Molecular understanding of aluminum-induced topological changes in (CCG)12 triplet repeats: relevance to neurological disorders.

Recent studies have shown that gene mutations are involved in the pathology of neurological disorders. CCG repeats cause genetic instability and are localized at the 5' end of the non-coding regions of the FMR1 gene in fragile X syndrome. Our studies for the first time showed that aluminum (Al) levels were elevated in the serum samples of fragile X syndrome and also provide evidence for the interaction of aluminum with (CCG)12-repeats. Circular dichroism spectroscopic studies of (CCG)12 indicated B-DNA conformation and in the presence of Al (10(-5) M) CCG repeats attained Z-DNA conformation. Further spectroscopic studies, which included melting profiles, ethidium bromide binding patterns and interaction of Z-DNA specific polyclonal antibodies confirmed the Z-conformation in (CCG)12-repeats in the presence of Al (10(-5) M). It is interesting to mention that Al-induced Z-conformation is stable even after the total removal of Al from CCG by desferoximine, a chelating drug. This is the first report to proof the role of Al in modulating the DNA (CCG repeats) topology and this information provides a clue about the possible involvement of Al at a molecular level in neurological/neurodegenerative disorders.

First evidence for helical transitions in supercoiled DNA by amyloid Beta Peptide (1-42) and aluminum: a new insight in understanding Alzheimer's disease.

Previously, we evidenced a B --> Z helical change in Alzheimer's brain genomic DNA, leading to a hypothesis that Alzheimer's disease (AD) etiological factors such as aluminum (Al), amyloid beta (Abeta) peptide, and Tau might play a role in modulating DNA topology. In the present study, we investigated the interaction of Al and Abeta with DNA. Our results show that Abeta(1-42) could induce a B --> Psi (Psi) conformational change in pUC 18 supercoiled DNA (scDNA), Abeta(1-16) caused an altered B-form, whereas Al induced a complex B-C-A mixed conformation. Ethidium bromide binding and agarose gel electrophoresis studies revealed that Al uncoiled the DNAto a fully relaxed form, whereas Abeta(1-42) and Abeta(1-16) effected a partial uncoiling and also showed differential sensitivity toward chloroquine-induced topoisomer separation. Our findings show for the first time that Abeta and Al modulate both helicity and superhelicity in scDNA. A new hypothetical model explaining the potential toxicity of Abeta and Al in terms of their DNA binding properties leading to DNA conformational alteration is proposed.