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111	The Role of Saccharomyces Cerevisiae MRX Complex and Sae2 in Maintenance of Genome Stability Ghodke, Indrajeet Laxman January 2015 (has links) (PDF) In eukaryotes, the repair of DSBs is accomplished through two broadly defined processes: Non-Homologous End Joining (NHEJ) and Homologous Recombination (HR). The central step of HR is pairing and exchange of strands between two homologous DNA molecules, which is catalyzed by the conserved Rad51/RecA family of proteins. Prior to this step, an essential step in all HR pathways i.e. 5'→3' resection of broken DNA ends to generate 3' single stranded DNA tails. At the molecular level, initiation of DNA end resection is accomplished through the concerted action of MRX complex (Mre11, Rad50 and Xrs2) and Sae2 protein. To elucidate the molecular basis underlying DSB end resection in S. cerevisiae mre11 nuclease deficient mutants, we have performed a comprehensive analysis of the role of S. cerevisiae Mre11 (henceforth called as ScMre11) in the processing of DSB ends using a variety of DNA substrates. We observed that S. cerevisiae Mre11(ScMre11) exhibits higher binding affinity for single- over double-stranded DNA and intermediates of recombination and repair and catalyzes robust unwinding of substrates possessing a3' single-stranded DNA overhang but not of 5' overhangs or blunt-ended DNA fragments. Furthermore, reconstitution of DSB end resection network in-vitro revealed that Rad50, Xrs2, and Sae2 potentiated the DNA unwinding activity of Mre11. Since the exonuclease activity of Mre11 is of the opposite polarity to that expected for resection of DSBs, unwinding activity of Mre11 in conjunction with Rad50, Xrs2, and Sae2 might provide an alternate mechanism for the generation of ssDNA intermediates for DSB end repair and HR. Additionally, ScMre11 displays strong homotypic as well as heterotypic interaction with Sae2. In summary, our results revealed important insights into the mechanism of DSB end processing and support a model in which Sae2, Rad50, and Xrs2 positively regulate the ScMre11-mediated DNA unwinding activity via their direct interactions or through allosteric effects on the DNA or cofactors. Prompted by the closer association of MRX and Sae2 during DSB end processing, we asked whether Sae2 and its endonuclease activity is required for cellular response to replication stress caused by DNA damage. Toward this end, we examined the sensitivity of S. cerevisiae wild type, sae2Δ and various SAE2 mutant strains defective in phosphorylation and nuclease activity in the presence of different genotoxic agents, which directly or indirectly generate DSBs during replication. We found that S. cerevisiae lacking SAE2 show decreased cell viability, altered cell cycle dynamics after DNA damage, and more specifically, that Sae2 endonuclease activity is essential for these biological functions. To corroborate the genetic evidences for role of SAE2 during replicative stress, we investigated SAE2 functions in-vitro. For this, we purified native Sae2 protein and nuclease dead mutant of Sae2 i.e. sae2G270D. Our studies revealed dimeric forms of both the wild type and mutant forms of Sae2. Furthermore, Sae2 displays higher binding affinity and catalytic activity with branched DNA structures, such as Holliday junction and replication forks. By using nuclease dead Sae2 protein i.e. sae2G270D, we confirmed that the endonuclease activity is not fortuitous and is intrinsic to Sae2 polypeptide. Furthermore, nuclease-defective Mre11 stimulates Sae2endonuclease activity. Mapping of the cleavage sites of Sae2 revealed a distinct preference for cleavage on the 5' end of the Holliday junction, suggesting the importance of Sae2 nuclease during recombination mediated restart of the reversed replication fork. In summary, our data clearly demonstrate a previously uncharacterized role for Sae2 nuclease activity in resection of DSB ends, processing of intermediates of DNA replication/repair and attenuation of DNA replication stress-related defects in S. cerevisiae. Saccharomyces Cerevisiae MRX Complex Genome Stability DNA Repair DNA Damage DNA Double Strand Break Non Homologous End Joining Homologous Recombination Saccharomyces Cerevisiae Sae2 DNA Replication DNA Double Stranded Breaks Repair Sae2 Protein Saccharomyces cerevisiae Mre11 Biochemistry
112	Structural Studies On Mycobacterial Proteins Saikrishnan, K 01 1900 (has links) (PDF) No description available. Mycobacterial Proteins Mycobacterium Tuberculosis DNA-Binding Protein Protein X-ray Crystallography Ribosome Recycling Factor (RRF) Protein Synthesis M. tuberculosis Structure Molecular Plastlclty Structural Plasticity MtSSB Bacteriology
113	Uracil DNA Glycosylase From Mycobacteria And Escherichia coli : Mechanism Of Uracil Excision From Synthetic Substrates And Differential Interaction With Uracil DNA Glycosylase Inhibitor (Ugi) And Single Stranded DNA Binding Proteins (SSBs) Padmakar, Purnapatre Kedar. 03 1900 (has links) (PDF) No description available. DNA Damage DNA Repair Protein Binding Escherichia Coli - Genetics Mycobacterium Uracil DNA Glycosylase (UDG) Uracil DNA Glycosylase Inihibitor Myrobacterium smegmatis Myrobacterium tubercuiosis E. coli M. smegmatis Biochemical Genetics
114	Studies On The Mechanism Of Uracil Excision Repair In Escherichia Coli And Structure-Function Relationship Of Single Stranded DNA Binding Proteins From Escherichia Coli And Mycobacterium Tuberculosis Bharti, Sanjay Kumar 05 1900 (has links) (PDF) To maintain the genomic integrity, cell has evolved various DNA repair pathways. Base Excision Repair pathway (BER) is one such DNA repair pathway which is dedicated to protect DNA from small lesions such as oxidation, alkylation, deamination and loss of bases. Uracil is a promutagenic base which appears in the genome as a result of misincorporation of dUTP or due to oxidative deamination of cytosine. Uracil-DNA glycosylases (UDGs) are DNA repair enzymes that initiate multistep base excision repair (BER) pathway to excise uracil from DNA. Excision of uracil generates an abasic site (APDNA). AP-sites are cytotoxic and mutagenic to the cell. AP endonucleases act downstream to UDG in this pathway and generate substrates for DNA polymerase to fill in the correct bases. The cytotoxicity of AP-sites raises the question whether uracil excision activity is coupled to AP endonuclease activity. Also, there is transient formation of single stranded DNA (ssDNA) during DNA metabolic processes such as replication, repair and recombination. ssDNA is more prone to various nucleases and DNA damaging agents. All the living organisms encode single stranded DNA binding protein (SSB) that binds to ssDNA and protects it from various damages. In addition, SSB plays a vital role during DNA replication, repair and recombination. Studies on SSBs from prototype Escherichia coli and an important human pathogen, Mycobacterium tuberculosis have shown that despite significant variations in their quaternary structures, the DNA binding and oligomerization properties of the two are similar. My PhD thesis consists of four Chapters. Chapter 1 summarizes the relevant literature review on DNA damage and repair with an emphasis on uracil DNA glycosylase and its interacting protein, SSB. Chapters 2 and 3 describe my studies on the mechanism of uracil excision repair in E. coli. Chapter 4 describes my findings on the structure-function relationship of single stranded DNA binding proteins from E. coli and M. tuberculosis. Specific details of my research are summarized as follows: (1) Analysis of the impact of allelic exchange of ung with a mutant gene encoding Uracil DNA Glycosylase attenuated in AP-DNA binding in the maintenance of genomic integrity in Escherichia coli. There are five families of UDGs. Of these, Ung proteins (family 1 UDGs) represent highly efficient and evolutionary conserved enzymes. Structural and biochemical analysis of Ung proteins has identified two conserved motif, motif A (62GQDPY66) and motif B (187HPSPLS192) in E. coli that are important for the catalysis by Ung enzyme. Y66 of motif A is in van der Waals contact with the C5 position of the uracil and prevents entry of other bases. Earlier study from the laboratory showed that the Y66W and Y66H mutants of Ung were compromised by ~7 and ~170 fold, respectively in their uracil excision activities. However, unlike the wild-type and Y66H proteins, Y66W was not inhibited by its product (uracil or AP-DNA). In this study, by fluorescence anisotropy measurements I have shown that compared with the wild-type protein, the Y66W mutant is moderately compromised and attenuated in binding to AP-DNA. Allelic exchange of ung in E. coli with ung::kan, ungY66H:amp or ungY66W:amp alleles showed ~5, ~3.0 and ~2.0 fold, respectively increase in mutation frequencies. Analysis of mutations in the rifampicin resistance determining region (RRDR) of rpoB revealed that the Y66W allele resulted in an increase in A to G (or T to C) mutations. However, the increase in A to G mutations was mitigated upon expression of wild-type Ung from a plasmid borne gene. Biochemical and computational analyses showed that the Y66W mutant maintains strict specificity for uracil excision from DNA. Interestingly, a strain deficient in AP-endonucleases also showed an increase in A to G mutations. These findings have been discussed in the context of a proposal that the residency of DNA glycosylase(s) onto the AP-sites they generate shields them until recruitment of AP-endonucleases for further repair. It is proposed that an error prone replication against AP-sites (as a result of uracil excision activities on A:U pair) may result in A to G mutations. 2. Mechanism of appearance of A to G mutations in ungY66W:amp strain of Escherichia coli. In this part of my study, I have investigated the role of error prone DNA polymerases in the mutational specificity of ungY66W:amp strain. It was observed from various studies in E. coli that, DNA polymerase IV (Pol IV) and DNA polymerase V (Pol V) are involved in error-prone replication on damaged or AP-site containing DNA. E. coli strains containing deletion of either dinB (encoding DNA Pol IV) or umuDC (encoding DNA Pol V) were generated and used to study mutation frequency and mutation spectrum. Deletion of DNA Pol V resulted in a decrease in A to G mutations in ungY66W:amp E. coli strain, suggesting that increase in A to G mutations were a consequence of error prone incorporation by DNA Pol V. 3. Structure and Function studies on Single Stranded DNA Binding Proteins from Escherichia coli and Mycobacterium tuberculosis. SSB from M. tuberculosis (MtuSSB) has similar domain organization as the EcoSSB. Moreover, the biochemical properties such as oligomerization, DNA binding affinity and minimum binding site size requirements were shown to be similar to EcoSSB. However, structural studies suggested that quaternary structures of these two SSBs are variable. In this study I have used X-ray crystal structure information of these two SSBs to generate various chimeras after swapping at various regions of SSBs. Chimeras mβ1, mβ1’β2, mβ1-β5, mβ1-β6, and mβ4-β5 SSBs were generated by substituting β1 (residues 611), β1’β2 (residues 21-45), β1-β5 (residues 1 to 111), β1-β6 including a downstream sequence (residues 1 to 130), and β4-β5 (residues 74-111) regions of EcoSSB with the corresponding sequences of MtuSSB, respectively. Additionally, mβ1’β2ESWR SSB was generated by mutating the MtuSSB specific ‘PRIY’ sequence in the β2 strand of mβ1’β2 SSB to EcoSSB specific ‘ESWR’ sequence. Biochemical characterization revealed that except for mβ1 SSB, all chimeras and a control construct lacking the C-terminal domain (ΔC SSB) efficiently bound DNA in modes corresponding to limited and unlimited modes of binding. The mβ1 SSB was also hypersensitive to chymotrypsin treatment. The mβ1-β6, MtuSSB, mβ1’β2 and mβ1-β5 constructs complemented E. coli Δssb in a dose dependent manner. Complementation by the mβ1-β5 SSB was poor. In contrast, mβ1’β2ESWR SSB complemented E. coli as well as EcoSSB. Interestingly, the inefficiently functioning SSBs resulted in an elongated cell/filamentation phenotype of E. coli. Taken together, our observations suggest that specific interactions within the DNA binding domain of the homotetrameric SSBs are crucial for their biological function. DNA Binding Proteins Escherichia coli Mycobacterium tuberculosis DNA Repair Uracil DNA Glycosylase (UDG) Single Stranded DNA Binding Proteins DNA Damage DNA Polymerases ungY66W:amp Strain Uracil Excision Repair Uracil DNA-Glycosylase Inhibitor (Ugi) DNA Glycosylases Biochemistry
115	Elasticity And Structural Phase Transitions Of Nanoscale Objects Mogurampelly, Santosh 09 1900 (has links) (PDF) Elastic properties of carbon nanotubes (CNT), boron nitride nanotubes (BNNT), double stranded DNA (dsDNA), paranemic-juxtapose crossover (PX-JX) DNA and dendrimer bound DNA are discussed in this thesis. Structural phase transitions of nucleic acids induced by external force, carbon nanotubes and graphene substrate are also studied extensively. Electrostatic interactions have a strong effect on the elastic properties of BNNTs due to large partial atomic charges on boron and nitrogen atoms. We have computed Young’s modulus (Y ) and shear modulus (G) of BNNT and CNT as a function of the nanotube radius and partial atomic charges on boron and nitrogen atoms using molecular mechanics calculation. Our calculation shows that Young’s modulus of BNNTs increases with increase in magnitude of the partial atomic charges on B and N atoms and can be larger than the Young’s modulus of CNTs of same radius. Shear modulus, on the other hand depends weakly on the magnitude of partial atomic charges and is always less than the shear modulus of the CNT. The values obtained for Young’s modulus and shear modulus are in excellent agreement with the available experimental results. We also study the elasticity of dsDNA using equilibrium fluctuation methods as well as nonequilibrium stretching simulations. The results obtained from both methods quantitatively agree with each other. The end-to-end length distribution P(ρ) and angle distribution P(θ) of the dsDNA has a Gaussian form which gives stretch modulus (γ1) to be 708 pN and persistence length (Lp) to be 42 nm, respectively. When dsDNA is stretched along its helix axis, it undergoes a large conformational change and elongates about 1.7 times its initial contour length at a critical force. Applying a force perpendicular to the DNA helix axis, dsDNA gets unzipped and separated into two single-stranded DNA (ssDNA). DNA unzipping is a fundamental process in DNA replication. As the force at one end of the DNA is increased the DNA starts melting above a critical force depending on the pulling direction. The critical force fm , at which dsDNA melts completely decreases as the temperature of the system is increased. The melting force in the case of unzipping is smaller compared to the melting force when the dsDNA is pulled along the helical axis. In the case of melting through unzipping, the double-strand separation has jumps which correspond to the different energy minima arising due to sequence of different base-pairs. Similar force-extension curve has also been observed when crossover DNA molecules are stretched along the helix axis. In the presence of mono-valent Na+ counterions, we find that the stretch modulus (γ1 ) of the paranemic crossover (PX) and its topoisomer juxtapose (JX) DNA structure is significantly higher (30 %) compared to normal B-DNA of the same sequence and length. When the DNA motif is surrounded by a solvent of divalent Mg2+ counterions, we find an enhanced rigidity compared to in Na+ environment due to the electrostatic screening effects arising from the divalent nature of Mg2+ counterions. This is the first direct determination of the mechanical strength of these crossover motifs which can be useful for the design of suitable DNA motifs for DNA based nanostructures and nanomechanical devices with improved structural rigidity. Negatively charged DNA can be compacted by positively charged dendrimer and the degree of compaction is a delicate balance between the strength of the electrostatic interaction and the elasticity of DNA. When the dsDNA is compacted by dendrimer, the stretch modulus, γ1 and persistence length, Lp decreases dramatically due to backbone charge neutralization of dsDNA by dendrimer. We also study the effect of CNT and graphene substrate on the elastic as well as adsorption properties of small interfering RNA (siRNA) and dsDNA. Our results show that siRNA strongly binds to CNT and graphene surface via unzipping its base-pairs and the propensity of unzipping increases with the increase in the diameter of the CNTs and is maximum on graphene. The unzipping and subsequent wrapping events are initiated and driven by van der Waals interactions between the aromatic rings of siRNA nucleobases and the CNT/graphene surface. However, dsDNA of the same sequence undergoes much less unzipping and wrapping on the CNT/graphene due to smaller interaction energy of thymidine of dsDNA with the CNT/graphene compared to that of uridine of siRNA. Unzipping probability distributions fitted to single exponential function give unzipping time (τ) of the order of few nanoseconds which decrease exponentially with temperature. From the temperature variation of unzipping time we estimate the free energy barrier to unzipping. We have also investigated the binding of siRNA to CNT by translocating siRNA inside CNT and find that siRNA spontaneously translocates inside CNT of various diameters and chiralities. Free en- ergy profiles show that siRNA gains free energy while translocating inside CNT and the barrier for siRNA exit from CNT ranges from 40 to 110 kcal/mol depending on CNT chirality and salt concentration. The translocation time τ decreases with the increase of CNT diameter having a critical diameter of 24 A for the translocation. After the optimal binding of siRNA to CNT/graphene, the complex is very stable which can serve as siRNA delivery agent for biomedical applications. Since siRNA has to undergo unwinding process in the presence of RNA-induced silencing complex, our proposed delivery mechanism by single wall CNT possesses potential advantages in achieving RNA interference (RNAi). Structural Phase Transitions Elasticity Nanotubes Carbon Nanotubes (CNT) Boron Nitride Nanotubes (BNNT) Double Stranded DNA Paranemic-Juxtapose Crossover DNA Dendrimer Bound DNA Nucleic Acids Phase Transitions Nanoscience dsDNA Dendrimer siRNA Juxtapose DNA Nanostructures Condensed Matter Physics
116	Lack of Point Mutations in Exons 11–23 of the Retinoblastoma Susceptibility Gene RB-1 in Liver Metastases of Colorectal Carcinoma Hildebrandt, Bert, Heide, I., Thiede, Christian, Nagel, S., Dieing, Annette, Jonas, S., Neuhaus, Peter, Rochlitz, Christoph, Riess, Hanno, Neubauer, Andreas January 2000 (has links) Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich. info:eu-repo/classification/ddc/610 ddc:610
117	A Study of Single-stranded DNA Gaps in the Response to Replication Stress and Synthetic Lethality Cong, Ke 03 January 2022 (has links) Mutations in the hereditary breast/ovarian cancer genes BRCA1/2 were shown to be synthetic lethal with poly(ADP-ribose) polymerase inhibitors (PARPi). This toxicity is assumed to derive from PARPi-induced DNA double strand breaks (DSBs) that necessitate BRCA function in homologous recombination (HR) and/or fork protection (FP). However, PARPi accelerates replication forks. While high-speed replication could cause DSBs, the finding that PARPi leads to single-stranded DNA (ssDNA) gaps/nicks suggests replication gaps could also or alone be the cause of synthetic lethality. Here, we demonstrate that PARPi toxicity derives from replication gaps. Isogenic cells deficient in BRCA1 or the BRCA1-associated FANCJ, with common DNA repair defects in HR and FP, exhibit opposite responses to PARPi. Deficiency in FANCJ, a helicase also mutated in hereditary breast/ovarian cancer and Fanconi anemia, causes aberrant accumulation of fork remodeling factor HLTF and limits unrestrained DNA synthesis with ssDNA gaps. Thus, we predict replication gaps as a distinguishing factor and further uncouple HR, FP and fork speed from PARPi response. BRCA-deficient cells display excessive gaps that are diminished upon resistance, restored upon re-sensitization and when targeted augment synthetic lethality with PARPi. Furthermore, we define the source of gaps to defects in Okazaki fragment processing (OFP). Unchallenged BRCA1-deficient cells have elevated poly(ADP-ribose) and chromatin-associated PARP1 but aberrantly low XRCC1 indicating a defective backup OFP pathway. Remarkably, 53BP1 loss resuscitates OFP by restoring XRCC1-LIG3 that suppresses the sensitivity of BRCA1-deficient cells to drugs targeting OFP or generating gaps. Collectively, our study highlights unprotected lagging strand gaps as a determinant of synthetic lethality, providing a new paradigm and biomarker for PARPi toxicity. Single-stranded DNA gaps Replication stress FANCJ HLTF Fanconi anemia Fork protection BRCA1/2 deficiency Homologous recombination PARP inhibitor Synthetic lethality Gap suppression Okazaki fragment processing Chemo-resistance Cancer therapy Cancer Biology
118	Evaluation of Two String Tests for Obtaining Gastric Juice for Culture, Nested-PCR Detection, and Combined Single- and Double-Stranded Conformational Polymorphism Discrimination of Helicobacter Pylori Ferguson, David A., Jiang, C., Chi, D. S., Laffan, J. J., Li, C., Thomas, E. 01 October 1999 (has links) We have compared two gastric string tests for obtaining gastric juice for culture of Helicobacter pylori and for nested-PCR detection and PCR-based combined single- and double-stranded conformational polymorphism (SDSCP) discrimination of infecting strains. String test specimens were obtained from one seropositive volunteer for 13 consecutive weeks. The distal 10 cm of each string was suspended in 1 ml saline and quantitatively cultured. An additional nine volunteers with histories of upper-gastrointestinal complaints were given a string test for culture and nested-PCR assay. H. pylori isolates and/or gastric juice from each volunteer were extracted for DNA and analyzed by PCR-based SDSCP. Quantitative culture showed that the Entero-test was four times as sensitive as the Gastro-test but was more prone to contamination by oral flora. However, the two string tests are equally sensitive by PCR assays. Thus, the Gastro-test is more suitable for culture detection of H. pylori, since it is less prone to oral contamination and its shorter length is better tolerated. SDSCP analysis of H. pylori DNA from four PCR-positive volunteers without requiring culture showed four distinct profiles, indicating different infecting strains. SDSCP analysis of strains isolated before and after treatment of one volunteer had the same SDSCP profile, suggesting endogenous reinfection by the same strain. female gastric juice (microbiology) helicobacter infections (diagnosis) helicobacter pylori (genetics isolation & purification) humans male polymerase chain reaction polymorphism single-stranded conformational sensitivity and specificity specimen handling (methods) Biological Sciences
119	Vesicle-Protein Diffusion and Interaction Study Using Time Resolved Fluorescence Correlation Spectroscopy Rouhvand, Bahar January 2017 (has links) No description available. Physical Chemistry Biochemistry Biophysics Molecular Biology Molecular Chemistry Scientific Imaging Fluorescence spectroscopy DLS Vesicle FITC Fluorescence Correlation function Cross correlation Auto correlation Lipid bilayer Binding Double-stranded DNA Lipid-polymer interactions Brownian diffusion Lipid mobility
120	IRF9 AND NITRIC OXIDE: IMPORTANT ANTIVIRAL MEDIATORS IN THE ABSENCE OF KEY SIGNALLING MOLECULES Mehta, Devangi R. 10 1900 (has links) <p>The innate host response to virus infection is largely dominated by the production of type I interferons (IFNs). Fibroblasts, considered nonprofessional immune cells, respond to virus infection after recognition of viral components such as double-stranded (ds)RNA. The constitutively expressed transcription factor IFN regulatory factor 3 (IRF3) is rapidly activated and type I IFNs are produced. In the absence of IRF3, it was found that IFNs are still produced. This thesis identifies IRF9 as the transcription factor responsible for IFN production in the absence of IRF3 based on its ability to bind the murine (m)IFNβ promoter determined via oligonucleotide pull-down assays.</p> <p>In the absence of both IRF3 and IRF9, primary fibroblasts are deficient for IFN signalling. Surprisingly, significant inhibition of virus replication following dsRNA treatment of cells deficient for IRF3 and IFN signalling was recently observed with the large DNA virus herpes simplex virus type 1 (HSV-1) being more susceptible to inhibition than the small RNA virus vesicular stomatitis virus (VSV). As nitric oxide is known for its nonspecific antiviral effects against DNA viruses, involvement of this molecule in the antiviral response to HSV-1 in the absence of IRF3 and type I IFN induction and signalling was investigated. Here it is shown that in the absence of IRF3 and IFN, nitric oxide constitutes a major component of the innate response against HSV-1 in response to dsRNA in primary fibroblasts. In these cells, nuclear factor kappa-light-chain-enhancer of activated B cells (NF-κB) and IRF1 regulate inducible nitric oxide synthase (iNOS) expression, subsequently producing nitric oxide. As most viruses encode strategies to render their environment IRF3 and/or IFN deficient, it appears that IRF9 and nitric oxide serve as secondary responses to protect the host against viral infection. These data emphasize the importance and requirement of the host to employ multiple strategies to overcome infection.</p> / Master of Science (MSc) nitric oxide interferon innate immune response double-stranded RNA mouse embryo fibroblasts Biology Medical Cell Biology Medical Immunology Medical Molecular Biology

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