Lithium down-regulates tau in cultured cortical neurons: a possible mechanism of neuroprotection.

In tauopathies such as Alzheimer's disease (AD), the moleccular mechanisms of tau protein agregation into neurofibrillary tangles (NFTs) and their contribution to neurodegeneration are not fully understood. Recent studies indirectly demonstrated that tau, regardless of its aggregation, might represent a key mediator of neurodegeneration, especially that induced by the amyloid (Abeta) pathology. Lithium is a medication for bipolar mood disorders. Its therapeutic mechanism of action remains unclear, in part because of the large number of biochemical effects attributed to lithium. Since lithium directly inhibits glycogen synthase kinase-3beta (GSK3beta), a key enzyme involved in tau phosphorylation, it was suggested that the therapeutic use of lithium could be expanded from mood disorders to neurodegenerative conditions. Lithium has been also reported to protect cultured neurons against Abeta toxicity, and to prevent NFTs accumulation and cognitive impairments in transgenic models of tauopathies. However, the exact mechanism of neuroprotection provided by lithium remains unknown. Here, we show that exposure of cultured cortical neurons to lithium decreased tau protein levels. This decrease was not linked to the activation of proteolytic processes including calpains, caspases and proteasome or to neuronal loss, but was rather associated with a reduction in tau mRNA levels. Moreover, prior exposure to lithium, at concentrations effective in reducing tau protein levels, markedly reduced pre-aggregated Abeta-induced neuronal apoptosis. Our findings raise the possibility that lithium could exert its neuroprotective effect against Abeta toxicity through the downregulation of tau proteins and that, at least, by acting at the level of tau mRNA.

Detection of ganciclovir resistance after valacyclovir-prophylaxis in renal transplant recipients with active cytomegalovirus infection.

Whether valaciclovir (VCV) prophylaxis could be responsible for ganciclovir (GCV)-resistance of Human cytomegalovirus (HCMV) in transplantation has never been documented. A multicentric retrospective pilot study was undertaken to detect GCV-resistance through mutations within the UL97 gene in renal transplant recipients who experienced active HCMV infection and received valacyclovir prophylaxis. Twenty-three patients who experienced HCMV antigenaemia or DNAemia during or at the end of prophylaxis were included. UL97 genotyping was carried out on peripheral blood samples, using a nested in-house PCR, which amplified the full-length UL97 gene. One patient has a resistance-related mutation (M460I); the major risk factor for emergence of resistance in this patient was the presence of early and persistent antigenaemia. GCV-resistance during VCV-prophylaxis was rare after renal transplantation. However, special attention must be paid to patients developing early active HCMV infection under prophylaxis.

A novel mutation in the alpha-helix 1 of the C subunit of the F(1)/F(0) ATPase responsible for optochin resistance of a Streptococcus pneumoniae clinical isolate.

Previously reported mutations involved in optochin resistance of Streptococcus pneumoniae clinical isolates changed residues 48, 49 or 50, in the transmembrane alpha-helix 2 of the F(1)/F(0) ATPase subunit. We report here an unusual mutation which changes the sequence of the transmembrane alpha-helix 1 of the AtpC subunit. This mutation involves a Gly to Ser substitution resulting from a G to A transition at codon 14 of the atpC gene.