Global ETD Search

71	THOMSON MICROWAVE SCATTERING FOR DIAGNOSTICS OF SMALL PLASMA OBJECTS ENCLOSED WITHIN GLASS TUBES Apoorv Ranjan (12883115) 16 June 2022 (has links) <p>A specific class of small-scale plasmas (column diameters in a sub-mm to mm range) at rarefied pressures (under 10 Torr) enclosed in glass tubes hold significant interest currently in the scope of tunable plasma devices. Specifically, applications of these plasmas include plasma antennas and plasma photonic crystals. Reliable diagnostics are necessary for the development and implementation of these technologies as conventional tools are inadequate in such small-scale plasmas.</p> <p>Coherent microwave scattering in the Thomson regime (TMS) was recently demonstrated for diagnostics of electron number density in miniature free-standing laser-induced plasmas in air under 10 Torr with plasma column diameters < 0.5 mm. However, measurements by TMS diagnostics have never been applied for small-scale plasma objects enclosed within glass tubes. Additionally, TMS measurements were never independently confirmed with a previously verified experimental technique. This work aims to validate results of TMS measurements for small-scale plasma objects enclosed within glass tubes using the previously established and well-known hairpin resonator probe. A DC discharge plasma column of fairly large diameter (about 1.5 cm) is used in the experiments to ensure reliable non-intrusive measurements by the hairpin resonator probe.</p> <p>The experiments were conducted in a DC discharge tube with a diameter of 1.5 cm and a length of 7 cm. TMS diagnostics yielded electron number densities of about 5.9×10<sup>1</sup><sup>0</sup>cm<sup>-3</sup>, 2.8 ×10<sup>1</sup><sup>0</sup>cm<sup>-3 </sup>and 1.8 ×10<sup>1</sup><sup>0</sup>cm<sup>-3 </sup>at pressures of 0.2, 0.5 and 2.5 Torr, respectively. The corresponding densities measured with the hairpin resonator probe were 4.8×10<sup>1</sup><sup>0</sup>cm<sup>-3</sup>, 3.8 ×10<sup>1</sup><sup>0</sup>cm<sup>-3</sup> and 2.6 ×10<sup>1</sup><sup>0</sup>cm<sup>-3</sup>. Discrepancies between the two techniques were within 30% and can be attributed mainly to inaccuracies in the sheath thickness estimation required the hairpin resonator probe results.</p> Plasma diagnostics Thomson Microwave Scattering Hairpin Resonator Probe weakly ionized plasma glow discharge electron number density
72	Design of an electric motor (PMSM) & manufacturing lab Awawda, Lama January 2021 (has links) The thesis presents deals with the design, analysis, test and control of permanent magnetsynchronous motor(PMSM). An analytical model was carried out based on the d-q frame and the equivalent circuit of PMSM, theanalytical model gives an approximation value of the machine parameters and is carried out byequations from the listed references. this phase includes many iteration steps, once the results wereobtained they were compared with the motor specifications and if they don’t match the requiredspecifications the process must be done again until the desired design is obtained. Once the analytical model is obtained a Finite Element Simulation was carried out using FEMMsoftware to validate the design, in this phase the designed machine in the analytical model isanalyzed and validated, once the simulation is done the results from both models are compared anddiscussed in the results chapter. It’s important to mark that during the design phase some design parameters were affected andlimited by some factors, for example, the air gap length has been magnified due to manufacturinglimits. The manufacturing process and the prototype building have been started once the optimal designwas selected, the manufacturing process was explained and a comparison study was made to selectthe best manufacturing process suitable and available for this thesis. Permanent magnet synchronous machine PMSM Finite element analysis(FEA) FEMM Hairpin winding Motor assembly Prototype
73	Experimental Study of Magnetic Field Effects on Hairpin SNSPD Turn Designs for Single Photon Detection : Investigating the Relationship between Magnetic Field Strength and SNSPD Performance / Experimentell studie av magnetfältseffekter på hairpin-SNSPD-svängkonstruktioner för detektion av enstaka fotoner : Undersökning av sambandet mellan magnetfältsstyrka och SNSPD-prestanda Arthur Sutton, James January 2023 (has links) Superconducting Nanowire Single Photon Detectors (SNSPDs) are a promising technology for detecting single photon emissions with high efficiency and low noise. This detector class has numerous applications in quantum optics, communication, and sensing. One typical design for these devices is the hairpin structure, in which a superconducting nanowire is patterned into a meandering shape. The combination of academic research and interest from the industry is boosting the development of hairpin SNSPD devices to achieve high detection efficiency while maintaining fast response time and low jitter, requiring optimization of the device geometry, materials properties, and sophisticated readout electronics. This thesis qualitatively enquires about different device geometries, varying turn designs and features. Moreover, proposing a promising experimental setup with the potential of being scaled up to simultaneously test numerous devices with a varying magnetic field, driving the hairpin SNSPDs to their detection limit, and enabling further quantitative studies to deepen the understanding of the underlying mechanisms currently hindering the SNSPDs. Analyzing the acquired data draws results regarding the critical current and dark counts trends. Furthermore, at low magnetic field strength, the enquired devices are found to have their critical current enhanced. Moreover, comparisons are drawn among similar design structures. Furthermore, a discussion on manufacturing defects detrimental to the SNSPD performance is initiated. Finally, further studies on this topic adopting the presented method are encouraged to acquire additional quantitative results to be compared with theoretical models describing the thin superconducting structures. / Superconducting Nanowire Single Photon Detectors (SNSPD) är en lovande teknik för att detektera utsläpp av enstaka fotoner med hög effektivitet och lågt brus. Denna detektorkategori har många tillämpningar inom kvantoptik, kommunikation och avkänning. En typisk konstruktion för dessa anordningar är hairpin-strukturen, där en supraledande nanotråd är mönstrad i en slingrande form. Kombinationen av akademisk forskning och intresse från industrin ökar utvecklingen av hairpin-SNSPD-enheter för att uppnå hög detektionseffektivitet med bibehållen snabb responstid och låg jitter, vilket kräver optimering av enhetens geometri, materialegenskaper och sofistikerad avläsningselektronik. I denna avhandling undersöks kvalitativt olika anordningsgeometrier, varierande vridningsdesign och funktioner. Dessutom föreslås en lovande experimentell uppställning med potential att skalas upp för att samtidigt testa många anordningar med ett varierande magnetfält, vilket driver hairpin-SNSPD:erna till sin detektionsgräns och möjliggör ytterligare kvantitativa studier för att fördjupa förståelsen av de underliggande mekanismer som för närvarande hindrar SNSPD:erna. Analysen av de insamlade uppgifterna ger resultat när det gäller den kritiska strömmen och trenderna för mörkertalet. Dessutom visar sig de undersökta enheterna ha en ökad kritisk strömstyrka vid låg magnetfältsstyrka. Dessutom görs jämförelser mellan liknande konstruktionsstrukturer. Dessutom inleds en diskussion om tillverkningsfel som är skadliga för SNSPD:s prestanda. Slutligen uppmuntras ytterligare studier i detta ämne med den presenterade metoden för att få ytterligare kvantitativa resultat som kan jämföras med teoretiska modeller som beskriver tunna supraledande strukturer. SNSPD Hairpin device Magnetic field effect Current crowding SNSPD Hårnålsanordning Magnetfältseffekt Nuvarande trängsel Elektroteknik och elektronik
74	Design of Microwave Front-End Narrowband Filter and Limiter Components Cross, Lee W. 11 July 2013 (has links) No description available. Electromagnetics Electrical Engineering Plasma Physics microwave bandpass filter narrowband half-mode substrate integrated waveguide bent hairpin microstrip plasma limiter frequency selective surface plasma absorber
75	RNA 3D Motifs: Identification, Clustering, and Analysis Petrov, Anton Igorevich 09 April 2012 (has links) No description available. Bioinformatics Biology RNA 3D motifs RNA 3D Motif Atlas RNA 3D Hub clustering RNA 3D motifs internal loops hairpin loops junction loops WebFR3D
76	A Novel Method to Analyze DNA Breaks and Repair in Human Cells Goodman, Caitlin Elizabeth 15 May 2018 (has links) No description available. Biochemistry Molecular Biology Microsatellite DNA Double strand break DSB CTG expanded microsatellite MUS81 EME1 EME2 CTG CAG crossover junction endonuclease trinucleotide repeat replication stress hairpin secondary structure
77	Optimising His-tags for purification and phasing / Optimierte His-tags für Aufreinigung und Phasierung Groβe, Christian 05 October 2010 (has links) No description available. 540 Chemie Chemistry crystal structure peptide his-tag phase problem anomalous dispersion IMAC beta-hairpin Kristallstruktur Peptid His-Tag Phasenproblem anomale Dispersion IMAC beta-Hairpin 35.25 35.62 35 76 SP 000: Strukturchemie SXL 300: Peptide Polypeptide Peptone {Biochemie}
78	Structure Function Studies Of Biologically Important Simple Repetitive DNA Sequences Pataskar, Shashank S. 01 1900 (has links) The recent explosion of DNA sequence information has provided compelling evidence for the following facts. (1) Simple repetitive sequences-microsatellites and minisatellites occur commonly in the human genome and (2) these repetitive DNA sequences could play an important role in the regulation of various genetic processes including modulation of gene expression. These sequences exhibit extensive polymorphism in both length and the composition between species and between organisms of the same species and even cells of the same organism. The repetitive DNA sequences also exhibit structural polymorphism depending on the sequence composition. The functional significance of repetitive DNA is a well-established fact. The work done in many laboratories including ours has conclusively documented the functional role played by repetitive sequences in various cellular processes. Structural studies have established the sequence requirement for various non-B DNA structures and the functional significance of these unusual DNA structures is becoming increasingly clear. The structures that were characterised earlier purely from conformation point of view have aroused interest after the recent realisation that these structures could be formed in vivo when cloned in a supercoiled plasmid. The discovery of novel type of dynamic mutations where intragenic amplifications of trinucleotide repeats is associated with phenotypic changes causing many neurodegenerative disorders has provided the most compelling evidence for the importance of simple repeats in the etiology of these disorders. Secondary structures adopted by these simple repeats is a common causative factor in the mechanism of expansion of these repeats. This realisation prompted many investigations into the relationship between the DNA sequence, structure and molecular basis of dynamic mutation. Many experimental evidences have implicated paranemic DNA structures in various biological processes, especially in the regulation of gene expression. Earlier work done in our laboratory on the structure function relationship of repetitive DNA sequences provided experimental evidence for the role of paranemic DNA structure in the regulation of gene expression. It was demonstrated that intramolecular triplex potential sequences within a gene downregulate its expression in vivo (Sarkar and Brahmachari (1992) Nucleic Acids Res., 20, 5713-5718). Similarly the effect of cruciform structure forming sequences on gene expression was also documented. Sequence specific alterations in DNA structures were studied in our laboratory using a variety of biophysical and biochemical techniques. An intramolecular, antiparallel tetraplex structure was proposed for human telomeric repeat sequences (Balagurumoorthy, et al., (1994) J. Biol. Chem., 269, 21858-21869). The telomeric repeats are not only present at the end of chromosomes but they are also present at many interstitial sites in the human genome. Database search reveals that the human telomeric sequences as well as similar sequences with minor variations are present at many locations in the human genome. Telomeric repeats are GC rich sequences with the G rich strand protruding as a 3' end overhang at the end of chromosomes. When human telomeric repeats are cloned in a supercoiled plasmid, the C rich strand adopts a hairpin like conformation where as the G-rich strand extrudes into a quadruplex structure. However, the biological significance of these structures in vivo still remains to be elucidated completely. The role of a putative tetraplex DNA structure in the insulin gene linked polymorphic region of the human insulin gene in vivo in the regulation of expression of the insulin gene has been suggested. In this context, we have addressed the question whether the telomeric repeats when present within a gene affect its expression in vivol If so, what would be the possible mechanism? An attempt has been made to understand the effect of presence of telomeric repeats within a gene on its expression. The details of these studies have been presented in Chapter 2 of this thesis. Contrary to telomeric repeats which provide stability to the chromosomes, recently expansion of a GC rich dodecamer repeat upstream of cystatin B gene (chromosome 21q) has been shown to be the most common mutation associated with Progressive Myoclonus Epilepsy (EPM1) of Unverricht-Lundberg type. Two to three copies of the repeat (CCCCGCCCCGCG)n are present in normal individuals whereas the affected individuals have 30-75 copies of this repeat. The expression of cystatin B gene is reduced in patients in a cell specific manner. The repeat also shows intergenerational variability. The exact mechanism of expansion of this repeat is not known. In the case of trinucleotide repeat expansion, it is shown that the structure adopted by the repeat plays an important role in the mechanism of expansion and that some of the secondary structures adopted by trinucleotide repeats could be inherently mutagenic conformations. In order to understand the mechanism of expansion EPM1 dodecamer repeat, the work reported in this thesis was carried out with the following objectives. • To understand the structure of G rich and C-rich strands of EPM1 repeat. • To understand the variations in the structure with the increase in the length and its possible implications in the mechanism of expansion of EPM 1 repeat. Studies aimed with these objectives are presented in chapters 3, 4 and 5 of the thesis. Chapter 1 provides a general introduction to repetitive DNA, the various structures adopted by repetitive DNA sequences in the genome, the functional significance of the various simple repetitive DNA sequences in the genome has been presented. An account of trinucleotide repeat expansion and associated disorders, non-trinucleotide repeat expansions and associated disorders has been presented. The various non B-DNA structures adopted these repeats and their implications in the mechanism of expansion have been discussed. Chapter 2 describes in frame cloning of human telomeric repeats d(G3T2A)3G3 in the N-terminal region of β-galactosidase gene. The effect of such repeat Sequences on transcription elongation in vivo has been studied using E.coli as a model system. The 3.5 copies of human telomeric repeat sequences were cloned in the sense strand of plasmid pBluescriptllSK+ so as to create plasmid clone pSBQ8 and in the template strand of plasmid pBluescriptHKS+ so as to create clone pSBRQ8. One dimensional chloroquine gel shift assay indicated presence of an unwound structure in pSBQ8 and pSBRQ8. β-galactosidase activity assay suggested downregulation of the gene in vivo. In the case of plasmid pSBQ8 the difference in β-galactosidase activity was approximately 6 fold as compared to the parent plasmid pBluescriptIISK+ whereas in the case of pSBRQ8 the difference in β-galactosidase activity was approximately 8 fold as compared to the control pBluescriptIIKS+. The analysis of β-galactosidase transcript showed that full length transcript was formed in the case of pSBQ8. Full length transcript was not formed in the case of pSBRQ8. We propose that in the case of pSBQ8 the gene expression is inhibited in steps subsequent to transcription elongation. In the case of pSBRQ8, we propose that quadruplex structure may be formed by the template strand at the DNA level thereby blocking transcription elongation step. Chapter 3 describes studies aimed at understanding the structure of G-rich strand (referred to as G strand) of Progressive Myoclonus Epilepsy (EPM1) repeat. The sequence of the G strand of dodecamer EPM1 repeat is d(GGGGCGGGGCGC)n. Oligoucleotides containing one (12mer), two (24mer) and three(36mer) were synthesised. These oligonucleotides are referred to as dG12, dG24 and dG36 respectively. Structural studies were carried out using CD spectroscopy, UV melting, non-denaturing gel electrophoresis and chemical and enzymatic probing. The G strand oligonucleotides showed enhanced gel elecrophoretic mobility in the presence of monovalent cations KCl and NaCl. Oligonucleotide dG12 also showed retarded species on non-denaturing gel in the presence of 70mM KCl indicating intermolecular associations. Oligonucleotides dG24 and dG36 predominantly formed intramolecular structures which migrated anomalously faster than the expected size. The CD spectrum for dG12 showed an intense positive band at 260nm and a negative band at 240nm in the presence of KCl indicative of an intermolecular, parallel G quartet structure. The CD spectra of dG24 and dG36 showed 260nm positive peak, 240nm negative peak along with a positive band around 290nm. This is indicative of folded back structure. These findings support the results of non-denaturing gel electrophoresis of G strand oligonucleotides. The UV melting profiles suggested increase in the stability with the increase in the length. These structures were further characterised by PI nuclease and chemical probing using DMS and DEPC. The structural studies with G-rich strand of EPM1 dodecamer repeat showed that this repeat motif adopts intramolecularly folded structures with increase in the length of the repeat thereby favouring slippage during replication. Chapter 4 deals with the studies aimed at understanding the structure at acidic pH of C-rich strand (referred to as C strand) of Progressive Myoclonus Epilepsy (EPM1) repeat. The sequence of the C strand of dodecamer EPM1 repeat is d(CCCCGCCCCGCG)n. The C rich oligonucleotides are known to form a four stranded structure called i-motif at acidic pH involving intercalated base pairs. The i-motif consists of two parallel stranded, base paired duplexes are arranged in an antiparallel orientation. Since, the base pairs of one base paired duplex intercalate into those of the other duplex, the structure is called as i-motif. We have investigated structure of C strand of EPM1 repeat by circular dichroism (CD), native polyacrylamide gel electrophoresis and UV melting. Oligonucleotide dC12 showed two bands of which the major band was retarded on the native gel (pH 5.0) at low temperature suggesting that dC12 predominantly formed intermolecular structure, Oligonucleotides dC24 and dC36 migrated anomalously faster than the expected size indicating formation of compact, intramolecularly folded structures. Circular dichroism studies indicate that, all the oligonucleotides displayed an intense positive band near 285nm, a negative band around 260nm with a cross over at 270nm, This is a characteristic CD signature for an i-motif structure and reflects the presence of secondary structure due to formation of hydrogen bonded pairs between protonated cytosines. All the C strand oligonucleotides showed hyperchromism at 265nm, which is an isobestic wavelength for C protonation. Studies described in this chapter suggest an intramolecular i-motif structure for dC24 and dC36 and an intermolecular i-motif for oligonucleotide dC12. In addition, it was interesting to note that inspite of the presence of G residues, the stretch of C residues could adopt i-motif structure. Although these structures are formed at an acidic pH, it is indicative of formation of possible intramolecularly folded structure. Many reports have suggested the possibility of cytosine rich sequences adopting i-motif structure even at neutral pH. In order to test this possibility, structural studies were carried out on the C strand EPM1 oligonucleotides at pH 7.2 in the presence of 70mM NaCl. These studies have been described in Chapter 5. The investigations were done using CD spectroscopy, UV melting, native polyacrylamide gel electrophoresis, and chemical probing using hydroxylamine and PI nuclease. These studies indicate that all the C strand oligonucleotides form intramolecular, hairpin structure at physiological pH. All the three C strand oligonucleotides migrated anomalously faster on the native gel indicating the presence of a compact structure. The CD spectra at pH 7.2 showed a blue shift as compared to those at pH 5.0. This indicated absence of base pairs. The hydroxylamine chemical probing suggested presence of G-C Watson-Crick base pairs. The loop residues of the folded back hairpin structures were probed with PI nuclease. The C strand oligonucleotides showed possibility of formation of multiple hairpin structures with the increase in the length of the repeat. The propensity to form hairpin structures suggests a possibility of formation of slip loop structures during the replication process thereby promoting expansion of this repeat. Formation of folded back hairpin like structures is significant in terms of mechanism of expansion of this repeat. Chapter 6 is devoted to concluding remarks highlighting the significance of the experimental results presented in this thesis and their possible biological implications in the light of contemporary research. Biophysics DNA Structure Genomic Stability Slipped Strand DNA Repetitive Sequences Oligonucleotides Z-DNA Progressive Myoclonus Epilepsy (EPM1) Human Telomeric Repeats Hairpin Genome Gene Expression Dynamic Mutation Slipped Loop Structure i-motif Structure Dynamic Mutation Enhanced Myoclonus Epilepsy
79	DNA Unwinding by Helicases Investigated on the Single Molecule Level Klaue, Daniel 01 November 2012 (has links) (PDF) Each organism has to maintain the integrity of its genetic code, which is stored in its DNA. This is achieved by strongly controlled and regulated cellular processes such as DNA replication, -repair and -recombination. An essential element of these processes is the unwinding of the duplex strands of the DNA helix. This biochemical reaction is catalyzed by helicases that use the energy of nucleoside triphophate (NTP) hydrolysis. Although all helicases comprise highly conserved domains in their amino acid sequence, they exhibit large variations regarding for example their structure, their function and their target nucleic acid structures. The main objective of this thesis is to obtain insight into the DNA unwinding mechanisms of three helicases from two different organisms. These helicase vary in their structures and are involved in different pathways of DNA metabolism. In particular the replicative, hexameric helicase Large Tumor-Antigen (T-Antigen) from Simian virus 40 and the DNA repair helicases RecQ2 and RecQ3 from Arabidopsis thaliana are studied. To observe DNA unwinding by these helicases in real-time on the single molecule level, a biophysical technique, called magnetic tweezers, was applied. This technique allows to stretch single DNA molecules attached to magnetic particles. Simultaneously one can measure the DNA end-to-end distance. Special DNA hairpin templates allowed to characterize different parameters of the DNA unwinding reaction such as the unwinding velocity, the length of unwound DNA (processivity) or the influence of forces. From this mechanistic models about the functions of the helicases could be obtained. T-Antigen is found to be one of the slowest and most processive helicases known so far. In contrast to prokaryotic helicases, the unwinding velocity of T-Antigen shows a weak dependence on the applied force. Since current physical models for the unwinding velocity fail to describe the data an alternative model is developed. The investigated RecQ helicases are found to unwind and close short stretches of DNA in a repetitive fashion. This activity is shown for the first time under external forces. The experiments revealed that the repetitive DNA unwinding is based on the ability of both enzymes to switch from one single DNA strand to the other. Although RecQ2 and RecQ3 perform repetitive DNA unwinding, both enzymes differ largely in the measured DNA unwinding properties. Most importantly, while RecQ2 is a classical helicase that unwinds DNA, RecQ3 mostly rewinds DNA duplexes. These different properties may reflect different specific tasks of the helicases during DNA repair processes. To obtain high spatial resolution in DNA unwinding experiments, the experimental methods were optimized. An improved and more stable magnetic tweezers setup with sub-nanometer resolution was built. Additionally, different methods to prepare various DNA templates for helicase experiments were developed. Furthermore, the torsional stability of magnetic particles within an external field was investigated. The results led to selection rules for DNA-microsphere constructs that allow high resolution measurements. / Jeder Organismus ist bestrebt, die genetischen Informationen intakt zu halten, die in seiner DNA gespeichert sind. Dies wird durch präzise gesteuerte zelluläre Prozesse wie DNA-Replikation, -Reparatur und -Rekombination verwirklicht. Ein wesentlicher Schritt ist dabei das Entwinden von DNA-Doppelsträngen zu Einzelsträngen. Diese chemische Reaktion wird von Helikasen durch die Hydrolyse von Nukleosidtriphosphaten katalysiert. Obwohl bei allen Helikasen bestimmte Aminosäuresequenzen hoch konserviert sind, können sie sich in Eigenschaften wie Struktur, Funktion oder DNA Substratspezifität stark unterscheiden. Gegenstand der vorliegenden Arbeit ist es, die Entwindungsmechanismen von drei verschieden Helikasen aus zwei unterschiedlichen Organismen zu untersuchen, die sich in ihrer Struktur sowie ihrer Funktion unterscheiden. Es handelt sich dabei um die replikative, hexamerische Helikase Large Tumor-Antigen (T-Antigen) vom Simian-Virus 40 und die DNA-Reparatur-Helikasen RecQ2 und RecQ3 der Pflanze Arabidopsis thaliana. Um DNA-Entwindung in Echtzeit zu untersuchen, wird eine biophysikalische Einzelmolekültechnik, die \"Magnetische Pinzette\", verwendet. Mit dieser Technik kann man ein DNA-Molekül, das an ein magnetisches Partikel gebunden ist, strecken und gleichzeitig dessen Gesamtlänge messen. Mit speziellen DNA-Konstrukten kann man so bestimmte Eigenschaften der Helikasen bei der DNA-Entwindung, wie z.B. Geschwindigkeit, Länge der entwundenen DNA (Prozessivität) oder den Einfluß von Kraft, ermitteln. Es wird gezeigt, dass T-Antigen eine der langsamsten und prozessivsten Helikasen ist. Im Gegensatz zu prokaryotischen Helikasen ist die Entwindungsgeschwindigkeit von T-Antigen kaum kraftabhängig. Aktuelle Modelle sagen dieses Verhalten nicht vorraus, weshalb ein alternatives Modell entwickelt wird. Die untersuchten RecQ-Helikasen zeigen ein Entwindungsverhalten bei dem permanent kurze Abschnitte von DNA entwunden und wieder zusammengeführt werden. Dieses Verhalten wird hier zum ersten Mal unter dem Einfluß externer Kräfte gemessen. Es wird gezeigt, dass die permanente Entwindung auf die Fähigkeit beider Helikasen, von einem einzelen DNA-Strang auf den anderen zu wechseln, zurückzuführen ist. Obwohl RecQ2 und RecQ3 beide das Verhalten des permanenten Entwindens aufzeigen, unterscheiden sie sich stark in anderen Eigenschaften. Der gravierendste Unterschied ist, dass RecQ2 wie eine klassische Helikase die DNA entwindet, während RecQ3 eher bestrebt ist, die DNA-Einzelstränge wieder zusammenzuführen. Die unterschiedlichen Eigenschaften könnten die verschieden Aufgaben beider Helikasen während DNA-Reparaturprozessen widerspiegeln. Weiterhin werden die experimentellen Methoden optimiert, um möglichst hohe Auflösungen der Daten zu erreichen. Dazu zählen der Aufbau einer verbesserten und stabileren \"Magnetischen Pinzette\" mit sub-nanometer Auflösung und die Entwicklung neuer Methoden, um DNA Konstrukte herzustellen. Außerdem wird die Torsions\\-steifigkeit von magnetischen Partikeln in externen magnetischen Feldern untersucht. Dabei finden sich Auswahlkriterien für DNA-gebundene magnetische Partikel, durch die eine hohe Auflösung erreicht wird. Biophysik Helikase Magnetische Pinzette Einzelmolekülmethode DNA Entwindung DNA Entwindungsmechanismus T-Antigen RecQ DNA Haarnadelschleife Biophysics Helicase Magnetic tweezers Single-molecule method DNA unwinding DNA unwinding mechanism T-Antigen RecQ DNA Hairpin ddc:570 rvk:WD 3100 rvk:WD 5360
80	X-ray Crystallographic Studies Of Designed Peptides : Characterization Of Helices And B-Hairpins Aravinda, S 02 1900 (has links) (PDF) No description available. X-ray Crystallography Peptides - X-ray Crystallography Peptides - Helices Peptides - B-Hairpins Designed Peptides Polypeptide Helices Peptide Helices Peptide Helix Helical Peptide Scaffolds Peptide Design beta-Hairpin Peptides Gabapentin Biochemistry

Search results