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35. A large hinge bending domain rotation is necessary for the catalytic function of Escherichia coli 5'-nucleotidase

Author

Schultz-Heienbrok, Robert, Maier, Timm, and Strater, Norbert

Subjects
Catalytic antibodies -- Research, Nucleotidases -- Research, Escherichia coli -- Research, Biological sciences, Chemistry
Abstract

Two variants of Escherichia coli 5'-nucleotidase with disulfide bridges that were engineered to link the two domains of the protein were used to demonstrate that a large domain rotation is required for the catalytic mechanism of the enzyme. Kinetic analysis demonstrated that the variant trapped in the open form is almost inactive but can be activated upto 250 fold by reduction of the disulfide bridge.

Published
2005

36. Conjugated bile acid hydrolase is a tetrameric N-terminal thiol hydrolase with specific recognition of its cholyl but not of its tauryl product

Author

Rossocha, Maksim, Schultz-Heienbrok, Robert, Moeller, Holger von, Coleman, James P., and Saenger, Wolfram

Subjects
Bile acids -- Chemical properties, Hydrolases -- Chemical properties, Thiols -- Chemical properties, Enzymes -- Chemical properties, Biological sciences, Chemistry
Abstract

The 2.1 Angstrom resolution structure of unliganded Clostridium perfringens conjugated bile acid hydrolase (CBAH) apoenzyme and the 1.7 Angstrom resolution crystal structure of the complex formed between CBAH and the substrate taurodeoxycholic acid is presented. The structure analysis of C. perfringens CBAH identifies critical residues in catalysis, substrate recognition, and tetramer formation, which may serve in further biochemical characterization of bile acid hydrolases.

Published
2005

37. Die Domänenbewegung der 5'-Nukleotidase aus Escherichia coli

Author

Schultz-Heienbrok, Robert

Subjects
protein movement, CD-spectroscopy, disulfide crosslinking, Protein crystallography, Disulfide bridges, 500 Naturwissenschaften und Mathematik::540 Chemie::540 Chemie und zugeordnete Wissenschaften, domain motion
Abstract

0\. Titel, Abkürzungen und Inhaltsverzeichnis 1\. Einleitung 9 2\. Material und Methoden 22 3\. Proteinaufreinigung und Kristallisation 42 4\. Röntgenstrukturanalysen 51 5\. Kinetische Untersuchungen 110 6\. Zirkulardichroismus-Spektroskopie 119 7\. Domänenbewegung und katalytischer Mechanismus 127 8\. Zusammenfassung 132 9\. Ausblick 134 Literaturverzeichnis 136 Anhang 148, Das Protein 5'-Nukleotidase (5'-NT) aus Escherichia coli hydrolysiert eine große Anzahl verschiedener Nukleotide und Polynukleotide, wobei die Katalyse abhängig ist von zwei Metallionen im aktiven Zentrum. Das bakterielle Protein dient als Modellenzym zum einen, um den Mechanismus der Zweimetallionen- Katalyse von Phosphoestern zu untersuchen und zum anderen, um die Funktionsweise des humanen Homologs Ekto-5�-Nukleotidase (CD73) zu analysieren. Die hier vorgelegte Arbeit basiert auf den Röntgenstrukturanalysen der 5'-NT, die gezeigt haben, dass das Enzym in verschiedenen Konformationen kristallisiert. Die Konformationen unterscheiden sich hinsichtlich der Rotation der kleineren C-terminalen Domäne des Proteins relativ zur größeren N-terminalen Domäne. Die größte bislang beobachtete Rotation entspricht einer Drehung der C-terminalen Domäne um 96,7°. Die Domänenbewegung lässt sich als eine Gelenkbewegung beschreiben, bei der die Reste an der Domänengrenzfläche entlang der Grenzfläche gleiten und nicht - wie bei einer typischen Schließbewegung - sich von der Grenzfläche entfernen (offene Konformation) oder sich ihr nähern (geschlossene Konformation). Um die funktionelle Bedeutung von Proteinbewegungen nachzuweisen, werden häufig die beweglichen Proteinfragmente über Disulfidbrücken unter der Annahme quervernetzt, dass unter oxidierenden Bedingungen das Protein inaktiv ist, durch Reduktion der Cysteine das Protein aber aktiviert werden kann. In der vorliegenden Arbeit gelang es, ein solches System für die 5'-NT zu entwickeln und sowohl strukturell wie auch biochemisch zu analysieren. Die Cysteine, die die 5'-NT in einer offenen Konformation (Substratbindestelle weit ent-fernt vom aktiven Zentrum) fixieren sollten wurden an den Stellen Serin-228 und Prolin-513 eingeführt (Protein SP) und die Cysteine, die das Protein in einer geschlossenen Konformation (Substratbindestelle dicht bei dem aktiven Zentrum) fixieren sollten, wurden an den Stellen Prolin-90 und Leucin-424 eingeführt (Protein PL). Es gelang, die derart modifizierten Gene zu exprimieren, die Proteine zu isolieren und zu kristallisieren. Das PL-Protein kristallisierte in einer tetragonalen Kristallform, das SP-Protein kristallisierte in zwei verschiedenen Kristallformen: einer tetragonalen und einer monoklinen. Die Strukturbestimmung dieser Proteine zeigte, dass das Protein trotz der eingebauten Disulfidquervernetzung noch erstaunlich flexibel ist. So zeigt ein Vergleich der SP-Strukturen, dass sich die C-terminalen Domänen trotz der Domänenquervernetzung um eine Rotation von 11,5° unterscheiden. Die Struktur des PL-Enzyms unterscheidet sich um eine Drehung von 43° gegenüber der anvisierten geschlossenen Struktur. Mit Hilfe theoretischer Berechnungen und kinetischer Daten wird gezeigt, dass das PL-Enzym trotz der Disulfidbrücke um diese 43° rotieren kann. Die strukturelle Integrität des Proteins wurde durch die Einführung der Disulfidbrücken nicht angetastet. Dies konnte strukturell mittels Überlagerungen zu den Wildtyp-Strukturen, der Koordination von Metallionen im aktiven Zentrum, sowie durch den Vergleich der Rotationsachsen, die alle in der gleichen Ebene wie die der Wildtyp-Strukturen liegen, gezeigt werden. Obwohl die quervernetzten Proteine sich als äußerst beweglich herausstellten, sind sie dennoch in ihrer Rotationsfreiheit stark eingeschränkt und konnten für kinetische und spektroskopische Untersuchungen eingesetzt werden. Die kinetischen Untersuchungen ergaben, dass beide Enzyme sich durch Reduktion aktivieren ließen, wodurch bewiesen werden konnte, dass die Rotationsbewegung wichtiger Bestandteil des katalytischen Mechanismus ist. Desweiteren konnte gezeigt werden, dass die Roationsbewegung auch ursächlich ist für das Phänomen der Substratinhibierung, die für das Wildtyp-Protein charakteristisch ist. Durch Vergleichende CD-spektroskopische Messungen des Wildtyp-Proteins mit den quervernetzten Enzymvarianten konnten dem Wildtyp- Protein Konformationen in Lösung zugewiesen werden. Auf diese Weise konnte zweifelsfrei festgestellt werden, dass die 5'-NT in Lösung in einer offenen Konformation vorliegt. Desweiteren wurde beobachtet, dass sich die Konformation des Wildtyps ändert, wenn Metallionen und Inhibitor anwesend sind, nicht aber wenn nur der Inhibitor ohne Metallionen anwesend ist. Durch die Strukturbestimmung der disulfidverbrückten Proteine evaluiert diese Arbeit die Methode der Quervernetzung kritisch, indem sie auf die hohe Beweglichkeit der quervernetzten Proteine aufmerksam macht. Gleichzeitig gelang es jedoch, diese Enzymvarianten einzusetzen, um wichtige biochemische Erkenntnisse zu gewinnen. Ausschlaggebend für eine sinnvolle Interpretation der biochemischen Daten war die Kenntnis der Struktur der Enzyme., The enzyme 5'-nucleotidase from E. coli hydrolyses phosphoester and phosphoanhydride bonds of various nucleotides. Four different crystal structures of the enzyme revealed that the two domains of the monomeric protein can assume different conformations with a maximum rotation of 96° of the C-terminal domain relative to the N-terminal domain. In this thesis the two domains of the proteins were cross-linked via two genetically introduced cysteine residues that form a disulfide bridge. To trap the protein in both an open and closed conformation two double mutants were created: Ser-228->Cys, Pro-513->Cys (open conformation, referred to as SP-protein) and Leu-424->Cys (closed conformation, referred to as PL-protein). The modified genes could be expressed and the proteins could be purified. The PL-protein crystallised in a tetragonal crystal form, whereas two different crystal forms (one tetragonal and one monoclinic) of the SP-protein were obtained. Structure analysis revealed that the cross-linked enzyme variants were still very flexible. This is apparent from a comparison of the molecules within the two structures of the SP-protein that differ by 11,5° from each other. Moreover, the structure of the PL-enzyme differs by a rotation of 43,2° from the targeted closed conformation. Both kinetic data and theoretical calculations demonstrate that the PL-protein can indeed rotate more than 40° despite the movement constraining disulfide bridge. Introducing the disulfide bridge into the protein did not compromise its structural integrity. This conclusion is drawn on basis of structural superpositions and analysis of the metal ion coordination in the active centre where no differences in the mutant strucutres as compared to the wild-type structures could be found. Furthermore, the interdomain screw axes between the engineered proteins and the wild type protein were all located approximately in the same plane as all screw axes relating the wild-type conformations indicating that the enzyme was trapped in a conformation that belongs to the rotational landscape of the wild-type protein. Although the mutant proteins were unexpectedly flexible they could be used for kinetic and spectroscopic analysis. Both enzymes could be kinetically activated upon reduction of the disulfide bridges, which proved that the domain rotation is in integral part of the cataly-tic functioning of the enzyme. Moreover, the data show that the substrate inhibtion observed in the wild-type protein is linked to the domain rotation of the enzyme. The cross-linked proteins were also used as conformational reference states in CD- spectroscopy. With the help of these reference states it was possible to assign the wild-type protein to an open conformation. Furthermore, a conformational change has been observed for the wild-type protein after adding both inhibitor and metal ions. Taken together this thesis gives a detailed exemplary structural description on engineered disulfide bridges in proteins and shows that biochemical analysis of the cross-linked proteins provides valuable information on the interplay between protein movement and catalytic functioning in E. coli 5'-nucleotidase. The structural information greatly facilitated the interpretation of the biochemical data.

Published
2004

44. RPGR transcription studies in mouse and human tissues reveal a retina-specific isoform that is disrupted in a patient with X-linked retinitis pigmentosa.

Author

Kirschner, Renate, Rosenberg, Thomas, Schultz-Heienbrok, Robert, Lenzner, Steffen, Feil, Silke, Roepman, Ronald, Cremers, Frans P. M., Ropers, Hans-Hilger, and Berger, Wolfgang

Abstract

X-linked retinitis pigmentosa (XLRP) is a genetically heterogeneous group of progressive retinal degenerations. The disease process is initiated by premature apoptosis of rod photoreceptor cells in the retina, which leads to reduced visual acuity and, eventually, complete blindness. Mutations in the retinitis pigmentosa GTPase regulator (RPGR), a ubiquitously expressed gene at the RP3 locus in Xp21.1, account for ~20% of all X-linked cases. We have analysed the expression of this gene by northern blot hybridization, cDNA library screening and RT-PCR in various organs from mouse and man. These studies revealed at least 12 alternatively spliced isoforms. Some of the transcripts are tissue specific and contain novel exons, which elongate or truncate the previously reported open reading frame of the mouse and human RPGR gene. One of the newly identified exons is expressed exclusively in the human retina and mouse eye and contains a premature stop codon. The deduced polypeptide lacks 169 amino acids from the C-terminus of the ubiquitously expressed variant, including an isoprenylation site. Moreover, this exon was found to be deleted in a family with XLRP. Our results indicate tissue-dependent regulation of alternative splicing of RPGR in mouse and man. The discovery of a retina-specific transcript may explain why phenotypic abberations in RP3 are confined to the eye. [ABSTRACT FROM AUTHOR]

Published
1999
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45. Crystal structures of human saposins C andD: implications for lipid recognition and membrane interactions.

Author

Rossmann M, Schultz-Heienbrok R, Behlke J, Remmel N, Alings C, Sandhoff K, Saenger W, and Maier T

Subjects
Amino Acid Sequence, Cell Membrane metabolism, Cloning, Molecular, Conserved Sequence, Crystallography, X-Ray, Cysteine chemistry, Dimerization, Humans, Hydrophobic and Hydrophilic Interactions, Lipid Metabolism, Models, Biological, Models, Molecular, Molecular Sequence Data, Mutagenesis, Pichia genetics, Protein Structure, Secondary, Protein Structure, Tertiary, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Saposins genetics, Saposins isolation & purification, Sequence Homology, Amino Acid, Saposins chemistry
Abstract

Human saposins are essential proteins required for degradation of sphingolipids and lipid antigen presentation. Despite the conserved structural organization of saposins, their distinct modes of interaction with biological membranes are not fully understood. We describe two crystal structures of human saposin C in an "open" configuration with unusual domain swapped homodimers. This form of SapC dimer supports the "clip-on" model for SapC-induced vesicle fusion. In addition, we present the crystal structure of SapD in two crystal forms. They reveal the monomer-monomer interface for the SapD dimer, which was confirmed in solution by analytical ultracentrifugation. The crystal structure of SapD suggests that side chains of Lys10 and Arg17 are involved in initial association with the preferred anionic biological membranes by forming salt bridges with sulfate or phosphate lipid headgroups.

Published
2008
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46. Trapping a 96 degrees domain rotation in two distinct conformations by engineered disulfide bridges.

Author

Schultz-Heienbrok R, Maier T, and Sträter N

Subjects
5'-Nucleotidase genetics, Crystallography, X-Ray, Escherichia coli genetics, Pliability, 5'-Nucleotidase chemistry, Disulfides chemistry, Escherichia coli enzymology, Protein Structure, Tertiary, Rotation
Abstract

Engineering disulfide bridges is a common technique to lock a protein movement in a defined conformational state. We have designed two double mutants of Escherichia coli 5'-nucleotidase to trap the enzyme in both an open (S228C, P513C) and a closed (P90C, L424C) conformation by the formation of disulfide bridges. The mutant proteins have been expressed, purified, and crystallized, to structurally characterize the designed variants. The S228C, P513C is a double mutant crystallized in two different crystal forms with three independent conformers, which differ from each other by a rotation of up to 12 degrees of the C-terminal domain with respect to the N-terminal domain. This finding, as well as an analysis of the domain motion in the crystal, indicates that the enzyme still exhibits considerable residual domain flexibility. In the double mutant that was designed to trap the enzyme in the closed conformation, the structure analysis reveals an unexpected intermediate conformation along the 96 degrees rotation trajectory between the open and closed enzyme forms. A comparison of the five independent conformers analyzed in this study shows that the domain movement of the variant enzymes is characterized by a sliding movement of the residues of the domain interface along the interface, which is in contrast to a classical closure motion where the residues of the domain interface move perpendicular to the interface.

Published
2004
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