DNA block copolymers – from micelles to machines

DNA block copolymer, a new class of hybrid material composed of a synthetic polymer and an oligodeoxynucleotide segment, owns unique properties which can not be achieved by only one of the two polymers. Among amphiphilic DNA block copolymers, DNA-b-polypropylene oxide (PPO) was chosen as a model system, because PPO is biocompatible and has a Tg < 0 °C. Both properties might be essential for future applications in living systems. During my PhD study, I focused on the properties and the structures of DNA-b-PPO molecules. First, DNA-b-PPO micelles were studied by scanning force microscopy (SFM) and fluorescence correlation spectroscopy (FCS). In order to control the size of micelles without re-synthesis, micelles were incubated with template-independent DNA polymerase TdT and deoxynucleotide triphosphates in reaction buffer solution. By carrying out ex-situ experiments, the growth of micelles was visualized by imaging in liquid with AFM. Complementary measurements with FCS and polyacrylamide gel electrophoresis (PAGE) confirmed the increase in size. Furthermore, the growing process was studied with AFM in-situ at 37 °C. Hereby the growth of individual micelles could be observed. In contrast to ex-situ reactions, the growth of micelles adsorbed on mica surface for in-situ experiments terminated about one hour after the reaction was initiated. Two reasons were identified for the termination: (i) block of catalytic sites by interaction with the substrate and (ii) reduced exchange of molecules between micelles and the liquid environment. In addition, a geometrical model for AFM imaging was developed which allowed deriving the average number of mononucleotides added to DNA-b-PPO molecules in dependence on the enzymatic reaction time (chapter 3). Second, a prototype of a macroscopic DNA machine made of DNA-b-PPO was investigated. As DNA-b-PPO molecules were amphiphilic, they could form a monolayer at the air-water interface. Using a Langmuir film balance, the energy released owing to DNA hybridization was converted into macroscopic movements of the barriers in the Langmuir trough. A specially adapted Langmuir trough was build to exchange the subphase without changing the water level significantly. Upon exchanging the subphase with complementary DNA containing buffer solution, an increase of lateral pressure was observed which could be attributed to hybridization of single stranded DNA-b-PPO. The pressure versus area/molecule isotherms were recorded before and after hybridization. I also carried out a series of control experiments, in order to identify the best conditions of realizing a DNA machine with DNA-b-PPO. To relate the lateral pressure with molecular structures, Langmuir Blodgett (LB) films were transferred to highly ordered pyrolytic graphite (HOPG) and mica substrates at different pressures. These films were then investigated with AFM (chapter 4). At last, this thesis includes studies of DNA and DNA block copolymer assemblies with AFM, which were performed in cooperation with different group of the Sonderforschungsbereich 625 “From Single Molecules to Nanoscopically Structured Materials”. AFM was proven to be an important method to confirm the formation of multiblock copolymers and DNA networks (chapter 5).

The study of a novel zinc finger gene cluster TZF and a genomic region flanking the histone H 4 replacement gene H 4 r of Drosophila melanogaster

Part I : A zinc finger gene Tzf1 was cloned in the earlier work of the lab by screening a ë-DASH2 cDNA expression library with an anti-Rat SC antibody. A ë-DASH2 genomic DNA library and cosmid lawrist 4 genomic DNA library were screened with the cDNA fragment of Tzf1 to determine the genomic organization of Tzf1. Another putative zinc finger gene Tzf2 was found about 700 bp upstream of Tzf1.RACE experiment was carried out for both genes to establish the whole length cDNA. The cDNA sequences of Tzf and Tzf2 were used to search the Flybase (Version Nov, 2000). They correspond to two genes found in the Flybase, CG4413 and CG4936. The CG4413 transcript seems to be a splicing variant of Tzf transcripts. Another two zinc finger genes Tzf3 and Tzf4 were discovered in silico. They are located 300 bp away from Tzf and Tzf2, and a non-tandem cluster was formed by the four genes. All four genes encode proteins with a very similar modular structure, since they all have five C2H2 type zinc fingers at their c-terminal ends. This is the most compact zinc finger protein gene cluster found in Drosophila melanogaster.Part II: 34,056 bp insert of the cosmid 19G11

Thin functional conducting polymer films

In the present study, thin functional conducting polyaniline (PANI) films, either doped or undoped, patterned or unpatterned, were prepared by different approaches. The properties of the obtained PANI films were investigated in detail by a combination of electrochemistry with several other techniques, such as SPR, QCM, SPFS, diffraction, etc. The sensing applications (especially biosensing applications) of the prepared PANI films were explored. Firstly, the pure PANI films were prepared by the electropolymerisation method and their doping/dedoping properties in acidic conditions were investigated in detail by a combination of electrochemistry with SPR and QCM. Dielectric constants of PANI at different oxidation states were obtained quantitatively. The results obtained here laid a good foundation for the following investigations of PANI films in neutral pH conditions. Next, PANI multilayer films doped by a variety of materials were prepared by the layer-by-layer method in order to explore their biosensing applications, because of the loss of redox activity of pure PANI in neutral pH conditions. The dopants used include not only the traditionally used linear polyelectrolytes, but also, for the first tim, some other novel materials, like modified gold nanoparticles or modified carbon nanotubes. Our results showed that all the used dopants could form stable multilayer films with PANI. All the obtained PANI multilayer films showed good redox activity in a neutral pH environment, which makes them feasible for bioassays. We found that all the prepared PANI multilayer films can electrocatalyze the oxidation of NADH in neutral conditions at a low potential, although their catalytic efficiencies are different. Among them, PANI/carbon nanotube system showed the highest catalytic efficiency toward the oxidation of NADH, which makes it a good candidate as a NADH sensor. Besides, because some of the prepared PANI multilayer systems were end-terminated with –COOH groups (like PANI/Au nanoparticles system), which can be utilized to easily link biomolecules for biosensing applications. Here, we demonstrated, for the first time, to use the prepared PANI multilayer films for the DNA hybridisation detection. The detection event was monitored either by direct electrochemical method, or by enzyme-amplified electrochemical method, or by surface plasmon enhanced fluorescence spectroscopic method. All the methods can effectively differentiate non-complementary DNA from the complementary ones, even at the single-base mismatch level. It should also be noted that, our success in fabricating PANI multilayer films with modified Au nanoparticles or carbon nanotubes also offered another novel method for incorporating such novel materials into (conducting) polymers. Because of the unique electrochemical and optical properties of each component of the obtained PANI multilayer films, they should also find potential applications in many other fields such as microelectronics, or for electrochromic and photovoltaic devices. Finally, patterned PANI films were fabricated by the combination of several patterning techniques, such as the combination of electrocopolymerization with micromolding in capillaries (EP-MIMIC), the combination of microcontact printing with the layer-by-layer technique (µCP-LBL), and the polystyrene (PS) template induced electropolymerisation method. Using the obtained stripe-shaped PANI/PSS film, a redox-switchable polymer grating based on the surface-plasmon-enhanced mode was constructed and its application in the field of biosensing was explored. It was found that the diffraction efficiency (DE) of the grating was very sensitive to the applied potential (i.e. redox state of the film) as well as the pH environment of the dielectric medium. Moreover, the DE could also be effectively tuned by an electrocatalytic event, such as the electrocatalytic oxidation of NADH by the grating film. By using PS colloidal crystal assemblies as templates, well-ordered 3D interconnected macroporous PANI arrays (PANI inverse opals) were fabricated via electropolymerisation method. The quality of the obtained inverse opals was much higher than those reported by chemical synthesis method. By electrochemical method, the structures of the prepared inverse opals can be easily controlled. To explore the possible biosensing applications of PANI inverse opals, efforts were also done toward the fabrication of PANI composite inverse opals. By selecting proper dopants, high quality inverse opals of PANI composites were fabricated for the first time. And the obtained opaline films remained redox-active in neutral pH conditions, pointing to their possible applications for electrobioassays.

Mass spectrometric identification of Varicella-Zoster Virus (VZV) proteins recognized by human T cells

Primary varicella-zoster virus (VZV) infection during childhood leads to varicella commonly known as chickenpox. After primary infection has occurred VZV establishes latency in the host. During subsequent lifetime the virus can cause reactivated infection clinically known as herpes zoster or shingles. In immunodeficient patients’ dissemination of the virus can lead to life-threatening disease. Withdrawal of acyclovir drug prophylaxis puts allogeneic hematopoietic stem-cell transplantation (HSCT) patients at increased risk for herpes zoster as long as VZV-specific cellular immunity is impaired. Although an efficient live attenuated VZV vaccine for zoster prophylaxis exists, it is not approved in immunocompromised patients due to safety reasons. Knowledge of immunogenic VZV proteins would allow designing a noninfectious nonhazardous subunit vaccine suitable for patients with immunodeficiencies. The objective of this study was to identify T cell defined virus proteins of a VZV-infected Vero cell extract that we have recently described as a reliable antigen format for interferon-gamma (IFN-γ) enzyme-linked immunosorbent spot (ELISpot) assays (Distler et al. 2008). We first separated the VZV-infected/-uninfected Vero cell extracts by size filtration and reverse-phase high performance liquid chromatography (RP-HPLC). The collected fractions were screened for VZV reactivity with peripheral blood mononuclear cells (PBMCs) of VZV-seropositive healthy individuals in the sensitive IFN-γ ELISpot assay. Using this strategy, we successfully identified bioactive fractions that contained immunogenic VZV material. VZV immune reactivity was mediated by CD4+ memory T lymphocytes (T cells) of VZV-seropositive healthy individuals as demonstrated in experiments with HLA blockade antibodies and T cell subpopulations already published by Distler et al. We next analyzed the bioactive fractions with electrospray ionization mass spectrometry (ESI-MS) techniques and identified the sequences of three VZV-derived proteins: glycoprotein E (gE); glycoprotein B (gB), and immediate early protein 62 (IE62). Complementary DNA of these identified proteins was used to generate in vitro transcribed RNA for effective expression in PBMCs by electroporation. We thereby established a reliable and convenient IFN-γ ELISPOT approach to screen PBMCs of healthy donors and HSCT patients for T cell reactivity to single full-length VZV proteins. Application in 10 VZV seropositive healthy donors demonstrated much stronger recognition of glycoproteins gE and gB compared to IE62. In addition, monitoring experiments with ex vivo PBMCs of 3 allo-HSCT patients detected strongly increased CD4+ T cell responses to gE and gB for several weeks to months after zoster onset, while IE62 reactivity remained moderate. Overall our results show for the first time that VZV glycoproteins gE and gB are major targets of the post-transplant anti-zoster CD4+ T cell response. The screening approach introduced herein may help to select VZV proteins recognized by memory CD4+ T cells for inclusion in a subunit vaccine, which can be safely used for zoster prophylaxis in immunocompromised HSCT patients.

Synthese und Charakterisierung biologischer Hybridpolymere zur gentechnologischen Anwendung

KurzfassungrnrnZiel der vorliegenden Arbeit war es eine gezielte, hochspezifische Inhibierung der Proteinbiosynthese zu erreichen. Dies kann durch eine Blockierung des mRNA-Strangs durch komplementäre DNA/RNA-Stränge (ähnlich zur Antisense-Methode) oder durch die Hydrolyse des mRNA-Strangs mit Hilfe spezieller Enzyme (RNasen) realisiert werden. Da jedoch beide Methoden nicht zu zufriedenstellenden Ergebnissen führen, wäre deshalb eine Kombination aus beiden Methoden ideal, welche in einer spezifischen, gezielten und permanenten Ausschaltung der Proteinbiosynthese resultieren würde. Um dieses Ziel zu verwirklichen, ist es nötig, ein Molekül zu synthetisieren, welches in der Lage ist selektiv an einer spezifischen Position an den RNA-Strang zu hybridisieren und anschließend den RNA-Strang an dieser zu hydrolysieren. Der große Vorteil dieses Konzepts liegt darin, dass die DNA-Sequenz für die Hybridisierung an die entsprechende RNA maßgeschneidert hergestellt werden kann und somit jede RNA gezielt angesteuert werden kann, was letztendlich zu einer spezifischen Inhibierung der korrespondierenden Proteinbiosynthese führen soll.rnDurch die Verwendung und Optimierung der Nativen Chemischen Ligation (NCL) als Konjugationsmethode konnten zwei Biomakromoleküle in Form einer 46-basenlangen DNA (komplementär zum RNA-Strang) und einer 31-aminosäurelangen RNase kovalent verknüpft werden. Durch unterschiedliche chemische und molekularbiologische Analysemethoden, wie PAGE, GPC, CE, MALDI-ToF-MS etc., war es zudem möglich, die erfolgreiche Synthese dieses biologischen Hybridpolymers als monodisperses, reines Produkt zu bestätigen. rnDie Synthese des ca. 800-basenlangen RNA-Strangs, der als Modell-Matrize für die selektive und spezifische Degradierung durch das DNA-RNase-Konjugat dienen sollte, konnte unter Zuhilfenahme gentechnologischer Standard-Methoden erfolgreich bewerkstelligt werden. Weiterhin konnte durch die Verwendung der radioaktiven cDNA-Synthese gezeigt werden, dass das DNA-RNase-Konjugat an die gewünschte Stelle des RNA-Strangs hybridisiert. Die Identifizierung einer anschließenden spezifischen Hydrolyse des RNA-Strangs durch die an den DNA-Strang angeknüpfte RNase war aufgrund der geringen katalytischen Aktivität des Enzyms bisher allerdings nicht möglich.rn

DNA-Array-Technologie

Es wurde ein genomischer DNA-Array der Modellpflanze Arabidopsis thaliana mit einer 13.800 EST-Klone umfassenden cDNA-Bibliothek entwickelt und in der Genexpressionsanalyse der pflanzlichen Pathogenabwehr eingesetzt. Mittels PCR-Amplifikation sind 13.000 PCR-Produkte der cDNA-Fragmente hergestellt worden, mit denen 66 genomische Arabidopsis-Arrays auf Nylon und Polypropylen als Trägermaterial hergestellt werden konnten. Die Validierung mit Fluoreszenz- und Radiaktivhybridisierung sowie der Vergleich von drei Normalisierungsmethoden führte zu reproduzierbaren Ergebnissen bei hohem Korrelationskoeffizienten. Die etablierte DNA-Array-Technologie wurde zur Genexpressionsanalyse der pathogeninduzierten Abwehrmechanismen der Pflanze Arabidopsis thaliana in den ersten 24 Stunden nach Infektion mit dem avirulenten Bakterium Pseudomonas syringae pv. tomato eingesetzt. In einer Auswahl von 75 Genen der Stoffwechselwege Glycolyse, Citrat-Cyclus, Pentosephosphat-Cyclus und Glyoxylatmetabolismus konnte für 25 % der Gene, im Shikimat-, Tryptophan- und Phenylpropanoidsyntheseweg für 60 % der Gene eine erhöhte Transkriptionsrate nachgewiesen werden. Die Ergebnisse dieser Arbeit stimmen mit experimentellen Daten verschiedener unabhängiger Studien zur pflanzlichen Pathogenantwort überein. Darüberhinaus sind erstmals Transkriptionsprofile von bisher auf Transkriptionsebene nicht untersuchten Genen erstellt worden. Diese Ergebnisse bestätigen die transkriptionelle Aktivierung ganzer Stoffwechselwege und gewähren erstmals einen Einblick in die koordinierte differentielle Transkription ganzer Stoffwechselwege während der Pathogenabwehr.

DNA-Polymer-Hybride als molekulare Bausteine

Die DNA hat sich durch die herausstechende Eigenschaft zur Selbstorganisation in den Naturwissenschaften zu einem beliebten Werkzeug entwickelt. In dieser Arbeit wurde die Oligonukleotidselbsterkennung zum Aufbau komplexer Multiblockcopolymere genutzt. Dabei dienten komplementäre einzelsträngige Oligonukleotidsequenzen (ssDNA) als adressierbare Verbindungsstücke zwischen synthetischen Blöcken. Als Bausteine wurden asymmetrische Dreiblockcopolymere der Form DNA1-Polymer-DNA2 aus einer flexiblen Polymereinheit (PEO bzw. PPO) die an beiden Enden mit unterschiedlichen Oligonukleotidsequenzen „funktionalisiert“ ist, verwendet. Diese Bausteine konnten durch die Kombination von Festphasensynthese der Oligonukleotide und Blockkopplung dargestellt werden. Die Oligonukleotidsequenzen wurden so gewählt, dass deren Hybridisierung zu einer bei Raumtemperatur stabilen Verbindung führt. Durch die Verwendung dieser Bausteine erhält man ein modulares System, dass sich durch seine hohe Flexibilität auszeichnet. Aus den dargestellten Dreiblockcopolymeren konnten verschiedene alternierende Multiblockcopolymere aufgebaut werden, wobei die Anzahl der Blöcke (von 11 bis 15) und das PEO / PPO- Verhältnis variiert wurden. Derartige Strukturen sind auf der Grundlage chemischer Synthesen unerreichbar. Die Flexibilität dieses modularen Systems konnte gezeigt werden, indem einzelne Blockbausteine zur Strukturaufklärung einfach ausgetauscht oder weggelassen werden konnten. Durch geeignete Wahl der DNA-Sequenzen konnte zusätzlich das Polymerisationsverhalten dieser Bauelemente untersucht werden. Die Integration längerer kettensteifer DNA-Abschnitte in die Multiblockstrukturen erfolgte durch die Verwendung teilkomplementärer Oligonukleotide. Diese bieten den Vorteil, dass bis zu einer Größe von etwa 150 bp sowohl die Länge als auch die Sequenz der Doppelstrangabschnitte und sticky-ends frei variiert werden können. Die biosynthetischen Dreiblockcopolymere dienten hier als Linkermoleküle zwischen den einzelnen dsDNA-Blöcken. Nach diesem Konzept wurde ein Nonamer als Modellsystem eines mehrfach gebrochenen Stäbchens synthetisiert. Außerdem wurden mit Hilfe der Polymerase Kettenreaktion (PCR) semiflexible DNA Abschnitte erzeugt. Durch die Wahl des Synthesewegs konnte sowohl die Länge der semiflexiblen Einheit als auch die Länge und die Sequenz des sticky-ends variiert werden. Anhand dieser Modellverbindungen wurde dann das Hybridisierungsverhalten in Abhängigkeit der Linker- und Segmentlängen untersucht.

Investigations into the effect of nucleoside modifications on the physicochemical properties and biological function of DNA and RNA

This thesis explores the effect of chemical nucleoside modification on the physicochemical and biological properties of nucleic acids. Positional alteration on the Watson-Crick edge of purines and pyrimidines, the “C-H” edge of pyrimidines, as well as both the Hoogsteen and sugar edges of purines were attempted by means of copper catalyzed azide-alkyne cycloaddition. For this purpose, nucleic acid building blocks carrying terminal alkynes were synthesized and introduced into oligonucleotides by solid-phase oligonucleotide chemistry. rnOf particular interest was the effect of nucleoside modification on hydrogen bond formation with complementary nucleosides. The attachment of propargyl functionalities onto the N2 of guanosine and the N4 of 5-methylcytosine, respectively, followed by incorporation of the modified analogs into oligonucleotides, was successfully achieved. Temperature dependent UV-absorption melting measurements with duplexes formed between modified oligonucleotides and a variety of complementary strands resulted in melting temperatures for the respective duplexes. As a result, the effect that both the nature and the site of nucleoside modification have on base pairing properties could thus be assisted. rnTo further explore the enzymatic recognition of chemically modified nucleosides, the oligonucleotide containing the N2-modified guanosine derivative on the 5’-end, which was clicked to a fluorescent dye, was subjected to knockdown analyses of the eGFP reporter gene in the presence of increasing concentrations of siRNA duplexes. From these dose-dependent experiments, a clear effect of 5’-labeling on the knockdown efficiency could be seen. In contrast, 3’-labeling was found to be relatively insignificant.rn