Auswirkungen der Bestrahlung mit UVB, UVA-1 und PUVA-1 auf das Funktionsverhalten humaner dermaler Mastzellen nach Stimulation mit anti-IgE und Substanz P

Strathmann, Marc

16 September 2004

Die in dieser Arbeit isolierten und hochaufgereinigten, humanen dermalen Mastzellen wurden mit UVB, UVA-1 und PUVA-1 bestrahlt und anschließend entweder mit Substanz P oder anti-IgE stimuliert. Dadurch sollten Einblicke in die unterschiedlichen Wirkmechanismen der bei zahlreichen mastzellassoziierten Erkrankungen eingesetzten UV Licht Therapie gewonnen werden. Ein Schwerpunkt dieser Arbeit lag in der Erforschung der Histamin-, Tryptase- und Zytokinfreisetzung von menschlichen Mastzellen. Zusätzlich wurde die Expression von Lysosomen-assoziierten Membran Proteinen (LAMPs) auf der Oberfläche dieser Zellen untersucht. Im Gegensatz zu der durch UV Licht induzierbaren spontanen Histaminfreisetzung zeigte sich die anti-IgE stimulierte Histaminausschüttung durch UVB, UVA-1 und PUVA-1 signifikant und dosisabhängig inhibierbar. Auch die durch Substanz P stimulierten Mastzellen gaben nach UVA-1 Bestrahlung deutlich weniger Histamin ab. Demgegenüber blieb die sezernierte Menge des Mediators nach UVB und PUVA-1 konstant. Analog zu den erhobenen Histaminergebnissen konnte eine signifikante Inhibition der anti-IgE induzierten Tryptasefreisetzung nachgewiesen werden. Ebenso zeigte sich eine signifikante Verringerung, der innerhalb von vierundzwanzig Stunden basal freigesetzten Menge an Interleukin-6 und Interleukin-8, nach UV Bestrahlung. Die spontane Ausschüttung vom Tumornekrosefaktor-a verblieb in dem Untersuchungszeitraum auf sehr geringem Niveau, so dass eine relevante Beeinflussung durch UV Licht nicht stattfand. Des weiteren konnte eine vermehrte basale Expression von CD107a und CD63 auf der Mastzellmembran durch UV Bestrahlung demonstriert werden. Auch die anti-IgE induzierte Mehrexpression der LAMPs konnte bei den drei Bestrahlungsarten nachweisbar supprimiert werden. Die in dieser Arbeit gewonnenen Erkenntnisse zeigen, dass die Auswirkungen der UV Licht Therapie auf Mastzellen sehr komplex sind. Zu beachten ist, dass unter physiologischen Bedingungen nicht nur isolierte Mastzellen, sondern auch weitere bestrahlte Zellverbände eine Veränderung erfahren. Erst durch das Zusammenspiel aller Zellen lassen sich Rückschlüsse auf Krankheitsbilder und die anzuwendende Therapien ziehen. Letztendlich soll diese Arbeit dazu beitragen, dass das Verständnis der unterschiedlichen Wirkungen von UV Licht begriffen und so ein sinnvolles und gezieltes Einsetzen im klinischen Alltag ermöglicht wird. / For all experiments highly purified dermal mast cells were used. The aim of the current study was to systematically investigate the effects of UVB, UVA-1 and PUVA-1 on skin derived human mast cells. Baseline and stimulated release of histamine, tryptase and of the proinflammatory cytokines IL-6, IL-8 and TNF-a were examined. Furthermore, the CD 107a and CD 63 surface levels in UV treated cells were investigated representing two members of lysosome associated membrane proteins which were found to appear on mast cell surface during degranulation. Prior treatment with UV resulted in a striking suppression of the anti-IgE induced release of preformed mediators such as histamine and tryptase in a dose dependent manner. This inhibition was accompanied by a diminished, anti-IgE mediated increase in CD 107a and CD 63 surface expression. In sharp contrast, UV-light slightly preactivates mast cells as indicated by a marginal but statistically significant direct UV-caused histamine release. Theses findings matched the observation of slightly enhanced CD 107a and CD 63 surface levels in UV treated but unstimulated cells. After UVA-1 treatment the histamine release of substance P stimulated mast cells is statistically significant reduced which contrasts to the unchanged liberation of this preformed marker after UVB and PUVA-1 irradiation. Furthermore the release of mediators that are not or only partially preformed was examined. In the present study all types of UV-irradiation inhibits baseline IL-6 and IL-8 secretion from mast cells. The very low baseline level of TNF-a remained unaffected. Taken together, the present findings identify cutaneous human mast cells as important targets of UV-induced immunomodulation. They help explain both the dose-dependent adverse effects of UV-light and the beneficial and desired antiinflammatory effects during therapy.

Humane dermale Mastzelle

UV Licht

Mediatoren

human skin mast cell

UV light

mediators

610 Medizin

33 Medizin

XG 4304

YF 1804

WW 5000

ddc:610

Single-Molecule Measurements of Complex Molecular Interactions in Membrane Proteins using Atomic Force Microscopy

Sapra, K. Tanuj

01 March 2007

Single-molecule force spectroscopy (SMFS) with atomic force microscope (AFM) has advanced our knowledge of the mechanical aspects of biological processes, and helped us take big strides in the hitherto unexplored areas of protein (un)folding. One such virgin land is that of membrane proteins, where the advent of AFM has not only helped to visualize the difficult to crystallize membrane proteins at the single-molecule level, but also given a new perspective in the understanding of the interplay of molecular interactions involved in the construction of these molecules. My PhD work was tightly focused on exploiting this sensitive technique to decipher the intra- and intermolecular interactions in membrane proteins, using bacteriorhodopsin and bovine rhodopsin as model systems. Using single-molecule unfolding measurements on different bacteriorhodopsin oligomeric assemblies - trimeric, dimeric and monomeric - it was possible to elucidate the contribution of intra- and interhelical interactions in single bacteriorhodopsin molecules. Besides, intriguing insights were obtained into the organization of bacteriorhodopsin as trimers, as deduced from the unfolding pathways of the proteins from different assemblies. Though the unfolding pathways of bacteriorhodopsin from all the assemblies remained the same, the different occurrence probability of these pathways suggested a kinetic stabilization of bacteriorhodopsin from a trimer compared to that existing as a monomer. Unraveling the knot of a complex G-protein coupled receptor, rhodopsin, showed the existence of two structural states, a native, functional state, and a non-native, non-functional state, corresponding to the presence or absence of a highly conserved disulfide bridge, respectively. The molecular interactions in absence of the native disulfide bridge mapped onto the three-dimensional structure of native rhodopsin gave insights into the molecular origin of the neurodegenerative disease retinitis pigmentosa. This presents a novel technique to decipher molecular interactions of a different conformational state of the same molecule in the absence of a high-resolution X-ray crystal structure. Interestingly, the presence of ZnCl2 maintained the integrity of the disulfide bridge and the nature of unfolding intermediates. Moreover, the increased mechanical and thermodynamic stability of rhodopsin with bound zinc ions suggested a plausible role for the bivalent ion in rhodopsin dimerization and consequently signal transduction. Last but not the least, I decided to dig into the mysteries of the real mechanisms of mechanical unfolding with the help of well-chosen single point mutations in bacteriorhodopsin. The monumental work has helped me to solve some key questions regarding the nature of mechanical barriers that constitute the intermediates in the unfolding process. Of particular interest is the determination of altered occurrence probabilities of unfolding pathways in an energy landscape and their correlation to the intramolecular interactions with the help of bioinformatics tools. The kind of work presented here, in my opinion, will not only help us to understand the basic principles of membrane protein (un)folding, but also to manipulate and tune energy landscapes with the help of small molecules, proteins, or mutations, thus opening up new vistas in medicine and pharmacology. It is just a matter of a lot of hard work, some time, and a little bit of luck till we understand the key elements of membrane protein (un)folding and use it to our advantage.

info:eu-repo/classification/ddc/530

ddc:530

Protein precipitates, aggregation kinetics and membrane protein receptors characterized by solid-state NMR / Charakterisierung von Proteinpräzipitaten, Aggregationskinetik und Membranproteinen mittels Festkörper-NMR

Etzkorn, Manuel

19 June 2008

No description available.

500 Naturwissenschaften allgemein

Mathematics and Computer Science

Festkörper NMR

Membran Proteine

Protein Aggregation

MAS NMR

Crh

Sensorisches Rhodopsin

DcuS

solid-state NMR

Membrane proteins

protein aggregation

MAS NMR

crh

Sensory rhodopsin

DcuS

42.12

35.10

42.13

SP 000: Strukturchemie