L A Loeb

The Hippo pathway was initially discovered in Drosophila melanogaster as a key regulator of tissue growth. It is an evolutionarily conserved signaling cascade regulating numerous biological processes, including cell growth and fate decision, organ size ...Read More

The fragile X mental retardation syndrome is associated with the expansion of trinucleotide 5'-d(CGG)-3' repeats within the FMR1 gene and with hypermethylation of the cytosine residues of these repeats. The expansion and hypermethylation may account for the suppression of the transcription of the FMR1 gene and for the delay of its replication during the cell cycle. Here we show that d(CGG)n oligomers can form a stable Hoogsteen-bonded structure that exhibits properties consistent with those of tetraplex DNA. Oligomers, d(mCGG)n, (n = 4, 5, or 7), at pH 8.0 and in the presence of an alkali metal ion form stable species exhibiting a reduced electrophoretic mobility in nondenaturing polyacrylamide gels. These species are denatured by heating at 90 degrees C for 10 min. With a short d(mCGG)5 oligomer, the slowly migrating species is formed only when the cytosine residue is 5-methylated, whereas with the longer d(CGG)7 it is generated whether or not cytosine is 5-methylated. By contrast, complementary cytosine-rich oligomers do not form analogous complexes. The second-order association kinetics of the formation of the slowly migrating species of d(mCGG)5 suggests that it is an interstrand complex. Formation of intermediate-size complexes between d(mCGG)5 and d(mCGG)7 indicates that the stoichiometry of the slowly migrating structures is tetramolecular. Protection of the complex from methylation by dimethyl sulfate indicates the involvement of the N-7 positions of the guanine residues in Hoogsteen hydrogen bonding, a characteristic of quadruplex structures. If formed in vivo along the expanded and hypermethylated d(mCGG)n stretch, this tetraplex structure could suppress transcription and replication of the FMR1 gene in the fragile X syndrome cells.

The ability of metal ions to damage DNA and cause mutagenesis has been analyzed with reversion and forward mutation assays using single-stranded DNA templates. We previously reported that incubation of phi X174 am3 DNA with Fe2+ in vitro results in mutagenesis when the treated DNA is transfected into Escherichia coli spheroplasts (Loeb, L. A., James, E. A., Waltersdorph, A. M., and Klebanoff, S. J. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 3918-3922, 1988). We now extend these studies to other metal ions. Of the metal ions tested, copper ions were the most mutagenic; the frequency of mutants produced was equal to or greater than that produced by Fe2+. Mutagenesis by Cu+ was diminished by catalase, mannitol, and superoxide dismutase suggesting the involvement of H2O2, hydroxyl ions, and superoxide, respectively. However, the findings that Cu+ and Cu2+ are nearly equally mutagenic and that the mutagenic activities are not completely inhibited by oxygen free radical scavengers make it unlikely that the mechanism for mutagenesis is simply the production of hydroxyl free radicals. The spectra of mutations produced by either copper ion using the lacZ gene as a target are very similar and differ from those reported with other agents. The predominant mutagenic sequence changes are single-base substitutions, the most frequent being replacement of a template C by a T. This transition presumably results from mispairing of an altered C with deoxyadenosine. Copper-induced mutations are not randomly distributed. Instead, they are found predominantly in clusters suggesting direct interaction of copper ions with specific nucleotide sequences in DNA. Evidence is considered that the high frequency of C----T transitions may be a common manifestation of DNA damage by oxygen radicals.

An understanding of the contribution of reactive oxygen species to mutagenesis has been hampered by the vast number of different chemical modifications they cause in DNA. Even though many of these DNA alterations have been catalogued, the identification of specific lesions that cause mutations has depended on testing one modification at a time. In this study we present another approach to identify key mutagenic lesions from a pool of oxidatively modified nucleotides. dCTP was treated with an oxygen radical-generating system containing FeSO4, H2O2, and ascorbic acid. The modification products were separated by reverse-phase and anion-exchange HPLC and then incorporated by human immunodeficiency virus reverse transcriptase into a DNA that contains a target gene for scoring for mutations. One of the mutagenic species isolated was identified as 5-hydroxy-2'-deoxycytidine. It is incorporated efficiently into DNA and causes C-->T transitions in Escherichia coli at a frequency of 2.5%, which is more mutagenic than any previously identified oxidative DNA lesion.