Spelling suggestions: "subject:"exonucleases"" "subject:"exonuclease""
1 |
Exonuclease I : structural and biochemical insights/Busam, Robert Durstberger, January 2005 (has links)
Thesis (Ph. D.)--University of Oregon, 2005. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 83-89). Also available for download via the World Wide Web; free to University of Oregon users.
|
2 |
Structural studies of the progressive enzyme, Exonuclease I, from Escherichia coli /Breyer, Wendy Ann, January 2001 (has links)
Thesis (Ph. D.)--University of Oregon, 2001. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 99-114). Also available for download via the World Wide Web; free to University of Oregon users.
|
3 |
Essential roles of the T7 Endonuclease (Gene 3) and the T7 Exonuclease (Gene 6) in recombination of Bacteriophage DNALee, Marion A. January 1976 (has links)
The role of the T7-induced exonuclease (gene 6) in recombination was studied using both molecular and genetic techniques. In the molecular method the fate of parental DNA during parent-to-progeny recombination was examined. A comparison of infections with T7⁺, T7am6 (amber gene 6), or T7ts6 (temperature sensitive gene 6) under permissive and nonpermissive conditions was made. CsCl density gradient analysis of replicative DNA indicated that the T7 exonuclease is necessary for recombination to occur, i.e., in the absence of the exonuclease the parental DNA replicated continuously as a hybrid molecule and did not recombine. Analysis of denatured replicative DNA by CsCl density gradient centrifugation indicated that the exonuclease also may be needed for a limited amount of covalent repair of recombinants. Further confirmation of the essential role which the exonuclease plays in recombination came from genetic analysis. The T7 exonuclease was shown to be necessary for intragenic and intergenic recombination in several areas of the T7 genetic map; genetic recombination frequencies were found to be decreased from 3 to 18-fold under conditions nonpermissive for the exonuclease.
The role of the T7-induced endonuclease (gene 3) in molecular recombination was studied by examining the fate of parental DNA during parent-to-progeny recombination using a shear technique. The T7 endonuclease was found to be necessary for the dispersion of parental DNA in the newly replicated DNA. Concatemers synthesized by either T7⁺ or T7am3 (amber gene 3) phage containing the newly replicated DNA were sheared to the size of mature
phage DNA and also to quarter size molecules. In the presence of gene 3 protein, parental DNA and newly replicated DNA were interspersed, i.e., the 32P-label from the sheared DNA was found to sediment at the density of recombined DNA. In the absence of gene 3 protein, the parental strand of each sheared DNA molecule was usually found intact, i.e., the ³²P-label from the sheared DNA was found to sediment at the density of hybrid DNA. These results support the previous genetic data (52, 83) that the gene 3 protein is essential for T7 recombination.
The role of T7 recombination enzymes in the formation of concatemers was studied by examining selected gene 3 and gene 6 mutants. Results of sucrose gradient analysis showed that DNA concatemers were formed when both the T7 exonuclease (gene 6) and the T7 endonuclease (gene 3) were absent. Further results showed that concatemers cannot be maintained in the absence of the exonuclease unless the endonuclease was eliminated. In a T7am6 infection DNA concatemers formed early were prematurely broken down and accumulated as fragments smaller than mature size phage DNA. In a T7am3am6 (amber in both genes 3 and 6) infection concatemers accumulated and were not matured. These results indicate that concatemers are formed by a process other than normal phage recombination. However, selective defects in the recombination system do interfere with the stability of concatemers. / Science, Faculty of / Microbiology and Immunology, Department of / Graduate
|
4 |
Functional characterization of arabidopsis DXO, a5'-3' RNA exonucleasePan, Shuying 27 May 2019 (has links)
RNA decay plays an essential role in the regulation of gene expression during plant development and response to environmental stimuli. The protein DXO is a 5' to 3' exonuclease that functions in RNA degradation and RNA quality control that has been studied in animals. It has not yet been identified in plants. The gene locus At4g17620 in Arabidopsis thaliana encodes a protein homolog of the mammalian DXO, termed AtDXO. Recombinantly expressed AtDXO possesses a 5'-3' RNA exonuclease activity in vitro. Loss-of-function of AtDXO in Arabidopsis generates multiple growth defects, including curled and yellowish leaves, growth retardation and limited fertility, whereas overexpression show no obvious growth phenotype. The development defect of atdxo might be attributed to aberrant RNAs, which are not degraded when AtDXO is dysfunctioning. From the RNA-Seq analysis, the transcriptome pattern of atdxo mutants shows significant disparity from wild-type. Among the differences, the defense response genes are elevated in atdxo while photosynthesis-related and plastid genesis-related genes are downregulated. The constitutive expression of defense response genes causes the autoimmune phenotypes of atdxo. This could be modulated by temperature and is partially dependent on the master immunity regulators EDS1 or NPR1. Reactive oxygen species (ROS) accumulation was also detected in the atdxo mutant, and atdxo showed insensitivity to oxidative stress imposed by paraquat. Moreover, the atdxo mutant is hypersensitive to salt stress but not sensitive to general osmotic stress. In Arabidopsis, the 5'-3' RNA decay pathway could act as a repressor of endogenous post-transcriptional gene silencing (PTGS), which is regulated by small RNAs (sRNA). The mutation of AtDXO caused productions of 24- and 25-nucleotide endogenous sRNAs. The growth defect phenotype of atdxo could not be repressed by dysfunction of the RDR6 (RNA-DEPENDENT RNA POLYMERASE 6)-dependent sRNA biogenesis pathway. These findings demonstrate that AtDXO functions as a 5'-3' exoribonuclease both in vitro and in vivo to regulate plant development and to mediate the response to environmental stresses.
|
5 |
Analysis of the interactions between the 5' to 3' exonuclease and the single-stranded DNA-binding protein from bacteriophage T4 and related phages /Boutemy, Laurence S. January 2008 (has links)
Thesis (Ph. D.)--University of Toledo, 2008. / Typescript. "Submitted as partial fulfillment of the requirements for the Doctor of Philosophy in Chemistry." Includes bibliographical references (leaves 305-309).
|
6 |
The Molecular Machinery Critical to the Degradation of Cellular RNASchmier, Brad J. 03 March 2012 (has links)
Exoribonucleases are indispensable for cellular RNA metabolism. RNA processing, end-turnover, and degradation all require the concerted action of exoribonucleases. In this thesis, two families of exoribonucleases that act in the final steps of RNA decay pathways are explored. The first of these is the RNR superfamily of processive 3’→5’ RNases with major roles in both mRNA and stable RNA degradation. The initial focus of this work is the structural and enzymatic characterization of an unusual RNR family enzyme from the radiation-resistant bacterium Deinococcus radiodurans. This enzyme is demonstrated biochemically to be an RNase II-type enzyme (DrII), based on its sensitivity to secondary structure. Analysis of the DrII X-ray structure reveals that a novel, winged-HTH domain has replaced the canonical RNA binding clamp typical of RNR family proteins. The exposed architecture of DrII’s RNA binding surface offers an explanation for the nuclease’s ability to approach within 3-5 nt of a duplex, an important mechanistic difference from the well-studied E. coli RNase II. The open, clamp architecture of DrII may have broader relevance to mechanisms of duplex RNA recognition in the RNR superfamily. RNA decay by processive exonucleases such as RNR family proteins leaves 2-5 nt nanoRNA limit products that are further degraded to mononucleotides by nanoRNases. In E. coli, the DEDD family enzyme Oligoribonuclease (ORN) executes nanoRNA decay and represents the first major family of nanoRNases, with homologs widely conserved in eubacteria and eukaryotes. The B. subtilis NanoRNase A (NrnA), a DHH family phosphoesterase, represents a second major class of nanoRNases, with broad phylogenetic distribution in organisms that lack orn homologs. The second major focus of this thesis is a structural and mechanistic study of this nanoRNase machinery. The atomic structure of the B. subtillis nanoRNase NrnA is described, and unveils a bi-lobal architecture similar to the 5’→3’ DNase RecJ, where the catalytic DHH domain is linked via a partially helical connector to the C-terminal RNA binding domain. NrnA is a highly dynamic molecule, adopting both open and closed conformations. Co-crystallization with several substrates shows that NrnA has a nanoRNA specific substrate-binding patch that offers a structural explanation for its 3’→5’ nanoRNase activity. This RNA binding site feeds substrate to the DHH active site in an orientation opposite to the 5’→3’ path proposed for RecJ. Surprisingly, NrnA also maintains a weak 5’→3’ activity on certain substrates, and thus possesses both 5’→3’ and 3’→5’ exonuclease activities. In conclusion, an overall model is presented for how DHH family exonucleaess can degrade nucleic acids from both the 5’→3’ and 3’→5’ directions. Thus, the studies described in this thesis offer both an atomic and a biochemical view of the macromolecular machinery critical to the degradation of RNA.
|
7 |
Streamlined Extract Preparation for E. coli-Based Cell-Free Protein Synthesis and Rapid Site-Specific Incorporation of Unnatural Amino Acids in ProteinsShrestha, Prashanta 07 December 2012 (has links)
This thesis reports the viability of E. coli cell extracts prepared using equipment that is both common to biotechnology laboratories and able to process small volume samples and expression of proteins containing unnatural amino acids (UAAs) at higher level using PCR amplified linear DNA templates (LETs) in cell-free protein synthesis (CFPS) system. E. coli-based cell extracts are a vital component of inexpensive and high-yielding CFPS reactions. However, effective preparation of E. coli cell extract is limited to high-pressure homogenizers (French press style or impinge-style) or bead mill homogenizers, which all require a significant capital investment. This work specifically assessed the following capital cost lysis techniques: (1) sonication, (2) bead vortex mixing, (3) freeze-thaw cycling, and (4) lysozyme incubation to prepare E. coli cell extract for CFPS. In this work, simple shake flask fermentation with a commercially available E. coli strain was used. Additionally, the RNA polymerase was over expressed in the E. coli cells prior to lysis which eliminated the need to add independently purified RNA polymerase to the CFPS reaction. As a result, high yielding E. coli-based cell extract was prepared using equipment requiring reduced capital investment and common to biotechnology laboratories. To our knowledge, this is the first successful prokaryote-based CFPS reaction to be carried out with extract prepared by sonication or bead vortex mixing. LETs are an attractive alternative to plasmids for site-specific incorporation of unnatural amino acids in proteins in the CFPS system because of their short preparation time and ease of production. However, major limitations associated with LETs are: (1) their degradation by RecBCD enzyme present in the cell-extract used for CFPS and (2) high CFPS energy costs. In this work, we report the optimization of LET-based CFPS for improved protein yield by inhibiting the RecBCD enzyme with small inhibitor molecules resulting in three fold increment in yield of protein containing UAA. We also assessed alternative energy sources such as glucose, fructose-1,6-bisphospate, creatine phosphate/creatine kinase, and high glutamate salt for cost reduction. This work could be important for high-throughput applications based on linear expression templates. This work demonstrates simple E. coli extract preparation and improved yield with linear expression templates for further advancements of cell-free protein synthesis system.
|
Page generated in 0.0478 seconds