• Refine Query
  • Source
  • Publication year
  • to
  • Language
  • 2
  • 1
  • 1
  • 1
  • Tagged with
  • 6
  • 6
  • 3
  • 3
  • 3
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • 2
  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Engineering the (S)-3-O-Geranylgeranylglyceryl Phosphate Synthase (GGGPS) Monomer from its Dimer

Kharbanda, Neha 25 August 2011 (has links)
(S)-3-O-Geranylgeranylglyceryl Phosphate Synthase (GGGPS) is a TIM (βα)8 barrel protein found in Archaea and the enzyme catalyzing the first step in the biosynthesis of archaeal membrane lipids. The TIM (βα)8 barrel protein fold is thought to have evolved by duplication and fusion of (βα)4 half barrels. We propose that the GGGPS has also evolved from (βα)4 half barrels. One way to test this hypothesis is to generate putative half-barrels experimentally. GGGPS from Archaeaglobus fulgidus, is a dimer of (βα)8 barrels. Thus, before constructing half barrels, a stable monomer is needed to be engineered. Introducing three substitutions into the dimer interface formed the GGGPS monomer. AUC showed ~50 % of the protein is in the monomeric state. CD experiments confirmed that the engineered protein was properly folded but had decreased thermal stability. In an enzymatic assay, the monomeric GGGPS protein proved as active as the WT protein on a subunit basis.
2

Engineering the (S)-3-O-Geranylgeranylglyceryl Phosphate Synthase (GGGPS) Monomer from its Dimer

Kharbanda, Neha 25 August 2011 (has links)
(S)-3-O-Geranylgeranylglyceryl Phosphate Synthase (GGGPS) is a TIM (βα)8 barrel protein found in Archaea and the enzyme catalyzing the first step in the biosynthesis of archaeal membrane lipids. The TIM (βα)8 barrel protein fold is thought to have evolved by duplication and fusion of (βα)4 half barrels. We propose that the GGGPS has also evolved from (βα)4 half barrels. One way to test this hypothesis is to generate putative half-barrels experimentally. GGGPS from Archaeaglobus fulgidus, is a dimer of (βα)8 barrels. Thus, before constructing half barrels, a stable monomer is needed to be engineered. Introducing three substitutions into the dimer interface formed the GGGPS monomer. AUC showed ~50 % of the protein is in the monomeric state. CD experiments confirmed that the engineered protein was properly folded but had decreased thermal stability. In an enzymatic assay, the monomeric GGGPS protein proved as active as the WT protein on a subunit basis.
3

The Complex Role of Sequence and Structure in the Stability and Function of the TIM Barrel Proteins

Chan, Yvonne H. 03 November 2017 (has links)
Sequence divergence of orthologous proteins enables adaptation to a plethora of environmental stresses and promotes evolution of novel functions. As one of the most common motifs in biology capable of diverse enzymatic functions, the TIM barrel represents an ideal model system for mapping the phenotypic manifestations of protein sequence. Limits on evolution imposed by constraints on sequence and structure were investigated using a model TIM barrel protein, indole-3-glycerol phosphate synthase (IGPS). Exploration of fitness landscapes of phylogenetically distant orthologs provides a strategy for elucidating the complex interrelationship in the context of a protein fold. Fitness effects of point mutations in three phylogenetically divergent IGPS proteins during adaptation to temperature stress were probed by auxotrophic complementation of yeast with prokaryotic, thermophilic IGPS. Significant correlations between the fitness landscapes of distant orthologues implicate both sequence and structure as primary forces in defining the TIM barrel fitness landscape. These results suggest that fitness landscapes of point mutants can be successfully translocated in sequence space, where knowledge of one landscape may be predictive for the landscape of another ortholog. Analysis of a surprising class of beneficial mutations in all three IGPS orthologs pointed to a long-range allosteric pathway towards the active site of the protein. Biophysical and biochemical analyses provided insights into the molecular mechanism of these beneficial fitness effects. Epistatic interactions suggest that the helical shell may be involved in the observed allostery. Taken together, knowledge of the fundamental properties of the TIM protein architecture will provide new strategies for de novo protein design of a highly targeted protein fold.
4

Kristallstrukturuntersuchungen zum Katalyse- und Regulationsmechanismus der Tyrosin-regulierten 3-Deoxy-D-arabino-Heptulosonat-7-Phosphat-Synthase aus Saccharomyces cerevisiae / Crystal structure analysis on the tyrosine-regulated 3-Deoxy-D-arabino-heptulosonate-7-phosphate synthase from Saccharomyces cerevisiae

König, Verena 31 October 2002 (has links)
No description available.
5

Protein crystallographic studies of A-TIM—structure based development of new enzymes

Salin, M. (Mikko) 09 March 2010 (has links)
Abstract Enzymes are potentially superior as catalysts for many industrial chemical processes because of their high specificity, selectivity, minimum energy requirement and environmental friendliness. However, many challenges remain in order to exploit fully the potential of industrial enzymes. The qualities which are needed are catalytic proficiency, availability in high quantities, low price, low product inhibition, and high activity and stability under process conditions. Directed evolution and rational design are the most common strategies to produce enzymes with the desired properties. The TIM barrel is the most frequent and most versatile fold among naturally occurring enzymes. In all known TIM barrel enzymes, the catalytically active residues are located at one end of the barrel structure, while residues maintaining the stability of the fold are found on the opposite end of the barrel. This special architecture of the TIM barrel proteins makes it possible to change catalytic activity of the protein without compromising its stability, which is a perfect start for protein engineering studies. In this research project, a monomeric triosephosphate isomerase (TIM) variant with an engineered binding groove (A-TIM) was created by using a rational design approach. The major aims of this work were (i) to find novel binders and (ii) characterize the new, bigger binding groove using X-ray crystallographic methods. These studies have discovered that monomeric A-TIM can bind compounds completely different from the natural substrate. Studies on three different classes of binder molecules are reported: (i) true substrate analogues of wild type TIM, (ii) substrate analogues that have an extended hydrophobic tail, and (iii) more extended, phosphate containing substrate analogues. In addition to this, the A-TIM active site was shown to be competent. In general these studies illustrate the importance of protein crystallography for characterizing the binding properties of enzyme variants being studied in enzyme discovery projects. / Tiivistelmä Entsyymit voivat toimia ylivoimaisina katalyytteinä monissa kemianteollisuuden prosesseissa johtuen niiden hyvästä spesifisyydestä, valikoimiskyvystä, alhaisesta energiantarpeesta ja ympäristöystävällisyydestä. Näistä ominaisuuksista huolimatta entsyymien kaikkien mahdollisuuksien hyödyntämisen esteenä on monia haasteita. Tarvittavia ominaisuuksia ovat katalyyttinen tehokkuus, saatavuus suurina määrinä, alhainen hinta, alhainen tuoteinhibitio sekä korkea aktiivisuus ja stabiilisuus prosessiolosuhteissa. TIM-tynnyrirakenne on yleisin ja monipuolisin proteiinien laskostumisrakenne luonnossa esiintyvissä entsyymeissä. Tässä rakenteessa katalyyttisesti aktiiviset aminohappotähteet ovat sijoittuneet tynnyrirakenteen toiselle puolelle, kun taas stabiilisuuden kannalta tärkeät aminohappotähteet ovat sijoittuneet kokonaan toiselle puolelle. Tämä erityinen rakenne antaa mahdollisuuden muokata proteiinin katalyyttistä aktiivisuutta vaikuttamatta haitallisesti sen stabiilisuuteen. Tämä on täydellinen lähtökohta proteiininmuokkaukselle. Tässä tutkimusprojektissa käytettiin ns. järkiperäistä suunnittelua monomeerisen trioosifosfaatti-isomeraasivariantin (A-TIM) luomisessa. Tämän tutkimustyön pääasialliset tavoitteet olivat (i) uusien sitoutujien löytäminen ja (ii) uuden, suuremman sitoutumistaskun ominaisuuksien määrittäminen röntgenkristallografisilla menetelmillä. Tässä tutkimuksessa havaittiin, että A-TIM kykenee sitomaan yhdisteitä, jotka ovat täysin erilaisia luonnolliseen substraattiin verrattuna. Tässä tutkimuksessa kuvaillaan kolmenlaisia sitoutujia: (i) todelliset villityypin entsyymin substraattianalogit, (ii) substraattianalogit, joihin on liitetty hydrofobinen hiilivetyketju ja (iii) villityypin substraattia suuremmat sokerifosfaatit. Tämän lisäksi A-TIM:n aktiivisen keskuksen todistettiin olevan toimintakykyinen. Yleisellä tasolla tämä tutkimus osoittaa röntgenkristallografisten menetelmien tärkeyden entsyymienmuokkausprojekteissa, joissa entsyymivarianttien ominaisuuksien määritys on tärkeää.
6

D-Aminoacylases and Dipeptidases within the Amidohydrolase Superfamily: Relationship Between Enzyme Structure and Substrate Specificity

Cummings, Jennifer Ann 2010 December 1900 (has links)
Approximately one third of the genes for the completely sequenced bacterial genomes have an unknown, uncertain, or incorrect functional annotation. Approximately 11,000 putative proteins identified from the fully-sequenced microbial genomes are members of the catalytically diverse Amidohydrolase Superfamily. Members of the Amidohydrolase Superfamily separate into 24 Clusters of Orthologous Groups (cogs). Cog3653 includes proteins annotated as N-acyl-D-amino acid deacetylases (DAAs), and proteins within cog2355 are homologues to the human renal dipeptidase. The substrate profiles of three DAAs (Bb3285, Gox1177 and Sco4986) and six microbial dipeptidase (Sco3058, Gox2272, Cc2746, LmoDP, Rsp0802 and Bh2271) were examined with N-acyl-L-, N-acyl-D-, L-Xaa-L-Xaa, L-Xaa-D-Xaa and D-Xaa-L-Xaa substrate libraries. The rates of hydrolysis of the library components were determined by separating the amino acids by HPLC and quantitating the products. Gox1177 and Sco4986 hydrolyzed several N-acyl-D-amino acids, especially those where the amino acid was a hydrophobic residue. Gox1177 hydrolyzed L-Xaa-D-Xaa and N-acetyl-D-amino acids with similar catalytic efficiencies (~10⁴ M⁻¹s⁻¹). The best substrates identified for Gox1177 and Sco4986 were N-acetyl-D-Trp and N-acetyl-D-Phe, respectively. Conversely, Bb3285 hydrolyzed N-acyl-D-Glu substrates (kcat/Km ⁹́⁸ 5 x 10⁶M⁻¹s⁻¹) and, to a lesser extent, L-Xaa-D-Glu dipeptides. The structure of a DAA from A. faecalis did not help explain the substrate specificity of Bb3285. N-methylphosphonate derivatives of D-amino acids were inhibitors of the DAAs examined. The structure of Bb3285 was solved in complex with the N-methylphosphonate derivative of D-Glu or acetate/formate. The specificity of Bb3285 was due to an arginine located on a loop which varied in conformation from the A. faecalis enzyme. In a similar manner, six microbial renal dipeptidase-like proteins were screened with 55 dipeptide libraries. These enzymes hydrolyzed many dipeptides but favored L-D dipeptides. Respectable substrates were identified for proteins Bh2271 (L-Leu-D-Ala, kcat/Km = 7.4 x 10⁴ M⁻¹s⁻¹), Sco3058 (L-Arg-D-Asp, kcat/Km = 7.6 x 10⁵ M⁻¹s⁻¹), Gox2272 (L-Asn-D-Glu, kcat/Km = 4.7 x 10⁵ M⁻¹s⁻¹), Cc2746 (L-Met-D-Leu, kcat/Km = 4.6 x 10⁵ M⁻¹s⁻¹), LmoDP (L-Leu-D-Ala, kcat/Km = 1.1 x 10⁵ M⁻¹s⁻¹), Rsp0802 (L-Met-D-Leu, kcat/Km = 1.1 x 10⁵ M⁻¹s⁻¹). Phosphinate mimics of dipeptides were inhibitors of the dipeptidases. The structures of Sco3058, LmoDP and Rsp0802 were solved in complex with the pseudodipeptide mimics of L-Ala-D-Asp, L-Leu-D-Ala and L-Ala-D-Ala, respectively. The structures were used to assist in the identification of the structural determinants of substrate specificity.

Page generated in 0.0382 seconds