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Im experimentellen Ansatz sollte mithilfe der CRISPR-Cas9-Methode eine gerichtete ALK1-Rezeptor-Eliminierung in myoblastischen C2C12-Zellen durchgeführt werden. Nach erfolgreicher Klonierung der jeweiligen, für den Typ-I-Rezeptor ALK1-kodierenden, gRNA-Sequenzen in die Puro- und GFP-CRISPR-Plasmide gelang der mittels Lipofektion durchgeführte Transfer der vier klonierten Plasmide in die C2C12-Zellen. Parallel aufgetaut wurden C2C12*ALK2- sowie ALK3-Knockout-Zelllinien, welche zuvor durch die Masterandin L. Wiesmann, ebenfalls mithilfe der CRISPR-Cas9-Methode, induzierte Knockouts der jeweiligen Rezeptoren ALK2 sowie ALK3 enthielten. Anschließend erfolgte die Puromycin-Selektion der mit den Puro-Klonen transfizierten C2C12*ALK1-3, ALK1-4-, ALK2- sowie ALK3-KO-Zellpopulationen. Die Zellen der C2C12*ALK1-3-KO-Population überlebten die Selektion trotz erneuter Durchführung der Transfektion sowie Selektion nicht. Somit erfolgte die Kultivierung der verbliebenen Zellen der C2C12*ALK1 4-, C2C12*ALK2- sowie C2C12*ALK3-KO-Population. Anschließend galt es zu untersuchen, wie responsiv die einzelne KO-Zelle für verschiedene Liganden ist. Im Rahmen der Durchführung differenter, zellbasierter Versuche wie der qPCR, des Western Blots und des ALP-Assays wirkten verschiedene BMPs auf die KO-Populationen ein. Somit konnten die BMP-induzierten, nachfolgenden Ereignisse wie die mRNA-Expression, die SMAD-Phosphorylierung sowie die Induktion der ALP-Expression innerhalb der KO-Populationen genauer betrachtet werden.
Es ist allgemein bekannt, dass ALK1 sowohl bei der Angiogenese als auch bei der kardio-vaskulären Homöostase eine wichtige Rolle übernimmt. ALK1 ist vermutlich für die Gefäßneubildung in manchen Tumoren verantwortlich und auch die vaskuläre Erkrankung „Hereditäre hämorrhagische Teleangiektasie (HHT)“ steht im Zusammenhang mit einer Mutation des ALK1-Rezeptorgens. BMP9 beeinflusst als ALK1-bindender Ligand neben der Tumorentwicklung und der Angiogenese auch die osteogene Differenzierung mesenchymaler Stammzellen. Im Hinblick auf zukünftige Versuche sind daher weitere, noch aussagekräftigere Ergebnisse erstrebenswert, allerdings unter der Verwendung von ausschließlich homozygoten KO-Zelllinien. Weitere Erkenntnisse über die Rolle des ALK1-Rezeptors in BMP-vermittelter Signaltransduktion könnten für therapeutische Ansätze bei der Behandlung von vaskulären Erkrankungen und Tumorprogression sowie bei der Förderung der Knochenregeneration und -heilung hilfreich sein.
CRISPR-Cas systems are a versatile tool in genetic engineering because they can be easily reprogrammed to cut a specific chromosomal region or RNA transcript. The choice of nuclease, gRNA design, and target region all influence targeting efficiency, so the appropriate CRISPR components should be chosen depending on the desired application. This thesis examines factors that influence targeting in both DNA- and RNA-targeting CRISPR systems. Chapter 1 discusses the importance of target RNA abundance in shaping the immunity of type VI CRISPR systems. In bacteria, the Cas13 nuclease is known to degrade RNA specifically and non-specifically, leading to cell growth arrest, also known as dormancy. In this chapter, the factors that determine dormancy are investigated by targeting genome- and plasmid-encoded transcripts in E. coli. The observations are extended to a gRNA library targeting the entire coding genome and gRNA design rules are extrapolated. Finally, the role of Cas13 in defense is investigated by testing how the system behaves during viral infection or plasmid transformation. Chapter 2 also looks at the factors that characterize targeting efficiency, but focuses on the Cas12a DNA-targeting system in K. pneumoniae. The ultimate goal is to develop CRISPR antimicrobials as alternatives to antibiotics to eliminate multidrug-resistant and hypervirulent bacteria. Several nucleases are tested for antimicrobial activity, the Cas12a nuclease is selected and the same gRNAs are used against different strains to understand the robustness of the method. Rules for gRNA design are also investigated by looking at secondary structure and testing a gRNA library across several genomic regions in two different strains. This information is used to develop a machine-learning algorithm to predict gRNA activity. In addition, the CRISPR-Cas systems are also packaged in a T7-like phage with engineered tail fibers and delivered to K. pneumoniae. While Chapter 2 uncovers various factors that improve targeting efficiency, Chapter 3 aims to reduce targeting by the Cas9 and Cas12a nucleases to favor homology-directed repair for genome editing in E. coli. Targeting is slowed down so that some copies of the chromosomes remain intact, allowing the bacterium to survive and integrate the desired edit. To reduce targeting, different gRNA formats or nuclease variations are used, gRNA expression is modulated, or gRNAs with attenuated targeting are designed. Attenuated gRNAs are tested to introduce point mutations as well as whole gene deletions and substitutions, and the method is extended to Klebsiella oxytoca and Klebsiella pneumoniae, where it is applied to block transcription of an antibiotic resistance gene in the genome, restoring sensitivity to ampicillin. Overall, this work discusses how changing the CRISPR components alters the outcome of targeting and highlights strategies to achieve efficient or attenuated targeting depending on the desired application.
The evolutionary success of higher plants is largely attributed to their tremendous developmental
plasticity, which allows them to cope with adverse conditions. However, because these adaptations
require investments of resources, they must be tightly regulated to avoid unfavourable trade-offs.
Most of the resources required are macronutrients based on carbon and nitrogen. Limitations in the
availability of these nutrients have major effects on gene expression, metabolism, and overall plant
morphology. These changes are largely mediated by the highly conserved master kinase SNF1-RELATED
PROTEIN KINASE1 (SnRK1), which represses growth and induces catabolic processes. Downstream of
SnRK1, a hub of heterodimerising group C and S1 BASIC LEUCINE ZIPPER (bZIP) transcription factors has
been identified. These bZIPs act as regulators of nutrient homeostasis and are highly expressed in
strong sink tissues, such as flowers or the meristems that initiate lateral growth of both shoots and
roots. However, their potential involvement in controlling developmental responses through their
impact on resource allocation and usage has been largely neglected so far. Therefore, the objective of
this work was to elucidate the impact of particularly S1 bZIPs on gene expression, metabolism, and
plant development.
Due to the high homology and suspected partial redundancy of S1 bZIPs, higher order loss-of-function
mutants were generated using CRISPR-Cas9. The triple mutant bzip2/11/44 showed a variety of robust
morphological changes but maintained an overall growth comparable to wildtype plants. In detail
however, seedlings exhibited a strong reduction in primary root length. In addition, floral transition
was delayed, and siliques and seeds were smaller, indicating a reduced supply of resources to the shoot
and root apices. However, lateral root density and axillary shoot branching were increased, suggesting
an increased ratio of lateral to apical growth in the mutant. The full group S1 knockout
bzip1/2/11/44/53 showed similar phenotypes, albeit far more pronounced and accompanied by
growth retardation. Metabolomic approaches revealed that these architectural changes were
accompanied by reduced sugar levels in distal sink tissues such as flowers and roots. Sugar levels were
also diminished in leaf apoplasts, indicating that long distance transport of sugars by apoplastic phloem
loading was impaired in the mutants. In contrast, an increased sugar supply to the proximal axillary
buds and elevated starch levels in the leaves were measured. In addition, free amino acid levels were
increased in bzip2/11/44 and bzip1/2/11/44/53, especially for the important transport forms
asparagine and glutamine. The increased C and N availability in the proximal tissues could be the cause
of the increased axillary branching in the mutants.
To identify bZIP target genes that might cause the observed shifts in metabolic status, RNAseq
experiments were performed. Strikingly, clade III SUGARS WILL EVENTUALLY BE EXPORTED (SWEET)
8
genes were abundant among the differentially expressed genes. As SWEETs are crucial for sugar export
to the apoplast and long-distance transport through the phloem, their reduced expression is likely to
be the cause of the observed changes in sugar allocation. Similarly, the reduced expression of
GLUTAMINE AMIDOTRANSFERASE 1_2.1 (GAT1_2.1), which exhibits glutaminase activity, could be an
explanation for the abundance of glutamine in the mutants. Additional experiments (ATAC-seq, DAPseq, PTA, q-RT-PCR) supported the direct induction of SWEETs and GAT1_2.1 by S1 bZIPs. To confirm
the involvement of these target genes in the observed S1 bZIP mutant phenotypes, loss-of-function
mutants were obtained, which showed moderately increased axillary branching. At the same time, the
induced overexpression of bZIP11 in axillary meristems had the opposite effect.
Collectively, a model is proposed for the function of S1 bZIPs in regulating sink tissue development. For
efficient long-distance sugar transport, bZIPs may be required to induce the expression of clade III
SWEETs. Thus, reduced SWEET expression in the S1 bZIP mutants would lead to a decrease in apoplastic
sugar loading and a reduced supply to distal sinks such as shoot or root apices. The reduction in longdistance transport could lead to sugar accumulation in the leaves, which would then increasingly be
transported via symplastic routes towards proximal sinks such as axillary branches and lateral roots or
sequestered as starch. The reduced GAT1_2.1 levels lead to an abundance of glutamine, a major
nitrogen transport form. The combined effect on C and N allocation results in increased nutrient
availability in proximal tissues, promoting the formation of lateral plant organs. Alongside emerging
evidence highlighting the power of bZIPs to steer nutrient allocation in other species, a novel but
evolutionary conserved role for S1 bZIPs as regulators of developmental plasticity is proposed, while
the generation of valuable data sets and novel genetic resources will help to gain a deeper
understanding of the molecular mechanisms involved
Among the defense strategies developed in microbes over millions of years, the innate adaptive CRISPR-Cas immune systems have spread across most of bacteria and archaea. The flexibility, simplicity, and specificity of CRISPR-Cas systems have laid the foundation for CRISPR-based genetic tools. Yet, the efficient administration of CRISPR-based tools demands rational designs to maximize the on-target efficiency and off-target specificity. Specifically, the selection of guide RNAs (gRNAs), which play a crucial role in the target recognition of CRISPR-Cas systems, is non-trivial. Despite the fact that the emerging machine learning techniques provide a solution to aid in gRNA design with prediction algorithms, design rules for many CRISPR-Cas systems are ill-defined, hindering their broader applications.
CRISPR interference (CRISPRi), an alternative gene silencing technique using a catalytically dead Cas protein to interfere with transcription, is a leading technique in bacteria for functional interrogation, pathway manipulation, and genome-wide screens. Although the application is promising, it also is hindered by under-investigated design rules. Therefore, in this work, I develop a state-of-art predictive machine learning model for guide silencing efficiency in bacteria leveraging the advantages of feature engineering, data integration, interpretable AI, and automated machine learning. I first systematically investigate the influential factors that attribute to the extent of depletion in multiple CRISPRi genome-wide essentiality screens in Escherichia coli and demonstrate the surprising dominant contribution of gene-specific effects, such as gene expression level. These observations allowed me to segregate the confounding gene-specific effects using a mixed-effect random forest (MERF) model to provide a better estimate of guide efficiency, together with the improvement led by integrating multiple screens. The MERF model outperformed existing tools in an independent high-throughput saturating screen. I next interpret the predictive model to extract the design rules for robust gene silencing, such as the preference for cytosine and disfavoring for guanine and thymine within and around the protospacer adjacent motif (PAM) sequence. I further incorporated the MERF model in a web-based tool that is freely accessible at www.ciao.helmholtz-hiri.de.
When comparing the MERF model with existing tools, the performance of the alternative gRNA design tool optimized for CRISPRi in eukaryotes when applied to bacteria was far from satisfying, questioning the robustness of prediction algorithms across organisms. In addition, the CRISPR-Cas systems exhibit diverse mechanisms albeit with some similarities. The captured predictive patterns from one dataset thereby are at risk of poor generalization when applied across organisms and CRISPR-Cas techniques. To fill the gap, the machine learning approach I present here for CRISPRi could serve as a blueprint for the effective development of prediction algorithms for specific organisms or CRISPR-Cas systems of interest. The explicit workflow includes three principle steps: 1) accommodating the feature set for the CRISPR-Cas system or technique; 2) optimizing a machine learning model using automated machine learning; 3) explaining the model using interpretable AI. To illustrate the applicability of the workflow and diversity of results when applied across different bacteria and CRISPR-Cas systems, I have applied this workflow to analyze three distinct CRISPR-Cas genome-wide screens. From the CRISPR base editor essentiality screen in E. coli, I have determined the PAM preference and sequence context in the editing window for efficient editing, such as A at the 2nd position of PAM, A/TT/TG downstream of PAM, and TC at the 4th to 5th position of gRNAs. From the CRISPR-Cas13a screen in E. coli, in addition to the strong correlation with the guide depletion, the target expression level is the strongest predictor in the model, supporting it as a main determinant of the activation of Cas13-induced immunity and better characterizing the CRISPR-Cas13 system. From the CRISPR-Cas12a screen in Klebsiella pneumoniae, I have extracted the design rules for robust antimicrobial activity across K. pneumoniae strains and provided a predictive algorithm for gRNA design, facilitating CRISPR-Cas12a as an alternative technique to tackle antibiotic resistance.
Overall, this thesis presents an accurate prediction algorithm for CRISPRi guide efficiency in bacteria, providing insights into the determinants of efficient silencing and guide designs. The systematic exploration has led to a robust machine learning approach for effective model development in other bacteria and CRISPR-Cas systems. Applying the approach in the analysis of independent CRISPR-Cas screens not only sheds light on the design rules but also the mechanisms of the CRISPR-Cas systems. Together, I demonstrate that applied machine learning paves the way to a deeper understanding and a broader application of CRISPR-Cas systems.
In 2020, cancer was the leading cause of death worldwide, accounting for nearly 10 million deaths. Lung cancer was the most common cancer, with 2.21 million cases per year in both sexes. This non-homogeneous disease is further subdivided into small cell lung cancer (SCLC, 15%) and non-small cell lung cancer (NSCLC, 85%). By 2023, the American Cancer Society estimates that NSCLC will account for 13% of all new cancer cases and 21% of all estimated cancer deaths. In recent years, the treatment of patients with NSCLC has improved with the development of new therapeutic interventions and the advent of targeted and personalised therapies. However, these advances have only marginally improved the five-year survival rate, which remains alarmingly low for patients with NSCLC. This observation highlights the importance of having more appropriate experimental and preclinical models to recapitulate, identify and test novel susceptibilities in NSCLC. In recent years, the Trp53fl/fl KRaslsl-G12D/wt mouse model developed by Tuveson, Jacks and Berns has been the main in vivo model used to study NSCLC. This model mimics ADC and SCC to a certain extent. However, it is limited in its ability to reflect the genetic complexity of NSCLC. In this work, we use CRISPR/Cas9 genome editing with targeted mutagenesis and gene deletions to recapitulate the conditional model. By comparing the Trp53fl/fl KRaslsl- G12D/wt with the CRISPR-mediated Trp53mut KRasG12D, we demonstrated that both showed no differences in histopathological features, morphology, and marker expression. Furthermore, next-generation sequencing revealed a very high similarity in their transcriptional profile. Adeno-associated virus-mediated tumour induction and the modular design of the viral vector allow us to introduce additional mutations in a timely manner. CRISPR-mediated mutation of commonly mutated tumour suppressors in NSCLC reliably recapitulated the phenotypes described in patients in the animal model. Lastly, the dual viral approach could induce the formation of lung tumours not only in constitutive Cas9 expressing animals, but also in wildtype animals. Thus, the implementation of CRISPR genome editing can rapidly advance the repertoire of in vivo models for NSCLC research. Furthermore, it can reduce the necessity of extensive breeding.
Hypophosphatasie (HPP) beschreibt eine seltene Erbkrankheit, die hauptsächlich durch heterozygote Mutationen im ALPL-Gen verursacht wird. Diese führen zu einer verminderten Aktivität der gewebeunspezifischen alkalischen Phosphatase (TNAP). Neben skelettalen Symptomen sind Zahnanomalien wie der vorzeitige Verlust von Milchzähnen ohne resorbierte Wurzel sowie eine gestörte Mineralisierung der Zahnhart-substanzen ein typisches Merkmal der HPP. Die zugrunde liegenden molekularen Mechanismen sind bisher noch nicht vollständig verstanden.
In der vorliegenden Arbeit wurden Zelllinien des parodontalen Ligaments mit Mutationen im ALPL-Gen charakterisiert, um anschließend mögliche Therapiestrategien für die HPP auf molekularer Ebene zu untersuchen.
Im Rahmen der basalen Charakterisierung wurden die Zelllinien hinsichtlich der TNAP-Expression (Immunhistochemie, Western Blot), des Stoffwechselprofils (ATP-Assay) und des osteogenen Differenzierungspotenzials (Alizarin-Färbung) analysiert. Von Interesse war auch, ob durch CRISPR/Cas9-basiertes Genediting Off-Target Mutationen entstanden sind. Zur Untersuchung der molekularen Auswirkungen von PTH, welches die ALPL-Expression steigern kann, wurden zwei Protokolle etabliert, die eine kontinuier-liche, kurzzeitige bzw. intermittierende Präsenz von PTH in-vitro imitieren. Anschließend wurde die ALPL-Expression (qPCR) sowie TNAP-Aktivität (CSPD-Assay) ermittelt.
Die basale TNAP-Expression war variabel und reichte vom völligen Fehlen in den Zell-linien mit Deletionen bis hin zu einer starken TNAP-Expression in der Zelllinie mit einer heterogenen Punktmutation. Eine niedrige Expression ging mit einer verringerten Zell-proliferation sowie extrazellulären ATP einher. Es zeigte sich ein unterschiedliches Mineralisierungspotenzial, das hauptsächlich das TNAP-Expressionsniveau in den verschiedenen Zelllinien widerspiegelt, während die PTH-Stimulation keine Wirkung auf die Differenzierung hatte. Im Gegensatz zu klinischen Beobachtungen deuten die Ergebnisse auf eine hohe Korrelation zwischen Genotyp und Phänotyp in-vitro hin, die in-vivo noch bestätigt werden müssen. Die Sequenzierung bestätigte, dass durch die Geneditierung keine Off-Target Mutationen aufgetreten sind, welche somit keinen limitierenden Faktor hinsichtlich der Differenzierungskapazität darstellen können.
Die Stimulation mit PTH führte zwar nicht zu einer gesteigerten ALPL-Expression, doch konnte die TNAP-Aktivität in den ALPL-defizienten Zelllinien punktuell gesteigert werden und bildet somit eine solide Basis für weitere Experimente, die zur Therapieentwicklung für die Odonto-HPP beitragen können.
The emergence of human induced pluripotent stem cells (iPSCs) and the rise of the clustered regularly interspaced short palindromic repeats/CRISPR-associated protein 9 (CRISPR/Cas9) gene editing technology innovated the research platform for scientists based on living human pluripotent cells. The revolutionary combination of both Nobel Prize-honored techniques enables direct disease modeling especially for research focused on genetic diseases. To allow the study on mutation-associated pathomechanisms, we established robust human in vitro systems of three inherited cardiomyopathies: arrhythmogenic cardiomyopathy (ACM), dilated cardiomyopathy with juvenile cataract (DCMJC) and dilated cardiomyopathy with ataxia (DCMA).
Sendai virus vectors encoding OCT3/4, SOX2, KLF4, and c-MYC were used to reprogram human healthy control or mutation-bearing dermal fibroblasts from patients to an embryonic state thereby allowing the robust and efficient generation of in total five transgene-free iPSC lines. The nucleofection-mediated CRISPR/Cas9 plasmid delivery in healthy control iPSCs enabled precise and efficient genome editing by mutating the respective disease genes to create isogenic mutant control iPSCs. Here, a PKP2 knock-out and a DSG2 knock-out iPSC line were established to serve as a model of ACM. Moreover, a DNAJC19 C-terminal truncated variant (DNAJC19tv) was established to mimic a splice acceptor site mutation in DNAJC19 of two patients with the potential of recapitulating DCMA-associated phenotypes. In total eight self-generated iPSC lines were assessed matching internationally defined quality control criteria. The cells retained their ability to differentiate into cells of all three germ layers in vitro and maintained a stable karyotype. All iPSC lines exhibited a typical stem cell-like morphology as well as expression of characteristic pluripotency markers with high population purities, thus validating the further usage of all iPSC lines in in vitro systems of ACM, DCMA and DCMJC.
Furthermore, cardiac-specific disease mechanisms underlying DCMA were investigated using in vitro generated iPSC-derived cardiomyocytes (iPSC-CMs). DCMA is an autosomal recessive disorder characterized by life threatening early onset cardiomyopathy associated with a metabolic syndrome. Causal mutations were identified in the DNAJC19 gene encoding an inner mitochondrial membrane (IMM) protein with a presumed function in mitochondrial biogenesis and cardiolipin (CL) remodeling. In total, two DCMA patient-derived iPSC lines (DCMAP1, DCMAP2) of siblings with discordant cardiac phenotypes, a third isogenic mutant control iPSC line (DNAJC19tv) as well as two control lines (NC6M and NC47F) were directed towards the cardiovascular lineage upon response to extracellular specification cues. The monolayer cardiac differentiation approach was successfully adapted for all five iPSC lines and optimized towards ventricular subtype identity, higher population purities and enhanced maturity states to fulfill all DCMA-specific requirements prior to phenotypic investigations. To provide a solid basis for the study of DCMA, the combination of lactate-based metabolic enrichment, magnetic-activated cell sorting, mattress-based cultivation and prolonged cultivation time was performed in an approach-dependent manner. The application of the designated strategies was sufficient to ensure adult-like characteristics, which included at least 60-day-old iPSC-CMs. Therefore, the novel human DCMA platform was established to enable the study of the pathogenesis underlying DCMA with respect to structural, morphological and functional changes.
The disease-associated protein, DNAJC19, is constituent of the TIM23 import machinery and can directly interact with PHB2, a component of the membrane bound hetero-oligomeric prohibitin ring complexes that are crucial for phospholipid and protein clustering in the IMM. DNAJC19 mutations were predicted to cause a loss of the DnaJ interaction domain, which was confirmed by loss of full-length DNAJC19 protein in all mutant cell lines. The subcellular investigation of DNAJC19 demonstrated a nuclear restriction in mutant iPSC-CMs. The loss of DNAJC19 co-localization with mitochondrial structures was accompanied by enhanced fragmentation, an overall reduction of mitochondrial mass and smaller cardiomyocytes. Ultrastructural analysis yielded decreased mitochondria sizes and abnormal cristae providing a link to defects in mitochondrial biogenesis and CL remodeling. Preliminary data on CL profiles revealed longer acyl chains and a more unsaturated acyl chain composition highlighting abnormities in the phospholipid maturation in DCMA.
However, the assessment of mitochondrial function in iPSCs and dermal fibroblasts revealed an overall higher oxygen consumption that was even more enhanced in iPSC-CMs when comparing all three mutants to healthy controls. Excess oxygen consumption rates indicated a higher electron transport chain (ETC) activity to meet cellular ATP demands that probably result from proton leakage or the decoupling of the ETC complexes provoked by abnormal CL embedding in the IMM.
Moreover, in particular iPSC-CMs presented increased extracellular acidification rates that indicated a shift towards the utilization of other substrates than fatty acids, such as glucose, pyruvate or glutamine. The examination of metabolic features via double radioactive tracer uptakes (18F-FDG, 125I-BMIPP) displayed significantly decreased fatty acid uptake in all mutants that was accompanied by increased glucose uptake in one patient cell line only, underlining a highly dynamic preference of substrates between mutant iPSC-CMs.
To connect molecular changes directly to physiological processes, insights on calcium kinetics, contractility and arrhythmic potential were assessed and unraveled significantly increased beating frequencies, elevated diastolic calcium concentrations and a shared trend towards reduced cell shortenings in all mutant cell lines basally and upon isoproterenol stimulation. Extended speed of recovery was seen in all mutant iPSC-CMs but most striking in one patient-derived iPSC-CM model, that additionally showed significantly prolonged relaxation times. The investigations of calcium transient shapes pointed towards enhanced arrhythmic features in mutant cells comprised by both the occurrence of DADs/EADs and fibrillation-like events with discordant preferences.
Taken together, new insights into a novel in vitro model system of DCMA were gained to study a genetically determined cardiomyopathy in a patient-specific manner upon incorporation of an isogenic mutant control. Based on our results, we suggest that loss of full-length DNAJC19 impedes PHB2-complex stabilization within the IMM, thus hindering PHB-rings from building IMM-specific phospholipid clusters. These clusters are essential to enable normal CL remodeling during cristae morphogenesis. Disturbed cristae and mitochondrial fragmentation were observed and refer to an essential role of DNAJC19 in mitochondrial morphogenesis and biogenesis. Alterations in mitochondrial morphology are generally linked to reduced ATP yields and aberrant reactive oxygen species production thereby having fundamental downstream effects on the cardiomyocytes` functionality. DCMA-associated cellular dysfunctions were in particular manifested in excess oxygen consumption, altered substrate utilization and abnormal calcium kinetics. The summarized data highlight the usage of human iPSC-derived CMs as a powerful tool to recapitulate DCMA-associated phenotypes that offers an unique potential to identify therapeutic strategies in order to reverse the pathological process and to pave the way towards clinical applications for a personalized therapy of DCMA in the future.
Allogenic hematopoietic stem cell transplantation (allo-HCT) is a curative therapy for the treatment of malignant and non-malignant bone marrow diseases. The major complication of this treatment is a highly inflammatory reaction known as Graft-versus-Host Disease (GvHD). Cyclosporin A (CsA) and tacrolimus are used to treat GvHD which limits inflammation but also interferes with the anticipated Graft-versus-Leukemia (GvL) effect. These drugs repress conventional T cells (Tcon) along with regulatory T cells (Treg), which are important for both limiting GvHD and supporting GvL. Both of these drugs inhibit calcineurin (CN), which dephosphorylates and activates the nuclear factor of activated T-cells (NFAT) family of transcription factors. Here, we make use of our Cd4cre.Cas9+ mice and developed a highly efficient non-viral CRISPR/Cas9 gene editing method by gRNA-only nucleofection. Utilizing this technique, we demonstrated that unstimulated mouse T cells upon NFATc1 or NFATc2 ablation ameliorated GvHD in a major mismatch mouse model. However, in vitro pre-stimulated mouse T cells could not achieve long-term protection from GvHD upon NFAT single-deficiency. This highlights the necessity of gene editing and transferring unstimulated human T cells during allo-HCT. Indeed, we established a highly efficient ribonucleoprotein (RNP)-mediated CRISPR/Cas9 gene editing for NFATC1 and/or NFATC2 in pre-stimulated as well as unstimulated primary human T cells. In contrast to mouse T cells, not NFATC1 but NFATC2 deficiency in human T cells predominantly affected proinflammatory cytokine production. However, either NFAT single-knockout kept cytotoxicity of human CD3+ T cells untouched against tumor cells in vitro. Furthermore, mouse and human Treg were unaffected upon the loss of a single NFAT member. Lastly, NFATC1 or NFATC2-deficient anti-CD19 CAR T cells, generated with our non-viral ‘one-step nucleofection’ method validated our observations in mouse and human T cells. Proinflammatory cytokine production was majorly dependent on NFATC2 expression, whereas, in vitro cytotoxicity against CD19+ tumor cells was undisturbed in the absence of either of the NFAT members. Our findings emphasize that NFAT single-deficiency in donor T cells is superior to CN-inhibitors as therapy during allo-HCT to prevent GvHD while preserving GvL in patients.
CRISPR-Cas systems are highly diverse and canonically function as prokaryotic adaptive immune systems. The canonical resistance mechanism relies on spacers that are complementary to the invaders' nucleic acids. By accidental incorporation or other mechanisms, prokaryotes can also acquire self-targeting spacers that are complementary to their own genome. As self-targeting commonly leads to lethal autoimmunity, the existence of self-targeting spacers poses a paradox. In Chapter 1, we provide an overview of the prevalence of self-targeting spacers, summarize how they can be incorporated, and which means can be employed by the host to evade lethal self-targeting. In addition, we outline alternative functions of CRISPR-Cas systems that are associated with self-targeting spacers. Whether CRISPR-Cas systems can efficiently target their own genome depends heavily on the presence of protospacer adjacent motifs (PAMs) next to the target region. In Chapter 2, we developed a method to determine PAM requirements. Thereby, we specifically focused on type I systems that engage multi-protein complexes, which are challenging to assess. Using the cell-free transcription-translation (TXTL) system, we developed an enrichment-based binding assay and validated its reliability by examining the well-known PAM requirements of the E. coli type I-E system. In Chapter 3, we applied the TXTL-based PAM assay to assess 16 additional CRISPR-Cas systems. These 16 systems included three CRISPR-Cas associated transposons (CASTs). CASTs are recently discovered transposons that employ CRISPR-Cas systems in a non-canonical function for the directed integration of the transposon. To further characterize CASTs in TXTL outside their PAM requirements, we reconstituted the transposition of CASTs in TXTL. In Chapter 4, we turned to non-canonical self-targeting CRISPR-Cas systems, which were already discussed in Chapter 1. While investigating how the plant pathogen Xanthomonas albilineans survives self-targeting by its two endogenous CRISPR-Cas systems, we identified multiple putative anti-CRISPR proteins (Acrs) in the genome of X. albilineans. Two of the Acrs, named AcrIC11 and AcrIF12Xal, inhibited degradation by their respective CRISPR-Cas systems but still retained Cascade-binding ability, and appear responsible for the lack of autoimmunity in X. albilineans. In summary, we developed new technologies that eased the investigation of non-canonical multi-component systems and, if applied to additional systems, might reveal unique properties that could be implemented in new CRISPR-Cas based tools.
Die Hypophosphatasie (HPP) ist eine seltene Erberkrankung, welche durch compound-heterozygote oder dominant negative heterozygote Mutationen des ALPL Gens zu einem Funktionsverlust der gewebeunspezifischen Alkalischen Phosphatase (TNAP) führt. Die daraus resultierenden Mineralisierungsstörungen betreffen sowohl den Knochen als auch in milderen Ausprägungsformen die Zähne und den Zahnhalteapparat. Das zahnmedizinische Leitsymptom und in vielen Fällen das erste Anzeichen der HPP ist dabei der vorzeitige Verlust der Milchzähne ohne physiologische Wurzelresorption. Im Rahmen dieser Arbeit wurden verschiedene TNAP defiziente immortalisierte Zellen des parodontalen Ligaments (PDL) mittels der CRISPR/Cas9 Methode generiert und anschließend fünf Zelllinien charakterisiert. Die dabei entstandenen Mutationen variierten von einer moderaten heterozygoten Punktmutation zu einer schwerwiegenden homozygoten Deletion eines einzelnen Nukleotids, welche in einem vorzeitigen Stopcodon resultierte. Analysen der ALPL Expression (qPCR), TNAP Aktivitätsmessungen (CSPD Assay) und TNAP Färbungen zeigten einen signifikanten Rückgang in allen TNAP-defizienten Zelllinien mit einer starken Korrelation zwischen der Restaktivität und dem Ausmaß der Mutation, welche in Einklang mit der komplexen Genotyp-Phänotyp Korrelation bei HPP zu bringen ist. Das Potential der osteogenen Differenzierung der hTERT PDL Zellen wurde in der homozygot mutierten Zelllinie komplett unterdrückt. Mögliche Mechanismen des vorzeitigen Zahnverlustes bei HPP Patienten ist die geminderte Formation und Mineralisation des Wurzelzements und die fehlerhafte Insertion der parodontalen Fasern. Die hier erstmalig etablierten Zellkulturmodelle liefern ein valides spenderunabhängiges in vitro Modell der HPP, welches dazu beitragen kann, die molekularbiologischen Zusammenhänge der dentalen Aspekte der Hypophosphatasie zu ergründen und daraus gegebenenfalls neue Therapieansätze abzuleiten.