Temporal changes in tyrosine hydroxylase mRNA levels in A1, A2 and locus ceruleus neurons following electrical stimulation of A1 noradrenergic neurons.

We examined the effects of electrical stimulation (ES) of right A1 noradrenergic cells on temporal changes in tyrosine hydroxylase (TH) mRNA levels in A1, A2 and locus ceruleus (LC) neurons by in situ hybridization histochemistry and quantitative image analysis methods. The stimulation parameters used previously have been shown to increase hypothalamic norepinephrine (NE) release. Within 1 h after beginning A1 stimulation, TH mRNA levels were significantly increased and they continued to rise to reach plateau by 6 h. TH message levels at 12 h were not difference from 6 h values. A1-ES did not affect TH mRNA levels in contralateral A1 or in A2 or locus ceruleus neurons. These data suggest that changes in TH mRNA levels may serve as an index of increased A1 neuronal activity in circumstances when increases in hypothalamic NE secretion occur.     

Tyrosine Hydroxylase and DOPA Decarboxylase Activities in the Medial Preoptic Area and Arcuate Nucleus During the Estrous Cycle: Effects of Aging

HPLC and Palkovits' microdissection technique were used to measure activities of two catecholamine-synthesizing enzymes, tyrosine hydroxylase (TH) and dopa decarboxylase (DD), in the medial preoptic area (MPA) and arcuate nucleus (AN), both of which are involved in LH regulation. The measurements were made during an 8-h period at 1200, 1400, 1600, 1800, and 2000 h on the days of proestrus and diestrus in young (4–5-month-old) rats. Similar measurements were made at 1400, 1600, 1800, and 2000 h in middle-aged (8–10-month-old) proestrous rats and in 18–22-month-old persistently diestrous rats. For each hour (1200, 1400, etc.), five to seven rats were used. In the young proestrous rats, TH activity in the MPA increased progressively to maximum levels at 1800 h, which is approximately the time when the proestrous surge of LH is known to occur. In contrast, in the young diestrous rats, in which serum LH is known to remain stable, TH activity remained unchanged throughout the afternoon. As in the young proestrous rats, in the middle-aged proestrous rats TH activity reached a peak at 1800 h followed by a precipitous decline at 2000 h. As in the young diestrous rats, in the old persistently diestrous rats no changes in TH activity were observed. The profiles of TH activity in the AN of the four groups were essentially similar to those in the MPA. The cyclic changes in TH activity observed in this study provide a basis for the reported cyclic changes in NE activity, which, in turn, are believed to be responsible for cyclic changes in LH release. The marked deficiency and absence of changes in TH activity in the acyclic old animals corresponded to the reported marked decrease and absence of fluctuations in catecholamine activity in old age. A correlation between DD activities and catecholamine activities was not obvious, most probably due to the large number of compounds that are known to be substrates for this enzyme.     

Effects of reserpine on tyrosine hydroxylase mRNA levels in locus coeruleus and medullary A1 and A2 neurons analyzed by in situ hybridization histochemistry and quantitative image analysis methods.

These studies examined the effects of reserpine on concentrations of norepinephrine (NE), dopamine (DA) and epinephrine (EPI) and on levels of tyrosine hydroxylase (TH) mRNA in locus coeruleus (LC) and medullary A1 and A2 neurons. Noradrenergic neurons in these regions first were identified by immunocytochemistry and, thereafter, by in situ hybridization histochemistry. Levels of TH mRNA were measured by quantitative image analysis methods. Changes in catecholamine concentrations in micropunches of these brain regions were analyzed by HPLC. Epinephrine was not detected in any of the nuclei examined. Twenty-four hours after reserpine treatment, NE concentrations declined in A1, A2 and LC neurons by 46, 69 and 34% respectively while DA declined only in the region of A2 neurons. This reserpine-induced depletion of NE was accompanied by a 2- to 3-fold increase in TH mRNA levels in LC and A1 neurons but no change in message levels occurred in A2 cells 24 h after reserpine. Forty eight hours later, message levels in A1 and LC neurons did not differ significantly from the elevated 24 h values but TH mRNA levels in A2 neurons now were significantly elevated compared to 24 h values. TH mRNA levels 72 h after reserpine did not differ from 48 h values in A1, A2 and LC neurons. Thus, TH gene expression in A1 neurons increases after reserpine treatment in a manner equivalent to that observed in LC, adrenal medulla and superior cervical ganglia. The reason why it required 48 h for TH mRNA to increase in A2 neurons remains unclear.     

Changes in preproenkephalin messenger RNA level in the rat ventromedial hypothalamus during the estrous cycle

To gain a better understanding of the relationship between the female rat reproductive system and preproenkephalin (PPE) expressing neurons under physiological conditions, we examined changes in PPE mRNA levels in the mediobasal hypothalamus during the rat estrous cycle by means of northern blotting and in situ hybridization histochemistry (ISHH). In the Northern blot studies, we found that PPE mRNA levels in the mediobasal hypothalamus were significantly increased by noon of proestrus compared to those in the morning and stayed high until diestrus day 1, and returned toward low levels on diestrous day 2. In contrast, measured as controls, glyceraldehyde-3-phosphate-dehydrogenase mRNA levels were significantly higher on proestrus regardless of time of day compared to diestrus day 2, and levels of calcineurin mRNA on proestrous and estrous were significantly lower than diestrous day 1 and day 2. ISHH studies revealed that these changes in PPE mRNA levels were specific in the ventromedial hypothalamic nucleus pars ventrolateralis (VMHVL), since we could not see any significant changes in signal in other parts including ventromedial hypothalamic nucleus pars dorsomedialis and arcuate hypothalamic nucleus. In the VMHVL, PPE mRNA levels in the afternoon of proestrous were significantly higher than those in the afternoon of diestrous day 2 whereas no significant change in PPE mRNA was observed in the caudate-putamen. The present study provides additional information relevant to possible implications of PPE gene expression in female reproductive systems, since changes in PPE mRNA levels may be associated with estrogen as well as progesterone or other hormonal concentrations during the estrous cycle. Its high levels on diestrous day 1 may suggest that its involvement in female reproductive behavior is not limited to lordosis itself.     

Cyclic and age-related changes in norepinephrine concentrations in the medial preoptic area and arcuate nucleus

High-performance liquid chromatography with electrochemical detection (HPLC-EC) and Palkovits' microdissection technique were used to measure norepinephrine (NE) concentrations in the medial preoptic area (MPA) and arcuate nucleus (AN) during various stages of the estrous cycle. NE was measured seven times at 2-h intervals between 1000 h and 2200 h on the days of proestrus and diestrus in young (4-month-old) rats and four times at 2-h intervals between 1400 h and 2000 h in old (20–22-month-old) persistently diestrous rats. On the day of proestrus in young animals, NE increased progressively from low levels at 1000 h to peak levels at 2000 h, followed by a sharp decline at 2200 h. In contrast, no changes in NE occurred on the day of diestrus. Unlike the young proestrous rats, but similar to the young diestrous rats, no changes in NE concentrations either in the MPA or in the AN occurred in the old persistently diestrous rats. These data demonstrate that NE concentrations in the MPA and AN change during the estrous cycle. We believe the increase in NE on the aftemoon of proestrus is related to the surge in serum luteinizing hormone (LH) that occurs simultaneously in this stage of the estrous cycle. The lack of change in NE concentrations in the young diestrous and persistently diestrous old animals is consistent with the well-established absence of changes in serum LH in these animals.     

Effects of morphine on luteinizing hormone secretion and catecholamine turnover in the hypothalamus of estrogen-treated rats

This study examined the effects of morphine sulfate and naloxone alone or in combination on phasic luteinizing hormone (LH) secretion in estrogen-treated ovariectomized rats. Thereafter, the effects of morphine on initial concentrations, rate constants and rates of turnovers of norepinephrine and dopamine were evaluated in untreated or morphine-injected, estrogen-primed rats. Morphine, when given at 12.30 h, completely suppressed the spontaneous LH surges which occur in steroid-treated rats. The opiate antagonist, naloxone, (12.15 h) markedly amplified and advanced the time of LH release and a combination of morphine and naloxone produced peak afternoon LH values which were intermediate between those obtained in controls and in rats receiving only naloxone. Norepinephrine (NE) and dopamine (DA) turnover were calculated from data obtained in groups of rats sacrificed 0,45 or 90 min after administering 300 mg/kg b. wt. i.p. ofα-methyl-p-tyrosine (α-MPT) at 10.00 or 15.00 h. In these experiments, the medial preoptic nucleus (MPN) and the median eminence (ME) were microdissected and analyzed for changes in NE and DA concentrations by a radioenzymatic procedure. In estrogen-treated rats, NE rate constants and turnover significantly increased at 15.00 vs 10.00 h in MPN and ME concomitant with increases in serum LH. Morphine blocked both increases in rate constants and turnover in the MPN and ME and also significantly reduced initial concentrations of NE in the MPN. None of the DA parameters measured in MPN or ME changed in estrogen-treated controls between morning and afternoon. Further, while morphine did not affect DA turnover in the MPN, DA turnover declined in the ME. These data add to accumulating evidence which demonstrates an important modulatory role for hypothalamic opiate neurons in regulating catecholamine activity and gonadotropin secretion.     

Gonadotropin responses to naloxone may depend upon spontaneous activity in noradrenergic neurons at the time of treatment

The opiate system is thought to modulate gonadotropin secretion by its effect on catecholamine secretion. This action may be produced by opiates regulating the amount of catecholamine released from presynaptic terminals at a given frequency of depolarization and/or by increasing the rate of impulse traffic within catecholamine neurons. We examined the effects of naloxone, an opiate receptor antagonist, on luteinizing hormone (LH) and prolactin (Prl) secretion in 3 sex steroid-treated, gonadectomized rat models in which we have considerable information on the rates of turnover of norepinephrine (NE) and dopamine (DA) in the hypothalamus. In 7 day ovariectomized rats treated for 2 days with estradiol (E2), the injection of naloxone (10 mg/kg) at 09.15 h produced a small 3-fold rise in LH and a short-lived decline in Prl. In contrast, naloxone, given at 12.15 h, markedly amplified (10-fold) and advanced the time of the LH surge but did not affect afternoon Prl surges. Hypothalamic NE turnovers are low in the morning and high in the afternoon for such animals. Other ovariectomized (OVX) rats received E2 for 2 days and progesterone (P4) on day 2. Such treatment extinguishes the LH surges which normally occur the next day (day 3) but does not affect phasic Prl secretion. Naloxone, given at 09.15 h to E2P4-treated rats on day 3, did not affect basal LH levels but serum Prl declined for about 1 h. When given at 12.15 h, naloxone produced a small 3-fold rise in LH but did not affect phasic Prl release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of novel stressors on gene expression of tyrosine hydroxylase and monoamine transporters in brainstem noradrenergic neurons of long-term repeatedly immobilized rats

Responses of central noradrenergic (NE) neurons to stressors like immobilization (IMO), cold exposure, insulin-induced hypoglycemia, and cellular glucoprivation caused by 2-deoxy-D-glucose (2-DG) were investigated in intact and long-term repeatedly immobilized (LTR, 2 h daily IMO for 41 days) rats. Expression of tyrosine hydroxylase (TH), norepinephrine transporter (NET) and vesicular monoamine transporter (VMAT2) genes were determined by using in situ hybridization histochemistry in brainstem A1, A2, A5 and locus coeruleus (LC) neurons. TH mRNA levels were increased by single IMO or 2-DG administration in all areas studied. Cold was effective only in LC and A2 neurons while insulin had no effect. LTR immobilization elevated TH mRNA levels in all investigated cell groups. These elevations were equally high to those elicited by a single IMO in each noradrenergic group, except the LC where LTR IMO was less effective than the single IMO. The levels of NET and VMAT2 mRNAs were elevated only in the A1 and A2 cell groups of LTR IMO rats. A newly applied IMO in LTR rats did not alter TH, NET, and VMAT2 mRNA levels in any NE cell group investigated. Novel stressors like cold and 2-DG exaggerated the increased TH mRNA levels only in the LC of LTR IMO rats, unlike in the other NE cell groups. The present data indicate that repeated exposure of rats to homotypic stressor induces an adaptation of NE neurons, whereas single exposure of such animals to heterotypic novel stressor produces an exaggerated response of the system at the level of TH (in LC) and NET (in A1, A2) gene expression.     

Cyclic changes in the release of norepinephrine and dopamine in the medial basal hypothalamus: effects of aging

Push-pull perfusion and HPLC were used to measure the release of norepinephrine (NE) and dopamine (DA) in the medial basal hypothalamus of young (4–5 months old), middle-aged (8–10 months old), and old (22–24 months old) rats. In the young animals, the afternoon of proestrus was characterized by a gradual increase in NE release and a simultaneous gradual decrease in DA release. The peak in NE release and the nadir in DA release occurred at about the time when the proestrous surges in serum LH and PRL are known to occur. No changes in NE and DA releases occurred in the afternoon of diestrus when serum LH and PRL are known to remain stable. In the middle-aged proestrous animals, the patterns of NE and DA releases were similar to those in the young proestrous animals, but the peak in NE release was attenuated and did not reach statistical significance. This corresponded with the reported attenuation in the LH surge in middle age. In the old persistently diestrous animals, NE and DA were released at constant rates, which correlated with the well-documented constant levels of serum LH and PRL in old age. These data provide an explanation for the simultaneous proestrous surges of LH and PRL and lead us to conclude that NE plays a facilitatory role in the LH surge, while DA, through its inhibitory action, regulates the PRL surge. These studies, by monitoring NE and DA releases from adulthood through middle-age to old age, indicated that cyclicity in catecholamine (CA) activities begins to be dampened in middle-age and eventually completely disappears in the acyclic period of old age which is also characterized by a marked deficiency in CA activities.     

Oestradiol-dependent and -independent modulation of tyrosine hydroxylase mRNA levels in subpopulations of A1 and A2 neurones with oestrogen receptor (ER)alpha and ER beta gene expression

Oestradiol (E2) induces luteinizing hormone-releasing hormone (LHRH) hypersecretion, thereby triggering LH surge release in ovariectomized (OVX) rats. Neural signals responsible for the surge are marked by a morning increase in LHRH gene expression and an afternoon increase in LHRH release. Evidence suggests that subpopulations of noradrenergic neurones may be responsible for one or both of these signals. To further investigate this issue, we examined effects of E2 on the activity of A1 and A2 noradrenergic neurones, as reflected in changes in tyrosine hydroxylase (TH) mRNA expression, on the day of LH surge release. We then used dual-label in situ hybridization to determine whether E2-induced changes occurred primarily in A1 and A2 subdivisions wherein most noradrenergic neurones expressed oestrogen receptor (ER)alpha and/or ER beta mRNA. We found that in all subdivisions, levels of TH mRNA were higher in E2- than oil-treated rats at 12.00 h. These differences resulted from a decline in TH mRNA expression in oil-treated rats, as well as a rise in levels in E2-treated rats between 10.00 h and 12.00 h. During the afternoon, TH mRNA expression in most A1 and A2 subdivisions peaked at 14.00 h when LH surge release began. However, in all but the middle and caudal A2 subdivisons, levels were similar in E2-treated and control rats at this time. This was attributable to a widespread increase in TH mRNA expression between 12.00 h and 14.00 h in OVX rats. There was no evidence that E2 induced changes in TH mRNA expression preferentially in regions wherein most neurones contained ER alpha or ER beta mRNA. Our findings suggest that E2 activation of middle and caudal A2 neurones, in conjunction with the widespread E2-independent activation of noradrenergic neurones in other subdivisions, may play a role in the induction of LH surge release.     

Regulatory role of glucocorticoids and glucocorticoid receptor mRNA levels on tyrosine hydroxylase gene expression in the locus coeruleus during repeated immobilization stress

Sustained responsiveness of the hypothalamic-pituitary-adrenal (HPA) axis during chronic or repeated stress is associated with continuous activation of ascending noradrenergic neurons from the brainstem to the hypothalamic paraventricular nucleus (PVN). The fact that glucocorticoid receptor (GR) exists in the brainstem noradrenergic neurons including locus coeruleus (LC) suggests that glucocorticoids play a modulatory role in maintaining the activity of these neurons during chronic stress. To determine whether alterations in the sensitivity of noradrenergic neuronal activity to endogenous CORT occur during chronic or repeated stress, tyrosine hydroxylase (TH) and GR mRNA expressions in the LC were examined in acute (2 h) and repeated (2 h daily, 14 days) immobilization stress, using sham-operated rats and adrenalectomized rats with a moderate dose of CORT replacement (ADX+CORT group). In acute stress, TH mRNA in the LC increased in the ADX+CORT rats, but not in sham operated rats. In repeated stress, however, elevated endogenous CORT failed to inhibit TH mRNA responses in sham rats; LC TH mRNA in sham rats responded to the same extent as in ADX+CORT rats. A reduction of GR mRNA in the LC was observed in the acutely stressed and repeatedly stressed sham group, but not in the ADX+CORT groups. The decrease in LC GR mRNA levels in sham rats tended to be greater after repeated than after acute stress. LC GR mRNA levels decreased in response to systemic CORT treatment (200 mg pellet sc, for 14 days) and increased in response to adrenalectomy; neither CORT treatment nor adrenalectomy influenced TH mRNA levels in the LC. These results suggest that glucocorticoid responses to acute immobilization prevent LC TH mRNA levels from rising significantly, while glucocorticoids appear to decrease their capacity to restrain LC TH mRNA during repeated immobilization. Although the results clearly show glucocorticoid-dependent alterations in LC GR mRNA expression, the association between increased TH mRNA and decreased GR mRNA in the LC remains to be elucidated.     

Changing patterns of Fos expression in brainstem catecholaminergic neurons during the rat oestrous cycle

Brainstem catecholaminergic neurons are believed to play an important role in the activation of luteinising hormone-releasing hormone (LHRH) neurons on the afternoon of proestrus which results in the luteinising hormone (LH) surge. To examine the respective roles of brainstem A1 and A2 neurons and the adjoining C1 and C2 adrenergic cells at this time, we have examined the patterns of Fos-immunoreactivity within tyrosine hydroxylase (TH) and phenylethanolamine-N-methyl transferase (PNMT) neurons during diestrus and proestrus. Initial studies demonstrated that the LH surge commenced at approximately 15:00 h in proestrous animals and that peak plasma levels of LH were observed between 16:00 and 17:00 h. Groups of cycling female rats (n = 6) were then perfused between 09:00 and 11:00 (diestrus early) and 18:00 to 19:30 h (diestrus late) on diestrus and at the same times on proestrus (proestrus early and proestrus late). Double-labelling immunocytochemistry revealed little Fos expressions by adrenergic neurons of the C1 or C2 cell groups and this did not change significantly between any of the experimental groups. Analysis of the A2 region was divided into rostral, middle and caudal divisions and all regions showed a significant (P < 0.01) increase in the number of Fos-expressing TH neurons (up to 35% of TH cells) in proestrus early animals compared with diestrus and proestrus late rats. In the A1 region, a significant increase in the number of TH neurons expressing Fos ( 33%) was detected in both proestrus early (P < 0.05) and diestrus early (P < 0.01) rats compared with animals perfused in the late afternoon ( 12%). These results indicate that TH-immunoreactive neurons in both A1 and A2 cell groups are activated on the morning of proestrus prior to the LH surge whilst the C1 and C2 adrenergic neurons express little Fos throughout. The morning increase in Fos-expression by TH neurons within the A1 region on both diestrus and proestrus indicates a circadian pattern of activation for A1 noradrenergic cells and suggests different roles for the A1 and A2 cell groups in regulating the activity of LHRH neurons on proestrus.     

Luteinizing hormone and luteinizing hormone-releasing hormone secretion is under locus coeruleus control in female rats

It has been suggested that norepinephrine (NE) from the locus coeruleus (LC) plays an important role in triggering the preovulatory surge of gonadotropins. This work intended to study the role of LC in luteinizing hormone (LH) secretion during the estrous cycle and in ovariectomized rats treated with estradiol and progesterone (OVXE(2)P) and to correlate it with LH releasing hormone (LHRH) content in the medial preoptic area (MPOA) and median eminence (ME). Female rats on each day of the estrous cycle and OVXE(2)P were submitted to jugular cannulation and LC electrolytic lesion or sham-operation, at 09:00 h. Blood samples were collected hourly from 11:00 to 18:00 h, when animals were decapitated and their brains removed to analyze LC lesion and punch out the MPOA and ME. Plasma LH levels and LHRH content of MPOA and ME were determined by radioimmunoassay. During metestrus, diestrus and estrus, LC lesion did not modify either LH plasma concentrations or LHRH content, but completely abolished the preovulatory LH surge during proestrus and the surge of OVXE(2)P. These blockades were accompanied by an increased content of LHRH in the MPOA and ME. The results suggest that: (1). LC does not participate in the control of basal LH secretion but its activation is essential to trigger spontaneous or induced LH surges, and (2). the increased content of LHRH in the MPOA and ME may be due to a decreased NE input to these areas. Thus, LC activation may be required for depolarization of LHRH neurons and consequent LH surges.     

Inhibition of LH and prolactin release in the cycling rat following inhibition of dopamine-ß-hydroxylase

The effect of fusaric acid, an inhibitor of dopamine-ß-hydroxylase (DBH), on luteinizing hormone (LH) and prolactin levels during the estrous cycle was determined.Fusaric acid was found to cause a selective dose- and time-dependent inhibition of DBH activity in the medial basal hypothalamus without altering tyrosine hydroxylase activity. When DBH was inhibited during the afternoon of diestrus, the proestrous surges of both LH and, to a lesser extent, prolactin were inhibited. These results suggest that noradrenergic neuronal activity in the mediobasal hypothalamus is required during afternoon preceding proestrus in order for the LH and prolactin surges to occur. It is possible that the rise in serum estrogen during late diestrus 2 is blocked by fusaric acid treatment. This estrogen increase is necessary for LH and prolactin surges to occur during proestrus. When DBH was inhibited during the afternoon of proestrus, the LH and prolactin surges were completely eliminated. This indicates that noradrenergic neuronal activity in the mediobasal hypothalamus during the afternoon of proestrus is important for both the LH and prolactin surges to occur.     

Inhibition of LH and prolactin release in the cycling rat following inhibition of dopamine-beta-hydroxylase

The effect of fusaric acid, an inhibitor of dopamine-beta-hydroxylase (DBH), on luteinizing hormone (LH) and prolactin levels during the estrous cycle was determined. Fusaric acid was found to cause a selective dose- and time-dependent inhibition of DBH activity in the medial basal hypothalamus without altering tyrosine hydroxylase activity. When DBH was inhibited during the afternoon of diestrus, the proestrous surges of both LH and, to a lesser extent, prolactin were inhibited. These results suggest that noradrenergic neuronal activity in the mediobasal hypothalamus is required during the afternoon preceding proestrus in order for the LH and prolactin surges to occur. It is possible that the rise in serum estrogen during late diestrus 2 is blocked by fusaric acid treatment. This estrogen increase is necessary for LH and prolactin surges to occur during proestrus. When DBH was inhibited during the afternoon of proestrus, the LH and prolactin surges were completely eliminated. This indicates that noradrenergic neuronal activity in the mediobasal hypothalamus during the afternoon of proestrus is important for both the LH and prolactin surges to occur.     

Medial Preoptic Microimplants of the Antiestrogen, Keoxifene, Affect Luteinizing Hormone-Releasing Hormone mRNA Levels, Median Eminence Luteinizing Hormone-Releasing Hormone Concentrations and Luteinizing Hormone Release in Ovariectomized, Estrogen-Treated Rats

We examined the temporal changes in plasma luteinizing hormone (LH) levels, median eminence luteinizing hormone-releasing hormone (LHRH) concentrations and LHRH mRNA levels in estrogen-treated, ovariectomized rats with empty or antiestrogen- containing microcannulae stereotaxically implanted into the medial preoptic area. Neither treatment disrupted the negative feedback effects of estrogen on LH secretion, but antiestrogen (Keoxifene) blocked the afternoon LH surges. In rats exhibiting LH surges, median eminence LHRH concentrations were similar at 0800, 1200 and 1600 h, but they were significantly elevated by 2000 h. In contrast, no alterations in LHRH concentrations occurred in the Keoxifene-treated group. LHRH mRNA levels in control rats were significantly elevated at 1200, 1600 and 2000 h compared with 0800 h, but LHRH mRNA levels in Keoxifene-treated rats did not change significantly over the time period examined. When we compared treatment effects over time we saw that serum LH levels were significantly higher in control than Keoxifene-treated rats only at 1600 and 2000 h. Median eminence LHRH concentrations did not differ between treatment groups until 2000 h when control animals had significantly higher levels than those of Keoxifene-treated animals. LHRH mRNA levels in Keoxifene-treated rats were significantly higher than those of controls at 0800 hand significantly lower at 1600 h. No differences in LHRH mRNA levels were detected between groups at either 1200 h or 2000 h. In summary, although it was not clear on which neuronal system estrogen acted, depriving medial preoptic neurons of this steroid in systemically estrogenized rats certainly disrupted the neural mechanisms involved in surge, but not basal LH release. In addition, neither LHRH mRNA levels nor median eminence LHRH concentrations showed variations within the period studied when the estrogen-sensitive mechanisms involved in LH release were disrupted. Therefore, the changes in LHRH mRNA levels and LHRH concentrations in the median eminence seen in surging animals probably resulted from the same neural events which triggered LH release.     

Locus coeruleus lesions decrease norepinephrine input into the medial preoptic area and medial basal hypothalamus and block the LH, FSH and prolactin preovulatory surge

The aim of this work was to study the role of the dorsal noradrenergic ascending pathway (DNAP), which originates in the locus coeruleus (LC) on the preovulatory surge of luteinizing hormone (LH) follicle-stimulating hormone (FSH) and prolactin (PRL) by producing bilateral electrolytic lesions (cathodal or anodal) in this nucleus. LC lesions were placed at 11.00 h on proestrus in female rats with regular 4-day estrous cycles. Intact rats, sham-operated as well as animals with missed lesions served as controls. In Experiment I, anodal current was applied and hourly blood samples were withdrawn (from 13.00 to 17.00 h) via a jugular catheter from conscious, freely moving rats for determination of plasma LH, FSH and PRL concentrations. In Expt. II, Expt. I was repeated using cathodal current and collecting blood samples hourly from 13.00 to 18.00 h. In both experiments the animals were sacrificed on the next morning when the occurrence of ovulation was checked. The medial septal area (MSA), medial preoptic area (MPOA), and medial basal hypothalamus (MBH) were dissected and assayed for norepinephrine (NE), dopamine (DA) and 5-hydroxyindoleacetic acid (5-HIAA) content. Experiment III was performed in order to test if a hormonal discharge occurred immediately after lesion placement. Blood samples were collected immediately before and 15, 30, 60 and 90 min postoperatively (from 11.00 to 12.30 h). Either anodal or cathodal lesions blocked the proestrous surge of LH, FSH and PRL. The hypothesis that the lesions advanced or delayed these hormonal surges was rejected since we found no increases in the hormonal levels from 11.00 to 12.30 or from 13.00 to 18.00 h, and ovulation was not observed on the following morning in the lesioned animals. Since control, sham-operated and missed-lesion groups exhibited LH, FSH and PRL surges and ovulation, this blockage appears to be caused by the destruction of the LC neurons. Also, this blockade was correlated with a decrease in the NA content in the MPOA and MBH, but not in the MSA, whereas the DA and 5-HIAA content were not changed in all groups examined. The results lead us to suggest that the integrity of noradrenergic afferent input from the LC to luteinizing hormone-releasing hormone neurons in the MPOA and MBH is essential for triggering the preovulatory surge mechanisms for gonadotrophins and PRL.     

Tyrosine hydroxylase mRNA is increased in old age and norepinephrine uptake transporter mRNA is decreased in middle age in locus coeruleus of Brown-Norway rats

In normal aging, cell loss occurs in the locus coeruleus (LC), the major noradrenergic nucleus in the brain. This study examined changes in the LC of aged rats by measuring mRNA expression for tyrosine hydroxylase (TH) and the norepinephrine uptake transporter (NET). TH and NET mRNA expression were measured by in situ hybridization in young, middle-aged and aged rats. It appears that in middle age, the transporter system responds initially to LC cell loss by decreasing NET mRNA expression. Then, with further aging and cell loss, TH mRNA expression increases which may potentially increase NE synthesis in the remaining neurons. These findings suggest that multiple regulatory components are used to maintain stable noradrenergic synaptic levels despite neuronal loss. Published by Elsevier Science B.V.     

Possible Role of Neurokinin A in the Control of Prolactin Secretion in Rats and Hamsters

The possible role of neurokinin A (NKA) in the control of prolactin secretion was studied in vivo, by injecting anti-NKA serum to ovariectomized rats treated with estrogens and to proestrous rats and hamsters. Injections of an anti-NKA serum to ovariectomized rats treated with two doses of 80 μg 17ß-estradiol 24 h apart, or treated chronically with estradiol implants induced a significant decrease of serum prolactin levels as compared with those of similarly treated rats injected with normal rabbit serum. In proestrous rats, the anti-NKA serum did not modify the afternoon surge of prolactin or luteinizing hormone, but when the antiserum was injected the day before, on diestrus II, it significantly reduced the prolactin surge during the afternoon of proestrus. As in these results obtained in the rat, injections of anti-NKA serum to golden hamsters on diestrus II also significantly decreased the prolactin surge in the afternoon of proestrus. These results suggest a possible physiological role of NKA on prolactin secretion, exerting a stimulatory influence on the release of this hormone.