Mast cell number and maturation in the central nervous system: influence of tissue type, location and exposure to steroid hormones

Sex differences in the effects of early life stress exposure on mast cells in the developing rat brain

Early life stress leads to long lasting effects on behavior. Neuroimmune cells have been implicated as key mediators of experience-induced changes in brain and behavioral development, in that they are highly responsive to stress. Mast cells are one such type of neuroimmune cell, but little is known about their role in brain development or following early life stress. Here, we assessed the impact of three different early life stress exposure paradigms on mast cell dynamics in the developing brain of male and female rats, focusing on the hippocampus and hypothalamus, where most mast cells reside. We found that exposure to two weeks of chronic variable stress during gestation led to increased mast cell number and activation in the female offspring hypothalamus on the day of birth. Acute exposure to maternal separation stress on postnatal day (PN) 2 led to significant decreases in mast cells within the hypothalamus and hippocampus of females, but not males. In contrast, one week of exposure to brief daily maternal separation stress (e.g., handling), increased mast cell numbers in the female, but not male, hippocampus. We found significant sex differences in mast cell number and activation, including males having more mast cells than females in the hippocampus on the day of birth and males having significantly more degranulated mast cells on PN11. Thus, mast cells may be an unappreciated mediator of sex-specific brain development in response to early life perturbations.

The immune system as a novel regulator of sex differences in brain and behavioral development

Sexual differentiation of the brain occurs early in life as a result of sex-typical hormone action and sex chromosome effects. Immunocompetent cells are being recognized as underappreciated regulators of sex differences in brain and behavioral development, including microglia, astrocytes, and possibly other less well studied cell types, including T cells and mast cells. Immunocompetent cells in the brain are responsive to steroid hormones, but their role in sex-specific brain development is an emerging field of interest. This Review presents a summary of what is currently known about sex differences in the number, morphology, and signaling profile of immune cells in the developing brain and their role in the early-life programming of sex differences in brain and behavior. We review what is currently known about sex differences in the response to early-life perturbations, including stress, inflammation, diet, and environmental pollutants. We also discuss how and why understanding sex differences in the developing neuroimmune environment may provide insight into understanding the etiology of several neurodevelopmental disorders. This Review also highlights what remains to be discovered in this emerging field of developmental neuroimmunology and underscores the importance of filling in these knowledge gaps. © 2016 Wiley Periodicals, Inc.

Mast cells in the amphibian brain during development

This is the first descriptive study of ontogenesis and anatomical distribution of mast cells in the developing brain of three different amphibian species. In the toad and the green frog, mast cells are preferentially located in: (i) the meningeal lining (pia mater), (ii) the choroid plexuses, both anterior and posterior, and (iii) the neuropil, in close association with the epithelial cell lining of blood vessels. It is only in the perennially aquatic African clawed frog that mast cells never appear inside brain ventricles and within the neuropil. Mast cells first become identifiable in brain of different species in different stages of development. While there are differences in the number of mast cells in different species at different stages of development, the number nearly doubles in all three species during the transition from pro-metamorphic stage of larval development to the peak of metamorphic climax. Furthermore, the number of mast cells is comparatively higher in the toad and remarkably lower in the fully aquatic Xenopus laevis, in which species the first appearance of identifiable mast cells during larval development occurs much later than in equivalent stages of development of the toad and the green frog. The secretory nature of mast cells can be assumed by the presence of cytoplasmic granules, which may show species-specific texture. Further experimental analyses are required to unveil the usefulness of mast cells in the amphibian brain.

The effects of viscero-somatic interactions on thalamic mast cell recruitment in cystitic rats

Mast cells accessing the brain parenchyma through the blood-brain barrier in healthy animals are limited to pre-cortical sensory relays - the olfactory bulb and the thalamus. We have demonstrated that unilateral repetitive stimulation of the abdominal wall generates asymmetry in midline thalamic mast cell (TMC) distribution in cyclophosphamide-injected rats, consisting of contralateral side-prevalence with respect to the abdominal wall stimulation. TMC asymmetry 1) was generated in strict relation with cystitis, and was absent in disease-free and mesna-treated animals, 2) was restricted to the anterior portion of the paraventricular pars anterior and reuniens nuclei subregion, i.e., the rostralmost part of the paraventricular thalamic nucleus, the only thalamic area associated with viscero-vagal and somatic inputs, via the nucleus of the solitary tract, and via the medial contingent of the spinothalamic tract, respectively, and 3) originated from somatic tissues, i.e., the abdominal wall where bladder inflammation generates secondary somatic hyperesthesia leading to referred pain in humans. Present data suggest that TMCs may be involved in thalamic sensory processes, including some aspects of visceral pain and abnormal visceral/somatic interactions.

Mast cells accumulate in the anogenital region of somatosensory thalamic nuclei during estrus in female mice

Mast cells are located in the mammalian thalamus where their numbers are sensitive to reproductive hormones. To evaluate whether differences between sexes and over the estrus cycle influence the nuclear distribution of mast cells in mice, we mounted a comprehensive analysis of their distribution in males compared to females and in females over the estrus cycle. Compared to males, mast cells were more numerous in the lateral intralaminar and posterior nuclei of females during estrus and in the ventral posterolateral (VPL) and medial geniculate nuclei during proestrus. During estrus, mast cells were especially concentrated in those regions within the VPL and posterior thalamic nuclei that receive somatosensory information from the anogenital region. Treatment of ovariectomized mice with estrogen increased the number and the percent of mast cells that were degranulated compared to that after ovariectomy alone, an effect that was most apparent in the lateral intralaminar, VPL and posterior nuclei. In estrogen-primed, ovariectomized females, progesterone delivered 5 h before tissue collection counteracted the effects of estrogen. Cromolyn, a mast cell stabilizer, injected centrally 1 h prior to and 24 h after estrogen in ovariectomized mice, prevented the increase in number of mast cells in the whole thalamus and in the intralaminar, VPL and posterior nuclei. This suggests that estrogen induces hyperplasia by a mechanism that involves mast cell degranulation. Based on the discrete anatomical location of mast cells in areas of somatosensory nuclei that receive anogenital input together with the temporal correspondence of these cells with estrus, mast cells are well situated to influence sensory input in females during mating.

The majority of brain mast cells in B10.PL mice is present in the hippocampal formation

In the healthy mammalian CNS, mast cells (MCs) are thought to be located mostly in the thalamus. In this study, we have systematically assessed the presence of MCs in the hippocampal formation (HF) and in the thalamus of normal male and female B10.PL mice. Giemsa(+) and Toluidine Blue(+) MCs were detected by histomorphometric analyses at perivascular and intraparenchymal sites of both the hippocampus and the entorhinal cortex. We found a mean number of 4.4 MCs in the HF of female and 3.3 MCs in male B10.PL mice. In contrast to the HF, no MCs were present in the thalamus of these mice. Notably, all HF-MCs showed immunoreactivity for Kit, the receptor for the MC growth and maturation factor SCF, as assessed by FITC-avidin/Kit double labelling. We demonstrate that the majority of brain MCs is found in the hippocampus and entorhinal cortex of B10.PL mice, though the total number of MCs is small compared to other mouse strains or rats. The presence of most brain MCs in the HF of B10.PL mice suggests a potential role of MCs in hippocampal physiology and pathology.

Unilateral spinal nerve ligation leads to an asymmetrical distribution of mast cells in the thalamus of female but not male mice

Mast cells are restricted to the leptomeninges and thalamus of healthy mice. These populations are increased by stress and highly sensitive to reproductive hormones. To examine the influence of nociception, a form of stress, on thalamic mast cells, we ligated the left fifth lumbar spinal nerve of male and female mice to induce hyperalgesia. Two, 7 and 14 days later, mice were killed and thalami examined histologically using toluidine blue stain. The total number of thalamic mast cells was not influenced by ligation of the spinal nerve compared to sham-operation in either female or male mice. However, in females, the percent of thalamic mast cells located on the side of the thalamus contralateral to the ligation was greater on days 2 and 7, coincident with mechanical hyperalgesia. At these times, areas in which mast cells were most dense contralateral to nerve-injury included the posterior (Po) and lateral geniculate (LG) nuclei compared to their symmetrical distribution in sham-operated mice. These data suggest that local nociceptive signals to each side of the thalamus rather than stress hormones influence the location of mast cells during the development of allodynia and hyperalgesia. In addition, both hyperalgesia and mast cell distribution induced by nerve-ligation differ in females compared to males, reflecting a novel neuroimmune response to pain within the CNS.

Increase of rat medial habenular mast cell numbers by systemic administration of cyclophosphamide

Cyclophosphamide administration generates systemic toxicity having immune and nervous consequences. After focusing on nervous consequences by studying neuronal activity, we now consider cyclophosphamide impact on diencephalic mast cells as part of the brain immune system. Diencephalon, the ultimate sensory relay before neocortical processing, is the only brain structure containing mast cells. Single cyclophosphamide administration (100 mg/(kg 1 ml ip)) was performed in naturally behaving rats and diencephalic mast cell numbers were analyzed once all drug effects had developed (4 h postinjection). Significant increases were observed only in the medial habenular nucleus--bilaterally and especially in its caudal portion. Mast cell increase is temporally related to behavioral impairment and evoked neuronal activity in a restricted number of visceral/limbic extrathalamic structures. The medial habenular nucleus belongs to the limbic system involved in processing emotional reactions and regulation of the autonomic nervous system. Its involvement during toxic challenge is highly compatible with its presumed function in the maintenance of vital functions.

Mechanisms underlying mast cell influence on EAE disease course

It is well established that CD4(+) T cells are of central importance in mediating the autoimmune destruction associated with the neurological demyelinating disease Multiple sclerosis (MS) and the rodent model of MS, EAE (experimental allergic encephalomyelitis). However, other cells also play a critical role in the inflammatory events that lead to the varying degrees of myelin and axonal damage observed in this disease syndrome. In this review, we present evidence that mast cells, best studied in the context of allergic disease, contribute to EAE disease pathology. Using mast cell-deficient mice, we demonstrate that mast cells are necessary for the full manifestation of MOG-induced EAE disease and show that cross-linking of Fc receptors is one mechanism of mast cell activation in disease. In addition, we provide evidence that mast cells exert influences outside the CNS, perhaps through the effects on the generation of the anti-MOG T cell response.

Anaphylactoid reactions activate hypothalamo-pituitary-adrenocortical axis: comparison with endotoxic reactions

Infectious and allergic diseases represent distinct aspects of immune response that can be experimentally modeled as endotoxic reactions following bacterial lipopolysaccharide (LPS) administration and anaphylactoid reactions following systemic injection of foreign proteins, respectively. Although it is well established that LPS stimulates the activity of the hypothalamo-pituitary-adrenocortical (HPA) axis, such effects of anaphylactoid reactions are completely unknown. To evaluate the impact of anaphylactoid reactions on HPA regulation, secretion of adrenocorticotropin hormone (ACTH) was followed and the pattern of c-Fos induction in the hypothalamic paraventricular nucleus (PVN) was revealed in rats that were challenged with egg white or compound 48/80. Male rats were intravenously injected with 0.1 ml/100g b.wt. 1:1 diluted egg white or 50 microg/100 g b.wt. compound 48/80, blood samples were taken before and various time intervals between 15-240 min after challenge for plasma ACTH measurement. Anaphylactoid reactions resulted in a rapid, significant activation of ACTH secretion and induced c-Fos immunoreactivity in the corticotropin-releasing hormone (CRH)-secreting subset of the parvocellular neurosecretory neurons. In addition, magnocellular neurosecretory neurons and autonomic-related projection neurons in the PVN became also c-Fos positive upon challenge. Changes in these parameters are compared to those seen in rats challenged with bacterial endotoxin, LPS.

Distribution and local differentiation of mast cells in the parenchyma of the forebrain

Mast cells are found in the brain of many species. Although a considerable body of information is available concerning the development and differentiation of peripheral mast cells, little is known about brain mast cells. In the present study, the ontogeny of mast cells in the dove brain was followed by using three markers: acidic toluidine blue, alcian blue/safranin, and an antiserum to gonadotropin-releasing hormone (GnRH). Mast cells first appear in the pia on embryonic day (E)13-14 in ovo, then along blood vessels extending from the pia into the telencephalon on posthatch day 4-5, and in the medial habenula at week 3. Medial habenular mast cell numbers increase during development, peaking in peripubertal birds, and declining thereafter. Several measures indicate that mast cells mature within the medial habenula: there is an increase in the intensity of metachromasia, a switch from alcian blue granules in young animals to mixed alcian blue and safranin granules in older animals, and an increase in GnRH-like immunoreactivity. These results were extended by using electron microscopy. The architecture of mast cell granules evolved from electron lucent with small electron dense deposits at E15 to more electron dense granules with complex patterns of internal structure by 2 months. Ultrastructural immunocytochemistry for the GnRH-like peptide at 1 month revealed both immunopositive and negative cells, suggesting that the acquisition of this phenotype is not simultaneous across the population. Thus, immature mast cells infiltrate the central nervous system and undergo in situ differentiation within the neuropil.

Neonatal handling in EAE-susceptible rats alters NGF levels and mast cell distribution in the brain

Maternal separation in neonatal rodents causes a wide range of behavioural and metabolic alterations, affecting the physiological response of the neuro-immune-endocrine system. For example, interference with the normal mother-infant interactions leads to an increased susceptibility to experimentally-induced allergic encephalomyelitis (EAE) in adult life. Since it has been reported that mast cells (MCs) participate in the pathophysiology of the autoimmune inflammatory disease multiple sclerosis (MS) and also EAE and that brain nerve growth factor (NGF) levels are altered in EAE, studied whether maternal separation and gentle manipulation (gentling) of neonatal Lewis rats perturb NGF levels or MC distribution in the brain. EAE-induction susceptibility in adult life was also evaluated and NGF levels and mast cell distribution within the hippocampus and thalamus were measured at 0, 10, 20 and 60 postnatal days. Our results show an exacerbation of clinical signs in rats separated from mothers where EAE was induced, a general decrease in NGF protein levels and MC number in the hippocampus during the first developmental period and significant increase in the number of MC in the hippocampus and the thalamus at young-adulthood (60 days of age). These results indicate that disruption of the maternal bond during early infancy may produce long-lasting alterations in the brain cellular and molecular environment, leading to increased susceptibility to EAE in adult life.