Embryonic ablation of neuronal VGF increases energy expenditure and reduces body weight

Germline ablation of VGF, a secreted neuronal, neuroendocrine, and endocrine peptide precursor, results in lean, hypermetabolic, and infertile adult mice that are resistant to diet-, lesion-, and genetically-induced obesity and diabetes (Hahm et al., 1999, 2002). To assess whether this phenotype is predominantly driven by reduced VGF expression in developing and/or adult neurons, or in peripheral endocrine and neuroendocrine tissues, we generated and analyzed conditional VGF knockout mice, obtained by mating loxP-flanked (floxed) Vgf mice with either pan-neuronal Synapsin-Cre- or forebrain alpha-CaMKII-Cre-recombinase-expressing transgenic mice. Adult male and female mice, with conditional ablation of the Vgf gene in embryonic neurons had significantly reduced body weight, increased energy expenditure, and were resistant to diet-induced obesity. Conditional forebrain postnatal ablation of VGF in male mice, primarily in adult excitatory neurons, had no measurable effect on body weight nor on energy expenditure, but led to a modest increase in adiposity, partially overlapping the effect of AAV-Cre-mediated targeted ablation of VGF in the adult ventromedial hypothalamus and arcuate nucleus of floxed Vgf mice (Foglesong et al., 2016), and also consistent with results of icv delivery of the VGF-derived peptide TLQP-21 to adult mice, which resulted in increased energy expenditure and reduced adiposity (Bartolomucci et al., 2006). Because the lean, hypermetabolic phenotype of germline VGF knockout mice is to a great extent recapitulated in Syn-Cre^+/−,Vgf ^{flpflox/flpflox} mice, we conclude that the metabolic profile of germline VGF knockout mice is largely the result of VGF ablation in embryonic CNS neurons, rather than peripheral endocrine and/or neuroendocrine cells, and that in forebrain structures such as hypothalamus, VGF and/or VGF-derived peptides play uniquely different roles in the developing and adult nervous system.     

Adrenorphin immunoreactivity in rat brain

Adrenorphin is the first C-terminally amidated form of opioid peptides isolated from human pheochromocytoma tumor and is considered to be generated out of proenkephalin A by unique processing. By the highly specific and sensitive radioimmunoassay (RIA) procedure utilizing the antiserum against adrenorphin, combined with high performance liquid chromatography (HPLC), immunoreactive adrenorphin in rat brain was verified to be identical with its authentic peptide. It has been revealed that adrenorphin immunoreactivity distributes widely in rat brain but in the unique pattern distinct from those of other endogenous opioid peptides. Note that immunoreactive adrenorphin was most concentrated in the olfactory bulb, and appreciably in the hypothalamus and striatum. Furthermore, immunohistochemical study has revealed that adrenorphin-immunoreactive structures in hypothalamic region of rat were localized in the neurones of the arcuate nucleus. In addition, adrenorphin-immunoreactive fibre plexus was found in the various regions of the hypothalamus, such as median eminence, periventricular zone and paraventricular nucleus. These indicate that adrenorphin may have a unique physiological function.     

Radioimmunoassayable N-Tyr-MIF-1-like activity in rat brain is increased by pinealectomy

Levels of N-Tyr-MIF-1-like immunoreactivity were measured in rat brain by radioimmunoassay (RIA). Although the highest levels were found in the pineal and hypothalamus, the striatum and thalamus also contained significantly more immunoreactivity than the other parts of the brain. Since oxytocin cross-reacts 5.4% with the antibody for N-Tyr-MIF-1, oxytocin-like immunoreactivity was also measured by RIA, but could not account for the levels of radioimmunoassayable N-Tyr-MIF-1 found in these experiments. There was a significant increase in N-Tyr-MIF-1-like immunoreactivity after pinealectomy, a tendency for a decrease after stress, but essentially no change after hypophysectomy. A diurnal rhythm was observed with the highest levels at night and lowest levels during the day. The results demonstrate the presence in brain tissue of a novel immunoreactive peptide, the levels of which can be altered by neuroendocrine manipulations.     

Novel peptide pancreastatin: its occurrence and codistribution with chromogranin A in the central nervous system of the pig

The distribution of pancreastatin immunoreactivity was investigated in porcine brain, spinal cord, dorsal root ganglia, and pituitary. In the brain, immunoreactive cell bodies were present in many areas including the cortex, basal ganglia, hippocampus, thalamus, hypothalamus, mesencephalic reticular formation, cerebellum, and medulla oblongata. Immunoreactive fibres were most abundant in the globus pallidus, stria terminalis, entopeduncular nucleus, hippocampus, and in the substantia nigra. In the spinal cord, immunoreactive cells were found in laminae IV-IX. Immunoreactive fibres were concentrated in the dorsal horn. Pancreastatin immunoreactivity was localised to fibres and small cells (5-10% of the total) in the dorsal root ganglia. In the posterior pituitary, many immunoreactive fibres were present and in the anterior lobe subsets of gonadotrophs and thyrotrophs were pancreastatin-immunoreactive. The localisation of pancreastatin showed a parallel distribution with chromogranin A. Coexistence of pancreastatin with calcitonin gene-related peptide (CGRP) immunoreactivity in cell bodies in the spinal cord, including motoneurones, and with CGRP or galanin immunoreactivities in dorsal root ganglion cells was also noted. The differential pattern of pancreastatin immunostaining was reflected in the extractable levels of peptide with highest concentrations in the cortex (55.8 +/- 6.0 pmol/g wet weight, mean +/- S.E.M.), thalamus (60.0 +/- 5.0 pmol/g), hypothalamus (54.4 +/- 6.5 pmol/g), and anterior pituitary (2,714 +/- 380 pmol/g). Characterisation of pancreastatin immunoreactivity in the hypothalamus and pituitary by gel permeation and high-pressure liquid chromatography revealed multiple molecular forms, one of which was indistinguishable from natural porcine pancreastatin. The widespread distribution of pancreastatin immunoreactivity suggests this peptide may play a part in several neuroendocrine, autonomic, somatic, and sensory functions, and its colocalisation with chromogranin A is consistent with a precursor-product relationship.     

A pilot study of rat brain regional distribution of calcitonin,katacalcin and calcitonin gene-related peptide before and after antipsychotic treatment

In contrast to extensive determinations of calcitonin gene-related peptide (CGRP) in neural tissues, calcitonin and its carboxyl-terminal flanking peptide katacalcin (in human PDN-21) have not been systematically measured by radioimmunoassay (RIA) in discrete brain structures. Using microwave irradiation (MW), a procedure that increases the recovery of neuropeptides, we investigated by radioimmunoassay (RIA) the rat brain regional distribution of CGRP like- immunoreactivity (-LI), calcitonin-LI, and katacalcin-LI. Calcitonin-LI and katacalcin-LI were found in low concentrations in frontal cortex, occipital cortex, striatum and hippocampus. Moreover, a 4-week treatment with antipsychotic drugs altered the concentrations of the calcitonin-gene family peptides in the frontal cortex, occipital cortex, and hippocampus; the magnitude of these changes, however, was only moderate. Lastly, calcitonin-LI and katacalcin-LI baseline concentrations as well as after antipsychotic treatment were highly correlated in the frontal cortex, striatum, and hippocampus. The possible regulatory role of calcitonin gene family peptides in the central nervous system (CNS) needs to be further explored.     

Immunocytochemical distribution of corticotropin (ACTH) in monkey brain

The distribution of adrenocorticotropin (ACTH) in monkey brain was examined by immunoperoxidase immunohistochemistry. An antiserum to ACTH that recognized the C-terminal portion of the molecule was used. Immunoreactive ACTH was visualized as an intraneuronal constituent with a widespread distribution throughout the brain. Reactive cell bodies were seen only in the region of the arcuate nucleus of the hypothalamus. Dense axonal networks were seen in the hypothalamus, mesencephalic gray, and in the region around the anterior commissure. No staining was seen in the cerebral cortex, cerebellum, hippocampus, or striatum. ACTH or fragments of ACTH may function as neurotransmitters or neuromodulators in primate brain.     

Peptidomics of Cpe fat/fat mouse hypothalamus and striatum

Chronic morphine administration is known to affect several neuropeptide systems, and this could contribute to the behavioral effects of opiates. To quantitate global changes in neuropeptide levels upon chronic morphine administration, we took advantage of a method that allows selective isolation of neuropeptides from brains of mice lacking carboxypeptidase E (Cpefat/fat mice), a critical enzyme in the generation of many neuroendocrine peptides. We used a differential labeling procedure with stable isotopic tags and mass spectrometry to quantitate the relative changes in a number of hypothalamic and striatal peptides in Cpefat/fat mice chronically treated with morphine. A total of 27 distinct peptides were detected in hypothalamus and striatum. Of these, 27 were identified by mass spectrometry-based sequencing, 1 was tentatively identified by the mass and charge, and 9 were not identified. The identified peptides included fragments of proenkephalin, prothyrotropin-releasing hormone, secretogranin II, chromogranin Aand B, protachykinin B, provasopressin, promelanin concentrating hormone, and pro-SAAS. Upon morphine administration, although the levels of most of the peptides were unaltered (within a factor of 1.3 to 0.7 compared with saline control), the levels of a small number of peptides did show consistent changes (increased or decreased by 1.3-fold or more) in hypothalamus and/or striatum. Taken together, these results provide interesting insights into endogenous neuropeptide systems that are modulated by morphine and suggest further experiments to link candidate peptides with long-term effects of morphine.     

Hypothalamic expression of a novel gene product, VGF: immunocytochemical analysis

VGF is the designation for a new 712 amino acid protein, regulated by nerve growth factor (NGF) in PC12 cells, that has not been previously described in the CNS. Northern blot analysis with a nick-translated VGF cDNA probe revealed a single band of mRNA in the brain with a molecular weight identical to that found in PC12 cells. The current paper presents a series of immunocytochemical studies of VGF expression with a focus on the hypothalamus. Two different antisera were raised against nonoverlapping amino acid sequences of a bacterial-expressed protein from the VGF gene cloned from PC12 cells. VGF immunoreactivity is strongly expressed in the rat suprachiasmatic nucleus (SCN), particularly in the dorsomedial part of the nucleus. The administration of colchicine to block axonal transport facilitates detection of the VGF immunoreactivity also in the ventrolateral suprachiasmatic nucleus. This protein appears to be the first one of limited neuronal distribution which is found in both dorsomedial SCN and ventrolateral SCN. Immunostaining of serial 1 micron SCN sections reveals co-localization of VGF in cells which also contain vasopressin or vasoactive intestinal polypeptide. Weaker immunoreactivity is also found in the magnocellular paraventricular and supraoptic nuclei, where the VGF immunoreactivity co-localizes with oxytocin or vasopressin. Mutant Brattleboro rats which do not express vasopressin showed strong VGF immunoreactivity both in the dorsomedial SCN and in cells of the magnocellular neuronal systems, including cells which normally express vasopressin. When axonal transport of the protein is blocked by colchicine, VGF-immunoreactive cells in the hypothalamic arcuate, parvocellular paraventricular, and tuberomammillary nuclei can also be detected, in addition to weakly immunoreactive scattered cells in the hippocampus, amygdala, thalamus, and cortex. VGF immunoreactivity is strong in the axonal projections of SCN and weak in the axons of the paraventricular and supraoptic nuclei. With ultrastructural studies, VGF immunoreactivity is found in presynaptic boutons in the SCN and in axons in the neurohypophysis. Weak axonal staining is present in some regions of the hypothalamus and in the external and internal zones of the median eminence. Immunoreactivity is absent from the intermediate lobe of the hypophysis. In neonatal rats strong VGF immunoreactivity is found throughout the SCN at postnatal day 4 but not in the adjacent hypothalamus. VGF immunoreactivity is also seen in other areas of the brain in neonatal rats, including the lateral geniculate nucleus; while the staining in the dorsal lateral geniculate disappears in the adult, that in the intergeniculate leaflet, a visual center which projects to the SCN, remains.(ABSTRACT TRUNCATED AT 400 WORDS)     

A single meal elicits regional changes in bombesin-like peptide levels in the gut and brain.

Several studies have demonstrated that exogenous bombesin (BN) elicits a potent satiety effect when administered centrally or systemically. It has been suggested that BN-like peptides may play a physiological role in the control of food intake. The objective of the present study was to determine whether the levels of endogenous BN-like peptides change in response to a meal. All rats were food deprived overnight for a 12 h period. Half the animals were then allowed to feed for 35 min (postprandial group) and the remainder formed the preprandial group. Regions of the brain (hypothalamus, cerebellum, medulla, pons, neocortex, hippocampus, olfactory bulbs, striatum, midbrain and pituitary), gut (oesophagus, fundus, antrum, duodenum, jejunum, ileum, colon) and adrenal glands were analyzed for BN-like peptide levels using radioimmunoassay. Our results indicate significant increases in the levels of BN-like peptides in the hypothalamus and hippocampus, as well as in the antrum of the stomach, after food ingestion. These results are the first to demonstrate the activation of endogenous BN-like peptide mechanisms in response to ingestion. These rapid alterations in peptide levels may support the contention that BN-like peptides play a physiological role in the regulation of ingestive behavior.     

Preproenkephalin mRNA and enkephalin in normal and denervated adrenals in the Syrian hamster: comparison with central nervous system tissues.

The distribution and characteristics of preproenkephalin (PPenk) mRNA and enkephalin-containing (EC) peptides are compared in CNS and adrenal tissues from Syrian hamsters and Sprague-Dawley rats. Total cellular RNA extracts from both rat and hamster tissues produce a single hybridization band of PPenk mRNA of approximately 1500 bases when analyzed by Northern blot hybridization. Quantitation by solution hybridization reveals that in the hamster the highest levels of PPenk mRNA are found in adrenal (16.3 +/- 1.4 pg equivalents/micrograms RNA (mean +/- S.E.M.)) and striatum (13.3 +/- 0.7), followed by hypothalamus (0.8 +/- 0.2), and hippocampus (0.4 +/- 0.2). In the rat the highest levels of PPenk mRNA are in the striatum (35 +/- 2 pg/micrograms RNA) followed by the hypothalamus (3.0 +/- 0.5), hippocampus (0.3 +/- 0.1) and adrenal (0.18 +/- 0.04). Thus, the rank order of abundance of PPenk mRNA is similar in these CNS tissues for rat and hamster. The hamster adrenal levels are more than 90-fold greater than those of the rat. The abundance of EC peptides in both hamster and rat tissues mirror the rank order found with PPenk mRNA. Hamster adrenal contains the highest level of EC peptides (441 +/- 37 pmol/mg protein (mean +/- S.E.M.)) which is more than 400-fold greater than that of the rat adrenal and 8- to 12-fold greater than that found in rat and hamster striatum or hypothalamus. Both size exclusion chromatography and Western blot analysis indicate that EC peptides in hamster adrenal are predominantly large proenkephalin-like peptides with approximately 6 copies of Met- and 1 copy of Leu-enkephalin and that included in their number is a prominent EC peptide with a molecular weight of 34 kDa. Unilateral denervation of the hamster adrenal results in a time-dependent ipsilateral decrease in EC peptide and PPenk mRNA levels. Thus, by day 8 postsurgery, PPenk mRNA levels have declined by an average of 80% while EC peptides are reduced by 68% when compared to the innervated contralateral adrenal. These results demonstrate the great abundance of PPenk mRNA and EC peptides in the hamster adrenal. They also demonstrate the apparent need for transsynaptic impulse activity to maintain the high steady-state levels of PPenk and EC peptides. These characteristics of the hamster adrenal system provide opportunities for physiological and pharmacological investigations of the regulation of proenkephalin gene expression.     

Effects of Anterolateral and Posterolateral Cuts Around the Medial Hypothalamus on the Immunoreactive ACTH and β-Endorphin Levels in Selected Brain Regions of the Rat

To evaluate the relative weight of the ACTH-ergic and β-endorphin-ergic pathway(s) leaving the medial hypothalamus (MH) in anterior or posterior directions immunoreactive ACTH and β-endorphin (ir-ACTH and ir-βE) were quantified in selected brain regions of the rat 7–8 days after placing anterolateral (ALC) or posterolateral (PLC) cut around the MH. Retrograde accumulation of both peptides was observed in the MH after ALC, but not after PLC. ALC resulted in dramatic decrease in ir-ACTH/ir-βE concentrations in all extra-MH brain regions tested (extra-MH hypothalamus, septum, thalamus, hippocampus, amygdala, and medulla oblongata). In contrast, ir-ACTH and ir-βE levels decreased only in the thalamus and in the medulla oblongata after PLC. The present data indicate (a) ACTH- and βE-like substances synthesized in the arcuate region of the hypothalamus are axonally transported to extrahypothalamic brain regions by neuronal pathways leaving the MH primarily anterolateral, anterodorsal, or anteromedial direction (even the fibers of certain posteromedial or posterolateral projections leave the MH some anterior directions); (b) the posterior ACTH-/βE-ergic projections seem to be of minor importance except for the thalamus and the medulla oblongata where it contributes to about one-third of the peptide content. Our biochemical study provide quantitative complementary data to the detailed immunohistochemical picture of the ACTH/βE-ergic projections in the rat brain described by Khachaturian et al. [5].     

Distribution of morphine in brain regions, spinal cord and serum following intravenous injection to morphine tolerant rats

In order to determine the possible contribution of altered distribution of morphine in the morphine tolerance process, the distribution of morphine was studied in brain regions and spinal cord, following its intravenous administration. Male Sprague-Dawley rats were made tolerant to morphine by implanting 6 morphine pellets, each containing 75 mg of morphine base, for 7 days. Seventy-two hours after the removal of the pellets, a time when serum morphine levels were negligible or absent and yet tolerance to the pharmacological effects of morphine was present, morphine (10 mg/kg, i.v.) was injected in placebo and morphine pellet implanted rats. At various times (5, 30, 60, 120 and 360 min) after the injection of morphine, brain regions (hypothalamus, cortex, hippocampus, midbrain, pons and medulla, striatum and amygdala), spinal cord and serum were collected. The level of morphine in the tissues was determined by using a highly sensitive and specific radioimmunoassay (RIA) method. Five minutes after morphine injection, the concentration of morphine was the highest in the hypothalamus and the lowest in amygdala. The concentration of morphine in hypothalamus, pons and medulla, hippocampus and midbrain of morphine tolerant rats was smaller than in placebo pellet implanted rats. The tissue to serum ratio of morphine in the hypothalamus, hippocampus, striatum, midbrain and cortex were also smaller in morphine tolerant than in non-tolerant rats. The concentration of morphine in brain regions with time did not exhibit linearity. At other time intervals like 30 and 60 min, the concentration of morphine in several brain regions and spinal cord was significantly higher in morphine tolerant than in non-tolerant rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Diurnal variations of IR-Met-enkephalin in the brain of pentylenetetrazol-kindled rats

Pentylenetetrazol (PTZ) kindling was induced in male Wistar rats by daily i.p. injections of 40 mg/kg of the convulsant agent. Immunoreactive (IR)-Met-enkephalin was quantified in the amygdala, hippocampus and hypothalamus 17 days after the last stimulus, in groups of 6–7 rats, every 4 h, beginning at 08.00 h. IR-Met-enkephalin level displayed diurnal variations in brain regions of control animals. In the amygdala and the hippocampus the peptide peaked at 24.00 h and in the hypothalamus at 20.00 h; the troughs were at 08.00, 16.00 and 08.00 h, respectively. Diurnal variations were abolished in the amygdala and hypothalamus of kindled rats. In the amygdala the effect was characterized by an IR-Met-enkephalin increase at 04.00, 08.00 and 12.00 h; in the hypothalamus the peptide was enhanced at 08.00 and 12.00 h; in the hippocampus IR-Met-enkephalin increased at 12.00 h and showed a displacement of the peak during the dark phase. The results suggest that PTZ kindling in rats produces a long-lasting alteration on diurnal variations of IR-Met-enkephalin levels in limbic structures.     

Coexpression of dynorphin and neurokinin B immunoreactivity in the rat hypothalamus: Morphologic evidence of interrelated function within the arcuate nucleus

Considerable evidence suggests that dynorphin and neurokinin B (NKB) neurons in the hypothalamic arcuate nucleus participate in the sex-steroid regulation of reproduction. In the present study, we used dual-label immunofluorescence to explore the distribution of prodynorphin and proNKB immunoreactivity in the rat hypothalamus. Additionally, we investigated whether arcuate prodynorphin-ir (immunoreactive) neurons expressed the neurokinin 3 receptor (NK3R) or nuclear estrogen receptor-alpha (ERalpha). We found that the majority of prodynorphin-ir neurons in the rat arcuate nucleus expressed proNKB, whereas nearly all (99%) of the proNKB neurons were immunoreactive for prodynorphin. The arcuate nucleus was the only site in the hypothalamus where neuronal somata coexpressing prodynorphin and proNKB-immunoreactivity were identified. A dense plexus of double-labeled prodynorphin/proNKB-ir fibers was found within the arcuate nucleus extending to the median eminence and throughout the periventricular zone of the hypothalamus. Prodynorphin/proNKB fibers were also identified in the paraventricular nucleus, anterior hypothalamic area, medial preoptic area, median preoptic nucleus, anteroventral periventricular nucleus, and bed nucleus of the stria terminalis in a distribution consistent with previously described arcuate nucleus projections. Interestingly, the majority of prodynorphin-ir neurons in the arcuate nucleus expressed NK3R, and nearly 100% of the prodynorphin-ir neurons contained nuclear ERalpha. Our results suggest that there is a close functional relationship between dynorphin and NKB peptides within the arcuate nucleus of the rat, which may include an autofeedback loop mediated through NK3R. The diverse hypothalamic projections of fibers expressing both prodynorphin and proNKB provide evidence that these neurons may participate in a variety of homeostatic and neuroendocrine processes.     

Immunohistochemical localization of enkephalin in rat brain and spinal cord.

The distribution of immunoreactive enkephalin in rat brain and spinal cord was studied by immunoperoxidase staining using antiserum to leucine-enkephalin ([Leu5]-enkephalin) or methionine-enkephalin ([Met5]-enkephalin). Immunoreactive staining for both enkephalins was similarly observed in nerve fibers, terminals and cell bodies in many regions of the central nervous system. Staining of perikarya was detected in hypophysectomized rats or colchicine pretreated rats. The regions of localization for enkephalin fibers and terminals include in the forebrain: lateral septum, central nucleus of the amygdala, area CA2 of the hippocampus, certain regions of the cortex, corpus striatum, bed nucleus of the stria terminalis, hypothalamus including median eminence, thalamus and subthalamus; in the midbrain: nucleus interpeduncularis, periaqueductal gray and reticular formation; in the hind brain: nucleus parabrachialis, locus ceruleus, nuclei raphes, nucleus cochlearis, nucleus tractus solitarii, nucleus spinalis nervi trigemini, motor nuclei of certain cranial nerves, nucleus commissuralis and formatio reticularis; and in the spinal cord the substantia gelatinosa. In contrast enkephalin cell bodies appear sparsely distributed in the telencephalon, diencephalon, mesencephalon and rhombencephalon. The results of the histochemical staining show that certain structures which positively stain for enkephalin closely correspond to the distribution of opiate receptors in the brain and thus support the concept that the endogenous opiate peptides are involved in the perception of pain and analgesia. The localization of enkephalin in the preoptic-hypothalamic region together with the presence of enkephalin perikarya in the paraventricular and supraoptic nuclei suggest a role of enkephalin in the regulation of neuroendocrine functions.     

Forced swim stress elicits region-specific changes in CART expression in the stress axis and stress regulatory brain areas

CART mRNA and peptides are highly expressed in the anatomical structures composing the hypothalamo-pituitary-adrenal (HPA) axis and sympatho-adrenal system. Anatomical and functional studies suggest that CART peptides may have a role in the regulation of the neuroendocrine and autonomic responses during stress. Our previous study showed that CART peptides increased significantly in the male hypothalamus and amygdala 10 min after the forced swim stress. The present study aimed to examine the effect of forced swim stress on CART peptide expression in selected brain regions, including those where CART peptide expression has not been reported before (frontal cortex, pons, medulla oblongata), as well as in endocrine glands related to stress in male Sprague Dawley rats. A total of 16 (n = 8) animals were used, including control groups. Rats were subjected to forced swim on two consecutive days, and sacrificed on the second day, 2 h after the termination of the stress procedure. Frontal cortex, pons, medulla oblongata, hypothalamus, pituitary and adrenal glands were dissected and homogenized. CART peptide expression in these tissues was measured by Western Blotting and six different CART peptide fragments were identified. Our results showed that forced swim stress elicited region-specific changes in CART peptide expression. CART was upregulated in the frontal cortex, hypothalamus, medulla oblongata and adrenal gland while there was no change in the pons and pituitary. Enhanced CART peptide fragments in these brain regions and adrenal glands may have a role in the regulation of the HPA and sympatho-adrenal axis activity during stress response.     

The effects of mutated skeletal ryanodine receptors on calreticulin and calsequestrin expression in the brain and pituitary gland of boars

Mutations in skeletal ryanodine receptors (sRyR) result in malignant hyperthermia in humans and Porcine Stress Syndrome (PSS) in pigs. Whether the sRyR is expressed in neuronal tissue and what impact it has on neuronal function is relatively unexplored. We have hypothesized that the presence of mutated sRyR may be accompanied by compensatory changes in Ca(2+)-binding protein expression. We were interested in whether pigs heterozygous for mutated sRyR would show changes in the expression of Ca(2+)-binding proteins, in specific regions of the brain, and whether changes in this expression would be accompanied by the presence of sRyR within that region. The objectives of the current experiments were to determine (1) whether calreticulin (CR) and calsequestrin (CS) are expressed in the pituitary gland and brain of the pig, (2) if boars heterozygous for mutated sRyR differed from wild-type boars in the expression of CR or CS, and (3) if altered Ca(2+)-binding protein expression would be accompanied by the presence of sRyR mRNA. Boars either heterozygous or wild-type (n=6) for the mutation in sRyR known to cause PSS, were euthanized and the pituitary gland and brains were collected for western blotting for CR and CS. An additional four wild-type boars were sacrificed and brains were collected for in situ hybridization for sRyR mRNA. Immunoreactive CR was expressed in porcine tissues with highest (p<0.0001) expression in the pituitary gland and lower but equivalent expression in the hypothalamus, frontal cortex, and hippocampus. Immunoreactive CS was not detectable in the pituitary gland while low levels were observed in the hypothalamus and frontal cortex. Dramatically higher (p<0.0001) levels of CS were found in the hippocampus. Genotype did not affect CR expression in the pituitary gland or any brain region examined. Immunoreactive CS levels were lower (p<0.002) in the hippocampus of heterozygous compared to wild-type boars. In situ hybridization experiments revealed the presence of sRyR mRNA in the hippocampus equally distributed across all cell subfields. In conclusion, both CR and CS were expressed in the porcine brain with specific patterns of expression across the brain regions examined. Boars heterozygous for mutated sRyR had lower CS in the hippocampus, which was accompanied by the expression of mRNA for sRyR.