Sex differences in the activity of mice: modulation by postnatal gonadal hormones

A series of six experiments was performed to examine the influence of postnatal-gonadal-hormone exposure on home-cage activity in Rockland-Swiss albino mice. Intact females were more active than their male counterparts and gonadectomy in adulthood, while reducing levels of the behavior in both sexes, did not eliminate the gender difference. Males that were castrated on the day of birth were more active than animals castrated 5, 10, or 25 days later. Also, females treated with testosterone propionate on the day of birth were less active than oil-treated controls and females exposed to the steroid 10 days after birth. Thus, perinatal exposure to gonadal hormones suppresses adult levels of home-cage activity in mice.     

Sex differences and sex hormones in anxiety-like behavior of aging rats

Sex differences in the prevalence of affective disorders might be attributable to different sex hormone milieu. The effects of short-term sex hormone deficiency on behavior, especially on anxiety have been studied in numerous animal experiments, mainly on young adult rats and mice. However, sex differences in aged animals and the effects of long-term hypogonadism are understudied. The aim of our study was to analyze sex differences in anxiety-like behavior in aged rats and to prove whether they can be attributed to endogenous sex hormone production in males. A battery of tests was performed to assess anxiety-like behavior in aged female, male and gonadectomized male rats castrated before puberty. In addition, the aged gonadectomized male rats were treated with a single injection of estradiol or testosterone or supplemented with estradiol for two-weeks. Female rats displayed a less anxious behavior than male rats in most of the conducted behavioral tests except the light-dark box. Long-term androgen deficiency decreased the sex difference in anxiety either partially (open field, PhenoTyper cage) or completely (elevated plus maze). Neither single injection of sex hormones, nor two-week supplementation of estradiol in gonadectomized aged male rats significantly affected their anxiety-like behavior in the elevated plus maze. In conclusion, our results confirm sex differences in anxiety in aged rats likely mediated by endogenous testosterone production in males. Whether long-term supplementation with exogenous sex hormones could affect anxiety-like behavior in elderly individuals remains to be elucidated.     

Sex differences in juvenile mouse social behavior are influenced by sex chromosomes and social context

Play behavior in juvenile primates, rats and other species is sexually dimorphic, with males showing more play than females. In mice, sex differences in juvenile play have only been examined in out-bred CD-1 mice. In this strain, contrary to other animals, male mice display less play soliciting than females. Using an established same-sex dyadic interaction test, we examined play in in-bred C57BL/6J (B6) 21-day-old mice. When paired with non-siblings, males tended to be more social than females, spending more time exploring the test cage. Females displayed significantly more anogenital sniffing and solicited play more frequently than did males. To determine if the origin of the sex difference was sex chromosome genes or gonadal sex, next we used the four core genotype mouse. We found significant interactions between gonadal sex and genotype for several behaviors. Finally, we asked if sibling pairs (as compared to non-siblings) would display qualitatively or quantitatively different behavior. In fact, XX females paired with a sibling were more social and less exploratory or investigative, whereas XY males exhibited less investigative and play soliciting behaviors in tests with siblings. Many neurobehavioral disorders, like autism spectrum disorder (ASD), are sexually dimorphic in incidence and patients interact less than normal with other children. Our results suggest that sex chromosome genes interact with gonadal hormones to shape the development of juvenile social behavior, and that social context can drastically alter sex differences. These data may have relevance for understanding the etiology of sexually dimorphic disorders such as ASD.     

Sex chromosomes and sex determination in reptiles

Reptiles occupy a crucial position with respect to vertebrate phylogeny, having roamed the earth for more than 300 million years and given rise to both birds and mammals. To date, this group has been largely ignored by contemporary genomics technologies, although the green anole lizard was recently recommended for whole genome sequencing. Future experiments using flow-sorted chromosome libraries and high-throughout genomic sequencing will help to discover important findings regarding sex chromosome evolution, early events in sex determination, and dosage compensation. This information should contribute extensively toward a general understanding of the genetic control of development in amniotes.     

Albutensin A and complement C3a decrease food intake in mice

Albutensin A (Ala-Phe-Lys-Ala-Trp-Ala-Val-Ala-Arg) derived from serum albumin dose-dependently decreased food intake after intracerebroventricular (10-50 nmol/mouse) or peripheral (0.3-1.0 micromol/mouse) administration in fasted conscious ddY mice. Albutensin A delayed gastric emptying and elevated blood glucose levels. Although albutensin A showed low affinity for bombesin receptor, it decreased food intake in bombesin receptor knockout mice, indicating that its inhibitory effect on feeding was not mediated through bombesin receptor. Then, we investigated whether the albutensin A-induced decrease in food intake was mediated by complement C3a and C5a receptors, because albutensin A had affinities for these receptors. Des-Arg-albutensin A, lacking affinity for C3a and C5a receptors, did not inhibit food intake. We found for the first time that centrally administered C3a (10-100 pmol/mouse) by itself decreased food intake in fasted mice. In contrast, C5a increased food intake after central injection. Based on these results, we conclude that the inhibitory effect of albutensin A on food intake is mediated through the C3a receptor.     

The number of x chromosomes causes sex differences in adiposity in mice

Sexual dimorphism in body weight, fat distribution, and metabolic disease has been attributed largely to differential effects of male and female gonadal hormones. Here, we report that the number of X chromosomes within cells also contributes to these sex differences. We employed a unique mouse model, known as the "four core genotypes," to distinguish between effects of gonadal sex (testes or ovaries) and sex chromosomes (XX or XY). With this model, we produced gonadal male and female mice carrying XX or XY sex chromosome complements. Mice were gonadectomized to remove the acute effects of gonadal hormones and to uncover effects of sex chromosome complement on obesity. Mice with XX sex chromosomes (relative to XY), regardless of their type of gonad, had up to 2-fold increased adiposity and greater food intake during daylight hours, when mice are normally inactive. Mice with two X chromosomes also had accelerated weight gain on a high fat diet and developed fatty liver and elevated lipid and insulin levels. Further genetic studies with mice carrying XO and XXY chromosome complements revealed that the differences between XX and XY mice are attributable to dosage of the X chromosome, rather than effects of the Y chromosome. A subset of genes that escape X chromosome inactivation exhibited higher expression levels in adipose tissue and liver of XX compared to XY mice, and may contribute to the sex differences in obesity. Overall, our study is the first to identify sex chromosome complement, a factor distinguishing all male and female cells, as a cause of sex differences in obesity and metabolism.     

Sex chromosomes and sex determination in weird mammals

Weird mammals are of two types. Highly divergent mammals, such as the marsupials and monotremes, have informed us of the evolutionary history of the Y chromosome and sex-determining gene, and the recently specialized rodents can help us predict its future. The Y chromosome has had a short but eventful history, and is already heading briskly for oblivion. It originated as a homologous partner of the X when it acquired a sex-determining gene (not necessarily SRY). Most of the genes on the Y, even those with a male-specific function, evolved from genes now on the X. At the mercy of a high rate of variability and the forces of drift and selection, the Y has lost genes at a rate of 3-6 genes/million years, sparing those that acquired critical male-specific functions. Even these genes have disappeared from one mammalian lineage or another as their functions were usurped by genes elsewhere in the genome. The mammalian testis-determining gene, SRY, is a typical Y-borne gene. It arose by truncation of a gene (SOX3) on the X that is expressed in brain development, and it may work by interacting with (inhibiting?) related genes, including SOX9. Variant sex-determining systems in rodents show that the action of SRY can change, as it evidently has in the mouse, and SRY can be inactivated, as in akodont rodents, or even completely superseded, as in mole voles.     

Gonadectomy reveals sex differences in circadian rhythms and suprachiasmatic nucleus androgen receptors in mice

In mammals, it is well established that circadian rhythms in physiology and behavior, including the rhythmic secretion of hormones, are regulated by a brain clock located in the suprachiasmatic nucleus (SCN) of the hypothalamus. While SCN regulation of gonadal hormone secretion has been amply studied, the mechanisms whereby steroid hormones affect circadian functions are less well known. This is surprising considering substantial evidence that sex hormones affect many aspects of circadian responses, and that there are significant sex differences in rhythmicity. Our previous finding that "core" and "shell" regions of the SCN differ in their expression of clock genes prompted us to examine the possibility that steroid receptors are localized to a specific compartment of the brain clock, with the discovery that the androgen receptor (AR) is concentrated in the SCN core in male mice. In the present study, we compare AR expression in female and male mice using Western blots and immunochemistry. Both of these methods indicate that ARs are more highly expressed in males than in females; gonadectomy eliminates and androgen treatment restores these sex differences. At the behavioral level, gonadectomy produces a dramatic loss of the evening activity onset bout in males, but has no such effect in females. Treatment with testosterone, or with the non-aromatizable androgen dihydrotestosterone, restores male locomotor activity and eliminates sex differences in the behavioral response. The results indicate that androgenic hormones regulate circadian responses, and suggest an SCN site of action.     

Sex difference in neural tube defects in p53-null mice is caused by differences in the complement of X not Y genes

To shed light on the biological origins of sex differences in neural tube defects (NTDs), we examined Trp53-null C57BL/6 mouse embryos and neonates at 10.5 and 18.5 days post coitus (dpc) and at birth. We confirmed that female embryos show more NTDs than males. We also examined mice in which the testis-determining gene Sry is deleted from the Y chromosome but inserted onto an autosome as a transgene, producing XX and XY gonadal females and XX and XY gonadal males. At birth, Trp53 nullizygous mice were predominantly XY rather than XX, irrespective of gonadal type, showing that the sex difference in the lethal effect of Trp53 nullizygosity by postnatal day 1 is caused by differences in sex chromosome complement. At 10.5 dpc, the incidence of NTDs in Trp53-null progeny of XY* mice, among which the number of the X chromosomes varies independently of the presence or absence of a Y chromosome, was higher in mice with two copies of the X chromosome than in mice with a single copy. The presence of a Y chromosome had no protective effect, suggesting that sex differences in NTDs are caused by sex differences in the number of X chromosomes.     

Sex chromosome complement influences operant responding for a palatable food in mice

The procurement and consumption of palatable, calorie‐dense foods is influenced by the nutritional and hedonic value of foods. Although many factors can influence the control over behavior by foods rich in sugar and fat, emerging evidence indicates that biological sex may play a particularly crucial role in the types of foods individuals seek out, as well as the level of motivation individuals will exert to obtain those foods. However, a systematic investigation of food‐seeking and consumption that disentangles the effects of the major sex‐biasing factors, including sex chromosome complement and organizational and activational effects of sex hormones, has yet to be conducted. Using the four core genotypes mouse model system, we separated and quantified the effects of sex chromosome complement and gonadal sex on consumption of and motivation to obtain a highly palatable solution [sweetened condensed milk (SCM)]. Gonadectomized mice with an XY sex chromosome complement, compared with those with two X chromosomes, independent of gonadal sex, appeared to be more sensitive to the reward value of the SCM solution and were more motivated to expend effort to obtain it, as evidenced by their dramatically greater expended effort in an instrumental task with progressively larger response‐to‐reward ratios. Gonadal sex independently affected free consumption of the solution but not motivation to obtain it. These data indicate that gonadal and chromosomal sex effects independently influence reward‐related behaviors, contributing to sexually dimorphic patterns of behavior related to the pursuit and consumption of rewards.     

Gender-dependent differences in biological rhythms of mice

The advantage of a variable's rhythm resides in its optimal time-phasing. This implies that, for a given function, members of a species will strive to exhibit identical time-phasing namely, their inter-individual genetic differences will be masked. To examine the generality of this assumption we explored if inbred mice exhibit gender dependent differences in rhythm parameters of biochemical variables. Male and female mice, entrained by exposure to 12:12 light:dark illumination were sacrificed, every 3 hours over a 27 hours period. Activities of creatine-phosphokinase (CK) and alkaline- phosphatase (AP), white blood cell (WBC) counts and urea nitrogen (UN) concentration were determined at each time point. For each significant rhythm four parameters were computed: period, acrophase, mesor and amplitude. In addition two derived parameters were also calculated: relative-amplitude (RA) and the rate of change in RA (CRA) which provide information about the slope and width of the peak. Patterns of most variables exhibited a compound rhythm containing two significant periodicities. Gender dependent differences were documented in the parameters of most rhythms indicating that the genetic and physiological differences limit to a certain extent the phasing ability of the entraining signals and point to an independent control of each of the rhythm parameters.     

Transthyretin is up-regulated by sex hormones in mice liver

The chaperone function of alpha-crystallin is significantly affected in diabetes. Increased formation of advanced glycation end products (AGEs) is the likely cause. This study was aimed to investigate the effect of AGE crosslinks on the chaperone activity of alpha-crystallin and to show the effect of an AGEs crosslink breaker, phenacyl-4,5-dimethylthiazolium bromide (DMPTB). Recombinant alphaA-crystallin was prepared by expressing it in Escherichia coli and purified by size exclusion chromatography. Glycation of alphaA-crystallin was performed with 1-100 mM glucose-6-phosphate (G6P) as the glycating agent for a period of 1-15 days. To break AGE crosslinks, pre-glycated alphaA-crystallin was treated with 0.1-20 mM DMPTB for 3 days. Excess G6P and DMPTB were removed by gel filtration before performing additional experiments. AGEs and crosslinked proteins were estimated by measuring non-tryptophan fluorescence and by SDS-PAGE. Chaperone activity was determined with alcohol dehydrogenase as the target protein. With increasing duration of glycation and G6P concentration, chaperone activity of alpha-crystallin decreased. When pre-glycated alphaA-crystallin was treated with 5-20 mM DMPTB, a DMPTB concentration-dependent recovery of chaperone activity was seen. Lower concentrations, 0.1, 0.5, and 1.0 mM, of DMPTB also showed significant recovery of the chaperone activity. SDS-PAGE analysis after DMPTB treatment showed 40% decrease in crosslinked proteins and fluorescence scan indicated 30% decrease in AGEs. DMPTB is expected to regain alpha-crystallin chaperone activity and provide structural stability to other eye lens proteins that are in aggregation mode which emphasizes the clinical importance of the present finding.     

Spermatogenesis is modified by food intake in mice

Spermatogenesis is generally viewed as being resistant to reduced food intake in inbred strains of adult mammals. This consensus stems from studies that have failed to place testicular responses within the context of a species' reproductive characteristics. We exposed two species of wild rodents, house mice and deer mice, to a mild but sustained food restriction (30% reduction of ad libitum consumption for 5 weeks). Reproductive adjustments made by each species to inanition were strikingly different. Food restriction failed to modify spermatogenesis in house mice, but evoked a continuum of testicular responses in deer mice ranging from normal spermatogenesis to azoospermia. These findings have several novel implications: 1) modest food restriction evokes species-specific adjustments in testicular function, and 2) intraspecific variation in spermatogenesis suggests robust individual differences in sensitivity to alterations in food intake. Taken together, our findings underscore the importance of considering the effects of food intake on male reproduction within the framework of a species' physiological and evolutionary background.     

Gastrointestinal hormones and regulation of food intake.

Obesity has been described as the greatest current threat to human health. In order to design drugs to target obesity, it is essential to understand its physiology and pathophysiology. Several peptides synthesised in the gastrointestinal tract which affect food intake have been identified including ghrelin, cholecystokinin (CCK), glucagon-like peptide-1 (7-36) amide (GLP-1), oxyntomodulin, peptide YY (PYY) and pancreatic polypeptide (PP). These peptides represent potential targets for the design of anti-obesity drugs. In this article we review recent advances in our understanding of food intake by these gastrointestinal hormones.     

Dynamics of food intake and blood level of hormones regulating appetite in pregnant and lactating mice

Leptin, insulin, corticosterone regulate food intake. Hyperphagia and hormonal rearrangement are typical for pregnancy and lactation. The aim of the study is to correlate food intake with blood levels of these hormones in pregnant and lactating mice. Food intake, body weight, blood glucose, insulin, leptin and corticosterone levels were measured in virgin C57B1/6J micc and on the day 7, 13,17 of pregnancy, and day 1, 7, 14, 30 postpartum. Insulin sensitivity was measured at the day 7, 17 of pregnancy. Food intake and body weight increased towards the second postpartum week and then decreased. Insulin sensitivity decreased towards the end of the pregnancy. Mothers differed from virgin females in hormones and glucose levels only during pregnancy. Leptin level was decreased at the day 7 of gestation, insulin level - during whole gestation. Glucose fell, and leptin and corticosterone increased from the day 7 to 17. Probably, these hormones affect food intake only in pregnant females and do not influence appetite during lactation.