Development of a brain-permeable peptide nanofiber that prevents aggregation of Alzheimer pathogenic proteins.

Alzheimer's disease (AD) is proposed to be induced by abnormal aggregation of amyloidß in the brain. Here, we designed a brain-permeable peptide nanofiber drug from a fragment of heat shock protein to suppress aggregation of the pathogenic proteins. To facilitate delivery of the nanofiber into the brain, a protein transduction domain from Drosophila Antennapedia was incorporated into the peptide sequence. The resulting nanofiber efficiently suppressed the cytotoxicity of amyloid ßby trapping amyloid ß onto its hydrophobic nanofiber surface. Moreover, the intravenously or intranasally injected nanofiber was delivered into the mouse brain, and improved the cognitive function of an Alzheimer transgenic mouse model. These results demonstrate the potential therapeutic utility of nanofibers for the treatment of AD.

PE859, A Novel Curcumin Derivative, Inhibits Amyloid-ß and Tau Aggregation, and Ameliorates Cognitive Dysfunction in Senescence-Accelerated Mouse Prone 8.

Aggregation of amyloid-ß (Aß) and tau plays a crucial role in the onset and progression of Alzheimer's disease (AD). Therefore, the inhibition of Aß and tau aggregation may represent a potential therapeutic target for AD. Herein, we designed and synthesized both Aß and tau dual aggregation inhibitors based on the structure of curcumin and developed the novel curcumin derivative PE859. In this study, we investigated the inhibitory activity of PE859 on Aß aggregationin vitro and the therapeutic effects of PE859 on cognitive dysfunction via dual inhibition of Aß and tau aggregation in vivo. PE859 inhibited Aß aggregation in vitro and protected cultured cells from Aß-induced cytotoxicity. Furthermore, PE859 ameliorated cognitive dysfunction and reduced the amount of aggregated Aß and tau in brains of senescence-accelerated mouse prone 8 (SAMP8). These results warrant consideration of PE859 as a candidate drug for AD.

Miller-Dieker Syndrome with unbalanced translocation 45, X, psu dic(17;Y)(p13;p11.32) detected by fluorescence in situ hybridization and G-banding analysis using high resolution banding technique.

Lissencephaly is one of the central nervous system anomalies of Miller-Dieker Syndrome (MDS). Fetuses with lissencephaly have an abnormal smooth brain with fewer folds and grooves that will be detected by ultrasounds or fetal magnetic resonance imaging (MRI) after 30 weeks of gestation. We report a fetus with lissencephaly diagnosed as Miller-Dieker Syndrome postnatally. G banded chromosome analysis revealed 45,X,psu dic(17;Y)(p13;p11.32).ish dic (17;Y)(LIS1-,RARA+, SRY+, DYZ3+) by G-banding analysis using high resolution banding technique. Fetal delayed cortical development will be the findings to perform further investigations including fluorescence in situ hybridization analysis for MDS, a 17p13.3 microdeletion syndrome, pre/postnatally. This will be the first case of MDS with unbalanced translocation between deleted short arm of chromosome 17 and Y chromosome.

Ritodrine-induced rhabdomyolysis, infantile myotonic dystrophy, and maternal myotonic dystrophy unveiled.

A primiparous pregnant woman in remission of myositis suffered very acute-onset ritodrine-induced rhabdomyolysis. At 29 gestational weeks, ritodrine was administered for threatened preterm labor. Just 3 h later, she complained of severe limb muscle pain, with serum creatinine phosphokinase elevated to 32 019 U/L and myoglobinuria. The muscle pain disappeared immediately after ceasing administration of ritodrine. At 31 weeks, premature rupture of the membranes occurred, necessitating cesarean section, yielding a baby with weak tonus, and the presence of infantile muscle diseases was suspected. Genetic analysis of the infant confirmed myotonic dystrophy (dystrophia myotonica, DM), which prompted us to perform maternal genetic analysis, confirming maternal DM. Ritodrine can induce rhabdomyolysis even in the prodromal phase with a mild phenotype of DM. A literature review suggested that ritodrine-induced rhabdomyolysis may be likely to occur more acutely after ritodrine administration in DM compared with non-DM mothers.

Oct-3/4 promotes migration and invasion of glioblastoma cells.

As a result of increased glioblastoma migration and invasion into normal brain parenchyma, treatment of local tumor recurrence following initial treatment in glioblastoma patients remains challenging. Recent studies have demonstrated increased Oct-3/4 expression, a self-renewal regulator in stem cells, in glioblastomas. However, little is known regarding the influence of Oct-3/4 in glioblastoma cell invasiveness. The present study established Oct-3/4-overexpressing glioblastoma cells, which were prepared from human glioblastoma patients, to assess migration, invasion, and mRNA expression profiles of integrins and matrix metalloproteinases (MMPs). Compared with control cells, Oct-3/4 expressing-glioblastoma cells exhibited increased migration and invasion in wound healing and Matrigel invasion assays. Oct-3/4 overexpression resulted in upregulated FAK and c-Src expression, which mediate integrin signals. Vinculin accumulated along the leading edges of Oct-3/4 expressing-glioblastoma cells and associated with membrane ruffles during cell migration. Oct-3/4 expressing-cells exhibited increased MMP-13 mRNA expression and MMP-13 knockdown by shRNA suppressed cell invasion into Matrigel and organotypic brain slices. These results suggested that Oct-3/4 enhanced degradation of surrounding extracellular matrix by increasing MMP-13 expression and altering integrin signaling. Therefore, Oct-3/4 might contribute to tumor promoting activity in glioblastomas.