Lithium suppression of tau induces brain iron accumulation and neurodegeneration

Lithium is a first-line therapy for bipolar affective disorder. However, various adverse effects, including a Parkinson-like hand tremor, often limit its use. The understanding of the neurobiological basis of these side effects is still very limited. Nigral iron elevation is also a feature of Parkinsonian degeneration that may be related to soluble tau reduction. We found that magnetic resonance imaging T₂ relaxation time changes in subjects commenced on lithium therapy were consistent with iron elevation. In mice, lithium treatment lowers brain tau levels and increases nigral and cortical iron elevation that is closely associated with neurodegeneration, cognitive loss and parkinsonian features. In neuronal cultures lithium attenuates iron efflux by lowering tau protein that traffics amyloid precursor protein to facilitate iron efflux. Thus, tau- and amyloid protein precursor-knockout mice were protected against lithium-induced iron elevation and neurotoxicity. These findings challenge the appropriateness of lithium as a potential treatment for disorders where brain iron is elevated (for example, Alzheimer's disease), and may explain lithium-associated motor symptoms in susceptible patients.

Aβ Produced as a Fusion to Maltose Binding Protein Can Be Readily Purified and Stably Associates with Copper and Zinc

The 42 amino acid Alzheimer's Abeta peptide has been produced in E. coli as a soluble fusion to maltose binding protein (MBP). Affinity purification on amylose columns of MBP-Abeta and MBP led to the recovery of proteins at purities that were suited for physicochemical analyses. MBP-Abeta was able to bind approximately 2 mole equivalents of copper or 4 mole equivalents of zinc, while MBP alone bound negligible amounts of zinc or copper. We conclude that Abeta can bind 2 copper or 4 zinc ions in its fusion format. Because MBP-Abeta is a convenient protein to work with, this system is well suited for further studies on the structure of Abeta and its interactions with metals.

Corticotrophs and peptides

Corticotrophs were long thought to be a static, homogeneous population of cells that respond positively to hypothalamic stimulation, are inhibited by glucocorticoid feedback and secrete a single biologically active peptide, ACTH(1-39). Our current understanding is that this is an oversimplification and corticotrophs are a dynamic and more complex group of cells. The biosynthetic precursors of ACTH and other cleavage products of proopiomelanocortin (POMC) have been found to be secreted by anterior pituitary cells, to circulate and to have biological activity. POMC and the biosynthetic intermediate, pro-ACTH, exert activity antagonistic to ACTH(1-39) on glucocorticoid secretion by adrenal cells, and other derivatives of POMC are mitogenic to adrenocortical cells. In terms of responses to hypothalamic and peripheral factors, corticotrophs are functionally heterogeneous. This is reflected in the sensitivity of individual subtypes of corticotrophs to CRH, vasopressin and glucocorticoids. There is a functional plasticity amongst the various types of corticotrophs. During gestation, in fetal sheep, changes occur in the overall ACTH-secretory responses to CRH relative to vasopressin, the proportions of total corticotrophs that respond to the respective peptides and the average secretory response of individual cells. Corticotrophs also respond to locally produced pituitary factors. Local actions of leukaemia inhibitory factor are demonstrated by the effects of immunoneutralization of the peptide in pituitary cells. Urocortin and preproTRH(178-199) are locally produced peptides with potent stimulatory and inhibitory actions on corticotrophs, respectively. The specific roles of these peptides are under investigation.