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Measles virus (MeV) is an aerosol-borne and one of the most contagious pathogenic viruses known. Almost every MeV infection becomes clinically manifest and can lead to serious and even fatal complications, especially under conditions of malnutrition in developing countries, where still 115,000 to 160,000 patients die from measles every year. There is no specific antiviral treatment. In addition, MeV infections cause long-lasting memory B and T cell impairment, predisposing people susceptible to opportunistic infections for years. A rare, but fatal long-term consequence of measles is subacute sclerosing panencephalitis. Fifteen years ago (2001), WHO has launched a programme to eliminate measles by a worldwide vaccination strategy. This is promising, because MeV is a human-specific morbillivirus (i.e. without relevant animal reservoir), safe and potent vaccine viruses are sufficiently produced since decades for common application, and millions of vaccine doses have been used globally without any indications of safety and efficacy issues. Though the prevalence of wild-type MeV infection has decreased by >90 % in Europe, measles is still not eliminated and has even re-emerged with recurrent outbreaks in developed countries, in which effective vaccination programmes had been installed for decades. Here, we discuss the crucial factors for a worldwide elimination of MeV: (1) efficacy of current vaccines, (2) the extremely high contagiosity of MeV demanding a >95 % vaccination rate based on two doses to avoid primary vaccine failure as well as the installation of catch-up vaccination programmes to fill immunity gaps and to achieve herd immunity, (3) the implications of sporadic cases of secondary vaccine failure, (4) organisation, acceptance and drawbacks of modern vaccination campaigns, (5) waning public attention to measles, but increasing concerns from vaccine-associated adverse reactions in societies with high socio-economic standards and (6) clinical, epidemiological and virological surveillance by the use of modern laboratory diagnostics and reporting systems. By consequent implementation of carefully designed epidemiologic and prophylactic measures, it should be possible to eradicate MeV globally out of mankind, as the closely related morbillivirus of rinderpest could be successfully eliminated out of the cattle on a global scale.
Das Protein p21 (Cip1/Waf1/Sdi1), ein Mitglied der Familie der Cyclin abhängigen Kinasen-Inhibitoren, ist ein wichtiger Modulator des Zellwachstums und der Reaktion auf DNA-Schädigung. Die Funktion von p21 hängt von der Stabilität des Proteins ab. p21 ist besonders stabil in der Phase G0/G1 des Zellzyklus. Phoshorylierungsvorgänge sowie Interaktionen mit anderen Proteinen spielen in der Stabilität von Proteinen eine wichtige Rolle. Ziel der vorliegenden Arbeit war, herauszufinden, ob die Phosphorylierung von p21 durch die Proteinkinase AKT oder die durch diese Phosphorylierung beeinflusste Interaktion mit dem Proliferating cell nuclear antigen, kurz PCNA, einen Einfluß auf die Stabilität von p21 hat. Mittels Proteinhalbwertszeitbestimmung konnte demonstriert werden, daß die Phosphorylierung am Threonin 145 durch AKT keinen signifikanten Einfluß auf die Stabilität von p21 aufwies. Durch Pulse chase und Westem-Blot Versuche konnte aber nachgewiesen werden, daß die Anwesenheit von PCNA das Protein p21 stabilisierte und die Degradation beeinflusste. Es konnte mittels p21 Mutanten, deren PCNA- Bindung durch Austausch der Aminosäure (M147) inhibiert ist, gezeigt werden, daß nur eine direkte Bindung von PCNA an p21 die Degradation beeinflussen konnte. Die Bestimmung der subzellulären Lokalisation von p21, die zur weiteren Abklärung der erhöhten p21-Stabilität durch PCNA diente, zeigte in Immunopräzipitationsversuchen nach subzellulärer Fraktionierung eine Interaktion von p21 mit PCNA vorwiegend im Zytoplasma. Dies ließ sich auch durch Immunofluoreszenzuntersuchungen bestätigen. Schließlich zeigten die Untersuchungen, daß die subzelluläre Lokalisation von der direkten Bindung an PCNA abhängig war. Zusammenfassend zeigte die Arbeit auf, daß die Stabilität von p21 durch seinen Bindungspartner PCNA beeinflusst werden konnte, und dies vermutlich durch subzelluläre Translokation erfolgt.
Glycogen synthase kinase-3 couples AKT-dependent signaling to the regulation of p21Cip1 degradation
(2002)
Signaling via the phosphoinositide 3-kinase (PI3K)/AKT pathway is crucial for the regulation of endothelial cell (EC) proliferation and survival, which involves the AKT-dependent phosphorylation of the DNA repair protein p21(Cip1) at Thr-145. Because p21(Cip1) is a short-lived protein with a high proteasomal degradation rate, we investigated the regulation of p21(Cip1) protein levels by PI3K/AKT-dependent signaling. The PI3K inhibitors Ly294002 and wortmannin reduced p21(Cip1) protein abundance in human umbilical vein EC. However, mutation of the AKT site Thr-145 into aspartate (T145D) did not increase its protein half-life. We therefore investigated whether a kinase downstream of AKT regulates p21(Cip1) protein levels. In various cell types, AKT phosphorylates and inhibits glycogen synthase kinase-3 (GSK-3). Upon serum stimulation of EC, GSK-3beta was phosphorylated at Ser-9. Site-directed mutagenesis revealed that GSK-3 in vitro phosphorylated p21(Cip1) specifically at Thr-57 within the Cdk binding domain. Overexpression of GSK-3beta decreased p21(Cip1) protein levels in EC, whereas the specific inhibition of GSK-3 with lithium chloride interfered with p21(Cip1) degradation and increased p21(Cip1) protein about 10-fold in EC and cardiac myocytes (30 mm, p < 0.001). These data indicate that GSK-3 triggers p21(Cip1) degradation. In contrast, stimulation of AKT increases p21(Cip1) via inhibitory phosphorylation of GSK-3.
(±)-Aeroplysinin-1, an optically active 1.2-dihydroarene-1.2-diol. was isolated from the marine sponges Verongia aerophoba (+-isomer) and lanthella ardis (--isomer). For the experiments presented we used the +-isomer from Verongia aerophoba. Here we describe the hitherto unknown biological and pharmacological property of this compound to display pronounced anticancer activity against L5178y mouse lymphoma cells (ED50: 0.5 μm). Friend erythroleukemia cells (ED50: 0.7μm) , human mamma carcinoma cells (ED50: 0.3μm) and human colon carcinoma cells (ED50: 3.0 μm) in vitro. Furthermore, aeroplysinin caused a preferential inhibition of [3H]thymidine (dThd) incorporation rates in L5178y mouse lymphoma cells if compared with murine spleen lymphocytes in vitro. At concentrations between 1.1 and 28.5 μm, the [3H]dThd incorporation rates in L5178y cells were suppressed to 28% -0% but only to 78% -18% in murine spleen lymphocytes. The same differential effect in vitro was found with the following epithelial cells: 14.70 μm of the compound were required to inhibit normal human fibroblasts to 50% , but only 2.9 μm in the assays with human malign keratinocytes or malignant melanoma cells to observe the same inhibitory effect. Moreover, aeroplysinin-1 displayed antileukemic activity in vivo using the L5178y cell/NMRI mouse system; administered at a dose of 50 mg/kg for five consecutive days, the T/C (% ) value was determined to be 338. Preliminary toxicology studies revealed an acute LD50 of 202 mg/kg and a subacute LD50 of 150 mg/kg. Aeroplysinin-1 is neither a direct mutagen nor a premutagen in the umu/Salmonella typhimurium test system.