Role of Electrostatic Interactions in Calcitonin Prefibrillar Oligomer-Induced Amyloid Neurotoxicity and Protective Effect of Neuraminidase.

Salmon calcitonin is a good model for studying amyloid behavior and neurotoxicity. Its slow aggregation rate allows the purification of low molecular weight prefibrillar oligomers, which are the most toxic species. It has been proposed that these species may cause amyloid pore formation in neuronal membranes through contact with negatively charged sialic acid residues of the ganglioside GM1. In particular, it has been proposed that an electrostatic interaction may be responsible for the initial contact between prefibrillar oligomers and GM1 contained in lipid rafts. Based on this evidence, the aim of our work was to investigate whether the neurotoxic action induced by calcitonin prefibrillar oligomers could be counteracted by treatment with neuraminidase, an enzyme that removes sialic acid residues from gangliosides. Therefore, we studied cell viability in HT22 cell lines and evaluated the effects on synaptic transmission and long-term potentiation by in vitro extracellular recordings in mouse hippocampal slices. Our results showed that treatment with neuraminidase alters the surface charges of lipid rafts, preventing interaction between the calcitonin prefibrillar oligomers and GM1, and suggesting that the enzyme, depending on the concentration used, may have a partial or total protective action in terms of cell survival and modulation of synaptic transmission.

Comprehensive nuclear magnetic resonance studies on interactions of amyloid-ß with different molecular sized anesthetics.

Laboratory research on anesthetic-induced structural changes of amyloid beta (Aß) peptide, from normal monomeric α-helix to the micro-aggregated form, has generated much interest in the scientific community as Aß oligomerization is considered a key step in Alzheimer disease pathogenesis. A comprehensive review of the interactions of Aß peptide with anesthetics of different molecular sizes is summarized as follows. Smaller sized anesthetics could access and perturb the cavity containing crucial amino acid residues G29, A30 and I31 of Aß peptide leading to Aß oligomerization. However, bulkier sized anesthetics are sterically hindered from accessing the cavity containing these crucial residues and do not initiate Aß oligomerization. Notably, when a small sized anesthetic is co-administered with a larger sized one, the latter does not prevent access of the small sized anesthetic to the cavity. The results of these biophysical studies are supported by animal model studies which indicate that inhaled small molecular anesthetics induce enhanced Aß plaque deposition in transgenic mice with AD pathology. In this review, a molecular pathway for the A$\beta $-anesthetic interaction at the atomic level is presented.

Metal exposure and Alzheimer's pathogenesis.

With the growing aging population in Western countries, Alzheimer's disease (AD) has become a major public health concern. No preventive measure and effective treatment for this burdensome disease is currently available. Genetic, biochemical, and neuropathological data strongly suggest that Abeta amyloidosis, which originates from the amyloidogenic processing of a metalloprotein-amyloid precursor protein (APP), is the key event in AD pathology. However, neurochemical factors that impact upon the age-dependent cerebral Abeta amyloidogenesis are not well recognized. Growing data indicate that cerebral dysregulation of biometals, environmental metal exposure, and oxidative stress contribute to AD pathology. Herein we provided further evidence that both metals (such as Cu) and H(2)O(2) promote formation of neurotoxic Abeta oligomers. Moreover, we first demonstrated that laser capture microdissection coupled with X-ray fluorescence microscopy can be applied to determine elemental profiles (S, Fe, Cu, and Zn) in Abeta amyloid plaques. Clearly the fundamental biochemical mechanisms linking brain biometal metabolism, environmental metal exposure, and AD pathophysiology warrant further investigation. Nevertheless, the study of APP and Abeta metallobiology may identify potential targets for therapeutic intervention and/or provide diagnostic methods for AD.

Phase I trial of dolastatin-10 (NSC 376128) in patients with advanced solid tumors.

Dolastatin-10 (dola-10) is a potent antimitotic peptide, isolated from the marine mollusk Dolabela auricularia, that inhibits tubulin polymerization. Preclinical studies of dola-10 have demonstrated activity against a variety of murine and human tumors in cell cultures and mice models. The purpose of this Phase I clinical trial was to characterize the maximum tolerated dose, pharmacokinetics, and biological effects of dola-10 in patients with advanced solid tumors. Escalating doses of dola-10 were administered as an i.v. bolus every 21 days, using a modified Fibonacci dose escalation schema. Pharmacokinetic studies were performed with the first treatment cycle. Neurological testing was performed on each patient prior to treatment with dola-10, at 6 weeks and at study termination. Thirty eligible patients received a total of 94 cycles (median, 2 cycles; maximum, 14 cycles) of dola-10 at doses ranging from 65 to 455 microg/m2. Dose-limiting toxicity of granulocytopenia was seen at 455 microg/m2 for minimally pretreated patients (two or fewer prior chemotherapy regimens) and 325 microg/m2 for heavily pretreated patients (more than two prior chemotherapy regimens). Nonhematological toxicity was generally mild. Local irritation at the drug injection site was mild and not dose dependent. Nine patients developed new or increased symptoms of mild peripheral sensory neuropathy that was not dose limiting. This toxicity was more frequent in patients with preexisting peripheral neuropathies. Pharmacokinetic studies demonstrated a rapid drug distribution with a prolonged plasma elimination phase (t 1/2z = 320 min). The area under the concentration-time curve increased in proportion to administered dose, whereas the clearance remained constant over the doses studied. Correlation analysis demonstrated a strong relationship between dola-10 area under the concentration-time curve values and decrease from baseline for leukocyte counts. In conclusion, dola-10 administered every 3 weeks as a peripheral i.v. bolus is well tolerated with dose-limiting toxicity of granulocytopenia. The maximum tolerated dose (and recommended Phase II starting dose) is 400 microg/m2 for patients with minimal prior treatment (two or fewer prior chemotherapy regimens) and 325 microg/m2 for patients who are heavily pretreated (more than two prior chemotherapy regimens).

[Cerebral amyloidosis]. / Amylose cérébrale.

Cerebral amyloidoses affects only the central nervous system, with rare exceptions. Most of them are related to A beta deposits. They usually occur in the absence of genetic defect in the precursor of A beta. The prevalence and density of A beta deposits increase during the aging process, and in Alzheimer's disease. This A beta amyloidosis has never been transmitted. In contrast, PrPres occurs as a sporadic or genetic event, and induces transmissible amyloidoses (Creutzfeldt-Jakob's disease and other disorders related to non conventional agents). PrPres may be the infectious agent itself (prion hypothesis). Other proteins are rarely responsible for cerebral amyloidoses. The fascinating hypothesis that a common mechanism would be acting in all cerebral amyloidoses has not yet been confirmed.