Combined effect of genetic variants in the GluN2B coding gene (GRIN2B) on prefrontal function during working memory performance.

BACKGROUND: The GluN2B subunit of N-methyl-d-aspartate receptors is crucially involved in the physiology of the prefrontal cortex during working memory (WM). Consistently, genetic variants in the GluN2B coding gene (GRIN2B) have been associated with cognitive phenotypes. However, it is unclear how GRIN2B genetic variation affects gene expression and prefrontal cognitive processing. Using a composite score, we tested the combined effect of GRIN2B variants on prefrontal activity during WM performance in healthy subjects. METHOD: We computed a composite score to combine the effects of single nucleotide polymorphisms on post-mortem prefrontal GRIN2B mRNA expression. We then computed the composite score in independent samples of healthy participants in a peripheral blood expression study (n = 46), in a WM behavioural study (n = 116) and in a WM functional magnetic resonance imaging study (n = 122). RESULTS: Five polymorphisms were associated with GRIN2B expression: rs2160517, rs219931, rs11055792, rs17833967 and rs12814951 (all corrected p < 0.05). The score computed to account for their combined effect reliably indexed gene expression. GRIN2B composite score correlated negatively with intelligence quotient, WM behavioural efficiency and dorsolateral prefrontal cortex activity. Moreover, there was a non-linear association between GRIN2B genetic score and prefrontal activity, i.e. both high and low putative genetic score levels were associated with high blood oxygen level-dependent signals in the prefrontal cortex. CONCLUSIONS: Multiple genetic variants in GRIN2B are jointly associated with gene expression, prefrontal function and behaviour during WM. These results support the role of GRIN2B genetic variants in WM prefrontal activity in human adults.

Thermodynamics of (dG--dC)3 double-helix formation in water and deuterium oxide.

The thermodynamics of double-helix formation by (dG-dC)3 in H2O and D2O were measured spectrophotometrically and calorimetrically. Spectrophotometric values based on plots of inverse melting temperature vs. log of concentration are in good agreement with calorimetry. However, spectrophotometric values based on the shape of absorbance vs. temperature curves are in good agreement with calorimetry only if linear pre- and posttransition base lines are subtracted before analysis. The averages of the enthalpies measured by the three most reliable spectroscopic methods are -56.9 and -62.7 kcal/mol of helix in H2O and D2O, respectively. The corresponding calorimetric values are -59.6 and -65.8 kcal/mol of helix.

Solvent effects on thermodynamics of double-helix formation in (dG-dC)3.

The thermodynamics of double-helix formation by (dG-dC)3 have been measured in aqueous solvent mixtures containing 10 mol % methanol, ethanol, 1-propanol, formamide, N,N-dimethylformamide, or urea and 20 mol % ethanol. Optical activity measurements indicate the conformation of the double helix at 3 degree C is the same in all the solvent mixtures except 20 mol % ethanol. All the cosolvents destabilize the helix relative to water. With 10 mol % alcohol cosolvents, this destabilization is associated with a more unfavorable entropy change averaging approximately 8% and a more favorable enthalpy change averaging approximately 5%. This is consistent with a small contribution of hydrophobic bonding to stability. In contrast, the destabilization by formamide, N,N-dimethylformamide, and urea is associated with a more unfavorable enthalpy change averaging approximately 23% and a more favorable entropy change averaging approximately 21%. Since all three of these cosolvents have dipole moments larger than water, this is consistent with increased competition for dipolar interactions between the nucleic acid bases. None of the results correlate with any one bulk solvent parameter such as surface tension, viscosity, or dielectric constant. With 20 mol % ethanol, optical activity measurements are consistent with a partial B to C form transition. This is associated with a 27% less favorable enthalpy and 25% more favorable entropy for helix formation relative to water. Since the B to C transition is associated with helix dehydration, this may imply a significant contribution of bound water to stability.