Caracterización de ODCp como una nueva proteína inhibidora de antizimias (AZIN2). Aspectos estructurales y funcionales

López Contreras, Andrés Joaquín

31 October 2008

Las poliaminas regulan procesos de crecimiento y diferenciación celular, y su desregulación está relacionada con diferentes patologías incluyendo el cáncer. Las antizimas (AZs) de ornitina descarboxilasa (ODC) inhiben tanto su biosíntesis, como su captación, regulando los niveles intracelulares de poliaminas. En esta tesis se ha caracterizado una nueva proteína inhibidora de antizimas (AZIN2) que posee alta homología con ODC y el inhibidor de antizimas previamente conocido (AZIN1). Esta nueva proteína está desprovista de actividad enzimática, pero es capaz de revertir la acción que las tres antizimas conocidas ejercen sobre la actividad ODC y la captación de poliaminas. A diferencia de sus proteínas homólogas, AZIN2 se localiza subcelularmente en el ERGIC, y se expresa específicamente en cerebro y testículo, pero de forma muy abundante en espermátidas y espermatozoides, al igual que AZ3, indicando que estas dos proteínas juegan un importante papel regulando los niveles de poliaminas durante la espermiogénesis. / Polyamines regulate cell growth and differentiation, and the alteration of their homeostasis is related to different diseases, including cancer. Ornithine decarboxylase (ODC) antizymes (AZs) regulate polyamine levels by inhibiting both their biosynthesis and the cellular uptake. In this work, a new ODC paralogue has been characterized as a novel antizyme inhibitor protein that has been named AZIN2. This protein lacks decarboxylating activity, but it is able to reverse the action of any of the three antizymes on ODC activity and polyamine uptake. Unlike its homologue proteins ODC and AZIN1, AZIN2 is located in the ERGIC, and it is specifically expressed in brain and testes. The abundant expression in spermatids and spermatozoa, concomitantly with AZ3, suggests that both proteins may play an important role in regulating polyamine levels during spermiogenesis

Antizymes

Ornithine decarboxylase

Polyamines

Transporte de poliaminas

Espermatogénesis

Inhibidor de Antizimas

Antizimas

Ornitina descarboxilasa

Poliaminas

Antizyme Inhibitor

Spermatogenesis

Polyamine Transport

Bioquímica y Biología Molecular

577

Mechanism Of Anticancer And Antimalarial Action Of A Modulator Of Heat Shock Proteins

Ramya, T N C

06 1900

This thesis entitled “Mechanism of Anticancer and Antimalarial Action of a Modulator of Heat Shock Proteins” describes the successful elucidation of the mechanism of anticancer and antimalarial action of 15-Deoxyspergualin (DSG). DSG, a relatively well known immunosuppressant and antitumor molecule has been demonstrated to kill the malaria parasite in vitro and in vivo (Midorikawa et al., 1997; Midorikawa et al., 1998). A highly polar molecule, DSG binds the carboxy terminal “EEVD” motif of heat shock proteins, Hsp70 and Hsp90, enhances the ATPase activity of Hsp70 (Nadler et al., 1992; Nadler et al., 1998), and modulates several seemingly unrelated cellular processes. DSG has also been demonstrated to inhibit protein synthesis and polyamine synthesis in cells (Kawada et al., 2002; Hibasami et al., 1991), and previously speculated to inhibit malaria parasite growth by inhibiting polyamine synthesis. The grim situation with regard to malaria infection and mortality, principally an offshoot of the emergence of chloroquine resistant strains of the causative agent of malaria - Plasmodium falciparum, calls for intense efforts towards developing efficacious antimalarial agents with few side effects. DSG, having been used already in graft rejection cases in man and demonstrated to potently inhibit malaria in mice (Midorikawa et al., 1997), offers promise in this regard. It was, therefore, of interest to solve the mystery of its mechanism of antimalarial action. Chapter 1 surveys literature related to DSG mechanism of action and presents the thesis objective. Chapter 1 also gives an overview of heat shock proteins and their role in cancer, and the biology of the malaria parasite (Plasmodium falciparum), the working of the principal metabolic pathways existing in it, and a description of processes related to the intriguing, relict plastid present in apicomplexans. The metabolic processes previously speculated to be targeted by DSG, and those later found to be involved in DSG mechanism of action – polyamine synthesis and transport, protein synthesis and apicoplast processes are dealt with in more detail. Though DSG has been speculated to kill the malaria parasite by inhibiting polyamine synthesis, that DSG could clear malaria infection in Plasmodium berghei infected mice did not corroborate with the observation that inhibitors of polyamine biosynthesis are incapable of inhibiting the malaria parasite in vivo probably because the parasites make do with polyamines salvaged from the host (Assaraf et al., 1984; Bitonti et al., 1987). On the other hand, DSG is known to bind heat shock proteins, and inhibit protein synthesis, and heat shock proteins are speculated to be involved in the activation of HRI (heme regulated inhibitor), a type of eIF2á kinase that phosphorylates the eukaryotic initiation factor, eIF2á in conditions of heme deficiency or other cellular stress. eIF2á phosphorylation leads to stalling of protein synthesis. It seemed likely that if HRI is activated upon sequestration of heat shock proteins by DSG, it would culminate in protein synthesis inhibition and ultimately, cell death. With the intention to investigate this line of thought, the PlasmodB database was mined for proteins essential to the existence of heme dependent protein synthesis in Plasmodium falciparum. Two Hsp70 proteins from Plasmodium falciparum, one with the carboxy terminal “EEVD” motif implicated in DSG binding, and one without, and an Hsp70 interacting protein were cloned and expressed in their recombinant form in Escherichia coli. The preliminary characterization of these heat shock proteins described in Chapter 2 revealed that they were functionally active. DSG did not inhibit either the chaperone activity of the Hsp70s or the interaction of Hsp70 with Hip, but stimulated their ATPase activity as anticipated. Chapter 3 gives a complete picture of the mechanism of protein synthesis inhibition by DSG in the standard protein synthesis system – reticulocyte lysate. The experiments carried out revealed that DSG inhibits protein synthesis precisely through the mechanism envisaged, i.e. through phosphorylation of HRI following sequestration of Hsp70. Experiments involving exogenous addition of heat shock protein to in vitro translation reactions confirmed this hypothesis. Moreover, DSG inhibited protein synthesis in cancer cells in vivo, too, and HRI knockdown cells were not affected by DSG. Interestingly, the Hsp70 levels in various cancer cell lines inversely correlated with the inhibitory activity of DSG, and modulation of Hsp70 levels through standard methods altered DSG inhibition of protein synthesis in these cells. It was thus confirmed that DSG did indeed inhibit mammalian cells through the pathway envisaged. Its previously reported antitumor property is probably through this outlined mechanism of interference with protein regulation. In the malaria parasite, too, DSG inhibited protein synthesis through eIF2 alpha phosphorylation following Hsp70 sequestration as outlined in Chapter 4. However, while the concentration of DSG required for inhibition of malaria parasite growth was in the nanomolar range, high micromolar concentrations of DSG were required to effect protein synthesis inhibition in the malaria parasite, indicating that yet another target for DSG existed in the malaria parasite. With protein synthesis no longer a candidate target of DSG, I looked into the previously implicated polyamine synthesis pathway. In the event of DSG inhibiting polyamine transport in addition to polyamine biosynthesis, it would be expected to clear malaria infection in vivo contrary to other inhibitors of polyamine biosynthesis. In Chapter 5, evidence for the polyamine synthesis pathway in the malaria parasite is provided. Experiments involving incorporation of radiolabeled precursors in the malaria parasite and in mammalian cells, however, revealed that only high micromolar concentrations of DSG inhibit polyamine synthesis. Polyamine transport was also studied in considerable detail in malaria parasite infected red blood cells. Though infected red blood cells demonstrated different kinetic parameters, implying that new polyamine transporters were employed by the parasite on the red blood cell upon infection, DSG did not potently inhibit polyamine transport, either. The mystery of the target of DSG in the malaria parasite was, however, close to solution, when the growth inhibition of the malaria parasite by DSG was studied carefully. DSG invoked “delayed death” – a phenomenon wherein death is invoked only one cycle after incubation with the inhibitor. “Delayed death” is typical of inhibitors that target apicoplast processes (Fichera and Roos, 1997). DSG did not inhibit either fatty acid synthesis or prokaryotic protein synthesis – processes that occur in the apicoplast, but effected a decrease in the amount of nucleus encoded proteins that are targeted to the apicoplast, suggesting that it inhibited the trafficking of nucleus encoded proteins to the apicoplast. Confocal microscopy of parasites transfected with GFP fusion protein confirmed these findings, and is described in Chapter 6. The thesis ends with a summary of the findings in Chapter 7. Apicoplast processes have always been considered to harbor immense potential in the development of antimalarial agents, thanks to the absence of an equivalent organelle and hence pathways, in the human host. Trafficking of nucleus encoded proteins to the apicoplast has remained unexplored however. The work done in this thesis not only serves to demystify DSG with regard to its mechanism of action, but also paves the way for further studies in this area of intracellular trafficking, which could help in the development of more efficacious antimalarial agents. It also adds a new dimension to previous work conducted with regard to the anticancer action of DSG. Appendix 1 revolves around inhibitors which target various apicoplast processes. Apicoplast processes have been conventionally linked to the intriguing but unfortunate (with respect to clinical application) “delayed death”. Results presented in this section demonstrate that not all apicoplast processes invoke “delayed death”. Inhibition of apicoplast processes such as fatty acid biosynthesis and heme synthesis evoke rapid death. Inhibitors designed to target these processes could, therefore, be highly efficacious.

Proteins

Anticancer Proteins

Antimalarial Action

Deoxyspergualin Mechanism

Heat Shock Proteins

Protein Synthesis

Polyamine Synthesis

Malaria Parasites

15-Deoxyspergualin (DSG)

Malaria

Apoptosis

Hsp70

Plasmodium falciparam

Biochemistry

Pyruvoyl dependent arginine decarboxylases from Chlamydiae and Crenarchaea

Giles, Teresa Neelima

06 November 2012

Arginine decarboxylase is a key enzyme involved in the polyamine pathway of organisms. Pyruvoyl-dependent arginine decarboxylases are expressed in the form of proenzymes that self-cleave to form N-terminal [beta] and C-terminal [alpha] subunits generating an active pyruvoyl group at the [alpha] terminus. We have identified an archaeal homolog of a pyruvoyl-dependent arginine decarboxylase in Chlamydophila pneumoniae that could play a role in the persistence of the organism in the host. The recombinant enzyme showed highest activity at pH 3.4, which is the lowest optimum pH ever reported for a pyruvoyl dependent arginine decarboxylase. The proton-consuming decarboxylation raises intracellular pH, and thereby plays a role in acid-resistance. It could inhibit the pro-inflammatory nitric oxide synthase resulting in asymptomatic infection. A variant protein Thr⁵²Ser at the predicted cleavage site showed less pro-enzyme cleavage and activity compared to the wild-type. The homologs of arginine decarboxylase and flanking arginine-agmatine antiporter were also found in different biovariants of Chlamydia trachomatis. In the invasive L2 strain of C. trachomatis, the presence of a nonsense codon in the gene encoding arginine decarboxylase enzyme prevented the expression of an active enzyme. The variant protein with tryptophan replacing nonsense codon restored arginine decarboxylase activity. The non-invasive D strain of C. trachomatis had an intact arginine decarboxylase gene, but it was recombinantly expressed as a proenzyme that was uncleaved. The arginine-agmatine antiporters from both the strains were active and transported tritiated arginine into their cells. The polyamine pathway of the crenarchaeon Sulfolobus solfataricus uses arginine to make putrescine, but the organism lacks homologs of arginine decarboxylase. However, it has two paralogs of pyruvoyl dependent S-adenosylmethionine decarboxylase − SSO0536 and SSO0585. These enzymes were recombinantly expressed as pro-enzymes that self-cleaved into [beta] and [alpha] subunits. Even with a 47% amino acid sequence identity, the SSO0536 protein exhibited significant arginine decarboxylase activity whereas SSO0585 protein had significant S-adenosylmethionine decarboxylase activity. This is the first report of an S-adenosylmethionine decarboxylase enzyme showing alternative decarboxylase activity. The chimeric protein with the [alpha]-subunit of SSO0585 and [beta]-subunit of SSO0536 had arginine decarboxylase activity, suggesting that the residues responsible for substrate recognition are located in the amino terminus. / text

Arginine decarboxylase

Polyamine pathway

Pyruvoyl-dependent

Pro-enzyme cleavage

Chlamydophila pneumoniae

pH

Chlamydia trachomatis

Arginine-agmatine antiporters

Sulfolobus solfataricus

Homologs

Amino terminus

Impact of intestinal bacteria on the anatomy and physiology of the intestinal tract in the PRM/Alf mouse model

Slezak, Kathleen

January 2013

Introduction: Intestinal bacteria influence gut morphology by affecting epithelial cell proliferation, development of the lamina propria, villus length and crypt depth [1]. Gut microbiota-derived factors have been proposed to also play a role in the development of a 30 % longer intestine, that is characteristic of PRM/Alf mice compared to other mouse strains [2, 3]. Polyamines and SCFAs produced by gut bacteria are important growth factors, which possibly influence mucosal morphology, in particular villus length and crypt depth and play a role in gut lengthening in the PRM/Alf mouse. However, experimental evidence is lacking. Aim: The objective of this work was to clarify the role of bacterially-produced polyamines on crypt depth, mucosa thickness and epithelial cell proliferation. For this purpose, C3H mice associated with a simplified human microbiota (SIHUMI) were compared with mice colonized with SIHUMI complemented by the polyamine-producing Fusobacterium varium (SIHUMI + Fv). In addition, the microbial impact on gut lengthening in PRM/Alf mice was characterized and the contribution of SCFAs and polyamines to this phenotype was examined. Results: SIHUMI + Fv mice exhibited an up to 1.7 fold higher intestinal polyamine concentration compared to SIHUMI mice, which was mainly due to increased putrescine concentrations. However, no differences were observed in crypt depth, mucosa thickness and epithelial proliferation. In PRM/Alf mice, the intestine of conventional mice was 8.5 % longer compared to germfree mice. In contrast, intestinal lengths of C3H mice were similar, independent of the colonization status. The comparison of PRM/Alf and C3H mice, both associated with SIHUMI + Fv, demonstrated that PRM/Alf mice had a 35.9 % longer intestine than C3H mice. However, intestinal SCFA and polyamine concentrations of PRM/Alf mice were similar or even lower, except N acetylcadaverine, which was 3.1-fold higher in PRM/Alf mice. When germfree PRM/Alf mice were associated with a complex PRM/Alf microbiota, the intestine was one quarter longer compared to PRM/Alf mice colonized with a C3H microbiota. This gut elongation correlated with levels of the polyamine N acetylspermine. Conclusion: The intestinal microbiota is able to influence intestinal length dependent on microbial composition and on the mouse genotype. Although SCFAs do not contribute to gut elongation, an influence of the polyamines N acetylcadaverine and N acetylspermine is conceivable. In addition, the study clearly demonstrated that bacterial putrescine does not influence gut morphology in C3H mice. / Einleitung: Die intestinale Mikrobiota beeinflusst die Morphologie des Darmes durch Beeinflussung der Epithelzellproliferation, Entwicklung der Lamina Propria, Zottenlänge und Kryptentiefe [1]. Zudem stehen bakterielle Faktoren im Verdacht, die Entwicklung eines 30 % längeren Darmes in der PRM/Alf Maus gegenüber anderen Mausstämmen zu begünstigen [2, 3]. Die von der intestinalen Mikrobiota produzierten Polyamine und kurzkettigen Fettsäuren (SCFA) stellen wichtige Wachstumsfaktoren dar, die bei der Ausbildung des Darmes sowie an der Darmverlängerung in der PRM/Alf Maus beteiligt sein könnten. Zielstellung: Ziel dieser Arbeit war, den Einfluss von bakteriell-produzierten Polyaminen auf die Kryptentiefe, Schleimhautdicke und Epithelzellproliferation zu untersuchen. Zu diesem Zweck wurden keimfreie C3H Mäuse mit einer vereinfachten menschlichen Mikrobiota (SIHUMI) assoziiert und mit C3H Mäusen, die mit einer SIHUMI plus dem polyaminproduzierendem Fusobacterium varium (SIHUMI + Fv) besiedelt worden waren, verglichen. Weiterhin sollte der mikrobielle Einfluss sowie die Rolle von SCFAs und Polyaminen bei der Ausbildung eines verlängerten Darms in der PRM/Alf Maus untersucht werden. Ergebnisse: Die SIHUMI + Fv Mäuse zeigten eine bis zu 1,7 fach höhere intestinale Polyaminkonzentration im Vergleich zu SIHUMI-Mäusen, welche vor allem auf eine Erhöhung von Putrescin zurückzuführen war. Trotz der höheren Polyaminkonzentrationen wurden keine Unterschiede in der Kryptentiefe, Schleimhautdicke und Epithelzellproliferation beobachtet. Die Untersuchung der Darmlänge in PRM/Alf Mäusen in Abhängigkeit vom Besiedlungsstatus ergab einen 8,5 % längeren Darm in konventionell besiedelten PRM/Alf Mäusen im Vergleich zu keimfreien PRM/Alf Mäusen. Im Gegensatz dazu wurden in C3H-Mäusen keine Unterschiede in der Darmlänge in Abhängigkeit von der Besiedlung beobachtet. Der Vergleich zwischen PRM/Alf und C3H Mäusen, die beide mit der SIHUMI + Fv Mikrobiota assoziiert wurden, zeigte einen 35,9 % längeren Darm in PRM/Alf Mäusen. Trotz des längeren Darmes waren die intestinalen SCFA- und Polyaminkonzentrationen vergleichbar bzw. geringer als in C3H Mäusen, mit einer Ausnahme: Die Konzentration von N Acetylcadaverin war in PRM/Alf Mäusen 3,1-fach erhöht. Wurden keimfreie PRM/Alf Mäuse mit einer komplexen PRM/Alf Mikrobiota assoziiert, so war ihr Darm ein Viertel länger als bei PRM/Alf Mäusen, die mit einer C3H Mikrobiota besiedelt wurden. Dieser längere Darm korrelierte mit der N Acetylsperminkonzentration. Schlussfolgerung: Die intestinale Mikrobiota ist in der Lage, die Darmlänge abhängig von der mikrobiellen Zusammensetzung und von dem Genotyp des Wirtes zu beeinflussen. Obwohl SCFAs die Darmlänge nicht beeinflussten, ist eine Beteiligung der Polyamine N Acetylcadaverin und N Acetylspermin denkbar. Darüber hinaus zeigte die Studie, dass Putrescin die Anatomie des Darmes in C3H Mäusen nicht beeinflusst.

Darmbakterien

Darmlänge

Polyamine

Kurzkettige Fettsäuren

PRM/Alf Maus

gut microbiota

gut length

polyamines

short chain fatty acids

PRM/Alf mouse

Life sciences

Níveis de Putrescina, Poliaminas e Nutrientes Minerais Relacionados a Diferentes Concentrações de Potássio em Bananeira (Musa sp., AAA e AAB) cvs. Nanica e Prata Anã in Vitro / Levels of putrescine, polyamines and mineral nutrients in relation to different potassium concentrations in banana plant (Musa sp., AAA and AAB) cvs. Nanica and Prata anã in vitro condition

Humberto Actis Zaidan

31 March 1998

Nas abordagens biotecnológicas de propagação de plantas, os meios de cultura devem ter uma composição química adequada à essa finalidade permitindo a otimização da produção. Como a bananeira (Musa sp.) é exigente em potássio, a busca do nível adequado desse macronutriente envolve não somente o comprometimento com o nível dos outros nutrientes (balanço iônico), mas também a relação entre eles. Para acompanhar os efeitos fisiológicos das relações de vários teores de K com os outros macro e micronutrientes é que explantes caulinares dos cvs. Nanica e Prata Anã foram cultivados em meio MS modificado em presença de BAP, sacarose, vitaminas, agar, suplementado com 6 diferentes doses de K: 5, 10, 15, 20, 25 e 30 mM, sendo que a dose 20 mM corresponde à concentração de K existente no MS básico, que foi adotado como controle.Foram feitas análises de massa de matéria seca (MMS),macro e micronutrientes na parte aérea, raiz e plântulas inteiras. Ao final do experimento foi determinado o número de plântulas e calculado o valor das relações N/K, K/P, K/Ca, K/Mg, K/Ca+Mg, K/S, K/Cu, K/Fe, K/Mn, K/Zn.Foram também dosados os teores da diamina putrescina e de poliaminas, e calculada a relação K/putrescina. Todos os parâmetros foram analisados segundo um delineamento experimental inteiramente casualizado. As plântulas que se desenvolveram em baixas concentrações de K apresentaram sintomas visuais de deficiência, como clorose e necrose das folhas mais velhas. Os cultivares apresentaram diferenças quantitativas entre si tanto em relação aos valores de MMS como em número de plântulas, relacionados às doses de K presentes nos meios de cultura. Em ambos os cultivares foi observada uma relação direta entre o desenvolvimento das plântulas e as concentrações de K com otimização ao redor de K 15 a 20 mM. Os teores de putrescina e de poliaminas foram maiores nos níveis mais baixos de K, atingindo o máximo na dose de K 5 mM. Em K 20 mM ocorreram maiores valores de MMS e em K 15 mM maior número de plântulas regeneradas. O íon K em geral foi mais intensamente absorvido do que os outros macro e micronutrientes sendo que estes tiveram sua absorção diminuída devido provavelmente a um efeito de diluição de seus teores pelo crescimento das plântulas in vitro. Esses resultados, inclusive os obtidos nas demais relações entre K e os outros macro e micronutrientes, as quais sempre foram crescentes (de K 5 a 30 mM), corroboram a essencialidade desse nutriente para os cvs. Nanica e Prata Anã. / Potassium is required in high dosis by the banana plant (Musa sp.) and interacts with other macro and micronutrients present in the medium in which banana tissues are maintained in vitro condition,with consequent modifications in the plant cell metabolism, mainly in nitrogen compounds, such as proteins and amino acids. When K is present in concentrations lower than the required, diamines such as putrescine, and polyamines, such as spermidine and spermine are formed. In order to establish the best dosis of K and follow the physiological consequences of the relationships N/K, K/P, K/Ca, K/Mg, K/Ca+Mg, K/S, K/Cu, K/Fe, K/Mn, K/Zn and K/putrescine, shoot apex of two banana cvs. Nanica and Prata Anã were maintained in asseptic conditions in modified MS media in the presence of 6 different dosis of K: 5, 10, 15, 20, 25 and 30 mM, K 20 mM being the K concentration in basic MS medium, and then transferred to rooting media with the same different K dosis. Dry wt., macro and micronutrients were measured in the shoots, roots and the intire plantlet, and number of plantlets produced determined, the data being analysed estatistically. Putrescine and polyamines were also determined. Visual symptoms of K deficiency such as clorosis and necrosis in the older leaves of all plantlets under low dosis of K were observed. The levels of putrescine and polyamines increased as K decreased in the medium, reaching the maximum value at K 5 mM, both cultivars presenting similar bahavior in relation to the diamine in some K concentrations. Quantitative differences were obtained among the two cultivars pertained to dry wt. values, number of in vitro regenerated banana plantlets and K concentration with optimization around K 15 and 20 mM. In general K absorption was more intense than the other nutrients, the absorption of the later being decreased probably due to a dilution effect of their values as the banana plantlets developed in vitro. These results, including those pertained to the relationships between K and the other nutrients, which always were high (from K 5 to 30 mM), corroborate the importance of potassium ion to the banana cvs. Nanica and Prata Anã.

banana nanica

banana prata-anã

biotecnologia

cultivo 'in vitro'

nutrição vegetal

poliamina

potássio

'in vitro' culture

banana nanica

banana prata-anã

biotecnology

polyamine

potassium

vegetable nutrition

Proteomics of diatoms: discovery of polyamine modifications in biosilica-associated proteins

Milentyev, Alexander

03 December 2019

Kieselalgen (Diatomee) sind eukaryotische einzellige Algen die hochspezifische Proteine (sogenannte Silaffine) erzeugen, um ‘nanopatterned’ Silica-Zellwände herzustellen. Diese Proteine zeigen geringe oder gar keine Homologie innerhalb der Diatomeen Gattung und sind ausgiebig (extensiv) posttranslatorisch modifiziert. Zum Unterschied zu konventioneller Modifikation (z.B. Phosphorylierung und Glykosylierung) weisen Lysinreste von Silaffinen einige Polyaminketten mit sehr heterogenen molekularen Strukturen auf. Diese Modifikationen sind spezifisch für Kieselalgen und spielen somit hypothetisch eine Rolle in der Biosilica-Synthese. Allerdings sind Lysin Polyamin Modifikationen, modifizierte Proteine und modifizierte Stellen kaum charakterisiert. Um diese Frage zu beantworten entwickelten wir eine Methode Polyamine zu quantifizieren und die Position von Polyamin-Modifikationen in engverwandte Proteine zu identifizieren (in morphologisch unterschiedliche Diatomeen Thalassiosira pseudonana, T. oceanica und Cyclotella cryptica). Wir zeigten, dass das Gesamtmuster von Polyaminender phylogenetischen Nähe dieser Kieselalgenarten folgt und dass diese Polyaminmodifikationen an Konsensusstellen sogar in Proteinen auftraten, die keine Sequenzähnlichkeit zeigten.:CONTENTS Summary Zusammenfassung List of figures List of tables Abbreviations 1 Introduction 1.1 Diatoms 1.2 Diatom biosilica 1.2.1 Biosilicification in nature 1.2.2 Diatom biosilica structure and cell cycle 1.2.3 The cell biology of biosilica morphogenesis 1.3 The role of polyamine PTMs in diatom biosilicification 1.3.1 Identifying biomolecules associated with diatom biosilica 1.3.2 PTM complexity of biosilica-associated proteins 1.3.3 Lysine ε-polyamine PTMs in biosilica-associated proteins 1.4 Mass spectrometry in PTM discovery 1.4.1 Modification-specific proteomics 1.4.2 Analysis of polyamine-modified lysines by MS 1.4.3 Fractionation of proteins and peptides prior to MS 1.4.4 MS/MS analysis in modification-specific proteomics 1.4.5 Bioinformatics tools for modification-specific proteomics 1.5 Rationale of the thesis 2 Aim of the thesis 3 Results and discussion 3.1 A method for analysis of ε-polyamine PTMs 3.1.1 Establishing a method to analyse ε-polyamines 3.1.2 Method applicability for lysine PTM profiling 3.1.3 Profiling of lysine PTMs in silaffin-3 3.2 Profiling lysine PTMs in biosilica extracts 3.2.1 Lysine PTM profile and characteristic fragments 3.2.2 Elucidation of phosphopolyamine structures 3.2.3 LysinePTMprofilesofAFSMextracts 3.2.4 Comparison of AFIM and AFSM profiles in T. pseudonana 3.2.5 Phylogenetic relationship across three diatom species 3.3 PTM localization and discovery of consensus motifs 3.3.1 Multiple protease strategy for mapping lysine PTMs 3.3.2 Selection of deprotection technique 3.3.3 Mapping lysine PTMs on tpSil3 using iterative search strategy 3.3.4 Deconvolution of raw MS/MS spectra 3.3.5 PTM mapping by polyamine-specific fragments 3.3.6 Identification of consensus motifs harboring lysine PTMs 4 Conclusions and Outlook 5.1 Synthesis of polyamine standards 5.2 Isolation of biosilica-associated proteins 5.3 Expression of tpSil3 from synthetic gene 5.4 HCl hydrolysis 5.5 AQC-derivatization of amino acids and polyamines 5.6 LC-MS/MS analysis of QAC-derivatives 5.7 Amino acid measurement using UV-detection 5.8 Direct infusion MS/MS analysis 5.9 Acetylation of phosphopolyamines 5.10 31P-NMR measurements 5.11 Deglycosylation with TFMS 5.12 Treatment with HF·pyridine soluble complex 5.13 Anhydrous HF-treatment 5.14 Protein analysis by GeLC-MS/MS 5.15 Proteomics data processing A Appendix B Bibliography Acknowledgments Publications Declaration / Erklärung / Diatoms are eukaryotic unicellular algae that employ highly specialized proteins called silaffins for making nanopatterned silica-based cell walls. These proteins share little or no homology across diatom species and are extensively post-translationally modified. Apart from conventional modifications (e. g., phosphorylation and glycosylation) lysine residues of silaffins bear polyamine chains with highly heterogeneous molecular structure. The latter appear to be specific for silicifying organisms and therefore hypothesized to play a key role in biosilica synthesis. However, polyamine modifications of lysines, modified proteins, and modification sites remain poorly characterized. To address these questions, we developed a method to quantify polyamines and identify sites of polyamine modifications in proteins from phylogenetically closely related, yet morphologically distinct diatoms Thalassiosira pseudonana, T. oceanica, and Cyclotella cryptica. We demonstrated that the overall pattern of polyamines followed the phylogenetic proximity across these diatom species and showed that polyamine modifications occurred at consensus sites even in proteins showing no sequence similarity.:CONTENTS Summary Zusammenfassung List of figures List of tables Abbreviations 1 Introduction 1.1 Diatoms 1.2 Diatom biosilica 1.2.1 Biosilicification in nature 1.2.2 Diatom biosilica structure and cell cycle 1.2.3 The cell biology of biosilica morphogenesis 1.3 The role of polyamine PTMs in diatom biosilicification 1.3.1 Identifying biomolecules associated with diatom biosilica 1.3.2 PTM complexity of biosilica-associated proteins 1.3.3 Lysine ε-polyamine PTMs in biosilica-associated proteins 1.4 Mass spectrometry in PTM discovery 1.4.1 Modification-specific proteomics 1.4.2 Analysis of polyamine-modified lysines by MS 1.4.3 Fractionation of proteins and peptides prior to MS 1.4.4 MS/MS analysis in modification-specific proteomics 1.4.5 Bioinformatics tools for modification-specific proteomics 1.5 Rationale of the thesis 2 Aim of the thesis 3 Results and discussion 3.1 A method for analysis of ε-polyamine PTMs 3.1.1 Establishing a method to analyse ε-polyamines 3.1.2 Method applicability for lysine PTM profiling 3.1.3 Profiling of lysine PTMs in silaffin-3 3.2 Profiling lysine PTMs in biosilica extracts 3.2.1 Lysine PTM profile and characteristic fragments 3.2.2 Elucidation of phosphopolyamine structures 3.2.3 LysinePTMprofilesofAFSMextracts 3.2.4 Comparison of AFIM and AFSM profiles in T. pseudonana 3.2.5 Phylogenetic relationship across three diatom species 3.3 PTM localization and discovery of consensus motifs 3.3.1 Multiple protease strategy for mapping lysine PTMs 3.3.2 Selection of deprotection technique 3.3.3 Mapping lysine PTMs on tpSil3 using iterative search strategy 3.3.4 Deconvolution of raw MS/MS spectra 3.3.5 PTM mapping by polyamine-specific fragments 3.3.6 Identification of consensus motifs harboring lysine PTMs 4 Conclusions and Outlook 5.1 Synthesis of polyamine standards 5.2 Isolation of biosilica-associated proteins 5.3 Expression of tpSil3 from synthetic gene 5.4 HCl hydrolysis 5.5 AQC-derivatization of amino acids and polyamines 5.6 LC-MS/MS analysis of QAC-derivatives 5.7 Amino acid measurement using UV-detection 5.8 Direct infusion MS/MS analysis 5.9 Acetylation of phosphopolyamines 5.10 31P-NMR measurements 5.11 Deglycosylation with TFMS 5.12 Treatment with HF·pyridine soluble complex 5.13 Anhydrous HF-treatment 5.14 Protein analysis by GeLC-MS/MS 5.15 Proteomics data processing A Appendix B Bibliography Acknowledgments Publications Declaration / Erklärung

info:eu-repo/classification/ddc/570

ddc:570

Subcellular effects of pavetamine on rat cardiomyocytes

Ellis, Charlotte Elizabeth

05 January 2011

The aim of this study was to investigate the mode of action of pavetamine on rat cardiomyocytes. Pavetamine is the causative agent of gousiekte (“quick-disease”), a disease of ruminants characterized by acute heart failure following ingestion of certain rubiaceous plants. Two in vitro rat cardiomyocyte models were utilized in this study, namely the rat embryonic cardiac cell line, H9c2, and primary neonatal rat cardiomyocytes. Cytotoxicity of pavetamine was evaluated in H9c2 cells using the MTT and LDH release assays. The eventual cell death of H9c2 cells was due to necrosis, with LDH release into the culture medium after exposure to pavetamine for 72 h. Pavetamine did not induce apoptosis, as the typical features of apoptosis were not observed. Electron microscopy was employed to study ultrastructural alterations caused by pavetamine in H9c2 cells. The mitochondria and sarcoplasmic reticula showed abnormalities after 48 h exposure of the cells to pavetamine. Abundant secondary lysosomes with electron dense material were present in treated cells. Numerous vacuoles were also present in treated cells, indicative of autophagy. During this exposure time, the nuclei appeared normal, with no chromatin condensation as would be expected for apoptosis. Abnormalities in the morphology of the nuclei were only evident after 72 h exposure. The nuclei became fragmented and plasma membrane blebbing occurred. The mitochondrial membrane potential was investigated with a fluorescent probe, which demonstrated that pavetamine caused significant hyperpolarization of the mitochondrial membrane, in contrast to the depolarization caused by apoptotic inducers. Pavetamine did not cause opening of the mitochondrial permeability transition pore, because cyclosporine A, which is an inhibitor of the mitochondrial permeability transition pore, did not reduce the cytotoxicity of pavetamine significantly. Fluorescent probes were used to investigate subcellular changes induced by pavetamine in H9c2 cells. The mitochondria and sarcoplasmic reticula showed abnormal features compared to the control cells, which is consistent with the electron microscopy studies. The lysosomes of treated cells were more abundant and enlarged. The activity of cytosolic hexosaminidase was nearly three times higher in the treated cells than in the control cells, which suggested increased lysosomal membrane permeability. The activity of acid phosphatase was also increased in comparison to the control cells. In addition, the organization of the cytoskeletal F-actin of treated cells was severely affected by pavetamine. Rat neonatal cardiomyocytes were labelled with antibodies to detect the three major contractile proteins (titin, actin and myosin) and cytoskeletal proteins (F-actin, desmin and β-tubulin). Cells treated with pavetamine had degraded myosin and titin, with altered morphology of sarcomeric actin. Vacuoles appeared in the β-tubulin network, but the appearance of desmin was normal. F-actin was severely disrupted in cardiomyocytes treated with pavetamine and was degraded or even absent in treated cells. Ultrastructurally, the sarcomeres of rat neonatal cardiomyocytes exposed to pavetamine were disorganized and disengaged from the Z-lines, which can also be observed in the hearts of ruminants that have died of gousiekte. It is concluded that the pathological alteration to the major contractile and cytoskeleton proteins caused by pavetamine could explain the cardiac dysfunction that characterizes gousiekte. F-actin is involved in protein synthesis and therefore can play a role in the inhibition of protein synthesis in the myocardium of ruminants suffering from gousiekte. Apart from inhibition of protein synthesis in the heart, there is also increased degradation of cardiac proteins in an animal with gousiekte. The mitochondrial damage will lead to an energy deficiency and possibly to generation of reactive oxygen species. The sarcoplasmic reticula are involved in protein synthesis and any damage to them will affect protein synthesis, folding and post-translational modifications. This will activate the unfolded protein response (UPR) and sarcoplasmic reticula-associated protein degradation (ERAD). If the oxidizing environment of the sarcoplasmic reticula is disturbed, it will activate the ubiquitin-proteasome pathway (UPP) to clear aggregated and misfolded proteins. Lastly, the mitochondria, sarcoplasmic reticula and F-actin are involved in calcium homeostasis. Any damage to these organelles will have a profound influence on calcium flux in the heart and will further contribute to the contractile dysfunction that characterizes gousiekte. / Thesis (PhD)--University of Pretoria, 2010. / Paraclinical Sciences / unrestricted

Sarcoplasmic reticula

Cardiotoxicity

Actin

Cytoskeleton

F-actin

H9c2 cell line

Gousiekte

Lysosome

Mitochondria

Myosin

Necrosis

Pavetamine

Protein synthesis

Polyamine

Rat neonatal cardiomyocytes

Titin

UCTD

Study on the higher-order structure of DNA and gene expression / DNA高次構造の多様性と遺伝子発現活性 / DNA コウジ コウゾウ ノ タヨウセイ ト イデンシ ハツゲン カッセイ

西尾 天志, Takashi Nishio

22 March 2022

博士(工学) / Doctor of Philosophy in Engineering / 同志社大学 / Doshisha University

DNA高次構造

遺伝子発現活性

ポリアミン

DNA

Higher-order structure of DNA

Gene expression

Gene regulation

Polyamine

NMR-based Metabolomics: New Analysis Tools and Application to Metabolism of Pseudomonas aeruginosa Biofilms in Various Growth Conditions

Leggett, Abigail

27 September 2022

No description available.

Biochemistry

Microbiology

NMR

NMR-based metabolomics

metabolomics

Pseudomonas aeruginosa

cadaverine

polyamine metabolism

metabolomics data analysis

biofilm

bacterial metabolism

synovial fluid

metabolite marker

biofilm metabolism

periprosthetic joint infections

A matter of life and death - polyamine metabolism during zygotic embryogenesis of pine

Vuosku, J. (Jaana)

17 May 2011

Abstract The study gathered information about polyamine metabolism throughout the Scots pine (Pinus sylvestris L.) zygotic embryogenesis and about physiological events occurring simultaneously in the megagametophyte tissue. Additionally, novel sequence data of the Scots pine polyamine genes were used for studying the evolution of polyamine genes in plants. Phylogenetic analyses revealed that the eukaryotic ornithine decarboxylase (ODC) might have evolved from a multifunctional bacterial progenitor. In conifers, the alternative arginine decarboxylase (ADC) pathway is preferred in putrescine biosynthesis, which may have caused the relaxed purifying selection in the ODC genes. The phylogenetic analysis of spermidine synthase (SPDS), spermine synthase (SPMS) and thermospermine synthase (ACL5) sequences supported the view that eukaryotic SPDS genes are derived from a common ancestor, whereas SPMS genes have evolved several times from SPDS genes. The identified Scots pine sequence was defined as a putative thermospermine synthase (TSPMS) encoding gene and named PsACL5. The phylogenetic analysis of polyamine oxidase (PAO) sequences supported the view that plants possess several different PAOs, which may have different catalytic properties. The consistency of the polyamine concentration profiles during Scots pine zygotic embryogenesis suggested that polyamines have an important role in the embryo development and that individual polyamines may have different roles at different developmental stages. Generally, the polyamine concentrations increased at the early stages but decreased at the late stages of embryo development. Only the free putrescine fraction remained stable throughout the embryo development. Putrescine was almost solely produced via the ADC pathway and the ADC enzyme was at least partially transcriptionally regulated. Both ADC mRNA transcripts and ADC protein localized in dividing cells of embryos, which implicated the essential role of ADC in the mitosis of plant cells. The megagametophyte was viable from the early phases of embryo development until the early germination of mature seeds. However, the megagametophyte cells in the narrow embryo surrounding region (ESR) died via morphologically necrotic cell death. In the dying cells, extensive nucleic acid fragmentation caused the unspecific hybridization of probes in an in situ mRNA hybridization assay. The occurrence of necrotic cell death in Scots pine embryogenesis indicated that developmentally and physiologically regulated necrotic cell death is evolutionarily conserved and exists also in plants. / Tiivistelmä Työssä tutkittiin polyamiiniaineenvaihduntaa ja megagametofyyttisolukossa tapahtuvia fysiologisia muutoksia metsämännyn (Pinus sylvestris L.) alkionkehityksen aikana. Polyamiineja (putreskiini, spermidiini ja spermiini) syntetisoivia ja hajottavia entsyymejä koodaavien geenien emäsjärjestys selvitettiin metsämännystä. Sekvenssejä käytettiin kasvien polyamiinigeenien evoluution tutkimiseen. Tutkimuksessa todettiin, että eukaryooteissa putreskiinin biosynteesistä vastaava entsyymi, ornitiinidekarboksylaasi (ODC), on voinut kehittyä bakteerien lysiinikarboksylaasista (LDC), joka dekarboksyloi sekä ornitiinia että lysiiniä. Kasveissa putreskiinia voidaan tuottaa myös arginiinidekarboksylaasin (ADC) kautta, mikä on johtanut ODC-geeneihin kohdistuvan puhdistavan valinnan heikentymiseen. Aminopropyyli-ryhmiä liittävien entsyymien osalta tutkimus tukee käsitystä, jonka mukaan eukaryoottiset spermidiinisyntaasit (SPDS) ovat kehittyneet yhteisestä kantamuodosta, kun taas spermiinisyntaasi (SPMS) on syntynyt useita kertoja SPDS-geenin kahdentumisen kautta. Metsämännystä tunnistettiin termospermiinisyntaasia (TSPMS) koodaava geeni, jolle annettiin nimeksi PsACL5. Fylogeneettisen analyysin perusteella kasveissa on useita erilaisia polyamiinien hajotuksesta vastaavia polyamiinioksidaaseja (PAO), joiden katalyyttiset ominaisuudet voivat poiketa toisistaan. Metsämännyllä polyamiinipitoisuudet vaihtelivat alkionkehitysvaiheen mukaan yhdenmukaisesti eri vuosina, mikä viittaa polyamiinien tärkeään rooliin alkionkehityksessä. Polyamiinipitoisuudet kasvoivat varhaisen ja pienenivät myöhäisen alkionkehityksen aikana lukuun ottamatta vapaan putreskiinin pitoisuutta, joka pysyi samana koko alkionkehityksen ajan. Putreskiinia tuotettiin alkioissa lähes pelkästään ADC-reitin kautta, ja ADC-entsyymin säätelyn todettiin tapahtuvan ainakin osittain transkription tasolla. Koska sekä ADC-geenin lähetti-RNA että ADC-entsyymi löytyivät alkion jakautuvista soluista, on ilmeistä, että ADC-entsyymillä on tärkeä tehtävä kasvisolujen mitoosissa. Megagametofyytti säilyi elossa koko alkionkehityksen ajan lukuun ottamatta alkio-onteloa reunustavia soluja, jotka olivat morfologialtaan nekroottisia. Nukleiinihappojen voimakas pilkkoutuminen aiheutti soluissa koettimien epäspesifisen sitoutumisen, kun geenien ilmenemistä paikannettiin lähetti-RNA:han in situ hybridisaatio-menetelmällä. Tutkimuksessa löydetty männyn alkiokehitykseen liittyvä nekroottinen solukuolema osoitti ensimmäistä kertaa, että fysiologista ja kehityksellistä nekroottista solukuolemaa esiintyy myös kasveissa.

Pinus

developmental cell death

embryogenesis

evolution

in situ mRNA hybridization

megagametophyte

necrotic cell death

polyamine

seed development

Pinus

alkionkehitys

evoluutio

in situ hybridisaatio

kehityksellinen solukuolema

megagametofyytti

nekroottinen solukuolema

polyamiini

siemenen kehitys