Global ETD Search

1	Requirements and rationale for amber translation as pyrrolysine Longstaff, David Gordon 10 December 2007 (has links) No description available. pyrrolysine pyrrolysyl-tRNA pyrrolysyl-tRNA synthetase pyrrolysine biosynthesis genetic code expansion PYLIS element pyrrolysine function
2	The Mass Of L-Pyrrolysine In Methylamine Methyltransferases And The Role Of Its Imine Bond In Catalysis Soares, Jitesh A A 19 March 2008 (has links) No description available. Microbiology pyrrolysine pyrrolysine structure pyrrolysine function ATP-dependent redox-activation enzyme methylamine methyltransferase
3	Amber Codon translation as pyrrolysine in methanosarcina Spp Blight, Sherry Kathleen 21 September 2006 (has links) No description available. pyrrolysine tRNA methyltransferase Methanosarcina PYLIS element PylS
4	A novel aminoacyl-tRNA synthetase and its amino acid, pyrrolysine, the 22nd genetically encoded amino acid Larue, Ross C. January 2009 (has links) No description available. Biochemistry Microbiology Molecular Biology pyrrolysine aminoacyl tRNA-synthetases genetic code Methanosarcina aminoacylation PylS tRNA novel amino acid pyrrolysyl-tRNA pyrrolysine biosynthesis
5	Expansion of the Genetic Code to Include Acylated Lysine Derivatives and Photocaged Histidine Kinney, William D 01 January 2019 (has links) The genetic code of all known organisms is comprised of the 20 proteinogenic amino acids that serve as building blocks on a peptide chain to form a vast array of proteins. Proteins are responsible for virtually every biological process in all organisms; however, the 20 amino acids contain a limited number of functional groups that often leaves much to be desired. The lack of diversity addresses the need to increase the genetic repertoire of living cells to include a variety of amino acids with novel structural, chemical, and physical properties not found in the common 20 amino acids. In order to expand the chemical scope of the genetic code beyond the functionalities that can be directly genetically encoded, unnatural amino acids must be added to the proteome. The ability to incorporate unnatural amino acids (UAAs) into proteins at defined sites has a direct impact on the ability of scientists to study biological processes that are difficult or impossible to address by more classical methods. The UUAs of interest are acylated lysine derivatives (isovaleryl, isobutyryl, and β-hydroxybutyryl) and photocaged histidine. Acylation of histone lysine has been linked to epigenetic regulation of metabolism.1 A means to site-specifically incorporate each acylated lysine derivative would help study the effect of acylated lysine in epigenetic regulation. Likewise, in order to elucidate the role of histidine in specific protein functions, one can replace a critical histidine with a photocaged histidine. Photocaged amino acids are those that possess a photo-cleavable, aromatic caged group. Light-induced protein activation allows for the biological activity of the protein to be spatiotemporally regulated under non-invasive external control.2 The site-specific in vivo incorporation of unnatural amino acids is made possible by amber codon suppression by an orthogonal suppressor aminoacyl-tRNA synthetase (aaRS)/tRNA pair.3 In amber codon suppression the amber stop codon is decoded for an UAA by a suppressor aaRS/tRNA pair. To accept the UAA, the aaRS must be evolved to achieve orthogonal activity with specific UUAs. The pyrrolysyl aaRS/tRNA (PylRS/PylT) pair from M. barkeri and M. mazei was used to construct multiple, large-scale aaRS mutant libraries where critical residues within the active site of PylRS are mutated via site-saturated mutagenesis.4 The libraries were subjected to directed evolution through a series of positive and negative selections to enrich aaRS variants that exclusively bind to acylated lysine derivatives and photocaged histidine as substrates.5 The PylRS selection survivors were screened for UAA activity and identified successful clones underwent a fluorescent activity assay. The active aaRS were used for amber codon suppression to express the respective UAA in ubiquitin and green fluorescent protein constructs. genetic code expansion pyrrolysine protein library construction photocaged amino acids unnatural amino acids Organic Chemistry
6	Engineered pyrrolysyl-tRNAs for bioorthogonal labeling of G protein-coupled receptors Serfling, Robert 08 November 2019 (has links) No description available. info:eu-repo/classification/ddc/570 ddc:570
7	Anoxic quaternary amine utilization by archaea and bacteria through a non-<i>L</i>-pyrrolysine methyltransferase; insights into global ecology, human health, and evolution of anaerobic systems Ticak, Tomislav 27 April 2015 (has links) No description available. Microbiology Biochemistry Molecular Biology Ecology quaternary amines glycine betaine pyrrolysine methyltransferase one-carbon metabolism
8	Studies Of Molecular Structure-Function Relationships For A Pyrrolysine-Containing Methyltransferase And Novel Rna-Cleaving Protein Nucleic Acids Kang, Ting-Wei Patrick 11 February 2009 (has links) No description available. Biochemistry PNA RNA cleavage MttB trimethylamine methyltransferase Pyrrolysine X-ray crystallography
9	Translation of the amber codon in methylamine methyltransferase genes of a methanogenic archaeon Srinivasan, Gayathri 04 February 2004 (has links) No description available. Biology, Microbiology Archaea Methanogen Methanosarcina barkeri pyrrolysine PylS LysK LysS pylT amber decoding tRNA Monomethylamine methyltransferase in-frame amber codon
10	Investigating Anaerobic Choline Degradation Pathways from Citrobacteramalonaticus CJ25 and Methanococcoides methylutens Q3c Kashyap, Jyoti 16 June 2022 (has links) No description available. Microbiology Climate Change

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