A phenotype-driven ENU mutagenesis screen for the identification of dominant mutations involved in alcohol consumption

The aim of this study was the application of a phenotype-driven N-ethyl-N-nitrosourea (ENU) mutagenesis screen in mice for the identification of dominant mutations involved in the regulation and modulation of alcohol-drinking behavior. The chemical mutagen ENU was utilized in the generation of 131 male ENU-mutant C57BL/6J mice (G0). These ENU-treated mice were paired with wild-type C57BL/6J mice to generate G1 and subsequent generations. In total, 3327 mice were generated. Starting with G1, mice were screened for voluntary oral self-administration of 10% (v/v) alcohol vs. water in a two-bottle paradigm. From these mice, after a total period of 5 weeks of drinking, 43 mutants fulfilled the criteria of an “alcohol phenotype,” that is, high or low ethanol intake. They were then selected for breeding and tested in a “confirmation cross” (G2–G4) for inheritance. Although we did not establish stable high or low drinking lines, several results were obtained in the context of alcohol consumption. First, female mice drank more alcohol than their male counterparts. Second, the former demonstrated greater infertility. Third, all animals displayed relatively stable alcohol intake, although significantly different in two different laboratories. Finally, seasonal and monthly variability was observed, with the highest alcohol consumption occurring in spring and the lowest in autumn. In conclusion, it seems difficult to identify dominant mutations involved in the modulation or regulation of voluntary alcohol consumption via a phenotype-driven ENU mutagenesis screen. In accordance with the findings from knockout studies, we suggest that mainly recessive mutations contribute to an alcohol-drinking or alcohol-avoiding phenotype.     

The effect of intercalator structure on binding strength and base-pair specificity in DNA interactions

The interaction of naphthothiophene, phenanthrene and anthracene ring systems, which have amide and ester side chains with cationic groups (synthesized from the aromatic acid chlorides and appropriate amines and alcohols), with calf thymus DNA has been investigated by using viscometric titrations, spectrophotometric binding experiments and 1H-, 31P- and 17O-NMR methods. The viscosity and NMR experiments suggest that all of these compounds bind to DNA by intercalation. These experiments and spectrophotometric binding studies, however, indicate that there is considerable variation in the interaction of these compounds with DNA. These variations can all be explained by the geometry of the ring systems, the position of protons adjacent to the side chains, and the relative sizes of the amide and ester side chains. With the naphthothiophene ester and amide, for example, the planar amide cannot rotate into the plane of the naphthothiophene ring whereas the smaller planar ester can. With this ring system the ester has a significantly higher binding constant than the amide derivative. Additional binding studies with poly[d(A-T)2] and poly[d(G-C)2] have shown that all of these compounds bind more strongly to the A-T- than the G-C-containing polymer. Since the ester compounds do not have hydrogen bond donating groups proximate to the aromatic ring, these results suggest a model for the A-T specificity of these compounds that involves a solvent-mediated hydrogen bond between the C-2 carbonyl of thymine and the carbonyl group of the intercalators.     

The influence of intercalator structure on DNA binding strength: the importance of side chain orientation

A naphthothiophene intercalator with a cationic side chain linked to the ring through an ester group (1E) has been shown to bind to DNA almost an order of magnitude more strongly than a similar compound with the side chain linked to the ring through an amide group (1A) (W.D. Wilson, et al., Biophys. Chem. 24, 101-109 (1986]. X-ray crystallographic analysis of these two compounds indicates that both the ester and amide groups are essentially planar but that the amide is twisted approximately 30 degrees out of the aromatic plane of the naphthothiophene while the ester and ring system are co-planar. Proton NMR studies of the DNA complexes of these two compounds indicate that the naphthothiophene ring is intercalated in both 1A and 1E but that the protons of the ring system near the side chain interact with DNA base pairs at the binding site significantly better in 1E than in 1A. The protons next to the ester group on the side chain of 1E are also shifted upfield significantly more on addition of DNA than those of 1A. The large planar area of 1E, thus, allows greater stacking, complex geometry optimization, and dipolar interactions of the ester group with DNA base pairs at the binding site to account for the larger binding constant of this compound relative to 1A.     

Commentary on Coram et al. (2021) on the use of Facebook to understand marine mammal stranding issues in Southeast Asia

We reviewed Coram et al. (Biodivers Conserv 30:2341–2359, 2021, https://doi.org/10.1007/s10531-021-02196-6), a paper that highlights the use of social media data to understand marine litter and marine mammals in Southeast Asia. While we commend its intent, we find that the methodology used and conclusions drawn portray an incomplete and inaccurate perception of how strandings, stranding response, and analysis of stranding data have been conducted in the region. By focusing on investigative results revealed by a very limited search of one social media platform (Facebook), using only English keywords, and insufficient ground-truthing, Coram et al. (2021) have, unintentionally, given the perception that Southeast Asian scientists have not conducted even the bare minimum of investigation required to better understand the issue of marine litter and its impact on marine mammals. In this commentary we provide a more accurate account of strandings research in Asia and include recommendations to improve future studies using social media to assess conservation issues.