Region-specific changes in transient receptor potential vanilloid channel expression in the vasopressin magnocellular system in hepatic cirrhosis-induced hyponatraemia.

The present study aimed to measure the expression of transient receptor potential (TRP) channels in the magnocellular neurones of the paraventricular (PVN) and supraoptic nucleus (SON) in an animal model of hepatic cirrhosis associated with inappropriate vasopressin (AVP) release. In these studies, we used chronic bile duct ligation (BDL) in the rat, which is a commonly used model of hepatic cirrhosis, associated with elevated plasma AVP. The present study tested the hypothesis that changes in TRP vanilloid (TRPV) channel expression may be related to inappropriate AVP release in BDL rats. To test our hypothesis, we utilised laser capture microdissection of AVP neurones in the PVN and SON and western blot analysis from brain punches. Laser capture microdissection and quantitative reverse transcriptase-polymerase chain reaction demonstrated elevated TRPV2 mRNA in the PVN and SON of BDL compared to sham-ligated controls. AVP transcription was also increased as determined using intron specific primers to measure heteronuclear RNA. Immunohistochemistry demonstrated increased AVP and TRPV2 positive cells in both the PVN and SON after BDL. Also, there was an increased co-expression of TRPV2 and AVP cells after BDL. However, there was no change in the colocalisation counts of TRPV2 and oxytocin in both the magnocellular regions evaluated. In the SON but not the PVN, the transcription levels of TRPV4 were also significantly increased in BDL rats. Western blot analysis of punches containing the PVN and SON revealed that TRPV2 protein content was significantly increased in these brain regions in BDL rats compared to sham rats. Our data suggest that regionally specific changes in TRPV expression in the magnocellular neurosecretory cell AVP neurones could alter their osmosensing ability.

Brain-derived neurotrophic factor-tyrosine kinase B pathway mediates NMDA receptor NR2B subunit phosphorylation in the supraoptic nuclei following progressive dehydration.

We studied the effects of water deprivation (WD) on the phosphorylation of tyrosine kinase B (TrkB) and NMDA receptor subunits in the supraoptic nucleus (SON) of the rat. Laser capture microdissection and quantitative reverse transcriptase polymerase chain reaction was used to demonstrate brain-derived neurotrophic factor (BDNF) and TrkB gene expression in vasopressin SON neurones. Immunohistochemistry confirmed BDNF staining in vasopressin neurones, whereas staining for phosphorylated TrkB was increased following WD. Western blot analysis of brain punches containing the SON revealed that tyrosine phosphorylation of TrkB (pTrkBY(515)), serine phosphorylation of NR1 (pNR1S(866) or pNR1) and tyrosine phosphorylation of NR2B subunits (pNR2BY(1472) or pNR2B) were significantly increased in WD animals compared to controls. Access to water for 2 h reduced pTrkBY(515) content to control levels without affecting pNR1 or pNR2B. Four hours of rehydration was needed to reduce pNR1 and pNR2B to control levels. To test whether increased phosphorylation of TrkB in the present study is mediated by BDNF, a group of animals were instrumented with right SON cannula coupled to mini-osmotic pumps filled with vehicle or TrkB-Fc fusion protein, which prevents BDNF binding to TrkB. In the left SON contralateral to the cannula, TrkB phosphorylation was significantly enhanced following WD. Separate analysis of the right SON, which received TrkB-Fc, showed that the TrkB receptor phosphorylation following WD was significantly attenuated. Although increased pNR1S(866) following WD was not affected by local infusion of TrkB-Fc, pNR2BY(1472) was significantly reduced. Co-immunoprecipitation revealed an increased physical interaction between Fyn kinase and NR2B and TrkB in the SON following WD. Thus, activation of TrkB in the SON following WD may affect cellular excitability through the phosphorylation of NR2B subunits.

Effects of hypoglycaemia on neurotransmitter and hormone receptor gene expression in laser-dissected arcuate neuropeptide Y/agouti-related peptide neurones.

Arcuate neuropeptide Y (NPY)/agouti-related pepide (AgRP) neurones regulate energy homeostasis, and express the putative glucosensor, glucokinase (GCK). The present study performed multi-transcriptional profiling of these neurones to characterise NPY, AgRP and GCK gene expression during intermediate insulin-induced hypoglycaemia, and to determine whether these transcriptional responses acclimate to repeated insulin dosing. We also examined whether these neurones express insulin, glucocorticoid and oestrogen receptor gene transcripts, and whether the levels of these receptor mRNAs are modified by insulin-induced hypoglycaemia. Individual NPY-immunoreactive neurones were laser-microdissected from the caudal arcuate nucleus after single or serial dosing with neutral protamine Hagedorn insulin (NPH), and evaluated by quantitative real-time reverse transcriptase-polymerase chain reaction for the assessment of neurotransmitter and receptor gene expression. Mean NPY and AgRP mRNA in harvested NPY neurones was unchanged or augmented, respectively, by one NPH dose, although repeated NPH administration up-regulated NPY, whereas AgRP gene transcripts were down-regulated. NPH elicited divergent modifications in the ERalpha and ERbeta mRNA content of sampled neurones. ERalpha transcripts were amplified by both acute and chronic NPH-induced hypoglycaemia, whereas ERbeta gene expression was unaltered during a single bout, but suppressed during recurring hypoglycaemia. Glucocorticoid receptor (GR) mRNA levels were increased by a single insulin dose, but unaffected by serial NPH dosing. Insulin receptor-beta chain (InsRb) gene transcripts were insensitive to acute NPH-induced hypoglycaemia, but repeated NPH inhibited this gene transcript. Neither acute nor recurring hypoglycaemia modified GCK mRNA levels in caudal hypothalamic arcuate nucleus (ARH) NPY/AgRP neurones, but baseline GCK transcription was suppressed by the latter. This evidence for the habituation of hypoglycaemic patterns of InsRb, GR and ERbeta gene transcription to serial NPH dosing implies that such treatment may alter reactivity of caudal ARH NPY/AgRP neurones to receptor ligands, and supports the need to determine whether adaptive changes in neuronal sensitivity to insulin, corticosterone and/or oestrogen cause up- versus down-regulation of NPY and AgRP neurotransmission, respectively, by this caudal ARH subpopulation during chronic hypoglycaemia.

Adaptation of feeding and counter-regulatory hormone responses to intermediate insulin-induced hypoglycaemia in the ovariectomised female rat: effects of oestradiol.

Oestradiol regulates basal food intake and glucagon and corticosterone secretion, but its influence on these responses to acute and recurring hypoglycaemia remains unclear. The present study utilised an experimental model for repeated intermediate-acting insulin-induced hypoglycaemia that replicates the route of delivery, frequency of administration, and duration of insulin action in the clinical setting. Groups of ovariectomised (OVX) rats were implanted with s.c. capsules containing oestradiol benzoate (EB) or oil, and injected with one or four doses of Humulin neutral protamine Hagedorn (HN), on as many days, or diluent alone. Baseline feeding followed divergent trends in EB- versus oil-implanted animals over a 9-h period after final injections. Recurring HN-induced hypoglycaemia resulted in significantly greater baseline-corrected food intake in OVX + EB and OVX + oil groups, relative to acute hypoglycaemic hyperphagia. Although oestradiol did not modify net food consumption after single or serial HN doses, EB replacement maintained uniform feeding over time in each treatment paradigm. Baseline glucagon and corticosterone secretion was higher in EB- versus oil-treated OVX rats. Oestradiol prolonged acute hypoglycaemic glucagonemia, and increased the magnitude, but shortened the duration, of glucagon secretion during recurring hypoglycaemia. OVX + oil rats responded to both acute and recurring hypoglycaemia with elevated corticosterone secretion at a single time point, which was advanced from +6 to +4 h during recurrent insulin-induced hypoglycemia, whereas OVX + EB animals exhibited increased plasma hormone levels at both +4 and +6 h in response to each paradigm. Area-under-the curve analyses showed that total glucagon and corticosterone release was greater in EB- versus oil-implanted rats after both single and serial dosing with HN. These results demonstrate that repeated HN administration increases food intake in female rats via oestrogen-independent mechanisms, but that oestradiol preserves temporal patterns of hypoglycaemic hyperphagia. The data also reveal that normo- and hypoglyacemic glucagon and corticosterone secretion are enhanced in the presence of oestrogen. Further studies are necessary to identify the sites and cellular substrates that are responsible for this hormonal regulation of behavioural and endocrine responses to prolonged hypoglycaemia.

Effects of estradiol on glycemic and CNS neuronal activational responses to recurrent insulin-induced hypoglycemia in the ovariectomized female rat.

Recurrent insulin-induced hypoglycemia (RIIH) results in glucose counterregulatory dysfunction in men and male rodents. Intensified hypoglycemia in the latter coincides with diminished neuronal Fos expression in central metabolic regulatory structures, evidence that supports habituation of CNS-mediated compensatory motor outflow during re-exposure to this metabolic stress. In light of the evidence for counterregulatory resistance to precedent hypoglycemia in women, we utilized estradiol-treated ovariectomized (OVX) female rats to examine the hypothesis that this hormone regulates neural adaptability to recurring hypoglycemia. Groups of OVX rats were implanted with subcutaneous silastic capsules containing estradiol benzoate (E) or oil alone, and injected subcutaneously with one or four doses of the intermediate-acting insulin, Humulin NPH, one dose daily, or with diluent alone. Blood glucose levels were not altered by RIIH in E-implanted OVX animals, but were significantly decreased after four versus one insulin injection in the OVX+oil group. Mean numbers of Fos-immunoreactive (ir) neurons in the paraventricular nucleus hypothalamus (PVH), dorsomedial nucleus hypothalamus (DMH), and lateral hypothalamic area (LHA) were higher in both E- versus oil-implanted OVX rats injected with diluent only. Acute hypoglycemia significantly increased mean counts of Fos-ir-positive neurons in the PVH, DMH, and LHA, as well as the nucleus of the solitary tract (NTS) and area postrema (AP) in E- and oil-treated animals to an equivalent extent. OVX+E rats exhibited comparable numbers of Fos-positive neurons in the PVH, DMH, and LHA after one versus four insulin injections, whereas the numbers of labeled neurons in NTS and AP were increased or decreased, respectively, by RIIH. Oil-implanted OVX rats showed significantly diminished numbers of Fos-ir-positive neurons in each neural structure after repeated hypoglycemia. The present data demonstrate that estradiol sustains or enhances neuronal reactivity to recurring hypoglycemia in central metabolic structures, whereas hypoglycemic patterns of Fos expression in each site become habituated during RIIH in the absence of this steroid. The brain sites characterized here by estrogen-dependent maintenance of neuronal genomic reactivity to this substrate fuel imbalance may contain direct and/or indirect cellular targets for hormonal actions that prevent adaptation of CNS-controlled motor responses to this metabolic stress.