Dichlorodiphenyltrichloroethane (DDT), a persistent organochlorine pesticide, continues to be used for malaria control under the Stockholm Convention. We investigated associations between exposure to Show more
Dichlorodiphenyltrichloroethane (DDT), a persistent organochlorine pesticide, continues to be used for malaria control under the Stockholm Convention. We investigated associations between exposure to DDT and its metabolite dichlorodiphenyldichloroethylene (DDE) and midlife cognitive function and brain structure among primarily Mexican-born Latina women in an agricultural community in California, USA. In the CHAMACOS Maternal Cognition Study, a prospective cohort study, we assessed global and domain-specific cognitive performance in 472 women. A subset of 95 women underwent T1-weighted brain MRI to measure cortical thickness. We evaluated associations between serum p,p'-DDT and p,p'-DDE concentrations-measured 12 years earlier-and cognitive Z scores and cortical thickness using linear regression. Bayesian hierarchical models accounted for co-exposure to other organochlorine pesticides. Apolipoprotein E (APOE) genotype was assessed as a potential modifier. Higher p,p'-DDT and p,p'-DDE concentrations were significantly associated with lower executive function scores (p,p'-DDT β=-0·10 [95% CI -0·18 to -0·02]; p,p'-DDE β=-0·09 [-0·19 to 0·00]; SDs per ten-fold increase in serum concentration). No associations were observed with other cognitive domains. Results were robust to adjustment for APOE genotype and organochlorine co-exposures. No effect modification by APOE ε4 status was found. Both exposures were associated with greater frontal lobe cortical thickness, particularly in the medial orbitofrontal and pars orbitalis regions. p,p'-DDT and p,p'-DDE exposure was associated with reduced executive function more than a decade later, and with altered frontal brain structure. These findings suggest potential long-term neurodevelopmental effects of legacy organochlorine exposure and warrant further investigation. US National Institutes of Health and US Environmental Protection Agency. Show less
Because of high stability and slow unfolding rates of G-quadruplexes (G4), cells have evolved specialized helicases that disrupt these non-canonical DNA and RNA structures in an ATP-dependent manner. Show more
Because of high stability and slow unfolding rates of G-quadruplexes (G4), cells have evolved specialized helicases that disrupt these non-canonical DNA and RNA structures in an ATP-dependent manner. One example is DHX36, a DEAH-box helicase, which participates in gene expression and replication by recognizing and unwinding parallel G4s. Here, we studied the molecular basis for the high affinity and specificity of DHX36 for parallel-type G4s using all-atom molecular dynamics simulations. By computing binding free energies, we found that the two main G4-interacting subdomains of DHX36, DSM and OB, separately exhibit high G4 affinity but they act cooperatively to recognize two distinctive features of parallel G4s: the exposed planar face of a guanine tetrad and the unique backbone conformation of a continuous guanine tract, respectively. Our results also show that DSM-mediated interactions are the main contributor to the binding free energy and rely on making extensive van der Waals contacts between the GXXXG motifs and hydrophobic residues of DSM and a flat guanine plane. Accordingly, the sterically more accessible 5'-G-tetrad allows for more favorable van der Waals and hydrophobic interactions which leads to the preferential binding of DSM to the 5'-side. In contrast to DSM, OB binds to G4 mostly through polar interactions by flexibly adapting to the 5'-terminal guanine tract to form a number of strong hydrogen bonds with the backbone phosphate groups. We also identified a third DHX36/G4 interaction site formed by the flexible loop missing in the crystal structure. Show less