Post-translational modification of NF-kappaB regulation of stability and gene expression /

Hertlein, Erin K.

January 2006

Thesis (Ph. D.)--Ohio State University, 2006. / Full text release at OhioLINK's ETD Center delayed at author's request

Glucose-induced oscillations in protein phosphorylation in clonal pancreatic beta-cells (INS-1): implications for metabolic function

Narmuratova, Gulzhan

10 March 2022

OBJECTIVE: Type 2 diabetes (T2D), the most common type of diabetes characterized by high blood glucose and insulin resistance, results from both genetic and environmental factors. Our lab has proposed that chronic excess nutrients induce insulin hypersecretion from the pancreatic ß-cell, contributing to hyperinsulinemia, a prequel to T2D. Normal glucose-stimulated insulin secretion (GSIS) is oscillatory, a feature that is lost in patients with T2D. In this thesis we examine the oscillatory secretion profiles of clonal pancreatic ß-cells cultured in normal and excess nutrients that mimic conditions of T2D. We also begin to examine oscillations in protein phosphorylation that may contribute to normal ß-cell metabolism and GSIS, but if altered might potentially lead to impaired insulin secretion. METHODS: Nutrient regulation of oscillatory insulin release was studied in clonal pancreatic β-cells (INS-1) cultured in multiwell plates in both low (4 mM) and high (11 mM) glucose. Insulin secretion was stimulated in cells from multiwell plates one well at a time at 30 sec intervals and sampled simultaneously at the end of the timecourse. Insulin secretion and insulin content were measured using a homogenous time-resolved fluorescence (HTRF) insulin kit (Cisbio). Protein was extracted from these same cells for analysis of time-dependent phosphorylation by western blot using specific antibodies. Protein phosphorylation was detected using SuperSignal West Femto chemiluminescence reagent (ThermoFisher) and imaged on an iBright Imaging System (Invitrogen). RESULTS: Insulin secretion from INS-1 cells grown in separate plates and in 4 mM glucose oscillated with a period of 8.2  0.5 min compared to 5.0  0.5 min in cells cultured at 11 mM glucose. The amplitude of oscillations was 40.4  11.5 and 14.6  1.5 for cells cultured in 4 and 11 mM glucose respectively. Oscillations in secretion from cells cultured in 4 and 11 mM glucose in the same plate were not different in period but different in amplitude due in part to reduced insulin content. Oscillation in the phosphorylation patterns of acetyl-CoA carboxylase (ACC) and myristoylated alanine rich C kinase substrate (MARCKS) were measured in cells cultured in 4 mM glucose and both exhibited a peak in phosphorylation that occurred at the nadir of the insulin oscillation between peaks of insulin release. CONCLUSION: Insulin secretion from pancreatic ß-cells is affected by nutrient status as excess nutrients decrease the amplitude of oscillations in insulin release. The period of oscillations can also be affected. Oscillations in protein phosphorylation are consistent with both ACC and MARCKS contributing to normal GSIS. These initial studies provide evidence of the suitability of this model system to correlate oscillations in protein activity to exocytosis. Future studies focused on the effects of low and high glucose will potentially reveal new important therapeutic targets that may help prevent/reverse/ameliorate insulin hypersecretion leading to insulin resistance and T2D.

Nutrition

Glucose-stimulated insulin secretion

Oscillatory insulin secretion

Pancreatic ß-cell

Protein phosphorylation

T2D

Differential Translocation or Phosphorylation of Alpha B Crystallin Cannot Be Detected in Ischemically Preconditioned Rabbit Cardiomyocytes

Armstrong, Stephen C., Shivell, Christine L., Ganote, Charles E.

01 January 2000

Alpha B Crystallin (αBC) is a putative effector protein of ischemic preconditioning (IPC). that is phosphorylated on Ser 45 by ERK1/2 and Set 59 by the p38 MAPK substrate, MAPKAPK-2. Translocation and phosphorylation of αBC was determined in cytosolic and cytoskeletal fractions by 1D SDS-PAGE and IEF, or using Ser 45 and Set 59 phospho-specific antibodies in: (1) control rabbit cardiomyocytes; (2) cells preconditioned by 10 min in vitro ischemia; or after pre-treatment with specific inhibitors of (3) Ser/Thr protein phosphatase 1/2A (calyculin A); (4) p38 MAPK (SB203580); or (5) ERK 1/2 (PD98059); all prior to 180 min ischemia. Ischemia induced a cytosolic to cytoskeletal translocation of αBC, which was similar in all the groups. Highly phosphorylated isoforms (D1/2) of αBC were present in cytosolic but not cytoskeletal fractions at 0 min ischemia. By 60-90 min ischemia. D1/2 isoforms had translocated to the cytoskeletal fraction. Calyculin A maintained D1/2 levels throughout prolonged ischemia. SB203580 decreased αBC phosphorylation. Neither PD98059 nor IPC altered αBC phosphorylation during prolonged ischemia. It is concluded that αBC phosphorylation during ischemia is regulated by p38 MAPK but not by ERK 1/2. The inability to detect a correlation between IPC protection and either αBC translocation or phosphorylation suggests that the proteins in the highly phosphorylated isoform bands of αBC quantitated in this study are not protective end effectors of classical IPC.

heat-shock proteins

ischemic preconditioning

isolated cardiomyocytes

mitogen-activated protein kinases

protein phosphatases

protein phosphorylation

Casein Kinase 1 Alpha Associates With the Tau-Bearing Lesions of Inclusion Body Myositis

Kannanayakal, Theresa, Mendell, Jerry R., Kuret, Jeff

31 January 2008

Inclusion body myositis and Alzheimer's disease are age-related disorders characterized in part by the appearance of intracellular lesions composed of filamentous aggregates of the microtubule-associated protein tau. Abnormal tau phosphorylation accompanies tau aggregation and may be an upstream pathological event in both diseases. Enzymes implicated in tau hyperphosphorylation in Alzheimer's disease include members of the casein kinase 1 family of phosphotransferases, a group of structurally related protein kinases that frequently function in tandem with the ubiquitin modification system. To determine whether casein kinase 1 isoforms associate with degenerating muscle fibers of inclusion body myositis, muscle biopsy sections isolated from sporadic disease cases were subjected to double-label fluorescence immunohistochemistry using selective anti-casein kinase 1 and anti-phospho-tau antibodies. Results showed that the alpha isoform of casein kinase 1, but not the delta or epsilon isoforms, stained degenerating muscle fibers in all eight inclusion body myositis cases examined. Staining was almost exclusively localized to phospho-tau-bearing inclusions. These findings, which extend the molecular similarities between inclusion body myositis muscle and Alzheimer's disease brain, implicate casein kinase 1 alpha as one of the phosphotransferases potentially involved in tau hyperphosphorylation.

Alzheimer's disease

casein kinase 1

immunohistochemistry

inclusion body myositis

protein kinases

protein phosphorylation

tau protein

CHARACTERIZATION AND STUDY OF THE PHYSIOLOGICAL ROLE OF CTL0511, A CHLAMYDIAL PROTEIN PHOSPHATASE TYPE 2C

Claywell, Ja

01 May 2019

Chlamydia are obligate intracellular bacterial pathogens that are responsible for infectious blindness, sexually transmitted infections, and acute respiratory disease in humans. These pathogens undergo an essential biphasic developmental cycle differentiating between two functionally distinct forms known as the infectious elementary body (EB) and the replicative reticulate body (RB). Identifying the signals and regulatory mechanisms that enable Chlamydia to establish infection, differentiate between the two developmental forms, and survive within the host cell is critical to understanding chlamydial pathogenesis and developing future therapeutic strategies. In pathogenic bacteria, serine, threonine, and tyrosine (Ser/Thr/Tyr) protein kinases and phosphatases are critical for development, metabolism, and virulence. Chlamydia encode two validated protein kinases (pkn1 and pknd), a putative protein phosphatase (ctl0511; CppA), and appear capable of global phosphorylation that differs between the developmental forms. While these findings support a role for protein phosphorylation in chlamydial pathogenesis, a validated cognate protein phosphatase for Pkn1 and PknD mediating reversible phosphorylation was lacking. We hypothesized that CppA is the partner phosphatase for the chlamydial protein kinases, and in this study we validated and characterized CppA as a broad specificity protein phosphatase type 2C. Using in vivo and in vitro approaches we demonstrated that CppA acts on P-Ser/Thr/Tyr residues and can dephosphorylate multiple chlamydial protein substrates including PknD and the FHA 2 domain of CdsD, a component of the type 3 secretion apparatus. The importance of CppA for chlamydial growth and development was determined using a chemical “knock-out” approach and study of CppA missense mutations identified in slow growing C. trachomatis L2 chemical mutants. Treatment of C. trachomatis L2, C. trachomatis D, and C. muridarum with CppA inhibitors significantly reduced progeny levels and inclusion size in a time dependent manner with more significant growth inhibition in the first 12 hours post infection. Collectively, our findings support that CppA works in conjunction with PknD, and likely Pkn1, to mediate reversible phosphorylation of multiple protein substrates leading to changes in chlamydial physiology that appear to be key for early steps in development.

Bacterial development

Chlamydia trachomatis

Protein kinase

Protein phosphatase

Protein phosphorylation

Small molecule inhibitors

Effects of the Protein Phosphatase Inhibitors Okadaic Acid and Calyculin a on Metabolically Inhibited and Ischaemic Isolated Myocytes

Armstrong, Stephen C., Ganote, Charles E.

01 January 1992

Isolated adult rat myocytes were subjected to 180 min of metabolic inhibition or incubated in ischaemic pellets, in the presence and absence of 10 μm okadaic acid (OA) or calyculin A (CL-A). Contracture and viability was determined by light microscopic analysis of trypan blue-stained preparations and ATP levels by HPLC. Osmotic fragility was assessed by brief hypotonic swelling of cells in 170 or 85 mOsm media prior to determination of viability. Neither drug significantly affected the relatively rapid rates of contracture of myocytes during metabolic inhibition, and both afforded significant protection from development of trypan blue permeability and osmotic fragility. Both OA and CL-A significantly accelerated the rates of contracture and ATP depletion of myocytes during ischaemic incubations. Despite an enhanced rate of ATP depletion, which would be expected to accelerate development of injury, neither drug accelerated development of loss of viability or development of osmotic fragility as measured by 170 mOsm swelling. Mathematical compensation for different rates of ATP depletion confirmed that a protective effect of the drugs, during ischaemic incubation, was masked by their enhancement of the rate of injury, following swelling at 170 mOsm. When the effects of CL-A on ischaemic cells were examined at 85 mOsm, a more stringent test for osmotic fragility, protection was found without compensation for differing rates of ATP depletion. A dose/response curve for CL-A showed some effect at 100 nm and a nearly full effect during metabolic inhibition at 1 μm concentrations. It is concluded that protein phosphatase inhibitors reduce the rates of development of osmotic fragility of metabolically inhibited cells and reduces the rate of injury relative to the rate of ATP depletion of ischaemic cardiomyocytes. Phosphorylation mechanisms may be important to development of irreversible myocardial cell injury.

adenine nucleotides

cell injury

cytoskeleton

ischaemic injury

isolated myocytes

osmotic fragility

protein phosphorylation

Protein phosphorylation in yeast mitochondria: enzymes, substrates and function

Krause, Udo

16 July 2013

Protein phosphorylation is one of the major post-translational modifications to allow for signal transmission and fine tuning of metabolism on the cellular proteomic level. As such it is “one of the last instances” to modulate the activity of enzymes and hence to impact the cellular life irrespective of the basic conditions provided by the genome – and epigenome– controlled gene expression. The evolutionary increase in cellular complexity is reflected by highly sophisticated regulatory networks in multicellular eukaryotes based on the transfer of phosphate mostly onto the side chains of serine, threonine and tyrosine residues. Nature has chosen phosphate for inter- and intracellular communication, which is also an integral component of nucleic acids and can be regarded as the molecule of choice for life. Currently, life science is interested to unravel the network of reversible protein phosphorylation that is catalyzed by two antagonistic enzyme classes: the protein kinases and protein phosphatases. We are currently in the era of proteomics and enormously benefit from the progress of mass-spectrometry methods. This is documented by a huge number of “proteomic studies” that mostly provide a simple inventory of the existence of proteins – and/or their phosphorylated forms – under more or less defined conditions. So far, the physiological correlations could be established only in a few cases, e.g. by comparing two physiological conditions. Another strategy, which was addressed in this work, is the systematic screening of mutants defective in genes encoding either protein kinases or protein phosphatases. This approach benefits from the ease to predict these enzymes due to the presence of characteristic protein motifs. In combination with the major goal of this work – to shed light on the impact of protein phosphorylation in the mitochondrial (mt) compartment – the yeast Saccharomyces cerevisiae was chosen as a model system because of its respiro-fermentative metabolism, that allows for the maintenance of respiratory defective mutants. Indeed, this reverse genetic approach successfully revealed two kinases (Pkp1p, Pkp2p) and two phosphatases (Ppp1p, Ppp2p) as the key components regulating the pyruvate dehydrogenase complex by phosphorylation of serine 313 of its α- subunit Pda1p. In addition, evidence is provided that Pkp1p has an additional role in the assembly process of the PDH complex. Also, the effect of the deletion of the COQ8 gene (gene engaged in coenzyme Q synthesis; originally named ABC1) leading to respiratory deficiency, could be correlated with the phosphorylation of subunit Coq3p of the mitochondrial ubiquinone biosynthesis complex. Finally, in the case of the kinase Sat4p (protein involved in salt tolerance), overexpression of the enzyme was used as an alternative approach to unravel the molecular basis of the originally observed salt sensitivity of sat4 mutants. The data suggest that Sat4p has a direct or indirect role in the late steps of iron-sulfur (Fe/S) cluster assembly of the so-called “aconitase-type” enzymes in mitochondria, accompanied by a strongly reduced steady state concentration of the Fe/S-cluster protein aconitase. Interestingly, a secondary phenotype became apparent upon overexpression of Sat4p: the abundance of the lipoic acid containing mitochondrial proteome was markedly reduced. Most likely this phenotype is due to the fact that the synthesis and/or attachment of lipoic acid depend on a Fe/S-cluster bearing enzyme. In the course of the work it became clear that the regulatory (mt) protein phosphorylation network of yeast evolved to meet the criteria of a life adapted to the ecological niche on temporarily available sugar rich sources. Clearly, the transfer of the respective data to higher eukaryotes is limited. However, it shows that yeast is primarily an excellent model system for the principal molecular reactions shared with higher eukaryotes.:1 SUMMARY 1 ZUSAMMENFASSUNG 3 2 INTRODUCTION 5 2.1 Why phosphate? 5 2.2 Protein phosphorylation in prokaryotes 6 2.3 Protein phosphorylation in mitochondria 7 2.4 Regulation of mammalian pyruvate dehydrogenase complex (PDH) by phosphorylation 9 2.5 Mammalian cytochrome c oxidase (COX) 10 2.6 Protein phosphorylation in yeast mitochondria 11 3 AIM OF THIS WORK 13 4 PROLOG 14 4.1 Critical evaluation of tools for phosphoproteomics 14 4.2 Introducing a new method for in gel profiling of phospho-proteins 17 4.3 In-gel screening of phosphorus of yeast mitochondrial proteins by LA-ICP-MS 20 4.4 Detection of phosphorylated subunits of ATPase 22 5 RESULTS 23 5.1 YIL042c and YOR090c encode the kinase and phosphatase of the Saccharomyces cerevisiae pyruvate dehydrogenase complex 28 5.2 Yeast Pyruvate Dehydrogenase Complex Is Regulated by a Concerted Activity of Two Kinases and Two Phosphatases 29 5.3 Proteomic analysis reveals a novel function of the kinase Sat4p in yeast mitochondria 30 5.4 Ubiquinone biosynthesis in Saccharomyces cerevisiae: the molecular organization of O –methylase Coq3p depends on Abc1p/Coq8p 53 6 DISCUSSION AND PERSPECTIVES 54 6.1 Mitochondrial phosphorylation in yeast 54 6.1.1 An evolutionary view 54 6.1.2 The yeast ABC1-kinase family 55 6.1.3 Regulation of yeast pyruvate dehydrogenase (PDH) complex 57 6.1.4 Regulation of iron sulfur cluster biogenesis 60 6.2 Challenges to investigate the network of (mt) protein phosphorylation 62 6.2.1 When is a kinase a mitochondrial kinase? 64 6.2.2 Epilog 66 7 LITERATURE 69 8 APPENDIX 78 8.1 Related publications 78 8.2 List of publications 80 8.3 ERKLÄRUNGEN 82 / Phosphorylierungen von Aminosäuren ist eine der verbreitetsten post-translationalen Modifikationen für zelluläre Signalübertragungswege und zur Regulation des Metabolismus auf Proteom-Ebene. Mit der reversiblen Protein-Phosphorylierung eng verbunden ist die unabhängige Modulation der Aktivität von Enzymen ungeachtet der Genom- und Epigenom-basierten Genexpression. Die evolutionäre Zunahme der zellularen Komplexität äußert sich in zunehmend komplexeren Regulations-Netzwerken in mehrzelligen eukaryotischen Organismen basierend auf dem Transfer von Phosphatgruppen vorzugsweise auf die Aminosäuren Serin, Threonin und Tyrosin. Die Natur hat evolutionär als Baustein der inter- und intrazellulären Kommunikation Phosphat gewählt, welches auch ein integraler Bestandteil der Nukleinsäuren ist und somit als das „Molekül der Wahl“ für das Leben bezeichnet werden darf. Die Lebenswissenschaften sind gegenwärtig daran interessiert das Netzwerk der Proteinphosphorylierung aufzuklären, welches durch zwei antagonistisch wirkende Enzymklassen, die Proteinkinasen und Proteinphosphatasen charakterisiert ist. Dabei profitieren wir gegenwärtig von den Fortschritten der „Proteomics-Ära“ auf dem Gebiet der massenspektrometrischen Proteinidentifizierung. Ausdruck dessen ist eine Vielzahl von Proteom-Studien, die jedoch meist nur eine einfache Inventarisierung der unter mehr oder weniger gut definierten zellulären Bedingungen existierenden Proteine in ihrer Phosphat-modifizierten oder unphosphorylierten Form darstellen. Die beteiligten Enzyme werden dabei kaum berücksichtigt. Insbesondere gilt dies für extra-cytoplasmatische Ereignisse. Bisher gelang es nur in wenigen Fällen eine Korrelation der physiologischen Rolle dieser Proteinmodifikation, z.B. durch den Vergleich der Phospho-Proteome unter zwei unterschiedlichen physiologischen Bedingungen, herzustellen. Eine andere Strategie, die auch Gegenstand dieser Arbeit ist, sieht ein Screening von Mutanten vor, die durch Deletionen von Genen, die für Proteinkinasen bzw. –phosphatasen kodieren, gekennzeichnet sind. Dieser Ansatz profitiert von der Existenz und leichten bioinformatischen Vorhersagbarkeit charakteristischer Kinase- bzw. Phosphatase- Sequenzmotive. In Kombination mit dem Hauptziel der Arbeit – Licht ins Dunkel der Proteinphosphorylierung im mitochondrialen Kompartiment zu bringen – wurde die Hefe Saccharomyces cerevisiae als Modellsystem gewählt, insbesondere vor dem Hintergrund ihres fermentativen Metabolismus. Als Beleg der prinzipiellen Funktionalität des vorgeschlagenen Ansatzes konnten zwei Kinasen (Pkp1p, Pkp2p) und zwei Phosphatasen (Ppp1p, Ppp2p) als Schlüsselkomponenten der Regulation des Pyruvatdehydrogenase (PDH) Komplexes identifiziert und charakterisiert werden. Darüber hinaus konnte sowohl das Zielprotein der Phosphorylierung, Pda1p, die α-Untereinheit des Komplexes, als auch die modifizierte Aminosäure (Serin 313) experimentell bestätigt werden. Ferner konnte der Atmungsdefekt von Stämmen mit einer nicht-funktionellen Abc1p-Kinase mit dem Phosphorylierungszustand der Untereinheit Coq3p des Ubiquinon-Biosynthese Komplexes und dem Ausfall der Ubiquinonsynthese korreliert werden. Eine alternative Herangehensweise, die Überexpression einer Kinase, führte zur Identifizierung möglicher Zielproteine von Sat4p. Vergleichende Analysen des 2D-gelelektrophoretisch separierten mitochondrialen Genoms mit dem des Wildtyps legen die Vermutung nahe, dass Sat4p eine direkte oder indirekte Rolle bei der Regulation der „Aconitase-Typ“ Eisen-Schwefel (Fe/S) Proteine besitzt. Der darüber hinaus beobachtete Effekt einer Abnahme von Liponsäure-tragenden mitochondrialen Enzymen, ist wahrscheinlich sekundärer Natur und kann durch die Zugehörigkeit der Liponsäure-Synthase zur oben erwähnten Gruppe der „Aconitase-Typ“ -Fe/S-Proteine erklärt werden. Im Verlauf der Arbeit wurde deutlich, dass das regulatorische Netzwerk der Proteinphosphorylierung der Hefe eher den Kriterien einer evolutionären Adaptation an eine spezifische ökologische Nische – der temporären Verfügbarkeit zuckerreicher Substanzen – entsprechen. Das schränkt die Übertragbarkeit der gewonnen Einsichten in die Regulation des mitochondrialen Metabolismus auf höhere Eukaryonten ein. Es zeigt jedoch, dass Hefe in erster Linie ein exzellentes Modellsystem für die prinzipiellen molekulare Mechanismen ist, die sie mit den höheren Eukaryonten teilt.:1 SUMMARY 1 ZUSAMMENFASSUNG 3 2 INTRODUCTION 5 2.1 Why phosphate? 5 2.2 Protein phosphorylation in prokaryotes 6 2.3 Protein phosphorylation in mitochondria 7 2.4 Regulation of mammalian pyruvate dehydrogenase complex (PDH) by phosphorylation 9 2.5 Mammalian cytochrome c oxidase (COX) 10 2.6 Protein phosphorylation in yeast mitochondria 11 3 AIM OF THIS WORK 13 4 PROLOG 14 4.1 Critical evaluation of tools for phosphoproteomics 14 4.2 Introducing a new method for in gel profiling of phospho-proteins 17 4.3 In-gel screening of phosphorus of yeast mitochondrial proteins by LA-ICP-MS 20 4.4 Detection of phosphorylated subunits of ATPase 22 5 RESULTS 23 5.1 YIL042c and YOR090c encode the kinase and phosphatase of the Saccharomyces cerevisiae pyruvate dehydrogenase complex 28 5.2 Yeast Pyruvate Dehydrogenase Complex Is Regulated by a Concerted Activity of Two Kinases and Two Phosphatases 29 5.3 Proteomic analysis reveals a novel function of the kinase Sat4p in yeast mitochondria 30 5.4 Ubiquinone biosynthesis in Saccharomyces cerevisiae: the molecular organization of O –methylase Coq3p depends on Abc1p/Coq8p 53 6 DISCUSSION AND PERSPECTIVES 54 6.1 Mitochondrial phosphorylation in yeast 54 6.1.1 An evolutionary view 54 6.1.2 The yeast ABC1-kinase family 55 6.1.3 Regulation of yeast pyruvate dehydrogenase (PDH) complex 57 6.1.4 Regulation of iron sulfur cluster biogenesis 60 6.2 Challenges to investigate the network of (mt) protein phosphorylation 62 6.2.1 When is a kinase a mitochondrial kinase? 64 6.2.2 Epilog 66 7 LITERATURE 69 8 APPENDIX 78 8.1 Related publications 78 8.2 List of publications 80 8.3 ERKLÄRUNGEN 82

info:eu-repo/classification/ddc/570

ddc:570

Analysis of Mold and Yeast Phosphoproteomes in the Dimorphic Fungus Penicillium marneffei

Rowe, Garett

06 October 2011

No description available.

Biology

Cellular Biology

Molecular Biology

Phosphoproteome

Dimorphic fungi

Penicillium marneffei

Protein phosphorylation

TOR kinase

Functional analysis of Ribonuclease III regulation by a viral protein kinase

Gone, Swapna

January 2011

The bacteriophage T7 protein kinase enhances T7 growth under suboptimal growth conditions, including elevated temperature or limiting carbon source. T7PK phosphorylates numerous E. coli proteins, and it has been proposed that phosphorylation of these proteins is responsible for supporting T7 replication under stressful growth conditions. How the phosphorylation of host proteins supports T7 growth is not understood. Escherichia coli (Ec) RNase III is phosphorylated on serine in bacteriophage T7-infected cells. Phosphorylation of Ec-RNase III induces a ~4-fold increase in catalytic activity in vitro. Ec-RNase III is involved in the maturation of several T7 mRNAs, and it has been shown that RNase III processing controls the translational activity and stability of the T7 mRNAs. Perhaps T7PK phosphorylation of Ec- RNase III ensures optimal processing of T7 mRNAs under suboptimal growth conditions. In this study a biochemical analysis was performed on the N-terminal portion of the 0.7 gene (T7PK), exhibiting only the protein kinase activity. In addition to phosphotransferase activity, T7PK also undergoes self-phosphorylation on serine, which down-regulates catalytic activity by an unknown mechanism. Mass spectral analysis revealed that Ser216 is the autophosphorylation site in T7PK. The serine residue is highly conserved, which in turn suggests that autophosphorylation is a conserved reaction with functional importance. Phosphorylated T7PK exhibits reduced phosphotransferase activity, compared to its dephosphorylated counterpart (dT7PK). The dT7PK exhibits enhanced ability to phosphorylate proteins, as well as undergo autophosphorylation. The mechanism by which autophosphorylation inhibits T7PK activity is unknown. An in vitro phosphorylation assay revealed that T7PK directly phosphorylates RNase III. Ec-RNase III processing activity is stimulated from two to ten-fold upon phosphorylation by the T7PK. The primary site of phosphorylation in RNase III is found to be Ser33, and Ser34 may act as the recognition determinant for T7PK. This was established by Ser →Ala mutations at the concerned site. The enhancement of catalytic activity is primarily due to a larger turnover number (kcat), with some additional contribution from a greater substrate binding affinity, as revealed by lower Km and K‟D values. Substrate cleavage assays under single turn over conditions established that the product release is the rate limiting step. Since there is no significant increase in the kcat as measured under single-turnover (enzyme excess) conditions, the increase in the kcat in the steady-state is due to enhancement of the product release step, and not due to an enhancement of the hydrolysis (chemical) step. / Chemistry

Biochemistry

Biology, Molecular

Protein Phosphorylation

Ribonuclease Iii

T 7 Protein Kinase

Expressão gênica diferencial durante o desenvolvimento e na resposta ao choque térmico em Blastocladiella emersonii / Differential gene expression during development and in the heat shock response in Blastocladiella emersonii

Silva, Aline Maria da

25 August 1987

Usando incorporação \"in vivo\" de 35S metionina tradução \"in vitro\" de RNA e eletroforese bidimensional, iniciamos um estudo do controle da síntese de proteínas durante duas fases distintas de diferenciação celular, a esporulação e a germinação, do fungo Blastocladiella emersonii. Durante a esporulação ocorre uma intensa variação no padrão de síntese proteica. Foi analisada a síntese de 108 proteínas, sendo verificado que o aumento na síntese de várias proteínas está associado com estágios definidos da esporulação. Um grande número de proteínas básicas é sintetizado exclusivamente no final da esporulação, que corresponde à fase de diferenciação dos zoósporos. Também foram detectadas drásticas variações na população de mRNAs ao longo de toda a esporulação. A síntese de várias proteínas típicas da esporulação parece ser controlada ao nível da transcrição. Além disso a maioria dos RNAs mensageiros específicos da esporulação não é conservada nos zoósporos maduros; o zoósporos contém mRNAs armazenados que provavelmente são sintetizados nos últimos 30 minutos da esporulação. Durante a transição dos zoósporos a células redondas, que ocorre nos primeiros 25 minutos após a indução da germinação em meio inorgânico, não foram verificadas diferenças qualitativas no padrão de síntese proteica, tanto na ausência como na presença de actinomicina D, indicando que os eventos precoces da germinação são inteiramente pré-programados pelo mRNA que está armazenado nos zoósporos. Contudo, na germinação tardia são verificadas profundas variações no padrão de síntese proteica. A síntese de algumas dessas proteínas (seis polipeptídios), provavelmente corresponde a uma tradução seletiva de mensagens armazenadas nos zoósporos, enquanto que a maioria das novas proteínas expressas (vinte e dois polipeptídios) corresponde a tradução de novos mRNAs. Assim, durante a germinação dos zoósporos, ocorrem múltiplos níveis de regulação da síntese proteica, envolvendo controles ao nível da tradução e transcrição. Durante o início da germinação também foi observado um controle ao nível de pós-traduçãoo, com várias proteínas dos zoósporos sendo especificamente degradadas ou modificadas. Também analisamos o padrão das proteínas sintetizadas durante a germinação em meio nutriente sendo observada a síntese de polipeptídios específicos desta condição de germinação e crescimento. Algumas proteínas cuja síntese é controlada pelo desenvolvimento foram identificadas. Utilizando anticorpos monoclonais comerciais contra actina, α e β-turbulinas foip-tubulinas foi possível identificar estas proteínas no perfil eletroforético de proteínas sintetizadas durante a esporulação. Comparando a cinética da síntese \"oin vitro\" destas proteínas com o acúmulo de seus respectivos mRNAs traduzidos \"in vitro\", o, foi possível demonstrar que o intenso aumento na síntese de actina, α e β-tubulinas que ocorre durante a esporulação apresenta uma correlação temporal com o aumento dos mRNAs correspondentes. Em paralelo ao aumento da síntese destas três proteínas citoesqueLéticas pôde ser detectado um aumento dos seus conteúdos em massa. Durante a germinação e crescimento ocorre uma sensível diminuição no conteúdo destas proteínas. Além disso, verificamos que as proteínas identificadas como α e β-tubulinas estão presentes no flagelo dos zoósporos. Muito interessante foi a observação de que três proteínas sintetizadas durante a esporulação correspondiam aparentemente a três proteínas, Hsp70, Hsp76 e Hsp39a, cuja síntese é induzida pelo choque térmico. Esta verificação decorreu do fato de estarmos investigando se em Blastocladiella a resposta ao choque térmico teria algum controle do desenvolvimento, uma vez que alguns dados da literatura sugeriam o envolvimento de certas proteínas de choque térmico (Hsps) no desenvolvimento normal de alguns organismos. Em Blastocladiella a resposta ao choque térmico é dependente do estágio do desenvolvimento. Células expostas a temperaturas elevadas nos diferentes estágios do desenvolvimento (esporulação, germinação e crescimento) mostram uma síntese diferencial de proteínas de choque térmico. Conjuntos específicos de Hsps (de um total de 22 Hsps) são induzidos em cada fase, demonstrando uma expressão não coordenada dos genes de choque térmico. A proteína de 70 kDa, sintetizada espontaneamente durante um certo intervalo da esporulação, apresenta mobilidade eletroforética em géis bidimensionais idêntica à Hsp70. A confirmação da identidade entre estas proteínas foi obtida através de análise dos seus peptídios resultantes de digestão enzimática parcial bem como pelo reconhecimento de ambas as proteínas por anticorpos contra a proteína DnaK (homóloga à Hsp70> de E. coli e contra a proteína Hsp70 de Drosophila. Utilizando tradução o\"in vitro\"o de RNA e hibridização de RNA com uma sonda do gene hsp70 de Drosophila, demonstramos que o aumento de síntese da Hsp70 que ocorre durante o choque térmico e espontaneamente durante a esporulação, está associado com a acumulação do mRNA desta proteína. Embora a síntese de Hsps seja controlada pelo desenvolvimento em Blastocladiella, a aquisição de termotolerância pode ser induzida em qualquer estágio do seu ciclo de vida. A indução da termotolerância em Blastocladiella é dependente da síntese de proteínas e está correlacionada com o aumento da síntese de algumas Hsps: Hsp82a, Hsp82b, Hsp76, Hsp70, Hsp60,Hsp25 e Hsp17b. As outras Hsps parecem não estar envolvidas especificamente com a termotolerância. As observações anteriores de que o estado de fosforilação da proteína ribossômica 56, em Blastocladiella, varia durante o desenvolvimento e em resposta a alterações do meio ambiente (Bonato et al., 1984, Eur. J. Biochem. 144:597-606) e a verificação de que a resposta ao choque térmico, em Blastocladiella, também está sob o controle do desenvolvimento proporcionou a oportunidade de verificar se os diferentes níveis de fosforilação de 56 poderiam ser correlacionados com a tradução de mensageiros específicos isto é, mRNAs normais ou de choque térmico durante o choque térmico, recuperação do choque térmico e indução de termotolerância nos diferentes estágios do ciclo de vida deste fungo. Assim foi observado que, independente do estado inicial de fosforilação de 56 (máximo ou intermediário>, ocorre uma rápida e completa desfosforilação de 56 durante o choque térmico, sendo que a 56 permanece desfosforilada durante a termotolerância. Durante a recuperação do choque térmico, ocorre a refosforilação de 56 para os níveis característicos de cada estágio do desenvolvimento, coincidentemente com a interrupção da síntese de proteínas de choque térmico. / Using 35S methionine pulse labeling in vitro translation and two-dimensional gel electrophoresis, we investigated the regulation of protein synthesis during two distinct phases of cell differentiation, sporulation and germination, in the aquatic fungus Blastocladiella emersonii. We have found dramatic changes in the spectrum of proteins synthesized during sporulation. Synthesis of 108 polypeptides was analyzed and a large increase in the synthesis of several proteins is associated with particular stages. A large number of basic proteins are synthesized exclusively during late sporulation. Changes in translatable mRNA species were also detected by in vitro translation of RNA prepared at different stages of sporulation. The synthesis of several proteins during sporulation seems to be transcriptionally controlled. Most of the sporulationspecific messages are not present in the mature zoospores; the zoospores contain stored mRNA, which is apparently synthesized in the last 30 min of sporulation.We analyzed the pattern of proteins synthesized during zoospore germination in an inorganic solution, in both the presence and absence of actinomycin D. During the transition from zoospore to round cells (the first 25 min), essentially no qualitative differences were noticeable, indicating that the earliest stages of germination are entirely preprogrammed with stored RNA. Later in germination (after 25 min), however, changes in the pattern of protein synthesis were found. Some of these proteins (a total of 6 polypeptides) correspond possibly to a selective translation of stored messages, whereas the majority of the changed proteins (22 polypeptides) corresponds to newly synthesized mRNA. Thus, multiple levels of protein synthesis regulation seem to occur during zoospore germination, involving both transcriptional and translational controls. We also analyzed the pattern of protein synthesis during germination in a nutrient medium; synthesis of specific polypeptides occurred during late germination. During early germination posttranslational control was also observed, several labeled proteins from zoospores being specifically degraded or charge modified. Some proteins whose expression is developmentally regulated were identified. Actin, α- and β-tubulin have been identified in the two-dimensional pattern of proteins synthesized during sporulation by using well characterized monoclonal antibodies and western blotting. We compared the kinetics of synthesis of these proteins, by pulse-labeling experiments with ‌35S‌methionine, with the accumulation of their corresponding mRNAs, translated in a cell-free system. Large increases occur in the rates of actin and α- and β-tubulin biosynthesis during sporulation and there is an accumulation of the corresponding mRNAs. In parallel to the increased synthesis, these cytoskeletal proteins accumulate during the late stage of sporulation. During germination and early growth there is a strong decrease in the level of these proteins. We also verified that α- and β-tubulin are present in flagellar axonemes of zoopores. Very interesting was the observation that three proteins spontaneously expressed during sporulation correspond possibly to three heat shock-induced proteins CHsp70, Hsp76, Hsp39a). This fact was noticed when we were investigating the heat shock-response during the development of Blastocladiella. The heat-shock response in Blastocladiella is dependent on the developmental stage. Cells exposed to elevated temperatures at different stages of life cycle (sporulation, germination or growth) show a differential synthesis of heat-shock proteins (Hsps). Of a total af 22 polypeptides induced, particular subsets of Hsps appear in each phase, demonstrating a non-coordinate heat-shock gene expression. By the criteria of two-dimensional gel electrophoresis and partial proteolysis mapping, the 70-kDa protein, whose synthesis is induced spontaneously during sporulation, is indistinguishable from the heat-inducible hsp70. Additional evidence in support of the identity between the 70-kDa protein and Hsp70 was provided by immunological cross-reaction of both proteins with antibodies against DnaK protein from E.coli and Hsp70 from Drosophila. The techniques of in vitro translation, and Northern analysis using a Drosophila hsp70 probe, demonstrated that enhanced synthesis of hsp70, which occurs during heat-shock treatment and spontaneously during sporulation, is associated with an accumulation of Hsp70 mRNA. Although the Hsps synthesis is developmentally regulated in Blastocladiella, the acquisition of thermotolerance can be induced at any stage of the life cycle. lhe development of thermotolerance is correlated with the enhanced synthesis of some heat-shock proteins: Hsp82a, Hsp82b, Hsp76, Hsp70, Hsp60, Hsp25, Hsp17b. Other Hsps are not specifically involved in thermotolerance. In B. emersonii the state of 56 phosphorylation changes depending on the developmental stage and environmental conditions (Bonato et al., 1984, Eur. J. Biochem. 144, 597-606). On the other hand, we verified that the heat-shock response is developmentally regulated. Then, we examined the changes in 56 phosphorylation during heat shock, thermotolerance, and recovery from heat shock at different stages of life cycle in order to investigate whether the different levels of 56 phosphorylation might be correlated with the translation of specific message subsets. We observed that independently of the initial state of 56 phosphorylation (maximal or intermediate), a rapid and complete dephosphorylation of 56 is induced by heat shock and 56 remains unphosphorylated during the acquired thermotolerance. During recovery from heat shock rephosphorylation of 56 occurs always to the levels characteristic of that particular stage, coincidently with the turn off of heat shock protein synthesis.

Aquatic fungus

Cell differentiation

Diferenciação celular

Fosforilação de proteínas

Fungo aquático

Gene regulation

Protein phosphorylation

Proteína S6

Regulação gênica

S6 protein