Water and Ions Dynamics in Modified Hydrophobic Si3N4 Nanopores for Protein Sequencing

Tabasso, Fabrizio

January 2024

This thesis presents a computational study of water and ion dynamics in modified hydrophobic silicon nitride (Si3N4) nanopores, aimed at enhancing protein sequenc- ing technologies. By employing molecular dynamics (MD) simulations, the research investigates the wetting-dewetting behavior within nanopores as an indirect measure of amino acid residue hydrophobicity, focusing on how post-translational modifications (PTMs) of lysine, particularly the acetylation of lysine residues, influence nanopore hydrophobicity and ionic conductance. The study reveals that nanopore radius and hydrophobicity significantly affect water and ion permeation, with smaller nanopores oscillating between open and closed states, while larger ones remain open.  Using umbrella sampling and the Weighted Histogram Analysis Method (WHAM), the potential of mean force (PMF) for potassium (K+), chloride (Cl−), and water within the nanopores was determined, showing distinct PMF profiles based on lysine and acetyl- lysine presence. The modulation of ionic currents as a tool for protein sequencing was explored, demonstrating that different amino acid residues affect ionic currents by par- tially blocking the pore and altering local permeability, thereby enabling differentiation based on size, shape, charge, and hydrophobicity.  The findings suggest that silicon nitride pore hydrophobicity can be tailored for nanopore sequencing, correlating changes in ionic currents with amino acid residue translocation. This research enhances the understanding of interactions within nanopore environments, potentially leading to more precise nanopore-based sequencing methods.

nanopore sequencing

silicon nitride

water

ions

current blockade

hydrophobic gating

Biophysics

Biofysik

Determine the composition of spoilage bacteria and their dynamic changes in fresh broiler breast meat during refrigerated storage

Lesak, Dylan Joseph

10 May 2024

Traditional plating methods for bacterial enumeration can be limited, but the development of high-throughput DNA sequencing, such as Oxford Nanopore Technologies (ONT), can provide rapid and highly specific alternative for species-level identification. In this study, ONT amplicon sequencing was applied to fresh broiler breast meat to identify their bacterial composition and monitor their dynamic changes. The sequencing data were complemented by sensory panels, physicochemical analysis, and traditional plating methods. Over time, the bacterial diversity decreased within and across samples. By the end of shelf-life, Pseudomonas fragi, Pseudomonas lundesis, and Brochothrix thermosphacta became the most prevalent species. These bacteria were associated with spoilage attributes that were reported in the sensory panels. This study demonstrated the effectiveness of Nanopore sequencing in determining the spoilage associated bacteria in chicken meat. Future research may focus on developing targeted interventions to mitigate the impact of these spoilage bacteria and extend the shelf life of chicken meat.

Equine Herpesvirus Type 1: Filling Gaps Toward Improved Outbreak Management

Saklou, Nadia Talal

06 September 2023

Equine herpesvirus type 1 (EHV-1) is a common pathogen of horses that typically causes upper respiratory disease, however is also associated with late-term abortion, neonatal foal death and neurologic disease. Once a horse is infected, the virus concentrates to local lymphoid tissue, where it becomes latent. The virus can recrudesce during times of stress, which can lead to the initiation of devastating outbreaks. Some variants of EHV-1 have been associated with more severe disease outcomes. Appropriate outbreak management focuses on minimizing the movement of potentially exposed horses. This approach lacks a strategy for prevention at the level of latency largely due to a knowledge paucity in regards to carriage rate of latent EHV-1. Biosecurity decisions are also dependent on awaiting currently-available diagnostic testing that often take several days for results. Thus, our work has been focused on understanding the carriage rate of the latent virus in different geographic regions as well as improving diagnostic efficiency, both of which are essential for improving the management of EHV-1 disease. Loop mediated isothermal amplification (LAMP) is a method that amplifies nucleic acid rapidly at a constant temperature and is minimally affected by inhibitors that are often found in clinical samples. This procedure can be followed by multiple detection methods. A new, efficient sequencing method, called nanopore sequencing, has been developed in a handheld device, called MinION, that provides thorough output in a timely manner. When combined with LAMP, it has been referred to as LAMPore. The first objective of our work was to estimate the prevalence of latent EHV-1 and compare the frequency of each variant in the submandibular lymph nodes from horses in Virginia. Our second objective was to perform direct DNA sequencing of EHV-1 using the mobile MinION sequencer in combination with LAMP viral enrichment. Our findings demonstrated a low apparent prevalence of latent EHV-1 DNA in submandibular lymph nodes in this population of horses in Virginia as well as successful detection and identification of EHV-1 in equine nasal swab samples using LAMPore sequencing. / Doctor of Philosophy / Horses can develop disease from a virus called equine herpesvirus type 1 (EHV-1). Symptoms can vary from mild respiratory signs to the inability to rise leading to death or euthanasia. Horses transmit this virus to other nearby horses; however, the virus also becomes dormant once a horse is infected, meaning the virus is not infectious but is present within the animal. When the horse undergoes stress, such as during travel or competition, the virus can become active again, leading to the spread to other horses. This results in outbreaks, many of which are devastating to the equine industry. In order to minimize the risks of this virus spreading and causing disease, management is currently focused on minimizing the movement of horses that may have been exposed to the virus. There is little information regarding the number of horses that harbor the dormant virus and the current methods to detect the infectious virus can take multiple days for results. These limit decision-making during the management of an outbreak. Our work seeks to determine the number of horses in a region that harbor EHV-1 and also to test a new, efficient diagnostic method to identify the virus in samples from horses. Our findings showed a low number of horses in Virginia harbor dormant EHV-1 in the lymph nodes under their mandible, a common site of dormancy. Further, we found that our new method of detection was effective in identifying the virus in samples from nasal secretions from horse.

horse

herpesvirus

submandibular lymph nodes

PCR

latency

nanopore sequencing

DNA

equine herpesvirus-1

Identification of bacterial species composition and diversity of chicken breast meat during processing.

Zaldivar, Lizzie Raquel

13 December 2024

Understanding the bacterial profile of chicken during processing is essential to identify spoilage-related bacteria. Using advanced methods like Oxford Nanopore sequencing, specific bacterial species on chicken meat can be identified. This study aimed to characterize bacterial composition and diversity on chicken breast during processing. Results showed a reduction in aerobic bacteria, E. coli, coliform, and lactic acid bacteria counts. However, three thermophilic bacteria, Anoxybacillus contaminants, Neobacillus thermocopriae, and Anoxybacillus flavithermus, dominated across processing steps. Notably, Pseudomonas species were undetected by conventional plating but identified via Nanopore sequencing, highlighting the need for molecular detection methods. Although antimicrobial interventions significantly reduced bacterial counts. Therefore, combining molecular and conventional plating methods provides a more comprehensive understanding of bacterial populations. This approach could enhance processing practices, leading to a better understanding of quality and safety.

Nanopore

Bacteria Profile

Anoxybacillus contaminants

Pseudomonas

Poultry Processing

Spoilage Bacteria

Food Science

Life Sciences

Zum Einfluss elektrochemischer Doppelschichten auf den Stofftransport in nanoskaligen Elektrolytsystemen:

Kubeil, Clemens

28 February 2017

Es besteht enormes Interesse den Stofftransport in nanoskaligen Systemen zu verstehen und selektiv zu steuern, um analytische und synthetische Anwendungen zu entwickeln, aber auch um die physiologischen Prozesse lebender Zellen zu entschlüsseln. Im Rahmen dieser Arbeit wurde der Einfluss der elektrochemischen Doppelschicht an ausgewählten nanoskaligen Elektrolytsystemen untersucht. Die Gleichrichtung von Ionenströmen (engl. Ionic Current Rectification ICR) in Nanoporen mit einer Oberflächenladung äußert sich in einer gekrümmten Strom-Spannungs-Kurve. Die Überlappung von innerem und äußerem Potential ist dabei hinsichtlich der Ionenverteilung und somit der Porenleitfähigkeit einander verstärkend oder gegenläufig. Auf Grundlage dieses Mechanismus wurde die Gleichrichtung bei einem sehr großen Verhältnis von Porenöffnung zu Debye-Länge erklärt. Ferner wurde mittels der eingeführten relativen Leitfähigkeit κ´ die verschiedenen Leitfähigkeitszustände in Abhängigkeit der Elektrolytkonzentration und Temperatur sichtbar gemacht und Implikationen für Sensoranwendungen wie z.B. dem resistiven Pulszähler zur Partikelanalyse abgeleitet. Es wurde ein numerisches Modell basierend auf dem Poisson-Nernst-Planck-Gleichungssystem entwickelt, um die Translokation eines Nanopartikels durch eine konische Nanopore bei einer geringen Leitsalzkonzentration zu beschreiben. Neben dem klassischen Volumenausschluss-Effekt tritt zusätzlich ein Gleichrichtungseffekt (ICR-Effekt) in der Pore auf. Eine Analyse zur Entflechtung von Partikelgröße und Partikelladung aus der Pulshöhe und Pulsform wurde erfolgreich durchgeführt. Wie der Stofftransport durch eine Oberflächenladung auf dem umgebenden Material einer Nanoelektrode beeinflusst wird, wurde anhand des voltammetrischen Verhaltens diskutiert. An sehr kleinen Elektroden (< 10 nm) ist demnach der Einfluss der elektrochemischen Doppelschicht auf die Strom-Spannungs-Kurve besonders groß und kann auch bei Vorliegen eines hohen Leitsalzüberschusses nicht vernachlässigt werden. In leitsalzfreien Elektrolyten sind die gefundenen Effekte so deutlich, dass sie auch an größeren Elektroden experimentell zweifelsfrei festgestellt worden sind. / There is an enormous interest in understanding and selectively controlling the material transport in nanoscale systems to develop analytical and synthetic applications, but also to decipher the physiological processes of living cells. Within this thesis, the influence of the electrochemical double layer on selected nanoscale electrolyte systems was studied. Ionic Current Rectification (ICR) in nanopores carrying a surface charge manifests itself in a non-linear current-voltage-curve. The overlap of interior and exterior potential is cumulative or opposing with regard to the ion distribution and therefore the pore conductivity. Based on this mechanism, ICR for very large ratios of pore size and Debye length was explained. Furthermore, the different conducting states as a function of electrolyte concentration and temperature were visualized by introducing the relative conductivity κ´ and hence implications for sensor applications such as the resistive pulse sensor have been deduced. A numerical model based on the Poisson-Nernst-Planck-equations was developed to describe the translocation of a nanoparticle through a conical nanopore at a low electrolyte concentration. An additional rectification effect (ICR effect) occurs in the pore beside the conventional volume exclusion effect. An analysis was successfully performed to deconstruct the particle size and particle charge from the pulse height and shape. The material transport is affected by a surface charge on the shrouding material of nanoelectrodes as it was discussed by means of the voltammetric behaviour. The influence of the electrochemical double layer on the current-voltage-curve is particularly large at very small electrodes (< 10 nm) and cannot be neglected even at a high excess of supporting electrolyte. The observed effects were pronounced in unsupported electrolytes, so that they could be clearly detected experimentally at even larger electrodes.

Nanopore

Nanoelektrode

Ionische Gleichrichtung

elektrochemische Doppelschicht

Poisson-Nernst-Planck

Leitfähigkeit

Pulszähler

Nanopore

Nanoelectrode

Ionic Current Rectification

Electrochemical Double Layer

Poisson-Nernst-Planck

Conductivity

Pulse Sensing

ddc:540

rvk:VE 9857

Elektrochemie

Simulation

Nanotechnologie

Zum Einfluss elektrochemischer Doppelschichten auf den Stofftransport in nanoskaligen Elektrolytsystemen:: Leitfähigkeit von Nanoporen und Voltammetrie an Nanoelektroden

Kubeil, Clemens

26 October 2016

Es besteht enormes Interesse den Stofftransport in nanoskaligen Systemen zu verstehen und selektiv zu steuern, um analytische und synthetische Anwendungen zu entwickeln, aber auch um die physiologischen Prozesse lebender Zellen zu entschlüsseln. Im Rahmen dieser Arbeit wurde der Einfluss der elektrochemischen Doppelschicht an ausgewählten nanoskaligen Elektrolytsystemen untersucht. Die Gleichrichtung von Ionenströmen (engl. Ionic Current Rectification ICR) in Nanoporen mit einer Oberflächenladung äußert sich in einer gekrümmten Strom-Spannungs-Kurve. Die Überlappung von innerem und äußerem Potential ist dabei hinsichtlich der Ionenverteilung und somit der Porenleitfähigkeit einander verstärkend oder gegenläufig. Auf Grundlage dieses Mechanismus wurde die Gleichrichtung bei einem sehr großen Verhältnis von Porenöffnung zu Debye-Länge erklärt. Ferner wurde mittels der eingeführten relativen Leitfähigkeit κ´ die verschiedenen Leitfähigkeitszustände in Abhängigkeit der Elektrolytkonzentration und Temperatur sichtbar gemacht und Implikationen für Sensoranwendungen wie z.B. dem resistiven Pulszähler zur Partikelanalyse abgeleitet. Es wurde ein numerisches Modell basierend auf dem Poisson-Nernst-Planck-Gleichungssystem entwickelt, um die Translokation eines Nanopartikels durch eine konische Nanopore bei einer geringen Leitsalzkonzentration zu beschreiben. Neben dem klassischen Volumenausschluss-Effekt tritt zusätzlich ein Gleichrichtungseffekt (ICR-Effekt) in der Pore auf. Eine Analyse zur Entflechtung von Partikelgröße und Partikelladung aus der Pulshöhe und Pulsform wurde erfolgreich durchgeführt. Wie der Stofftransport durch eine Oberflächenladung auf dem umgebenden Material einer Nanoelektrode beeinflusst wird, wurde anhand des voltammetrischen Verhaltens diskutiert. An sehr kleinen Elektroden (< 10 nm) ist demnach der Einfluss der elektrochemischen Doppelschicht auf die Strom-Spannungs-Kurve besonders groß und kann auch bei Vorliegen eines hohen Leitsalzüberschusses nicht vernachlässigt werden. In leitsalzfreien Elektrolyten sind die gefundenen Effekte so deutlich, dass sie auch an größeren Elektroden experimentell zweifelsfrei festgestellt worden sind. / There is an enormous interest in understanding and selectively controlling the material transport in nanoscale systems to develop analytical and synthetic applications, but also to decipher the physiological processes of living cells. Within this thesis, the influence of the electrochemical double layer on selected nanoscale electrolyte systems was studied. Ionic Current Rectification (ICR) in nanopores carrying a surface charge manifests itself in a non-linear current-voltage-curve. The overlap of interior and exterior potential is cumulative or opposing with regard to the ion distribution and therefore the pore conductivity. Based on this mechanism, ICR for very large ratios of pore size and Debye length was explained. Furthermore, the different conducting states as a function of electrolyte concentration and temperature were visualized by introducing the relative conductivity κ´ and hence implications for sensor applications such as the resistive pulse sensor have been deduced. A numerical model based on the Poisson-Nernst-Planck-equations was developed to describe the translocation of a nanoparticle through a conical nanopore at a low electrolyte concentration. An additional rectification effect (ICR effect) occurs in the pore beside the conventional volume exclusion effect. An analysis was successfully performed to deconstruct the particle size and particle charge from the pulse height and shape. The material transport is affected by a surface charge on the shrouding material of nanoelectrodes as it was discussed by means of the voltammetric behaviour. The influence of the electrochemical double layer on the current-voltage-curve is particularly large at very small electrodes (< 10 nm) and cannot be neglected even at a high excess of supporting electrolyte. The observed effects were pronounced in unsupported electrolytes, so that they could be clearly detected experimentally at even larger electrodes.

info:eu-repo/classification/ddc/540

ddc:540

Theoretical Study of Voltage-driven Capture and Translocation Through a Nanopore : From Particles to Long Flexible Polymers

Qiao, Le

03 June 2021

Voltage-driven translocation, the core concept of nanopore sensing for biomolecules, has been extensively studied in silico and in vitro over the past two decades. However, the theories of analyte capture are still not complete due to the complex dynamics resulting from the coupling of multiple physical processes such as di usion, electrophoresis, and electroosmotic flow. In this thesis, I build and design translocation simulations for analytes ranging from point-like particles to rod-like molecules and long flexible polymers. The primary goal is to test, clarify and complete the existing capture theories. For example, we revisit and revise the existing definitions of the capture radius, clarify the concept of depletion zones, and investigate the impacts of the flat field near the pore. Earlier theories of translocation underestimate the importance of the electric field out- side the nanopore. In our work, we analyze the non-equilibrium dynamics during the cap- ture process originating from the converging field lines, i.e., rod orientation and polymer deformation. We characterize the rod orientation and quantify its impact on capture time both with and without Electrohydrodynamic interactions. We investigate the polymer chain deformation and calculate the translocation time by taking the electric field outside the nanopore into account as opposed to the conventional simulation approaches. Besides nanopore sensing, there are many undiscovered possibilities for nanopore trans- location technologies. We test two proof-of-concept ideas in which we suggest to use capture and translocation to separate molecules of di erent physical properties. For example, we show how one could selectively capture particles sharing the same mobility but di erent di usion coe cients using a pulsed field. Moreover, we demonstrate that it is possible to build a ratchet using pulsed fields and a nanopore to change the concentration ratios of a polymer mixture of different sized polyelectrolytes.

nanopore

translocation

polymer

separation

Monte Carlo

Langevin Dynamic

Lattice Boltzmann

capture radius

nanopore translocation

electrophoresis

KMC

LMC

LD

LB

DNA

purification

diffusion

orientation

hydrodynamics

ratchet

coarse-grained

capture rate

Translocation de biopolymères à travers des pores naturels ou artificiels / Translocation of biopolymers through biological or artificial nanopores

Auger, Thomas

31 October 2016

La translocation de biopolymères à travers un nanopore intervient dans de nombreux processus biologiques et technologiques, comme le transport nucléocytoplasmique dans le pore nucléaire des cellules eucaryotes, la sécrétion de protéines, le séquençage rapide de l’ADN ou l’électrophorèse capillaire.Nous proposons une technique optique en molécule unique originale pour l’étude de la translocation de biopolymères à travers un nanopore basée sur l’effet Zero-Mode Waveguide. Nous nous sommes intéressés au passage d’ADN double-brin de plusieurs tailles, d’ADN simple-brin et d’ARN, entraînés par un flux à travers une membrane nanoporeuse track-etched. Nous montrons qu’il existe un flux critique régissant le passage des biopolymères indépendant du rayon des pores ainsi que de la taille des biopolymères et de leur nature, conformément aux prédictions théoriques de Brochard et de Gennes.Le pore nucléaire est un nanopore biologique responsable du transport sélectif entre le noyau et lecytoplasme des cellules. Nous avons étudié l’influence de la concentration en importinBeta1 – une protéine nécessaire au transport nucléocytoplasmique – sur l’organisation du canal central du pore nucléaire deXenopus laevis en mesurant la diffusion de molécules de Dextran fluorescentes à travers celui-ci. Nous observons une ouverture du canal central à basse concentration suivi d’un rétrécissement de celui-ci à plus forte concentration. Cette évolution du rayon du canal central avec la concentration en importin Beta1est conforme aux modèles en champ moyen de Opferman et coll. et de Ando et coll. et aux observations expérimentales sur des systèmes reconstitués in vitro de Lim et coll. et Zahn et coll. / The translocation of biopolymers through a nanopore is a feature common to many biological andtechnological processes such as the nucleocytoplasmic transport through the nuclear pore complex(NPC), protein secretion, fast DNA sequencing or capillary electrophoresis.We have developed an original single molecule optical detection technique for the study of biopolymerstranslocation through a nanopore based on the Zero-Mode Waveguide effect. We studied thepassage of double stranded DNA of different sizes, of single stranded DNA and of double-stranded RNAdriven by a flux through track-etched nanoporous membranes. We demonstrate that translocation isgoverned by a critical flux independent of both biopolymer size and nature and of the pore radius inagreement with the theoretical predictions of Brochard and de Gennes.The NPC is a biological nanopore responsible for the selective transport between cytoplasm andnucleus in cells. We studied the influence of importinBeta1 concentration – a protein involved in the nucleocytoplasmictransport – on the structure of the central channel of the NPC of Xenopus laevis byassessing the diffusion of fluorescently labeled Dextran molecules through the NPC. We observe anopening of the central channel at low concentration followed by a shrinking at higher concentrationin importinBeta1 in agreement with mean-field models from Opferman et al. and Ando et al. and withexperiments on biomimetic in vitro systems from Lim et al. and Zahn et al.

Biopolymère

ADN

Pore nucléaire

Nanopore

Molécule unique

Zero Mode Waveguide

Translocation

Flux hydrodynamique

Modèle de succion

Biopolymer

DNA

Nuclear pore complex

Nanopore

Single molecule

Zero Mode Waveguide

Translocation

Flow

Suction model

On-surface synthesis of porous graphene nanoribbons containing nonplanar [14]annulene pores

Ajayakumar, M. R., Di Giovannantonio, Marco, Pignedoli, Carlo A., Yang, Lin, Ruffieux, Pascal, Ma, Ji, Fasel, Roman, Feng, Xinliang

22 January 2024

The precise introduction of nonplanar pores in the backbone of graphene nanoribbon represents a great challenge. Here, we explore a synthetic strategy toward the preparation of nonplanar porous graphene nanoribbon from a predesigned dibromohexabenzotetracene monomer bearing four cove-edges. Successive thermal annealing steps of the monomers indicate that the dehalogenative aryl-aryl homocoupling yields a twisted polymer precursor on a gold surface and the subsequent cyclodehydrogenation leads to a defective porous graphene nanoribbon containing nonplanar [14]annulene pores and five-membered rings as characterized by scanning tunneling microscopy and noncontact atomic force microscopy. Although the C–C bonds producing [14] annulene pores are not achieved with high yield, our results provide new synthetic perspectives for the on-surface growth of nonplanar porous graphene nanoribbons.

info:eu-repo/classification/ddc/530

ddc:530

info:eu-repo/classification/ddc/540

ddc:540

info:eu-repo/classification/ddc/660

ddc:660

Transcriptome Analysis of MRG-1-deficient Caenorhabditis elegans animals using short and long read sequencing

Blume, Alexander

21 July 2022

Das Schicksal einer differenzierten Zelle wird durch epigenetische Grenzen bestimmt und mittels Schutzmechanismen bewahrt, wodurch die Reprogrammierung in andere Zelltypen verhindert wird. In dieser Studie haben wir ein Chromatin-regulierendes Protein, das konservierte MORF4-Verwandte-Gen (MRG) Protein MRG-1, als Barriere für die Reprogrammierung von Zellen in Caenorhabditis elegans (C. elegans) identifiziert. RNAi gegen MRG-1 ermöglicht es uns Keimzellen mittels Überexpression des Neuronen-induzierenden Transkriptionsfaktors CHE-1 in neuronenartige Zellen umzuwandeln. Mittels ChIP-seq fanden wir heraus, dass MRG-1 unterschiedliche DNA Bindungsstellen in den Keimbahnen und somatischen Geweben von C. elegans aufweist. Wir konnten zeigen, dass MRG-1 besonders stark am Genkörper angereichert ist und sich hauptsächlich auf Genen befindet, welche die aktive Histonmarkierung H3K36me3 tragen. Die Charakterisierung der Protein-Protein-Interaktionspartner von MRG-1 mittels Co-IP/MS ergab, dass MRG-1 mit der Histon-H3K9-Methyltransferase SET-26 und der b-gebundenen N-Acetylglucosamin Transferase OGT-1 zusammenarbeitet, um die Umwandlung von Keimzellen in Neuronen zu verhindern. Basierend auf RNA-Seq Experimenten in mrg-1-Mutanten und Wildtyp konnten wir weitreichende Veränderungen der Genexpression mit Auswirkung auf Signalwege wie den Notch Signalweg enthüllen, welcher bekanntermaßen die Zelltyp-Reprogrammierung fördern. Mittels Long-Read basiertem RNA-seq in mrg-1-Mutanten und der Integration entsprechender ChIP-seq Daten habe ich die Beteiligung von MRG-1 am prä-mRNA-Spleißen in C. elegans gezeigt, analog zum Säugetierortholog MRG15. Diese Ergebnisse weisen darauf hin, dass MRG-1 durch die Regulierung des Chromatins und die Sicherstellung des korrekten Spleißens die Expressionsniveaus kritischer Gene und Signalwege aufrechterhält, um eine ordnungsgemäße Keimbahnentwicklung zu gewährleisten und das Schicksal der Keimzellen zu schützen. / Das Schicksal einer differenzierten Zelle wird durch epigenetische Grenzen bestimmt und mittels Schutzmechanismen bewahrt, wodurch die Reprogrammierung in andere Zelltypen verhindert wird. In dieser Studie haben wir ein Chromatin-regulierendes Protein, das konservierte MORF4-Verwandte-Gen (MRG) Protein MRG-1, als Barriere für die Reprogrammierung von Zellen in Caenorhabditis elegans (C. elegans) identifiziert. RNAi gegen MRG-1 ermöglicht es uns Keimzellen mittels Überexpression des Neuronen-induzierenden Transkriptionsfaktors CHE-1 in neuronenartige Zellen umzuwandeln. Mittels ChIP-seq fanden wir heraus, dass MRG-1 unterschiedliche DNA Bindungsstellen in den Keimbahnen und somatischen Geweben von C. elegans aufweist. Wir konnten zeigen, dass MRG-1 besonders stark am Genkörper angereichert ist und sich hauptsächlich auf Genen befindet, welche die aktive Histonmarkierung H3K36me3 tragen. Die Charakterisierung der Protein-Protein-Interaktionspartner von MRG-1 mittels Co-IP/MS ergab, dass MRG-1 mit der Histon-H3K9-Methyltransferase SET-26 und der b-gebundenen N-Acetylglucosamin Transferase OGT-1 zusammenarbeitet, um die Umwandlung von Keimzellen in Neuronen zu verhindern. Basierend auf RNA-Seq Experimenten in mrg-1-Mutanten und Wildtyp konnten wir weitreichende Veränderungen der Genexpression mit Auswirkung auf Signalwege wie den Notch Signalweg enthüllen, welcher bekanntermaßen die Zelltyp-Reprogrammierung fördern. Mittels Long-Read basiertem RNA-seq in mrg-1-Mutanten und der Integration entsprechender ChIP-seq Daten habe ich die Beteiligung von MRG-1 am prä-mRNA-Spleißen in C. elegans gezeigt, analog zum Säugetierortholog MRG15. Diese Ergebnisse weisen darauf hin, dass MRG-1 durch die Regulierung des Chromatins und die Sicherstellung des korrekten Spleißens die Expressionsniveaus kritischer Gene und Signalwege aufrechterhält, um eine ordnungsgemäße Keimbahnentwicklung zu gewährleisten und das Schicksal der Keimzellen zu schützen.

Direkte Reprogrammierung

C. elegans

Long-Reads Sequenzierung

Nanopore Sequenzierung

ChIP-Seq

Spleißen

direct reprogramming

C. elegans

long-read sequencing

nanopore sequencing

ChIP-Seq

splicing

570 Biologie

WE 2600

ddc:570