Klinisches und diagnostisches Spektrum der pädiatrischen Hypophosphatasie : eine retrospektive Auswertung der Daten von 50 Patienten / Pediatric hypophosphatasia: a retrospective single-centre chart review of 50 children

Vogt, Marius Lothar

January 2020

Die Hypophosphatasie (HPP) ist eine seltene, angeborene Knochen- und Systemerkrankung, welche Patienten allen Alters betrifft. Verursacht wird die Erkrankung durch Mutationen im ALPL-Gen, welches für die gewebeunspezifische Alkalische Phosphatase codiert und mit einem Funktionsverlust des Enzyms einhergeht. Die Ausprägung der klinischen Symptomatik ist sehr heterogen und reicht von milden und unspezifischen bis hin zu potenziell lebensbedrohlichen Symptomen, was die korrekte Diagnose zusätzlich erschwert und verzögert. Um das Verständnis der pädiatrischen HPP zu verbessern und die Dauer von Symptombeginn bis zur korrekten Diagnose zu verkürzen, haben wir den Verlauf der Erkrankung anhand einer retrospektiven Aufarbeitung der Daten von 50 pädiatrischen HPP Patienten, die in den letzten 25 Jahren an der Universitäts-Kinderklinik in Würzburg vorstellig waren, untersucht. Diese Ergebnisse bestätigen den klinischen Eindruck der HPP als chronische Systemerkrankung, welche aufgrund ihrer unspezifischen klinischen Präsentation oftmals nur mit zeitlicher Verzögerung diagnostiziert wird. Dieser Verzögerung kommt insbesondere im Hinblick auf die 2015 zur Behandlung der pädiatrischen HPP zugelassenen Enzymersatztherapie mit dem Wirkstoff Asfotase alfa eine besondere Bedeutung zu, da die Patienten von einer frühzeitigen Diagnose und einem damit einhergehenden frühzeitigen Beginn der Behandlung profitieren können. Diese Ergebnisse tragen einen Teil dazu bei, das Bewusstsein und die Kenntnis der Erkrankung zu verbessern, um so die die Zeitspanne zwischen Symptombeginn und Diagnosestellung zu verkürzen und die medizinische Versorgung der Patienten zu verbessern. / Hypophosphatasia (HPP) is a rare, inherited metabolic disorder caused by loss-of-function mutations in the ALPL gene that encodes the tissue-nonspecific alkaline phosphatase TNAP (ORPHA 436). Its clinical presentation is highly heterogeneous with a remarkably wide-ranging severity. HPP affects patients of all age. Therefore, diagnosis is often difficult and delayed. To improve the understanding of HPP in children and in order to shorten the diagnostic time span in the future we studied the natural history of the disease in our large cohort of pediatric patients. In light of the enzyme replacement therapy (Asfotase alfa, a recombinant mineral-targeted TNAP), HPP patients may benefit from early treatment in the course of the disease. This single centre retrospective chart review included longitudinal data from 50 patients with HPP diagnosed and followed at the University Children`s Hospital Wuerzburg, Germany over the last 25 years. Reported findings support our clinical impression of a chronic multi-systemic disease with often delayed diagnosis. Our natural history information provides detailed insights into the prevalence of different symptoms which can help to improve and to shorten diagnostics and thereby lead to an optimised medical care, especially with promising therapeutic options like enzyme-replacement-therapy with Asfotase alfa in mind.

Hypophosphatasie

Alkalische Phosphatase

Stoffwechselkrankheit

Erbkrankheit

ddc:610

Potenciální využití WIP1 fosfatasy v terapii nádorového onemocnění prsu / Potenciální využití WIP1 fosfatasy v terapii nádorového onemocnění prsu

Pecháčková, Soňa

January 2017

Cells in our body respond to genotoxic stress by activation of a conserved DNA damage response pathway (DDR). Depending on the level DNA damage, DDR signaling promotes temporary cell cycle arrest (checkpoint), permanent growth arrest (senescence) or programmed cell death (apoptosis). Checkpoints prevent progression through the cell cycle and facilitate repair of damaged DNA. DDR represents an intrinsic barrier preventing genome instability to protect cells against cancer development. WIP1 (encoded by PPM1D) phosphatase is a major negative regulator of DDR pathway and is essential for checkpoint recovery. This thesis contributed to the understanding of molecular mechanisms of WIP1 function and revealed how WIP1 can be involved in tumorigenesis. Firstly, we described that WIP1 protein levels decline during mitosis by APC-Cdc20 dependent proteasomal degradation. WIP1 is phosphorylated at multiple residues which inhibit its enzymatic activity. We propose that inhibition of WIP1 in mitosis allows sensing of low levels of DNA damage that appear during unperturbed mitosis. Further, we identified novel gain-of-function mutations of PPM1D which result in expression of C-terminally truncated WIP1. These truncated WIP1 variants are enzymatically active and exhibit increased protein stability. As result, cells...

Morbidity and Mortality Associated With Paget's Disease of Bone: A Population-Based Study

Wermers, Robert, Tiegs, Robert D., Atkinson, Elizabeth J., Achenbach, Sara J., Melton, L. Joseph

01 June 2008

Introduction: Limited information is available about the clinical features of Paget's disease of bone among unselected patients in the community. We examined morbidity and mortality associated with this condition in a large inception cohort of Olmsted County, MN, residents with a new diagnosis of Paget's disease from 1950 through 1994. Materials and Methods: Survival was estimated using the Kaplan-Meier method. Cox proportional hazards models were used to assess the impact of various covariates on death. Results: Paget's disease of bone was diagnosed in 236 Olmsted County residents (mean age at diagnosis, 69.6 yr; 55% men). The majority were symptomatic at diagnosis (58%), and the proportion with symptoms did not change from the prescreening era (1950 to June 1974) to the postscreening era (July 1974-1994). Most patients had polyostotic disease (72%), and the pelvis (67%), vertebra (41%), and femur (31%) were the most common sites of involvement. Skeletal complications attributable to Paget's disease included bowing deformities (7.6%), fracture of pagetic bone (9.7%), and osteosarcoma (0.4%). Osteoarthritis was observed in 73% of patients, and 11% had a hip or knee replacement. Nonskeletal complications related to Paget's disease included cranial nerve (0.4%), peripheral nerve (1.7%), and nerve root (3.8%) compression, basilar invagination (2.1%), hypercalcemia (5.2%), and congestive heart failure (3.0%). Hearing loss, noted in 61%, was significantly higher than previously reported. Conclusions: Compared with white Minnesota residents, overall survival was slightly better than expected (p = 0.010). No clinical risk factors were identified that were associated with an increased risk of death.

alkaline phosphatase

epidemiology

morbidity

mortality

paget's disease

Remodeling of Helicobacter Pylori Lipopolysaccharide

Tran, An X., Stead, Christopher M., Trent, M. Stephen

23 August 2005

Modification of the lipid A domain of lipopolysaccharide (LPS) has been reported to contribute to the virulence and pathogenesis of various Gram-negative bacteria. The Kdo (3-deoxy-D-manno-octulosonic acid)-lipid A domain of Helicobacter pylori LPS shows several differences to that of Escherichia coli. It has fewer acyl chains, a reduced number of phosphate groups, much lower immunobiological activity, and only a single Kdo sugar is attached to the disaccharide backbone. However, H. pylori synthesizes a minor lipid A species resembling that of E. coli, which is both bis-phosphorylated and hexa-acylated suggesting that the major species results from the action of specific modifying enzymes. This work describes two enzymes, a lipid A phosphatase and a phosphoethanolamine transferase, involved in the periplasmic modification of the 1-position of H. pylori lipid A. Furthermore, we report a novel Kdo trimming enzyme that requires prior removal of the 1-phosphate group for enzymatic activity. Discovery of the enzymatic machinery involved in the remodeling of H. pylori LPS will help unravel the importance of these modifications in H. pylori pathogenesis.d.

helicobacter pylori

Kdo

lipid A

LPS

phosphatase

phosphoethanolamine

Biochemical Characterization of SAC9, a Putative Phosphoinositide Phosphatase in Arabidopsis thaliana, and Its Role in Cellular Abnormalities

Vollmer, Almut H.

01 May 2012

The phospholipid phosphatidylinositol and its phosphorylated derivatives, collectively referred to as phosphoinositides, form the basis for a multifaceted signaling pathway regulating many different cellular processes in eukaryotic cells. Phosphatidylinositol 4,5-bisphosphate, PI(4,5)P2, assumes a central position in this complex pathway. It can serve as a precursor for the generation of second messengers but can also act as a ligand to partner proteins. In order to mediate their physiological effects properly, the location and quantity of PI(4,5)P2 and other phosphoinositides have to be tightly controlled by enzymes. In general, phospholipid kinases lead to the activation of the pathway, whereas phospholipid phosphatases attenuate or terminate the signaling cascade. The SAC domain-containing protein 9 from Arabidopsis thaliana has been identified as a putative phosphoinositide phosphatase, but very little has been published on this particular protein. In my dissertation research, I broadened our knowledge of this protein and the effects seen in Arabidopsis plants carrying the mutant allele. I used molecular, genetic, and biochemical approaches to analyze the function of the putative phosphoinositide phosphatase, SAC9. To understand its physiological role, I investigated the cellular effects of a mutation in the SAC9 gene at the light microscopy, confocal microscopy, and transmission electron microscopy levels. My studies show that AtSAC9 is a soluble protein with an apparent molecular mass of 180 kDa and that it most likely is a phosphoinositide phosphatase. Furthermore, I show that the mutation of SAC9 induced unique cell wall defects that most likely have contributed to the stuntedness of the root. However, the cortical microtubule cytoskeleton was not disturbed in elongating root cells. These data are augmented by applying a novel approach for the mathematical analysis of cortical microtubule orientation.

biochemical

SAC9

putative

phosphoinositide

phosphatase

Biochemistry

Ssu72 and Rtr1 Serine 5 Phosphates and Their Role in NNS and CPF Transcription Termination

Victorino, Jose Fabian

05 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Polyadenylation dependent transcription termination is dependent on the Cleavage and Polyadenylation Factor complex (CPF) which is essential for the termination and processing of mature RNA. Polyadenylation (PolyA) independent transcription termination is carried out by the NNS (Nrd1-Nab3-Sen1) termination pathway, which helps regulate termination and processing of non-coding RNA (ncRNA). The disruption of these pathways can impact expression of nearby genes, both protein coding and noncoding. Recruitment of termination pathway components is achieved through a domain unique to the largest subunit of RNA Polymerase II (RNAPII) referred to as the Cterminal domain (CTD), which contains a repeating heptad sequence, Y1S2P3T4S5P6S7, and acts as a docking site for transcription regulatory proteins. Ssu72 is a serine 5 phosphatase and an essential member of the CPF complex. Rtr1 is also a serine 5 phosphatase, but its mechanism of action is less well characterized. Both Rtr1 and Ssu72 regulate transcription machinery recruitment through control of the phosphorylation status of the CTD. My studies have focused on Rtr1 and Ssu72 mutants in yeast which show evidence of transcription termination related phenotypes. Chromatin immunoprecipitation of RNAPII followed by exonuclease treatment (ChIP-exo) studies provide evidence of RNAPII transcription continuing through termination sites at ncRNA genes as a result of a hyperactive Ssu72-L84F mutant, while an RTR1 knockout results in increased premature RNAPII transcription termination. Northern blots and RNA sequencing confirm premature transcription termination and decreased total RNA expression in the RTR1 knockout and increased length of ncRNA transcripts as well as total RNA expression in the Ssu72-L84F mutant. Mass spectrometry analysis has identified changes in the protein-protein interactions (PPI) within the CPF complex in the Ssu72-L84F mutant and decreased PPIs between different transcription machinery in RTR1 knockout cells. My results show that the CTD phosphatases Rtr1 and Ssu72 play unique roles in the regulation of RNAPII termination in eukaryotes. / 2020-11-19

Phosphatase

RNAPII

Rtr1

Ssu72

Termination

Transcription

Mantle Dentin Defects in Odontohypophosphatasia

Kramer, Kaitrin

01 October 2020

No description available.

Dentistry

Continuous flow microwave heating : evaluation of system efficiency and enzyme inactivation kinetics

Lin, Man Guang, 1966-

January 2004

No description available.

Alkaline phosphatase.

Microwave heating.

Milk -- Pasteurization.

CALF INTESTINAL ALKALINE PHOSPHATASE APTAMER BASED BIOSENSORS

Cabrera, Pablo

11 1900

In recent years, there has been an increasing demand for newer, more accurate, technologies that can detect and identify biomolecules or biological entities related to health, agriculture or the environment. With the discovery of new properties of nucleic acids beyond the storage and transfer of genetic information, a new class of nucleic acid-based biosensors is emerging, using DNA and RNA as target recognition elements with the advantage of being simpler and more cost-effective compared to antibodies-based biosensor. Two sequences, TrG14MC and TrG10SC, with evidence to suggest that they are capable of inhibit the metalloenzyme CIP, were isolated from a selection conducted by Dr. Razvan Nutiu. Here we study the inhibitory properties of these two aptamer candidates and measure the IC50 value, determined as 94 nM for TrG14MC and 83 nM for TrG10SC. Different bivalent constructs, designed to increase the inhibitory effect of the isolated sequences, are studied showing a pronounce influence of the linker length improving the inhibitory effect over CIP. Modulating the interaction of the isolated sequences and the CIP is of key importance in order to develop a successful biosensor. Therefore, we try to recover CIP from the inhibition effect by using antisense sequences complementary to different segments of the construct. The maximum recovery, 75%, was achieved by an antisense sequence fully complemented to the inhibitory bivalent construct. We also study here the use of a linker in the bivalent construct that forms a secondary hairpin structure, and the effect of linearizing that structure with an antisense sequence complementary to the linker. This resulted in as 12% of the inhibitory effect. The purpose of this investigation was to establish the first steps toward the development of a new class of biosensors capable of disinhibiting CIP upon the recognition of a specific target, taking advantage of the suggested CIP-inhibitory properties of the isolated sequences TrG14MC and TrG10SC. / Thesis / Master of Applied Science (MASc)

aptamer

selex

Calf intestinal phosphatase

biosensor

Molekulare und funktionelle Charakterisierung der Serin/Threonin-Proteinkinase Stk und -Proteinphosphatase Stp von \(Staphylococcus\) \(aureus\) / Molecular and functional characterization of the serine/threonine protein kinase Stk and Protein phosphatase Stp of \(Staphylococcus\) \(aureus\)

Jarick, Marcel

January 2020

Staphylococcus aureus ist ein Kommensale, der die menschliche Haut und Schleimhaut der Nase und des Rachens besiedelt. Der Keim verursacht aufgrund zahlreicher Virulenzfaktoren leichte aber auch schwere Infektionen wie Pneumonie, Endokarditis oder Sepsis. Die Behandlung von S. aureus-Infektionen gestaltet sich heutzutage schwierig, da der Keim Resistenzen gegen verschiedenste Antibiotika ausgebildet hat. Zur Bekämpfung dieser Resistenzen werden neue Antibiotika benötigt, die u.a. mit der Zellphysiologie und der Zellwandwandsynthese der Bakterien interferieren. Die Zellphysiologie und Zellwandsynthese wird abhängig von der Wachstumsphase und Umwelt-einflüssen in den Bakterien streng reguliert. Neben den Zweikomponentensystemen sind Serin/Threonin-Proteinkinasen und -Phosphatasen wesentliche Sensoren und Regulatoren der Bakterien. Durch Phosphorylierung und Dephosphorylierung bewirken diese beiden Systeme eine Hemmung oder Aktivierung der entsprechenden Zielproteine. Dadurch kann sich die Bakterienzelle an innere und äußere Reize anpassen. In dieser Arbeit wurde die konservierte Serin/Threonin-Proteinkinase Stk und die Serin/Threonin-Phosphatase Stp von S. aureus untersucht. Die beiden Proteine Stk und Stp haben einen großen Einfluss auf die Signalweiterleitung, den zentralen Metabolismus, die Stressantwort, die Antibiotikaresistenz und die Virulenz von S. aureus. Im ersten Teil dieser Arbeit wird dargelegt, dass Stk und Stp in der bakteriellen Membran lokalisiert sind, dort miteinander interagieren und antagonistisch Zielproteine phosphorylieren bzw. dephospho-rylieren. Die Deletion der Phosphatase Stp bewirkt, dass zahlreiche Proteine in der Zelle permanent phosphoryliert und daher vermutlich nur noch eingeschränkt funktionstüchtig sind. Die ausbleibende Dephosphorylierung der Proteine in der stp-Mutante hat einen dramatischen Effekt auf die Zellwand-synthese und die Virulenz von S. aureus. So hat die stp-Mutante eine verdickte Zellwand und ist weniger virulent als die stk-Mutante und der Wildtypstamm. Im Rahmen dieser Arbeit wird erstmals eine Erklärung präsentiert, die die strukturellen Besonderheiten von Stk und deren Auswirkung auf die Zellwandsynthese zusammenführt: In der stp-Mutante akkumulieren Zellwandvorläufer in der Zelle, da vermutlich die entsprechenden Zellwandsyntheseproteine durch Stk-vermittelte Phosphorylierung gehemmt werden. Die Proteine FemXAB nehmen eine zentrale Rolle in der Zellwandsynthese ein, indem sie die Pentaglycin-Interpeptidbrücke des Zellwandvorläufers Pentaglycin-Lipid II syntheti-sieren. Stk wird durch die Bindung seiner extrazellulären Domänen an Pentaglycin-Lipid II aktiviert. In der vorliegenden Arbeit konnte FemX als in vitro Substrat von Stk und Stp identifiziert werden. Die permanente Phosphorylierung von FemX in der stp-Mutante führt zur verminderten Synthese der Pentaglycin-Brücken am Lipid II und infolgedessen zum Einbau von unvollständigen Muropeptiden in den neuen Peptidoglycanstrang. Diese strukturelle Veränderung führt zur Verdickung der Zellwand und folglich zur verminderten Empfindlichkeit gegenüber der Glycyl-Glycinpeptidase Lysostaphin. Neben FemX interagiert Stk mit weiteren Zellwandsyntheseproteinen wie FemAB und einigen Zellteilungsproteinen. Diese Ergebnisse verdeutlichen, dass Stk das Vorkommen seines extrazellulären Liganden Lipid II detektiert und dementsprechend die Zellwandsynthese über FemX reguliert. Im zweiten Teil der Arbeit wurde anhand verschiedener Omics-Techniken die stk-, stp- und stk/stp-Mutante im Vergleich zum S. aureus NewmanHG Wildtyp charakterisiert. Dabei zeigten sich teilweise große Unterschiede zwischen der stp-Mutante und den anderen Stämmen. Mit diesen Unter-suchungen konnten Ergebnisse aus anderen Studien bestätigt und mit weiteren Daten untermauert werden. So lässt sich die verminderte Virulenz der stp-Mutante mit der reduzierten Expression und Sekretion von Toxinen wie Hämolysinen und Leukozidinen erklären. Dies führt zu einer verminderten Hämolyse von Erythrozyten und einer verminderten Immunantwort gegen diese Toxine im Infektions-versuch. Stk und Stp phosphorylieren bzw. dephosphorylieren Transkriptionsfaktoren und Antwort-regulatoren von Zweikomponentensystemen, was zu der veränderten Expression und Sekretion der Virulenzfaktoren führt. Die Analyse der Mutanten offenbart, dass Stk ein negativer und Stp ein positiver Regulator der Virulenz in S. aureus ist. Außerdem regulieren Stk und Stp zentrale Aspekte des Metabolismus in S. aureus. So ist die Konzentration an Nukleotidtriphosphaten in der stp-Mutante reduziert, was auf eine verminderte Expression der Gene der Pyrimidinsynthese zurückzuführen ist. Anhand dieser Ergebnisse wird deutlich, dass Stk und Stp wesentliche Aspekte der Zellphysiologie wie die Zellwandsynthese, den zentralen Metabolismus und die Virulenz von S. aureus regulieren. / Staphylococcus aureus is a commensal that inhabits the human skin and mucosa. S. aureus causes a large variety of nosocomial and community-acquired infections. Nowadays, it is difficult to treat S. aureus infections because this bacterium has acquired resistance to multiple drugs. Therefore, there is a need for new antimicrobial drugs against S. aureus. The most promising strategy to combat antibiotic resistance is to find novel antibiotics which interfere with the cell physiology and cell wall synthesis pathway. The cell physiology and cell wall synthesis is tightly regulated depending on the bacterial growth phase and environmental influences. In addition to the two-component systems, serine/threonine protein kinases are essential sensors and regulators of bacteria. By phosphorylation and dephosphorylation, these systems cause inhibition or activation of the corresponding target proteins. This allows the bacterial cell to adapt to internal and external stimuli. In this work, the conserved serine/threonine protein kinase Stk and the phosphatase Stp in S. aureus were investigated. The two proteins Stk and Stp influence signal transduction, central metabolism, stress response, antibiotic resistance and virulence of S. aureus. In the first part of this work it is shown that Stk and Stp are localized in the bacterial membrane, where they interact with each other and phosphorylate or dephosphorylate target proteins antagonistically. The deletion of the phosphatase Stp leads to numerous proteins in the cell being permanently phosphorylated, which renders them partially unfunctional. The lack of protein dephosphorylation in the stp mutant has a dramatic effect on cell wall synthesis and virulence of S. aureus. Thus, the stp mutant has a thickened cell wall and is less virulent than the stk mutant and the wild-type strain. This work brings together the structural characteristics of Stk and their effect on cell wall synthesis for the first time. In the stp mutant, cell wall precursors accumulate in the cell, presumably because the corresponding cell wall synthesis proteins are inhibited by Stk-mediated phosphorylation. The proteins FemXAB play a key role in cell wall synthesis by synthesizing the pentaglycine interpeptide bridge of the final cell wall precursor pentaglycine lipid II. The pentaglycine lipid II is bound by the extracellular domains of Stk, thereby activating Stk. In the present work, FemX was identified as an in vitro substrate of Stk and Stp. The permanent phosphorylation of FemX in the stp mutant leads to inhibited synthesis of the pentaglycine bridges on the lipid II and consequently to the incorporation of incomplete muropeptides into the new peptidoglycan strand. This structural change leads to thickening of the cell wall and consequently reduced sensitivity to the glycyl-glycine peptidase lysostaphin. In addition to FemX, Stk interacts with other cell wall synthesis proteins such as FemAB and some cell division proteins. These results illustrate that Stk detects the presence of its extracellular ligand lipid II. This leads to an inhibition of FemX and a downregulation of the cell wall synthesis pathway. In the second part of this work, the stk, stp and stk/stp mutants were characterized by different omics- techniques in comparison to the S. aureus NewmanHG wild-type. There were some major differences between the stp mutant and the other strains. With these investigations, results from other studies were confirmed and substantiated with further data. Thus, the reduced virulence of the stp mutant can be explained by the reduced expression and secretion of toxins such as hemolysins and leukocidines. This leads to a reduced hemolysis of erythrocytes and a reduced immune response to these toxins in the infection experiment. Stk and Stp phosphorylate or dephosphorylate transcription factors and response regulators of two-component systems resulting in altered expression and secretion of virulence factors. Analysis of the mutants reveals that Stk is a negative and Stp is a positive regulator of virulence in S. aureus. In addition, Stk and Stp regulate central aspects of S. aureus metabolism. Thus, the concentration of nucleotide triphosphates in the stp mutant is reduced, which is due to a reduced expression of the genes of pyrimidine synthesis. From these results it becomes clear that Stk and Stp regulate essential aspects of cell physiology such as cell wall synthesis, central and virulence in S. aureus. This study of the function of Stk and Stp contributes significantly to the understanding of regulatory processes by phosphorylation in the bacterial cell.

Kinase

Phosphatase

Stk

Stp

Staphylococcus

ddc:570