Analysis of a Human Transfer RNA Gene Cluster and Characterization of the Transcription Unit and Two Processed Pseudogenes of Chimpanzee Triosephosphate Isomerase

Craig, Leonard C. (Leonard Callaway)

08 1900

An 18.5-kb human DNA segment was selected from a human XCharon-4A library by hybridization to mammalian valine tRNAiAc and found to encompass a cluster of three tRNA genes. Two valine tRNA genes with anticodons of AAC and CAC, encoding the major and minor cytoplasmic valine tRNA isoacceptors, respectively, and a lysine tRNAcuu gene were identified by Southern blot hybridization and DNA sequence analysis of a 7.1-kb region of the human DNA insert. At least nine Alu family members were found interspersed throughout the human DNA fragment. The tRNA genes are accurately transcribed by RNA polymerase III in a HeLa cell extract, since the RNase Ti fingerprints of the mature-sized tRNA transcription products are consistent with the DNA sequences of the structural genes. Three members of the chimpanzee triosephosphate isomerase (TPI) gene family, the functional transcription unit and two processed pseudogenes, were characterized by genomic blotting and DNA sequence analysis. The bona fide TPI gene spans 3.5 kb with seven exons and six introns, and is the first complete hominoid TPI gene sequenced. The gene exhibits a very high identity with the human and rhesus TPI genes. In particular, the polypeptides of 248 amino acids encoded by the chimpanzee and human TPI genes are identical, although the two coding regions differ in the third codon wobble positions for five amino acids. An Alu member occurs upstream from one of the processed pseudogenes, whereas an isolated endogenous retroviral long terminal repeat (HERV-K) occurs within the structural region of the other processed pseudogene. The ages of the processed pseudogenes were estimated to be 2.6 and 10.4 million years, implying that one was inserted into the genome before the divergence of the chimpanzee and human lineages, and the other inserted into the chimpanzee genome after the divergence.

tRNA genes

Transfer RNA.

Isomerases.

triosephosphate isomerase genes

Characterization of Human Glucose-6-Phosphate Isomerase of Different Sizes

Sun, An Qiang

12 1900

Glucose phosphate isomerase (GPI) was purified from human placenta utilizing cross-linked spherical particle phosphocellulose. In three steps, GPI could be purified approximately 5500 fold with greater than 50% recovery. The purified enzyme exhibited four bands upon non-denaturing PAGE and isoelectric focusing (IEF) when stained with GPI specific activity stain. The four isozymes were isolated by preparative IEF. The isoelectric points of the isozymes were determined. Sodium dodecyl sulfate (SDS) gel electrophoresis showed two types of subunits with different molecular weights. Structural analyses showed both types of subunits had blocked amino termini. Other properties of the isozymes and subunits, including immunological reactivity, pH stability, peptide mapping and amino acid composition, were also established.

glucose phospate isomerase

isozymes

purification of isomerases

Isomerases

Isoenzymes

Characterization of Genes Involved in Chromatic Acclimation in the Cyanobacterium Synechococcus sp. A 15-62

Pokhrel, Suman

01 May 2018

Synechococcus, a genus of photosynthetic cyanobacteria, is the second most abundant oxygenic microorganism in the marine environment that contributes significantly to the ocean’s primary productivity (Humily et al. 2013; Shukla et al. 2012). They are capable of utilizing available light of different wavelengths in the visible spectrum to perform photosynthesis and fix carbon dioxide and thus inhabit a wide range of light niches in the ocean along horizontal (coast vs offshore) and vertical gradients (depth) (Humily et al. 2013). A gene encoding a putative lyase isomerase, mpeQ, is present in phycoerythrin-II encoding operon that is expressed constitutively and a gene encoding putative lyase, mpeW, is present in CA-4 genomic island whose expression is regulated by ambient light color were identified and characterized in Synechococcus sp. A15- 62, a strain having a blue light specialist phenotype in its basal state. The amino acid sequence of the proteins encoded by mpeW and mpeQ are similar to other characterized lyases and these genes are conserved in cyanobacteria strains containing the CA4-B genomic island, which controls CA4 (Humily et al. 2013). The MpeW and MpeQ proteins were produced in E. coli and co-expressed with recombinant HT-MpeA and phycoerythrobilin (PEB) synthesis machinery. Site directed mutants of the HT-MpeA protein (Cys75Ala, Cys83Ala, Cys140Ala) were used to investigate the site for bilin attachment. The recombinant protein co-expression experiments of MpeQ and MpeW demonstrated that MpeQ attaches phycoerythrobilin (PEB) to cysteine-83 site on a-phycoerythrin II and isomerizes it to phycourobilin (PUB) and MpeW attaches phycoerythrobilin (PEB) to the same site.

Biology

Molecular insights into the protein disulfide isomerase family / Molekulare Mechanismen der Protein Disulfid Isomerase Familie

Kober, Franz-Xaver Wilhelm

January 2012

Upon synthesis, nascent polypeptide chains are subject to major rearrangements of their side chains to obtain an energetically more favorable conformation in a process called folding. About one third of all cellular proteins pass through the secretory pathway and undergo oxidative folding in the endoplasmic reticulum (ER). During oxidative folding, the conformational rearrangements are accompanied by the formation of disulfide bonds – covalent bonds between cysteine side chains that form upon oxidation. Protein disulfide isomerase (PDI) assists in the folding of substrates by catalyzing the oxidation of pairs of cysteine residues and the isomerization of disulfide bonds as well as by acting as chaperones. In addition to PDI itself, a family of related ER-resident proteins has formed. All PDI family members share the thioredoxin fold in at least one of their domains and exhibit a subset of the PDI activities. Despite many studies, the role of most PDI family members remains unclear. The project presented in this thesis was aimed to establish tools for the biochemical characterization of single members of the PDI family and their role in the folding process. A combination of fluorescence based assays was developed to selectively study single functions of PDI family members and relate their properties of either catalysis of oxidation or catalysis of isomerization or chaperone activity to the rest of the protein family. A binding assay using isothermal titration calorimetry (ITC) was established to complement the activity assays. Using ITC we could show for the first time that members of the PDI family can distinguish between folded and unfolded proteins selectively binding the latter. The unique information provided by this method also revealed a two-site binding of unfolded proteins by PDI itself. In addition to the functional characterization, experiments were conducted to further investigate the oligomeric state of PDI. We could show that the equilibrium between structurally different states of PDI is heavily influenced by the redox state of the protein and its environment. This new data could help to further our understanding of the interplay between oxidases like PDI and their regenerative enzymes like Ero1, which may be governed by structural changes in response to the change in redox status. Another structural approach was the screening of all investigated PDI family members for suitable crystallization conditions. As a result of this screening we could obtain protein crystals of human ERp27 and were able to solve the structure of this protein with X-ray crystallography. The structure gives insight into the mechanisms of substrate binding domains within the PDI family and helps to understand the interaction of ERp27 with the redox active ERp57. In collaboration with the group of Heike Hermanns we could further show the physiological importance of this interaction under oxidative stress. In conclusion, the project presented in this thesis provides novel tools for an extensive analysis of the activities of single PDI family members as well as a useful set of methods to characterize novel oxidoreductases and chaperones. The initial results obtained with the our novel methods are very promising. At the same time, the structural approach of this project could successfully solve the structure of a PDI family member and give information about the interplay within the PDI family. / Umlagerungsprozess nennt man Proteinfaltung. Schätzungsweise ein Drittel aller zellulären Proteine werden über den sekretorischen Transportweg geschleust und durchlaufen die oxidative Proteinfaltung im endoplasmatischen Retikulum (ER). Während der oxidativen Faltung werden zusätzlich zur Umlagerung von Seitenketten auch Disulfidbrücken gebildet. Dies sind kovalente Bindungen zwischen Zystein-Seitenketten durch Oxidation entstehen. Protein Disulfid Isomerase (PDI) unterstützt die Faltung von Proteinen im ER indem es die Oxidation zweier Zystein- Seitenketten katalysiert. Neben der Oxidation katalysiert PDI ebenfalls die Isomerisierung von fehlverknüpften Disulfidbrücken und wirkt als Chaperon der Aggregation entgegen. Im Laufe der Evolution hat sich zusätzlich zu PDI eine Gruppe verwandter ER-lokalisierter Proteine gebildet. Diese Mitglieder der PDI-Familie weisen alle das Thioredoxin-Faltungsmotiv in mindestens einer ihrer Domänen auf und besitzen mindestens eine der drei PDI-Aktivitäten. Trotz eingehender Untersuchung ist die Rolle der meisten dieser PDI Familienmitglieder weiterhin unklar. Im Rahmen des Projekts, welches dieser Dissertation zugrunde liegt, wurden Methoden zur biochemischen Charakterisierung einzelner Mitglieder der PDI-Familie, und deren Rolle im Faltungsprozess, entwickelt. Eine Kombination von Fluoreszenzexperimenten wurde etabliert mit der selektiv einzelne Aktivitäten von Faltungshelfern analysiert und qualitativ in die PDI- Familie eingeordnet werde können. Diese fluoreszenzbasierten Methoden wurden durch isothermale Titrationkalorimetrie (ITC) ergänzt. Mit ITC konnten wir als Erste zeigen, dass PDI- Familienmitglieder gefaltete von ungefalteten Proteinen unterscheiden können und letztere selektiv binden. Die zusätzlichen Informationen, die in einem ITC-Experiment gewonnen wurden, zeigten, dass PDI mit Substraten mit Hilfe von zwei unterschiedlichen Bindungsstellen interagiert. Neben der funktionellen Analyse der PDI-Familie wurde Experimente durchgeführt um den oligomeren Zustand von PDI näher zu untersuchen. Wir konnten zeigen, dass das Gleichgewicht zwischen strukturell verschiedenen Zuständen entscheidend vom Redox-Status von PDI abhängt. Diese neuen Daten werfen ein neues Licht auf die Interaktion zwischen Oxidasen wie PDI und ihren regenerativen Enzymen wie Ero1. Diese Interaktion könnte sehr wohl durch strukturelle Veränderungen, ausgelöst durch Redox-Reaktionen, reguliert werden. Als weiteren strukturellen Ansatz zur Erforschung der PDI-Familie wurden alle verwendeten Familienmitglieder auf aussichtsreiche Kristallisationsbedingungen hin untersucht. Durch dieses Screening konnte ERp27 kristallisiert und seine Struktur durch Röntgenkristallografie aufgeklärt werden. Die so gewonnene Struktur gibt Aufschluss über die Mechanismen der Substratbindung in der PDI- Familie und hilft ebenfalls dabei, die Interaktion zwischen ERp27 und dem redoxaktiven ERp57 besser zu verstehen. Auf Grund dieser Daten konnten wir gemeinsam mit der Gruppe von Heike Hermanns die physiologische Bedeutung dieser Interaktion bei oxidativem Stress aufzeigen. Zusammenfassend konnten im Rahmen dieses Projektes neue Werkzeuge zur eingehenden Analyse der PDI-Familie etabliert werden, welche auch zur Charakterisierung neuer Oxidoreduktasen und Chaperone verwendet werden können. Die ersten Ergebnisse die mit Hilfe dieser neuen Methoden gewonnen werden konnten sind vielversprechen. Gleichzeitig konnten wir mit ERp27 die Struktur eines weiteren PDI-Familienmitgliedes lösen und so weitere Einblicke in das komplexe Netzwerk der PDI-Familie gewinnen.

Biochemie

Proteinfaltung

Disulfidbrücken

Protein Disulfid Isomerase

ddc:570

Steroid receptor-associated immunophilins : influence of targeted knockdown and altered expression on receptor signalling

Cluning, Carmel

January 2008

[Truncated abstract] Steroid receptors belong to the superfamily of nuclear receptors, and include the androgen receptor (AR), estrogen receptors (ER[alpha] and ER[beta], glucocorticoid receptor (GR), mineralocorticoid receptor (MR), and the progesterone receptors (PRA and PRB). Before binding ligand, the receptor undergoes biochemical and structural modifications through a series of interactions with molecular chaperones and cochaperones all within a receptor heterocomplex. The mature receptor complexes with the major chaperone Hsp90, the stabilising cochaperone p23, and one member of a group of cochaperones termed immunophilins. Steroid receptor-associated immunophilins include the cyclophilin, CyP40, two FK506-binding proteins, FKBP51 and FKBP52, and the protein phosphatase, PP5. Immunophilins are characterised by the presence of TPR domains which compete directly for the TPR-acceptor site within Hsp90. This leads to mutually exclusive, immunophilin-containing receptor complexes. While PP5 contains a C-terminal phosphatase domain, CyP40, FKBP51 and FKBP52 each contain an N-terminal peptidyl prolyl isomerase (PPIase) domain, which catalyses the cis/trans isomerisation of prolyl peptide bonds. FKBP52 has been demonstrated to potentiate the ligand-dependent activity of AR, GR and PR, but not ER[alpha]. Knowing that CyP40 is the preferred immunophilin associated with the ER[alpha] heterocomplex, it was hypothesised that this immunophilin plays a role in ER[alpha] function. ... As all mutants maintained this potentiating activity it was concluded that the five altered residues found within gpGR do not contribute to the altered interaction of FKBP52 and receptor. However, it cannot be discounted that FKBP51 is more competitive for gpGR. Immunophilins are hormonally regulated, with FKBP52 found to be essential for female fertility in mice. It was hypothesised that levels of immunophilins, associated with steroid receptors important in the menstrual cycle, would be regulated to reflect hormonal activity within cycling endometrium. Human pre-menopausal endometrial sections taken from different phases of the menstrual cycle were examined immunohistochemically for expression of CyP40, FKBP51, FKBP51 and PP5. Immunophilin levels peaked at the mid-secretory phase correlating with stromal decidualization, a process essential for eventual blastocyst implantation. The importance of immunophilins to steroid receptor action was therefore reinforced by the observation that immunophilins appear to be hormonally regulated in cycling pre-menopausal human endometrium. Further studies into the effects of immunophilin loss and knockdown on steroid receptor-mediated responses in specific mouse tissues, knockout-derived mouse embryo fibroblasts and cancer cell lines may contribute to our understanding of the receptor-selective and tissue-specific actions of the immunophilins. Elucidation of the mechanisms through which they modulate receptor function may provide opportunities for therapeutic intervention in steroid-related disease.

Hormones, Sex -- Receptors

Peptidylprolyl isomerase

Immunophilins

Steroid receptors

Metabolical Engineering Of Pichia Pastoris For Extracellular Thermostable Glucose Isomerase Production

Ata, Ozge

01 September 2012

The aim of this study is to develop a metabolically engineered P. pastoris strain for production of an active extracellular thermostable glucose isomerase (GI) enzyme by using genetic engineering techniques. For this purpose, research program was performed in two sub-programs. In the first sub-program, xylA gene from Thermus thermophilus was amplified and inserted into pPICZ&alpha / -A expression vector. Thereafter, this pPICZ&alpha / -A::xylA vector was cloned into AOX1 locus in P. pastoris genome and expressed under alcohol oxidase promoter which is induced by methanol. After constructing the recombinant P. pastoris strains, the best producing strain was selected according to the specific enzyme activity assay and SDS-PAGE analyses in batch shaker-bioreactor experiments. The selected recombinant P. pastoris clone carrying xylA gene in its genome was named as eP20. Using recombinant P. pastoris eP20 clone, effects of salt and sorbitol concentration on the cell growth and recombinant GI activity were investigated. The data obtained from the experiments showed that the maximum cell and GI activity values were obtained in production medium that contained 30 g L-1 sorbitol, 4.35 g L-1 ammonium sulphate, 0.1 M potassium phosphate buffer (pH 6.0), 14.9 g L-1 MgSO4&bull / 7H2O, 1.17 g L-1 CaSO4 &bull / 2H2O, 1 ml L-1 chloramphenicol and 4.35 ml L-1 PTM1 / where, the maximum biomass and recombinant GI activity were calculated , respectively, as 6.3 g L-1 and 3.21 U L-1. Moreover, the research program related with the effect of initial sorbitol concentration shows that optimum initial sorbitol concentration, CS0 is 50 g L-1 that resulted a cell concentration and recombinant GI activity which are 7.32 g L-1 and 3.6 U L-1, respectively. In the second part of the M.Sc. of the study, a pilot scale bioreactor experiment in a working volume of 1 L was performed in controlled bioreactor system. The variations in the cell growth, recombinant GI activity, AOX activity, total protease activity and organic acid concentrations throughout the fermentation were analyzed whereas the specific growth rates, yield coefficients and specific consumption rates were also calculated. The results showed that a pH and oxygen controlled operation enabled an important increase in recombinant GI activity. In this context, recombinant GI activity was increased as 56.1-fold and resulted in 202.8 U L-1 at t=12 whereas the maximum biomass concentration was obtained as 85.2 g L-1 at t=36. In this study, an active thermostable recombinant GI enzyme was produced extracellularly by a yeast cell, i.e. recombinant P. pastoris, for the first time.

QH Genetics 426-470

The role of protein disulfide isomerase (PDI) in oxidative folding

Gonzalez, Veronica.

January 2008

Thesis (M.S.)--University of Texas at El Paso, 2008. / Title from title screen. Vita. CD-ROM. Includes bibliographical references. Also available online.

PDI, reactive oxygen species stress and polyphenolic phytochemicals implications for neurodegenerative diseases /

Pal, Rituraj,

January 2009

Thesis (M.S.)--University of Texas at El Paso, 2009. / Title from title screen. Vita. CD-ROM. Includes bibliographical references. Also available online.

Cloning, purification and crystallization of selenophosphate synthetase cloning, purification and crystallization of ERp44 from Mus musculus /

Chang, Li-Chi.

Unknown Date

Techn. University, Diss., 2006--München.

The interaction of silver nanoparticles with triosephosphate isomerase from human and malarial parasite (Plasmodium falciparum) : a comparative study

De Moor, Warren Ralph Josephus

January 2014

The advent of advanced modern nanotechnology techniques offers new and exciting opportunities to develop novel nanotech-derived antimalarial nanodrugs with enhanced selective and targeting abilities that allow for lower effective drug dosages, longer drug persistence and reduced drug degradation within the body. Using a nanodrug approach also has the advantage of avoiding drug resistance problems that plague reconfigured versions of already-existing antimalarial drugs. In this study recombinant triosephosphate isomerase enzymes from Plasmodium falciparum (PfTIM) and Humans (hTIM) were recombinantly expressed, purified and characterised. PfTIM was shown to have optimal pH stability at pH 5.0-5.5 and thermal stability at 25°C with Km 4.34 mM and Vmax 0.876 μmol.ml⁻ₑmin⁻ₑ. For hTIM, these parameters were as follows: pH optima of 6.5-7.0; temperature optima of 30°C, with Km 2.27 mM and Vmax 0.714 μmol.ml⁻ₑmin⁻ₑ. Recombinant TIM enzymes were subjected to inhibition studies using polyvinylpyrrolidone (PVP) stabilised silver nanoparticles (AgNPs) of 4-12 nm in diameter. These studies showed that the AgNPs were able to selectively inhibit PfTIM over hTIM with an 8-fold greater decrease in enzymatic efficiency (Kcat/Km) observed for PfTIM, as compared to hTIM, for kinetics tests done using 0.06 μM of AgNPs. Complete inhibition of PfTIM under optimal conditions was achieved using 0.25 μM AgNPs after 45 minutes while hTIM maintained approximately 31% of its activity at this AgNP concentration. The above results indicate that selective enzymatic targeting of the important, key metabolic enzyme TIM, can be achieved using nanotechnology-derived nanodrugs. It was demonstrated that the key structural differences, between the two enzyme variants, were significant enough to create unique characteristics for each TIM variant, thereby allowing for selective enzyme targeting using AgNPs. If these AgNPs could be coupled with a nanotechnology-derived, targeted localization mechanism – possibly using apoferritin to deliver the AgNPs to infected erythrocytes (Burns and Pollock, 2008) – then such an approach could offer new opportunities for the development of viable antimalarial nanodrugs. For this to be achieved further research into several key areas will be required, including nanoparticle toxicity, drug localization and testing the lethality of the system on live parasite cultures.

Silver

Nanoparticles

Triose-phosphate isomerase

Plasmodium falciparum

Nanotechnology

Antimalarials

Povidone