Aging-Related Behavioral, Adiposity, and Glucose Impairments and Their Association following Prenatal Alcohol Exposure in the C57BL/6J Mouse.

People that experience prenatal alcohol exposure (PAE) may have behavioral and metabolic impairments, and it is unclear whether these remain stable or change with age. We assessed behavioral and metabolic endpoints across the lifespan in a mouse model of fetal alcohol spectrum disorder (FASD). Pregnant C57BL/6J mice received alcohol (ALC; 3 g/kg) or maltose-dextrin (control, CON) daily from embryonic day 8.5 to 17.5. Offspring were tested on accelerating rotarod, Y-maze, novel object recognition, and fear conditioning at 6 weeks and 10 and 17 months; females were also tested at 24 months. Body composition, fasting glucose, and glucose clearance were assessed at 18 months. Female but not male ALC mice had greater adiposity than age-matched CON from 7 months onward. At 18 months, male but not female ALC mice had reduced glucose clearance and ALC mice were more likely to have elevated fasting glucose. In the rotarod training session, ALC females performed worse than CON. In the Y-maze, significant exposure-age interactions affected ALC performance in both sexes versus age-match CON. For fear conditioning, all animals acquired the task and froze more at older ages. In both the context and cued tasks, there were exposure-age interactions and ALC animals frozen less than CON at 10 months. Correlation analysis revealed that fasting glucose and glucose clearance correlated with % of body fat in ALC but not in CON mice. Additionally, glucose intolerance and % body fat negatively correlated with performance in the rotarod, context learning, and novel object recognition tasks in ALC but not CON mice. All mice exhibit worsening of behavioral performance as they age, and PAE did not further exacerbate this. ALC but not CON mice displayed adiposity and glucose intolerance that correlate with their cognitive impairments, suggesting that these may be mechanistically related in PAE. Findings emphasize that FASD should be considered a whole-body disorder.

Growth and behavioral differences in a C57BL/6J mouse model of prenatal alcohol exposure.

BACKGROUND: Prenatal alcohol exposure (PAE) can produce behavioral deficits in the presence or absence of growth and morphological deficits. Here, we describe a murine PAE model having parallels to the clinical diagnosis of alcohol-related neurodevelopmental deficit (ARND). METHODS: Pregnant C57BL/6J mice were gavaged with alcohol (ALC, 3 g/kg) or maltodextrin daily on embryonic days (E) E8.5 through E17.5. Blood alcohol levels were 211 ± 14 mg/dL at 30 min post-gavage. Offspring behavior was tested at adolescence. RESULTS: ALC dams gained less weight during the alcohol exposure period (p = 0.035). ALC male and female pups weighed more than controls at P15 (p ≤ 0.001) and P22 (p ≤ 0.001), but not at P37, perhaps because their dams were pair-housed. During the training session for accelerating rotarod, control offspring trended to stay longer on the rotarod than did ALC offspring [F(1,54) = 2.892, p = 0.095]. In the Y-maze, ALC offspring had a higher percent alternation than did controls [F(1,54) = 16.577, p < 0.001], but activity level did not appear to differ. In the fear-conditioning test, there was no ALC effect in the training trial. In the contextual test, there was a group × minute effect for males [F(4,120) = 2.94, p = 0.023], and ALC trended to freeze less than controls in minute 1 (p = 0.076) and froze less in minute 2 (p = 0.02). In the cue test, there was a trend for a group-sex interaction [F(1,53) = 3.008, p = 0.089] on overall freezing, such that ALC males (p < 0.05) again froze less than control males, whereas ALC females (p < 0.05) froze more than control females. CONCLUSIONS: This mouse model of PAE, using a repeated intermediate exposure, produces modest behavioral impairments that are consistent along the continuum of PAE models, including deficits in associative memory and hyper-responsivity. The lack of growth or morphological deficits suggests these mice may model aspects of ARND.

Prenatal exposure to the probiotic Lactococcus lactis decreases anxiety-like behavior and modulates cortical cytoarchitecture in a sex specific manner.

Development of the cerebral cortex may be influenced by the composition of the maternal gut microbiota. To test this possibility, we administered probiotic Lactococcus lactis in drinking water to mouse dams from day 10.5 of gestation until pups reached postnatal day 1 (P1). Pups were assessed in a battery of behavioral tests starting at 10 weeks old. We found that females, but not males, exposed to probiotic during prenatal development spent more time in the center of the open field and displayed decreased freezing time in cue associated learning, compared to controls. Furthermore, we found that probiotic exposure changed the density of cortical neurons and increased the density of blood vessels in the cortical plate of P1 pups. Sex-specific differences were observed in the number of mitotic neural progenitor cells, which were increased in probiotic exposed female pups. In addition, we found that probiotic treatment in the latter half of pregnancy significantly increased plasma oxytocin levels in mouse dams, but not in the offspring. These results suggest that exposure of naïve, unstressed dams to probiotic may exert sex-specific long-term effects on cortical development and anxiety related behavior in the offspring.

Reduced brain volume and impaired memory in betaine homocysteine S-methyltransferase knockout mice.

Using a mouse model, this study examined the impact of lack of betaine homocysteine S-methyltransferase (BHMT) on neurological function. Bhmt-/- mice maintained on a control diet had elevated concentrations of homocysteine, reduced total brain magnetic resonance imaging (MRI) volume, as well as impaired reference and short-term memories. The results of this study indicate that the absence of BHMT may play a role in neurological function.

Deletion of one allele of Mthfd1 (methylenetetrahydrofolate dehydrogenase 1) impairs learning in mice.

The MTHFD1 gene encodes for methylenetetrahydrofolate dehydrogenase 1, an enzyme that has an important role in folate-mediated one-carbon metabolism. In people, a single nucleotide polymorphism of this gene (1958G>A; rs2236225) is associated with increased risk for bipolar disorder and schizophrenia, neural tube and other birth defects. Mice homozygous for a loss of Mthfd1 via a gene-trap mutation are not viable, and heterozygotes, though they appear healthy, have metabolic imbalances in the folate- and choline-mediated 1-carbon metabolic pathways. In this study, we evaluated cognitive function in Mthfd1gt/+ male and female mice using a behavioral battery composed of eight different tests. We found that these mice display impaired cue-conditioned learning, while other behaviors remain intact.

The genetic and epigenetic landscape for CNS drug discovery targeting cross-diagnostic behavioral domains.

Animal studies play a central role in the identification and testing of novel drugs for CNS disorders. In his longstanding career, Berend Olivier has significantly contributed to CNS drug discovery by applying and supporting novel views and methodologies in the fields of behavioral neuroscience, pharmacology, and (epi-) genetics. Here we review and put forward some of these integrated approaches that have led to a productive collaboration and new insights into the genetic and epigenetic regulation of neurobehavioural traits related to psychiatric disorders.

Identifying predictors of activity based anorexia susceptibility in diverse genetic rodent populations.

Animal studies are very useful in detection of early disease indicators and in unravelling the pathophysiological processes underlying core psychiatric disorder phenotypes. Early indicators are critical for preventive and efficient treatment of progressive psychiatric disorders like anorexia nervosa. Comparable to physical hyperactivity observed in anorexia nervosa patients, in the activity-based anorexia rodent model, mice and rats express paradoxical high voluntary wheel running activity levels when food restricted. Eleven inbred mouse strains and outbred Wistar WU rats were exposed to the activity-based anorexia model in search of identifying susceptibility predictors. Body weight, food intake and wheel running activity levels of each individual mouse and rat were measured. Mouse strains and rats with high wheel running activity levels during food restriction exhibited accelerated body weight loss. Linear mixed models for repeated measures analysis showed that baseline wheel running activity levels preceding the scheduled food restriction phase strongly predicted activity-based anorexia susceptibility (mice: Beta  =  -0.0158 (±0.003 SE), P<0.0001; rats: Beta  =  -0.0242 (±0.004 SE), P<0.0001) compared to other baseline parameters. These results suggest that physical activity levels play an important role in activity-based anorexia susceptibility in different rodent species with genetically diverse background. These findings support previous retrospective studies on physical activity levels in anorexia nervosa patients and indicate that pre-morbid physical activity levels could reflect an early indicator for disease severity.

Epigenetics and eating disorders.

PURPOSE OF REVIEW: Eating disorders are complex psychiatric disorders in which genes, environment, and gene-environment interactions (G×E) have a role. Such G×E may occur in adulthood or during development. They may also be modified by factors such as (mal)nutrition or stress and this may result in acute or long-term epigenetic modifications. This review discusses the potential for recent developments in epigenetics to address ongoing aetiological issues in eating disorders. RECENT FINDINGS: Epigenetic studies in eating disorders have focussed on the DNA methylation status of promoter regions of candidate genes: differences have been reported between people with eating disorders and healthy controls, and between subtypes of eating disorders. Animal studies related to eating disorders have focussed on understanding the acute and long-term effects of environmental manipulation on epigenetic changes and on the resultant phenotypes: these studies are promising, but they have also identified some of the complexity of epigenetic processing. SUMMARY: Because of the difficulties in obtaining brain samples, epigenetic studies in eating disorders (like in other psychiatric illnesses) have used peripheral tissues, usually blood: this raises various problems. It is likely, therefore, that in the immediate future, animal, rather than human studies will guide the progress in epigenetics studies of eating disorders and other psychiatric disorders.

Heritability of regional and global brain structure at the onset of puberty: a magnetic resonance imaging study in 9-year-old twin pairs.

Puberty represents the phase of sexual maturity, signaling the change from childhood into adulthood. During childhood and adolescence, prominent changes take place in the brain. Recently, variation in frontal, temporal, and parietal areas was found to be under varying genetic control between 5 and 19 years of age. However, at the onset of puberty, the extent to which variation in brain structures is influenced by genetic factors (heritability) is not known. Moreover, whether a direct link between human pubertal development and brain structure exists has not been studied. Here, we studied the heritability of brain structures at 9 years of age in 107 monozygotic and dizygotic twin pairs (N = 210 individuals) using volumetric MRI and voxel-based morphometry. Children showing the first signs of secondary sexual characteristics (N = 47 individuals) were compared with children without these signs, based on Tanner-stages. High heritabilities of intracranial, total brain, cerebellum, and gray and white matter volumes (up to 91%) were found. Regionally, the posterior fronto-occipital, corpus callosum, and superior longitudinal fascicles (up to 93%), and the amygdala, superior frontal and middle temporal cortices (up to 83%) were significantly heritable. The onset of secondary sexual characteristics of puberty was associated with decreased frontal and parietal gray matter densities. Thus, in 9-year-old children, global brain volumes, white matter density in fronto-occipital and superior longitudinal fascicles, and gray matter density of (pre-)frontal and temporal areas are highly heritable. Pubertal development may be directly involved in the decreases in gray matter areas that accompany the transition of our brains from childhood into adulthood.