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1	Molecular recognition and post-translational modification of the lipoyl domains in 2-oxo acid dehydrogenase complexes Wallis, Nicola Gail January 1993 (has links) No description available. 572 Multienzyme complexes
2	The lipoyl domains of the 2-oxo acid dehydrogenase multienzyme complexes Graham, L. D. January 1986 (has links) No description available. 572 Multienzyme complex kinetics
3	Studies on the inner lipoyl domain of the human pyruvate dehydrogenase complex Quinn, Janet January 1993 (has links) No description available. 572 Multienzyme systems
4	Protein-protein interactions within the 2-oxoacid dehydrogenase complexes Richards, Susan Diane January 1999 (has links) No description available. 572 Multienzyme complexes
5	Analysis of expression, assembly and regulation of normal and mutant forms of mammalian pyruvate dehydrogenase multienzyme complex / Lib, Margarita Y., January 2002 (has links) Thesis (Ph. D.)--University of Oregon, 2002. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 92-101). Also available for download via the World Wide Web; free to University of Oregon users. Multienzyme complexes. Carbohydrates
6	Protein adaptability involved in self-assembled icosahedral capsids / Nilsson, Josefina, January 2006 (has links) Diss. (sammanfattning) Stockholm : Karolinska institutet, 2006. / Härtill 4 uppsatser.
7	Unraveling the Mystery for the Coexistence of Two Forms of Arginyl-tRNA Synthetase in Mammalian Cells Kyriacou, Sophia Vasou 22 September 2008 (has links) The aminoacyl-tRNA synthetases are among the major protein components in the translation machinery. These essential proteins are responsible for charging their cognate tRNAs with the correct amino acid. Mammalian arginyl-tRNA synthetase (ArgRS), unlike all other eukaryotic aminoacyl-tRNA synthetases, is unique due to the coexistence of two structurally distinct forms of the same enzyme within the same cell: a complexed (or high molecular weight) form that is part of the multi-synthetase complex, and a free (or low molecular weight) form. Until now, not much information is known as to why the cell would synthesize and utilize two different forms of the same enzyme. Do the two forms of ArgRS perform similar or different biological functions? The main hypothesis that was originally proposed is that only the complexed form of ArgRS plays a crucial role in protein synthesis, while the free form of this enzyme participates in the ubiquitination pathway by tagging proteins with acidic NH2-termini (destined for degradation) with an arginine residue on their NH2-terminal end which will serve as a signal for ubiquitin-mediated destruction. Based on my studies, the data indicate that the high molecular weight form of ArgRS, which is present exclusively as an integral component of the multisynthetase complex, is essential for normal protein synthesis and growth of CHO cells even when low molecular weight, free ArgRS is present and Arg-tRNA continues to be synthesized at close to wild type levels. Based on these observations, we can conclude that Arg-tRNA generated by the synthetase complex is a more efficient precursor for protein synthesis than Arg-tRNA generated by free ArgRS, exactly as would be predicted by the channeling model for mammalian translation. No phenotype has been determined for cells expressing only the complexed form of ArgRS, and no direct interaction has been observed between ArgRS and arginyl-tRNA-protein transferase (ATE). Based on this information, we suggest that the function(s) of the free form of ArgRS is either not necessary or is performed by the complexed form when the free form is missing.
8	Functional studies of the ubiquitin-proteasome system using GFP-based reporters / Lindsten, Kristina, January 2002 (has links) Diss. (sammanfattning) Stockholm : Karol. inst., 2002. / Härtill 6 uppsatser.
9	Euglena Fatty Acid Synthetase Multienzyme Complex Is a Unique Structure Worsham, Lesa M., Jonak, Zdenka L.P., Ernst-Fonberg, Mary Lou 21 March 1986 (has links) The composition, size, and peptide structure of a fatty acid synthetase aggregate from etiolated Euglena gracilis was studied. The fatty acid synthetase was a lipoprotein containing about 40% lipid. Low-angle laser light scattering of the native fatty acid synthetase yielded a molecular weight of 6 · 106 up to concentrations of about 30 μg fatty acid synthetase/ml; at higher concentrations, the molecular weight increased to 11 · 106. Viscometry of the synthetase solutions yielded results that suggested that the asymmetric fatty acid synthetase aggregate formed a 'dimer' at concentrations above 30 μg fatty acid synthetase/ml by side-to-side interaction. The peptide structure of the fatty acid synthetase prepared in the presence of a variety of proteinase inhibitors included at least six peptides of Mr 150000 or less. More than 68% of the protein was in peptides of less than Mr 150000. N-terminal amino acid analysis gave eight different residues all present in integral amounts, seven at about 11% and one at 24% of the total α-N-dansyl amino acids. The Euglena-aggregated fatty acid synthetase appears to be a very large true multienzyme complex. (euglena) fatty acid synthetase multienzyme complex
10	Isolation of xylanolytic multi-enzyme complexes from Bacillus subtilis SJ01 Jones, Sarah Melissa Jane January 2010 (has links) Cellulose and hemicellulose account for a large portion of the world‘s plant biomass. In nature, these polysaccharides are intertwined forming complex materials that require multiple enzymes to degrade them. Multi-enzyme complexes (MECs) consist of a number of enzymes working in close proximity and synergistically to degrade complex substrates with higher efficiency than individual enzymes. The cellulosome is a cellulolytic MEC produced by anaerobic bacteria that has been studied extensively since its discovery in 1983. The aim of this study was to purify a cellulolytic and/or hemicellulolytic MEC from an aerobic bacterium of the Bacillus genus. Several bacterial isolates were identified using morphological characteristics and 16S rDNA sequencing, and screened for their ability to degrade cellulose and xylan using a MEC. The isolate that produced a high molecular weight protein fraction with the greatest ability to degrade Avicel®, carboxymethyl cellulose (CMC) and birchwood xylan was identified as Bacillus subtilis SJ01. An optimised growth medium, consisting of vitamins, trace elements, birchwood xylan (as the carbon source), and yeast and ammonium sulphate (as the nitrogen sources), increased the production of CMCase and xylanase enzymes from this bacterium. The removal of a competing bacterial strain from the culture and the inhibition of proteases also increased enzyme activities. A growth curve of B. subtilis SJ01 indicated that xylanase production was highest in early stationary growth phase and thus 84 hours was chosen as the best cell harvesting time. To purify the MECs produced by B. subtilis SJ01 size-exclusion chromatography on a Sephacryl S-400 column was used. It was concluded that (for the purposes of this study) the best method of concentrating the culture supernatant prior to loading onto Sephacryl S-400 was the use of ultrafiltration with a 50 kDa cut-off membrane. Two MECs, named C1 and C2 of 371 and 267 kDa, respectively, were purified from the culture supernatant of B. subtilis SJ01. Electrophoretic analysis revealed that these MECs consisted of 16 and 18 subunits, respectively, 4 of which degraded birchwood xylan and 5 of which degraded oat spelt xylan. The MECs degraded xylan substrates (C1: 0.24 U/mg, C2: 0.14 U/mg birchwood xylan) with higher efficiency than cellulose substrates (C1: 0.002 U/mg, C2: 0.01 U/mg CMC), and could therefore be considered xylanosomes. Interestingly, the MECs did not bind to insoluble birchwood xylan or Avicel® and did not contain glycosylated proteins, which are common features of cellulosomes. This study is, therefore, important in revealing the presence of MECs that differ from the cellulosome and that may have particular application in industries requiring high xylanase activity, such as the paper and pulp industry. The abundant genetic information available on B. subtilis means that this organism could also be used for genetic engineering of cellulolytic/hemicellulolytic MECs. Bacillus subtilis Xylans Multienzyme complexes Botanical chemistry Cellulose Hemicellulose Polysaccharides

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