colorectal cancer cells. This work undoubtedly helps expand the current Fusobacterium genetic toolkit to study proteins and mechanisms relevant to Fusobacterium-accelerated diseases. By identifying and characterizing novel virulence strategies that Fusobacterium can take advantage of, we can increase our comprehension on this opportunistic microbe while devising innovative therapeutic treatments. / Doctor of Philosophy / Fusobacterium, a member of the microbial community in our mouth, has been a captivating study target due to its association with human health and diseases. By nature, Fusobacterium lives in oxygen-free pockets between our teeth and gumline in which this organism has been correlated with a multitude of complications and diseases including periodontitis, inflammatory bowel disease, preterm birth, and most importantly colorectal cancer. Though the connection to human health is established, we still have to learn more about the mechanisms utilized by Fusobacterium to exacerbate diseases. This challenge is mainly hindered by the lack of efficient tools and resources to systematically investigate the relationship between the bacterium and its human host. Therefore, the work in this dissertation focuses on expanding the existing molecular toolkit to study clinically relevant Fusobacterium strain, which provides the power and convenience to discover novel mechanisms that Fusobacterium can take advantage of to be a successful pathogen. Accordingly, we first enhanced our ability to work with a wider range of Fusobacterium species. We successfully introduced exogenous genetic materials into a clinical strain of Fusobacterium, Fusobacterium nucleatum ATCC 25586. This breakthrough was built on the success of our current toolkit to make genetic modifications to a sister strain, Fusobacterium nucleatum ATCC 23726. With this newfound capacity to modify F. nucleatum ATCC 25586, we have described the importance of a novel protein aiding in the invasion of Fusobacterium to colorectal cancer. Furthermore, we have determined that certain proteins within the fusobacterial type 5a protein family can play a key role in governing binding and invasion of colorectal cancer cells in this study. Concurrently, for the first time, we provided the snapshot of a small protein and its role in fusobacterial long-term survival inside its targeted host cells. Altogether, the findings in this dissertation will bring forth an innovative framework to better the comprehension of current Fusobacterium-induced disease implications, while exploring alternative treatments for enhanced patient health.

Fusobacterium

genome editing

cellular invasion

host-pathogen interaction

molecular biology

colorectal cancer

Expanding Genetic and Genomic Resources for Sex Separation and Mosquito Control Strategies

Compton, Austin

26 October 2021

Mosquitoes belonging to the genera Anopheles transmit malaria parasites, attributing the highest mortality of any vector-borne disease worldwide. Mosquitoes belonging to the genera Aedes transmit arboviruses including dengue, which has become the most important vector-borne virus due to a drastic surge in disease incidence. The scope of the studies in this dissertation is broad, with investigations bringing together elements of classical genetics, recent advances in sequencing and genome-editing technologies, and the use of modern forward genetics approaches. Chapter 2 of this dissertation explores the use of the Oxford Nanopore Sequencing Technology for the first time in mosquitoes. This new technology provides long reads that were used to piece together the AabS3 chromosomal assembly for Anopheles albimanus. The utility of this genomic resource is demonstrated by the discovery of novel telomeric repeats at the ends of the chromosomes that could have important implications in mosquito biology and control. Chapter 3 describes a forward genetics strategy called 'Marker-Assisted Mapping' (MAM) that enables high-resolution mapping of the causal gene locus of a mutant phenotype. The principle and effectiveness of MAM is first demonstrated by mapping a known transgene insertion. MAM is then used to identify cardinal as a candidate causal gene for the spontaneous red-eye (re) mutation. Genetic crosses between the re mutant and cardinal knocking out individuals generated using CRISPR/Cas9 confirmed that cardinal indeed is the causal gene for re mutation. Chapter 4 explores three innovative strategies for mosquito sex separation by exploiting several sex-linked marker lines. We show that by linking a transgenic marker to the male-determining locus (M locus), or by linking the male-determining Nix gene to a marker, males can be precisely separated from females. We also produce a two-marker transgenic line that allows for both non-transgenic male separation and for efficient line maintenance. Finally, we discuss further applications of the resources generated and future directions stemming from these findings. Altogether, the studies described in this dissertation contribute to the overall goal of understanding mosquito biology and of controlling mosquito-borne infectious diseases. / Doctor of Philosophy / Female mosquitoes bite and transmit deadly pathogens including the malaria parasite, and viruses such as dengue, Zika, and West Nile. Control programs that attempt to limit the spread of these deadly diseases rely on the control of mosquitoes themselves. These mosquito control methods have relied heavily on indoor and outdoor insecticidal spraying. However, the efficacy of these methods has been jeopardized by the increasing prevalence of insecticide resistance. Thus, it is necessary to implement other methods for effective mosquito control. Genetic control strategies such as the Sterile Insect Technique (SIT) and Wolbachia-based Incompatible Insect Technique (IIT) are excellent solutions to overcome the limitations of current control strategies. As female mosquitoes bite and transmit disease-causing pathogens, only males are released, which necessitate the separation of the non-biting males from females before release. The aim of this work was to use recent technological advancements to better understand the genome and basic genetics of vector mosquito species, and to identify possible approaches to improve current sex separation practices. To develop a deep understanding of mosquito biology and genetics, it is crucial that a high-quality and accurate genome assembly is available. However, many mosquito genome assemblies remain fragmented. To address this limitation, we used recent advances in sequencing technologies to produce a high-quality genome assembly for the New World malaria mosquito, Anopheles albimanus. These sequencing and assembly efforts led to the discovery of novel telomere sequences at the ends of chromosomes, which could have implications for mosquito control. Forward genetics, which identifies the gene(s) responsible for a given phenotype, has been hindered by the low recombination rate in the yellow and dengue fever mosquito, Aedes aegypti. We develop a Marker-Assisted Mapping (MAM) strategy to address this problem. We first demonstrate this method by mapping the known insertion of a transgene. MAM is then used to identify cardinal as a candidate causal gene for the spontaneous red-eye (re) mutation. MAM identification of the Cardinal gene was then verified by knocking out Cardinal, which represents the first successful gene mapping in Aedes aegypti using forward genetics. The MAM strategy has broad implications as it could enable the discovery of genes involved in important traits such as insecticide resistance. To improve sex separation methods, we took advantage of several sex-linked transgenic lines to develop three novel strategies. First, we demonstrate that screening for a genetic marker that is tightly linked to the male-determining locus (M locus) is an effective approach to reduce female contamination. Second, we demonstrate that instead of linking a marker to the M locus, we can link the male-determining factor, Nix, to a genetic marker. When a Nix transgene is located adjacent to the red-eye locus with extremely tight linkage, the red-eye phenotype becomes a faithful marker for separation of males and females. Finally, we developed a two-marker genetic sexing strain that produces non-transgenic males that could be used for release, and transgenic marked males and females for efficient line maintenance.

Mosquito

Aedes aegypti

genome assembly

genome editing

forward genetics

sex separation

sex linkage

Caractérisation de la RNase P nucléaire de Candida glabrata et amélioration des outils d’édition de son génome / Characterization of the nuclear RNase P of Candida glabrata and improvement of genome editing tools

Dahman, Yacine

19 September 2018

Candida glabrata est une levure pathogène opportuniste, apparaissant aujourd’hui comme la deuxième cause de candidémie en Europe et en Amérique du Nord. Cette levure présente de nombreuses particularités génomiques telles que la présence de nouveaux domaines structuraux au sein d’ARN non-codants ubiquitaires. Le premier aspect de cette thèse a consisté en l’étude de la sous-unité ARN atypique de la Ribonucléase P nucléaire de C. glabrata. Cet ARN contient trois grand domaines additionnels octroyant au transcrit une taille trois fois plus élevée que la moyenne des sous-unités ARN des RNase P eucaryotiques. Les expériences réalisées ont permis une meilleure compréhension du rôle de ces domaines additionnels et ont démontré la présence inédite de la protéine Rcl1 au sein du complexe de la RNase P. Dans un second temps ce travail de thèse a aussi contribué à l’amélioration des outils d’édition du génome de C. glabrata existants. De nouvelles cassettes intégratives de faible taille et positivement sélectionnables ont été mises au point. Ces éléments présentent toutes les caractéristiques permettant leur utilisation dans la modification du génome de souches sauvages et d’isolats cliniques de C. glabrata. / Candida glabrata is an opportunistic pathogenic yeast, and is today the second causative agent of candidemia in Europe and North America. This yeast has many genomic peculiarities such as the presence of new structural domains within ubiquitous non-coding RNAs. The first aspect of this thesis was the study of the atypical RNA subunit of the nuclear Ribonuclease P of C. glabrata. This RNA contains three large additional domains giving the transcript an overall size more than three times larger than the average eukaryotic RNase P RNA subunits. The experiments performed led to a better understanding of the role of these additional domains and demonstrated for the first time the presence of the Rcl1 protein within the RNase P complex. Secondly, this thesis work also contributed to the improvement of existing genome editing tools in C. glabrata. New small and positively selectable integrative cassettes have been developed. These elements exhibited all the required characteristics for their use in wild-type strains and clinical isolates of C. glabrata.

Levures pathogènes

RNase P

Edition du génome

Candida glabrata

Pathogenic yeasts

Non-coding RNA

RNase P

Genome editing

572.8

579

Site-directed nucleases as tools for genome editing in fish / Les nucléases ciblées comme outil d’édition du génome du poisson

Radev, Zlatko

19 December 2014

L'application des techniques de séquençage à haut débit dans les dernières années a conduit à l'obtention de la séquence de génomes complets de plusieurs organismes. Le développement de nouveaux outils de génétique inverse était donc souhaitable afin de faire un usage optimal des données accumulées. Les nucléases hautement spécifiques représentent un outil unique pour induire des modifications ciblées du génome in vivo. L'induction d'une cassure double brin dans l'ADN est réparée soit par la voie de jonction d’extrémités nonhomologues soit par la voie très fidèle de la recombinaison homologue. Le ciblage d'un locus précis avec une nucléase spécifique stimule fortement la réparation de l'ADN, qui peut être utilisé pour induire des modifications ciblées dans le génome. Dans ma thèse, je vise à fournir une preuve de prinicipe pour l'utilisation des méganucléases et des transcription activator like effector nucléases (TALENs), deux classes communes de nucléases très spécifiques, comme nouveaux outils d'édition du génome chez le medaka, Oryzias latipes, et le poisson zèbre, Danio rerio. J'ai d’abord trouvé les conditions optimales d'utilisation de ces nucléases dans nos modèles de poissons. J'ai à cette occasion également développé une méthode très sensible et rapide pour la détection de modifications génomiques ciblées. J'ai ensuite induit des mutations au sein de trois gènes différents chez le poisson zèbre avec des TALENs. Les mutations dans le gène col6a1 ont conduit à la mise en évidence pour la première fois d’une technique de modification d’un site d’épissage d’un gène de poisson zèbre à l’aide d’une nucléase ciblée. Ce travail nous a permis d’établir une lignée de poisson avec une mutation dans le collagène VI alpha 1 qui est similaire à une mutation fréquemment trouvée chez les patients humains atteints de myopathie de Bethlem. De même, j’ai pu induire des mutations dans le gène nle1 du poisson zèbre qui vont permettre la mise en place de lignées de poissons mutants de ce gène. En outre, j'ai pu montrer qu’un nouveau type de nucléase, une TALEN Compact, était actif sur une cible chromosomique chez le poisson zèbre. En conclusion, les études que j'ai effectuées ont apporté la preuve de principe pour l'activité de TALENs et Compact TALENs ainsi que la première démonstration de modification de l'épissage à l’aide d’une TALEN chez le poisson zèbre et ont abouti à la mise en place d'une lignée de poisson dont le phénotype est proche d’un syndrome humain ouvrant la voie à la création de modèles pour d’autres mutations de ce type. Pour finir, je discute dans cette thèse des conditions permettant un usage le plus efficace des nucléases ciblées pour la génération de mutants et l’édition du génome. / The application of high throughput sequencing techniques in the recent years has led to obtaining the full genome sequences of many organisms. The development of novel tools for reverse genetics was thus desirable to make optimal use of the accumulated data. Site directed nucleases represent a unique platform to induce targeted genome modifications in vivo. Targeting a precise locus with a highly specific nuclease stimulates DNA repair, which can be harnessed for genome editing. Induction of a double strand break in DNA is repaired by either the error prone pathway of nonhomologous end joining or the high fidelity pathway of homologous recombination in the cell. Both mechanisms can be used to insert foreign DNA into the genome of the host. In my thesis, I aimed to provide proof of principle for the use of meganucleases and transcription activator like effector nucleases (TALENs), two common classes of site directed nucleases, as novel tools for genome editing in medaka, Oryzias latipes, and zebrafish, Danio rerio. During the first years of my thesis, I found the optimal conditions to use these nucleases in our fish models. I also developed a very sensitive and rapid method for detection of targeted genome modifications. I then induced mutations at three different endogenous loci in zebrafish with TALENs. The mutations in the col6a1 gene led to the first demonstration of splicing site modification in zebrafish using a TALE nuclease. This allowed the establishment of a fish line with a mutation in type VI collagen alpha 1 chain homologous to one mutation frequently found in human patients with Bethlem myopathy. Then I generated mutations in the nle1 gene which are heritable and from which establishment of mutant fish lines is in progress. In addition, by using the method for detection of targeted genome modifications I developed, I showed that a novel type of nuclease, a Compact TALEN, was active on a chromosomal target in zebrafish. In conclusion, the studies I performed provided proof of principle for the activity of TALENs and Compact TALENs as well as the first demonstration of TALEN-Mediated modification of splicing in zebrafish and resulted in the establishment of a fish line with mutated collagen VI. Induction of heritable mutations in the nle1 gene in zebrafish was also confirmed. Additionally, I proved that the choice of expression vector is crucial for the synthesis of active site directed nucleases for use in fish and established a novel efficient method for detection of targeted genomic mutations.

Nucléases ciblées

TALENs

Méganucléases modifiées

Poissons modèles

Édition du génome

Site-directed nucleases

TALENs

Engineered meganucleases

Fish models

Genome editing

Caratterizzazione del gene LIPOSSIGENASI 4 e approccio CRISPR-Cas9 per aumentare la resistenza alla fusariosi di mais / LIPOXYGENASE 4 CHARACTERIZATION AND CRISPR-CAS9 APPROACH TO ENHANCE FUSARIUM VERTICILLIOIDES (FV) RESISTANCE IN ZEA MAYS

BORRELLI, VIRGINIA MARIA GRAZIA

14 December 2018

Il Fusarium verticillioides (Fv) causa il marciume rosa della spiga e contamina le cariossidi con fumonisine, una famiglia di micotossine che colpisce mangimi e alimenti considerata cancerogena per l'uomo e gli animali. Sono stati condotti diversi studi per identificare i geni del mais associati alla resistenza della pianta ospite all'infezione da Fv e l'accumulo di fumonisina. È noto che le ossilipine regolano la difesa contro i patogeni e che il cross-talk lipidico ospite-patogeno influenza la patogenesi. A questo proposito, i mutanti di mais trasposonici del gene ZmLOX4, la linea suscettibile W22 e la resistente TZI18 sono stati testati per la resistenza a Fv mediante il saggio biologico Rolled Towel Assay (RTA). Inoltre, sono stati studiati i profili di espressione di 16 geni coinvolti nella via LOX e volatili verdi (GLV) e l'attività della lipossigenasi è stata analizzata nelle stesse linee. Inoltre, è stata applicata la tecnologia di modifica del genoma di Clustered Shortspeed Palindromic Repeat / Cas9 associato (CRISPR / Cas9) regolarmente esaminata per indagare le possibili implicazioni del gene ZmLOX6 e del fattore di trascrizione ZmWRKY125 nei meccanismi di resistenza contro Fv. L'espressione di questi geni è stata precedentemente osservata dagli esperimenti di RNA - Seq in genotipi resistenti al mais e Studi di Genome Wide Association (GWAS) che hanno portato a un SNP significativamente associato a ZmWRKY125. Inoltre, il gene ZmLOX4 è stato overespresso nella linea A188 per valutare un possibile miglioramento della resistenza alla malattia verso Fv. Il lavoro molecolare del CRISPR si basa su una doppia clonazione utilizzando due diverse single guide RNA (sgRNA) per un bersaglio genico. I costrutti sotto il promotore ZmpUBI nel vettore binario p1609 sono stati trasformati nella linea A188 utilizzando la trasformazione mediata da Agrobacterium tumefaciens. Le piante di mais modificate nei geni ZmLOX6 e ZmWRKY125 e ZmLOX4 che sovraesprimono saranno caratterizzate per RTA, prove sperimentali in campo e per il loro contenuto di fumonisina. Inoltre, saranno testati l’attività lipossigenasica totale, i suoi metaboliti derivati ​​e le osslipine, oltre all'analisi dell'espressione dei principali geni coinvolti nella via dell'acido jasmonico. / Fusarium verticillioides (Fv) causes ear rot in maize and contaminates the kernels with fumonisins, a family of mycotoxins that affects feed and food and considered carcinogenic for humans and animals. Several studies were conducted to identify maize genes associated with host plant resistance to Fv infection and fumonisin accumulation. It is known that plant lipoxygenase (LOX)-derived oxylipins regulate defense against pathogens and that the host-pathogen lipid cross-talk influences the pathogenesis. In this regard, maize mutants carrying Mu insertions in the ZmLOX4 gene, the susceptible W22 and the resistant TZI18 lines were tested for Fv resistance by the screening method rolled towel assay (RTA). Additionally, the expression profiles of 16 genes involved in the LOX and green leaves volatiles (GLV) pathway were studied and the lipoxygenase activity was investigated in the same lines as well. Furthermore, the genome editing technology of Clustered Regularly Interspaced Short Palindromic Repeat/associated Cas9 (CRISPR/Cas9) was applied in order to investigate the possible implication of the lipoxygenase gene ZmLOX6 and the transcription factor ZmWRKY125 in the resistance mechanisms against Fv. The enhanced expression of these genes was previously observed by RNA - Seq experiments in maize resistant genotypes and Genome Wide Association Studies (GWAS) resulted in one SNP significantly associated with ZmWRKY125. Moreover, the gene ZmLOX4 was over-expressed in the line A188 for evaluating a possible improvement of the disease resistance towards Fv. The CRISPR cloning was based on a double cloning using two different guides (sgRNA) for one gene target. The constructs under the maize promoter ZmpUBI in the binary vector p1609 were transformed into the maize A188 line using Agrobacterium tumefaciens mediated transformation. Maize plants edited in the genes ZmLOX6 and ZmWRKY125, and over-expressing ZmLOX4 will be characterized for Fv resistance using rolled towel assay, field assay and for their fumonisin content. Furthermore, the content of jasmonic acid, its derivative metabolites, and oxylipins will be tested, as well as the expression analysis of the main genes involved in the jasmonic acid pathway will be performed.

BIO/04: FISIOLOGIA VEGETALE

AGR/07: GENETICA AGRARIA

The environmental impact of introducing a potato protein for human consumption in Sweden

Tromp, Malou

January 2020

In this study, a Consequential Life Cycle Assessment (CLCA) was conducted on the introduction of a potato protein for human consumption in Sweden. The assessed environmental impact cathegories in the CLCA were the categories global warming potential, eutrophication and land use. Potato protein is a side-stream that occurs during the production of potato starch and is currently used for animal feed (feed-grade). With the use of the new gene-editing technique CRISPR-Cas9, the stability of proteins in a starch potato can be improved to make the potato protein fit for human consumption (food-grade). The food-grade potato protein can be used as an ingredient in the food products: plant-based meat, quiche, sauces, wine and smoothies. When using the potato protein in one of these food products seven protein sources could potentially be substituted: soybean protein, yellow pea protein, beef protein, pork protein, chicken protein, egg protein and milk protein. The results of the CLCA show that when using the potato protein as an ingredient in a food product instead of other protein sources environmental impact can potentially be reduced. Most environmental impact can be reduced by substituting animal proteins by the potato protein. Therefore, from an environmental point of view, the most interesting food products to use the potato protein in as an ingredient are the food products where currently animal products are used in as the main source of protein.

Sustainable Development

food loss

plant-based

genome-editing

potato protein

Life Cycle Assessment

Earth and Related Environmental Sciences

Geovetenskap och miljövetenskap

Development of Transgenic Sterile Insect Technique Strains for the Invasive Fruit Pest Drosophila suzukii

Ahmed, Hassan Mutasim Mohammed

18 December 2021

No description available.

570

Gene drive

Molecular entomology

Insect pests

Genome editing

CRISPR/Cas

Genetic engineering

piggyBac

Transgenesis

Drosophila suzukii

Biologie (PPN619462639)