Sex differences in cortical thickness and the dendritic tree in the monocular and binocular subfields of the rat visual cortex at weaning age

Changes in sex differences in neuroanatomical structure and cognitive behavior across the life span

Sex differences occur in the structure and function of the rat cerebral cortex and hippocampus, which can change from the juvenile period through old age. Although the evidence is incomplete, it appears that in at least some portions of the cortex these differences develop due to the rise of ovarian hormones at puberty and are potentially not dependent on the perinatal rise in testosterone, which is essential for sexual differentiation of the hypothalamus and sexual behavior. During aging of female rats, the presence of continued ovarian hormone secretion after cessation of the estrous cycle also influences sex differences in neuroanatomical structure and cognitive behavior, resulting in nullification or reversal of sex differences seen in younger adults. Sex differences can be altered by experience in a stimulating environment during the juvenile/adolescent period, and sex differences in performance even can be affected by the parameters of a task. Thus, broad generalizations about differences such as "spatial ability" are to be avoided. It is clear that to understand how the brain produces behavior, sex and hormones have to be taken into account.

Gender differences in the rat corpus callosum: An ultrastructure study

Sexual dimorphism exists at all levels of the nervous system, from genetic, anatomical and system levels. The sexual dimorphism in the axonal content of the corpus callosum (CC) has always been controversial; hence, the aim of this study was to analyse the differences in total, myelinated and unmyelinated axons density of various regions of the CC between male and female rats. To assess that, six pairs of adult male and female rats were perfused and the CC was removed and sectioned. Four sections from different subregions of the corpus callosum that represent the genu, anterior body, posterior body, and splenium, were stained, and electron microscopic images were captured using stereological guidelines. Later, the axons density for each subregion was calculated and compared between males and females. The findings of the present study indicated region-specific differences in the myelinated, unmyelinated or the ratio of myelinated/total axons in the CC between male and female rats.

Progestin receptor is transiently expressed perinatally in neurons of the rat isocortex

Steroid hormones influence the development of numerous brain regions, including some that are not classically considered steroid-sensitive. For example, nuclear receptors for both androgen and estrogen have been detected in neonatal cortical cells. High levels of progestin binding and progestin receptor (PR) mRNA have also been reported in early perinatal isocortex. PR expression coincides with high levels of de novo progesterone produced within the cortex, suggesting that PR and its ligand influence the important developmental cortical processes occurring shortly after birth. In order to better understand the role PR plays in cortical development, we used the cellular-level resolution of immunohistochemistry and in situ hybridization (ISH) to characterize changes in perinatal PR expression within specific cortical lamina. PR immunoreactivity (PR-ir) was examined at embryonic days (E) 18, 20, 21, 22, and postnatal days (P) 1, 3, 6, 9, 13, and 27. We find that PR-ir is transiently expressed in specific lamina of frontal, parietal, temporal, and occipital cortex. PR-ir was observed in subplate cells on E18, in increasingly superficial lamina (primarily lamina V, then II/III) during early postnatal development, and was absent by P27. Double-labeling immunohistochemistry indicated that PR-ir colocalizes with the neuronal marker, microtubule associated protein-2, but not with the glial marker, nestin, nor with gamma-aminobutyric acid. These results suggest that specific subpopulations of cortical neurons may be transiently sensitive to progesterone, and that progesterone and its receptor may play a critical role in the fundamental mechanisms underlying normal cortical development.

Gender-specific left-right asymmetries in human visual cortex

The structural correlates of gender differences in visuospatial processing are essentially unknown. Our quantitative analysis of the cytoarchitecture of the human primary visual cortex [V1/Brodmann area 17 (BA17)], neighboring area V2 (BA18), and the cytoarchitectonic correlate of the motion-sensitive complex (V5/MT+/hOc5) shows that the visual areas are sexually dimorphic and that the type of dimorphism differs among the areas. Gender differences exist in the interhemispheric asymmetry of hOc5 volumes and in the right-hemispheric volumetric ratio of hOc5 to BA17, an area that projects to V5/MT+/hOc5. Asymmetry was also observed in the surface area of hOc5 but not in its cortical thickness. The differences give males potentially more space in which to process additional information, a finding consistent with superior male processing in particular visuospatial tasks, such as mental rotation. Gender differences in hOc5 exist with similar volume fractions of cell bodies, implying that, overall, the visual neural circuitry is similar in males and females.

Sex-specific alterations of cerebral cortical cell size in rats exposed prenatally to dioxin

Sex-specific patterns of cerebral cortical lateralization have been documented consistently in both the human and animal brain. Male rats tend to exhibit pronounced right hemisphere dominance compared with females, while females typically exhibit more diffuse lateralization patterns and greater left hemisphere bias compared with males. Prenatal TCDD (2,3,7,8 tetrachlorodibenzo-p-dioxin) exposure produces demasculinization of male offspring sexual behavior, suggesting interference with sexual differentiation of the brain. In previous studies, a reversal of cortical thickness patterns in rats was shown after prenatal TCDD exposure on gestational day 8 (GD 8). The current study, based on the same brain sections, attempted to define changes in the number of cortical cells and cell size distributions in brains of offspring from TCDD-treated dams. Pregnant females were given a single oral dose of 0 or 180 ng kg(-1) TCDD on GD 8. Cell counts and sizes were determined in 3-month-old offspring. Areas 17 and 18a at bregma -3.8 were analysed using digitized, enhanced images of brain sections produced by a photomicroscope fitted with a high-resolution digital camera. Prenatal TCDD exposure altered the relative proportions of smaller and larger cell sizes in male, but not in female offspring. Both exposed males and females, however, exhibited a significant reversal of hemispheric dominance based on cell number. These findings demonstrate that prenatal exposure to TCDD alters the normal patterns of cortical cell asymmetry in a manner consistent with our previous data on thickness patterns.

Organizational and activational effects of gonadal steroid hormones on the EEG of male and female rats

To analyze organizational and activational effects of sex steroids on adult rat electroencephalographic activity (recorded at postnatal day 100), seven groups were included: males (48)-intact, neonatally or adult castrated; females (64)-intact, ovariectomized and exposed pre- or neonatally to testosterone propionate. In males, neonatal orchidectomy increased beta relative power, whereas both neonatal and adult castration reduced interparietal correlation. In females, prenatal testosterone administration produced higher theta absolute power; theta relative power was higher in all experimental groups, whereas beta1 and beta2 were decreased by prenatal and increased by neonatal virilization; prenatal virilization enhanced, while neonatal virilization and adult ovariectomy decreased interparietal correlation. These data indicate that females are more sensitive to early prenatal than to neonatal organizational effects of sex steroids, and some electroencephalographic features are feminized in castrated males and virilized in perinatally androgenized females.

Gonadectomy in adult life increases tyrosine hydroxylase immunoreactivity in the prefrontal cortex and decreases open field activity in male rats

The prefrontal cortices in rats participate in a range of cognitive, emotional, and locomotor functions that are dependent on its rich catecholamine innervation. Sex differences identified in many of these functions suggest that the prefrontal cortex is also influenced by gonadal hormones. Previous studies have shown that prefrontal catecholamines can be modified by changes in the hormone environment in developing animals. The present analyses, carried out in male rats gonadectomized as adults, with and without supplementation with testosterone proprionate, and examined at intervals from two days to 10 weeks after surgery, revealed that both the anatomical organization of prefrontal catecholamine afferents, and a behavioral measure sensitive to their selective lesioning remain highly responsive to changes in testicular hormones in adulthood. Thus, gonadectomy in adult male rats rapidly led to a large but transient decrease in the density of tyrosine hydroxylase immunoreactivity in all layers of the dorsal anterior cingulate cortex. This was followed by a sustained period in which immunoreactivity in the supragranular layers returned to levels that were just below normal (between 72 and 79% of normal), and labeling in deep laminae stabilized at considerably elevated innervation densities (approximately 150% of normal). Neither the acute decrease nor the chronic over-innervation characteristic of gonadectomized animals was observed in rats that were gonadectomized and supplemented with testosterone proprionate. Open field activity assessed along a corresponding 10 week timeline showed that gonadectomized animals were significantly less active than hormonally intact controls, a behavioral pattern opposite to the hyperactivity which persists following prefrontal dopamine lesions. Gonadectomized animals supplemented with testosterone proprionate, on the other hand, had open field scores that were not significantly different from controls. Taken together, these findings indicate that the adult hormone environment provides a significant, and seemingly functionally significant influence over the catecholamine innervation of the rat prefrontal cortex. Such lifelong responsiveness of the prefrontal cortical catecholamines to circulating hormones suggests that gonadal steroids are an active component of the biology of normal adult cognition, and may also have relevance for cortical dysfunction in disorders such as schizophrenia which are not only strongly tied to the catecholamines, but exhibit considerable biases among men and women as well.

Sex differences in the development of axon number in the splenium of the rat corpus callosum from postnatal day 15 through 60

Axon number in the splenium was examined at 15, 25 and 60 days of age in male and female rats. The splenium (posterior fifth) of the corpus callosum was found to contain the axons from the visual cortex at all three ages and was extensively sampled with electron microscopy. Overall, there was a 15% decrease in the total number of axons between postnatal day 15 and day 60 in both sexes. The observed decrease in axon number between day 15 and 25 in both males and females is consistent with Elberger's (A.J. Elberger, Transitory corpus callosum axons projecting throughout developing rat visual cortex revealed by DiI, Cereb. Cortex 4 (1994) 279-299) data which suggest that the pattern of visual callosal projections in the rat visual cortex is not restricted to the adult form until the fourth postnatal week. There was a further decrease in axon number between day 25 and day 60 in females only such that by 60 days of age, the total number of axons was equivalent between the sexes. Thus in the rat splenium, males appear to attain the adult number of axons earlier than females. These results also indicate that there is a sex difference in the timing of axon withdrawal in the rat splenium, with axon withdrawal continuing in females after it has ceased in males.

A re-examination of sex differences in axon density and number in the splenium of the rat corpus callosum

Previous work from our laboratory reported a sex difference in axon number in the splenium of the adult rat corpus callosum. However, the cortical origin of the axons that were sampled is unknown and sex differences may exist in the topography of axons in this area. The present study revisits the issue of sex differences in axon number in the splenium. First, the topographical organization of axons in the splenium was investigated. Rats each received single intracortical injections of horseradish peroxidase (HRP). The location of HRP labelled fibers in the corpus callosum was compared across the various injection sites. There is a rostrocaudal organization of axons in the splenium based on rostral to caudal cortical location that does not vary by sex. Second, visual axons, which comprise the posterior fifth (relative to overall length) of the corpus callosum in both sexes, were thoroughly sampled with electron microscopy. Significant dorsoventral and rostrocaudal variation in myelinated and unmyelinated axon density was found. While axon density varied to some extent depending on the sex of the animal, axon number calculations revealed no sex differences in total axon number. Males, however, had significantly more myelinated axons than females. Thus, sex differences in axon density in the adult rat splenium were regional and did not result in overall sex differences in axon number.

Roles of steroid hormones and their receptors in structural organization in the nervous system

Due to their chemical properties, steroid hormones cross the blood-brain barrier where they have profound effects on neuronal development and reorganization both in invertebrates and vertebrates, including humans mediated through their receptors. Steroids play a crucial role in the organizational actions of cellular differentiation representing sexual dimorphism and apoptosis, and in the activational effects of phenotypic changes in association with structural plasticity. Their sites of action are primarily the genes themselves but some are coupled with membrane-bound receptor/ion channels. The effects of steroid hormones on gene transcription are not direct, and other cellular components interfere with their receptors through cross-talk and convergence of the signaling pathways in neurons. These genomic and non-genomic actions account for the divergent effects of steroid hormones on brain function as well as on their structure. This review looks again at and updates the tremendous advances made in recent decades on the study of the role of steroid (gonadal and adrenal) hormones and their receptors on developmental processes and plastic changes in the nervous system.

Sex differences in the distribution of axon types within the genu of the rat corpus callosum

Neuroanatomical sex differences have been documented in the rat neocortex, including dimorphism of its predominant commissure, the corpus callosum (CC). In particular, CC sex differences have been reported in the ultrastructure of the posterior callosal region, the splenium. Since the CC is a heterogeneous fiber tract with its axons arising from distinct cortical areas and passing through restricted regions along its length, it became of interest to ascertain whether cellular sexual dimorphisms may also be present in another division of the CC. To test this hypothesis, electron microscopy was used to examine axon composition in adult male and female rats in the anterior portion, the genu. The number and size of axons, the thickness of the myelin sheath, and the area within the genu occupied by these constituents, were quantified. Results showed a significant sex difference in the ratio of unmyelinated to myelinated axons, with females having a larger proportion of unmyelinated fibers. This effect was present for both (1) the number of axons, and (2) the area taken up by axonal fibers. No differences were found in the size of either axon type, or for myelin thickness. Comparison of these results with those from the splenium and possible mechanisms underlying this dimorphism are discussed.

Sex differences in the number of synaptic junctions in the binocular area of the rat visual cortex

We had found that the binocular area of the visual cortex is larger in volume and has more neurons in male than in female rats. The present study examined whether the number of synaptic junctions in this area is sexually dimorphic. Ten littermate pairs of 90-day-old (socially housed) Long-Evans hooded rats were used. Synaptic junctions were counted and their lengths were measured on electron micrographs taken from layers II-III of the binocular visual cortex. There were no sex differences in the numerical density of synaptic junctions, the number of synaptic junctions per neuron, or the length of synaptic junctions within any synaptic category or of all synapses combined. Sex differences were found in the total number of synaptic junctions and in several categories (asymmetric synapses, spine synapses, asymmetric spine synapses): male rats had more synaptic junctions than female rats because of the larger volume of layers II-III in the binocular area of male rats. These data indicate that neurons in the binocular visual cortex of both male and female rats receive a characteristic number of synaptic junctions, but the greater number of neurons in the binocular area of male rats results in more synaptic junctions in the area.