IGF-I and vasoactive intestinal peptide (VIP) regulate cAMP-response element-binding protein (CREB)-dependent transcription via the mitogen-activated protein kinase (MAPK) pathway in pituitary cells: requirement of Rap1.

In previous studies we demonstrated that vasoactive intestinal peptide (VIP) mediation, and interactions between mitogen-activated protein kinase (MAPK) and cAMP/protein kinase A (PKA) signaling pathways are implicated in insulin-like growth factor I (IGF-I)- and VIP-induced lactotroph proliferation. These facts led us to investigate the intracellular mechanisms involved in IGF-I- and VIP-induced lactotroph proliferation. Exposure of cultured male rat pituitary cells to IGF-I (10(-7) M) or VIP (10(-7) M) stimulated the MAPK cascade. Studies in GH4C1 cells, with an expression vector for Rap1 GTPase-activating protein (Rap1 GAP1), demonstrated reduced VIP-induced MAPK activation, indicating that VIP-dependent activation of the extracellular signal-regulated kinase (ERK) pathway requires PKA-Rap1 signaling. IGF-I induced cAMP-response element (CRE)-binding protein (CREB) phosphorylation through the Ras-MAPK pathway, whereas VIP phosphorylated CREB directly via PKA. The mechanisms that regulate IGF-I-and VIP-CREB-dependent gene transcription were examined using GH4C1 cells transiently transfected with a CRE reporter gene. IGF-I and VIP stimulation of CRE-mediated transcription required activation of both Ras-MAPK and cAMP/PKA signaling. This activation was blocked in the presence of Rap1 GAP1. In summary, we showed that IGF-I and VIP stimulated MAPK activity and the phosphorylation of CREB in pituitary cells. Furthermore, VIP-dependent activation of PKA-Rap1-ERK pathways mediated VIP and IGF-I effects on CREB-dependent transcription in GH4C1 cells. Thus, it is possible that VIP- and IGF-I-induced lactotroph proliferation may involve Rap1.

Immunoreactive adrenocorticotropin in the gastrointestinal tract and pancreatic islets of the rat.

Radioimmunoassayable ACTH is detectable in the gastrointestinal tract and pancreatic islets of the rat by using a midportion ACTH antiserum. Portions of the gastrointestinal tract and isolated pancreatic islets were extracted with 0.1 N HCl. Serial dilutions of the extracts resulted in inhibition curves parallel with human alpha ACTH-(1-39). The highest concentrations were in the isolated pancreatic islets (20 pg/ml protein) and the gastric antrum-pylorus (17.9 +/- 1.2 pg/ml protein). Chromatographic characterization of the stomach extract showed a main peak, with an elution constant identical to that of [125I]iodo-ACTH-(1-39) and an elution pattern identical to that of rat pituitary extracts and medium from incubated rat pituitaries.

Basal and growth hormone-induced hepatic messenger ribonucleic acid expression of insulin-like growth factor-I (IGF-I) and IGF-binding protein-3 is independent of hyperinsulinemia and increased energy status in the genetically obese Zucker rat.

Genetically obese Zucker rats, like obese humans, have normal or elevated circulating insulin-like growth factor-I (IGF-I) levels in the presence of low GH secretion. Hyperinsulinemia, increased energy status, or other nutritional factors associated with obesity could be responsible for these findings directly by increasing hepatic IGF-I production at the transcriptional or posttranscriptional level. Alternatively, circulating IGF-I could be modulated indirectly by affecting its binding proteins. To further elucidate this point, we quantitated hepatic IGF-I, IGF-binding protein-3 (IGFBP-3), and GH receptor messenger RNAs (mRNAs) expression in obese Zucker rats under different serum GH and insulin conditions using lean rats as controls. Eleven-week-old male rats were studied basally (intact) or after hypophysectomy (hx) at 9 weeks. In each condition, animals were killed before or 6 h after one dose of recombinant human GH (1.5 micrograms/g body weight ip). At this time, in addition to the mRNA expression of the above-mentioned genes, body weight, glycemia, insulinemia, serum GH (rat and human), and serum IGF-I levels were determined. Obese Zucker rats were significantly heavier than controls in all the conditions studied and did not show differences in glycemia. Severely hyperinsulinemic intact obese rats (146.9 +/- 14 vs. 46.3 +/- 3 microU/ml, P < 0.001) showed compared with intact lean rats significantly lower serum GH (2.39 +/- 0.9 vs. 4.98 +/- 0.68 ng/ml, P < 0.01), decreased hepatic IGF-I mRNA and IGFBP-3 mRNA accumulation (IGF-Ia: 79 +/- 5.9% vs. 100 +/- 0.9%, P < 0.05; IGF-Ib: 67 +/- 5.5% vs. 100.1 +/- 1.9%, P < 0.001; IGFBP-3: 54.7 +/- 2.75% vs. 100.5 +/- 1.55%, P < 0.001), and similar circulating IGF-I levels (1439 +/- 182 vs. 1516 +/- 121 ng/ml). Under comparable serum GH levels in GH-treated intact, hx, and GH-treated hx animals, hyperinsulinemia and/or increased body weight present in obese rats were not associated with increased hepatic IGF-I and IGFBP-3 mRNA amount. No differences in GH receptor/GH-binding protein mRNAs were found in any experimental condition. These results suggest that in vivo the imbalance of the serum GH/IGF-I axis present in obesity is primarily due to events distal to the hepatic IGF-I and IGFBP-3 mRNAs expression, which is tightly correlated to GH levels.

Regulation of growth hormone (GH) gene expression and secretion during pregnancy and lactation in the rat: role of insulin-like growth factor-I, somatostatin, and GH-releasing hormone.

GH appears to play an important metabolic role during late pregnancy and in lactation maintenance. In this study, pregnant (days 8, 15, and 20 of gestation) and postpartum (days 3 and 8 postpartum, including lactating and nonlactating dams) Wistar rats were used to investigate pituitary GH gene expression and hormone secretion, and the potential alterations of the major signals regulating GH secretion and action [somatostatin (SS) and GH-releasing hormone (GHRH), GH receptor (GH-R), and insulin-like growth factor-I (IGF-I)]. GH and SS messenger RNA (mRNA) were quantitated by Northern blot, and both IGF-I and GH-R mRNA were analyzed by the ribonuclease protection assay technique. Pituitary IR-GH content and GH mRNA increased at midpregnancy. IR-GH content was decreased in lactating rats. Plasma GH levels progressively increased during pregnancy, whereas no significant alterations were shown during lactation. Elevated GH levels persisted during lactation. Levels at this time were higher in nonsuckling compared with suckling dams. Liver GH-R mRNA progressively decreased during pregnancy, but it remained unchanged during lactation. Plasma IGF-I and liver IR-IGF-I constantly decreased during pregnancy, and no significant modifications were seen either in suckling or in nonsuckling animals. IGF-I mRNA accumulation in the liver decreased during pregnancy. After delivery, a progressive decrease of liver IGF-I mRNA occurred. At the hypothalamic level, a progressive increase in the IR-SS content was found during pregnancy, with no SS mRNA modification. After delivery, a higher hypothalamic IR-SS content was found in lactating than in nonlactating rats, with no changes in SS mRNA levels. Hypothalamic IR-IGF-I also showed a progressive increase during pregnancy with no significant alterations during lactation. Hypothalamic IR-GHRH presented a nonsignificant mild increase during pregnancy with no modifications during lactation. In the pituitary, IR-IGF-I content progressively increased during gestation, reaching its highest concentration at day 20. During lactation, pituitary IGF-I did not change. In summary, our data show that the mechanisms of the increase in plasma GH levels occurring during pregnancy include an increase in GH gene expression in the pituitary, a decrease in SS secretion from the hypothalamus, an increase in IR-IGF-I content in the hypothalamus and in the pituitary, and a significant decrease in circulating IGF-I. Plasma and liver IR-IGF-I and IGF-I mRNA in the liver decreased throughout gestation due to a lower GH-R gene expression in the liver. This state of GH resistance with a higher GH/IGF-I ratio could be important in providing supplementary nutrients to the fetus. During lactation, GH and its regulatory machinery did not show important modifications.

Prolactin gene expression and secretion during pregnancy and lactation in the rat: role of dopamine and vasoactive intestinal peptide.

It is known that dopamine (DA) is the major PRL-inhibiting factor, and vasoactive intestinal peptide (VIP) is one of the most potent and physiological PRL-releasing factors. We have investigated the implication of DA and VIP in PRL gene expression and peptide secretion regulation during the physiological hyperprolactinemic states of pregnancy and lactation. Pregnant rats were studied on days 8, 15, and 20 of pregnancy. Lactating rats suckled by eight pups were studied on days 3 and 8 of postpartum, and nonsuckling postpartum rats were used as controls. Plasma estradiol, progesterone, and PRL were measured by RIA, as well as pituitary immunoreactive (IR-) PRL, pituitary IR-VIP, and hypothalamic IR-VIP. DA was studied by measuring changes in gene expression of tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine synthesis. TH, PRL, and VIP messenger RNA (mRNA) were assessed by Northern blot hybridization. The results showed very high plasma PRL levels in early pregnancy and during lactation, whereas plasma PRL concentrations were normalized at the end of gestation and in nonsuckling control rats. The physiological hyperprolactinemia of both early pregnancy and lactation correlated with higher pituitary PRL mRNA levels and lower pituitary IR-PRL content. Moreover, hypothalamic TH mRNA levels were lower in early pregnancy and lactation than at the end of gestation and in nonsuckling rats, respectively. The hypothalamic IR-VIP content was lower on day 8 of pregnancy than on days 15 and 20. However, VIP gene expression in the hypothalamus did not change throughout pregnancy. During lactation, neither hypothalamic IR-VIP content nor VIP mRNA was significantly altered. In the pituitary, IR-VIP content did not significantly change, and VIP mRNA levels were higher on day 15 of pregnancy than on the other days. During lactation, the pituitary IR-VIP content was very low on day 8 compared with those on day 3 of lactation and in nonsuckling control rats. VIP mRNA 1.0-kilobase transcript levels were higher in the lactating rats than in the control animals. These data show that both early pregnancy and lactation are physiological hyperprolactinemic states in which increased PRL mRNA accumulation coincides with decreased IR-PRL content in the pituitary and higher plasma IR-PRL, indicating regulation at the gene expression level and of PRL secretion. Low TH gene expression also occurs during hyperprolactinemia, suggesting that the diminution of DA activity that occurs during early pregnancy and lactation might be the major regulator of PRL alterations. If hypothalamic VIP plays a role as a neuroendocrine PRL-releasing factor during pregnancy and lactation, this may occur at the secretory level, as suggested by the alterations in IR-VIP, with no modifications in VIP mRNA accumulation, in the hypothalamus. Pituitary VIP does not seem to be a major regulator of PRL secretion during pregnancy, whereas during lactation, it regulates PRL secretion in a paracrine and/or autocrine manner.

Thyroid hormone action on biosynthesis of somatostatin by fetal rat brain cells in culture.

Thyroid hormone (TH) action on somatostatin (SRIF) secretion and synthesis by fetal rat brain cells in culture was studied. Cortical and hypothalamic brain cells were maintained as monolayer cultures for 7-10 days. T3, T4, and [3H] phenylalanine [( 3H]Phe) (40 microCi/plate) were added simultaneously for 48 h. Alternately, cultures were pulse labeled with [3H] Phe for only the last 3 h, after being exposed to TH for 45 h. 3H-Labeled SRIF-like material [( 3H]IR-SRIF) was purified by immunoaffinity chromatography and further characterized by gel filtration in Bio-Gel P-10. Total protein synthesis was determined by the incorporation of [3H]Phe into trichloroacetic acid precipitable proteins. Forty eight-hour T3 treatment had a biphasic effect on secretion of IR-SRIF by both cortical and hypothalamic cells. In cortical cells, low doses of T3 (10(-11) M) significantly increased (P less than 0.01) and high T3 doses (10(-7) M) significantly decreased (P less than 0.05) total IR-SRIF (nanograms per plate); control: 2 +/- 0.25; T3 (10(-11) M): 3 +/- 0.3; T3 (10(-7) M): 1.3 +/- 0.1. Similarly, T4 had a significant stimulatory action at 10(-9) M, being inhibitory at 10(-7) M (picograms/plate); control: 290 +/- 20 T4 (10(-9) M): 510 +/- 40; T4 (10(-7) M): 201 +/- 10. When [3H]Phe was added during the 48 h of the experiment, [3H]IR-SRIF synthesis in response to T3 by cortical cells significantly increased after exposure to 10(-11) M (P less than 0.05) and decreased with 10(-7) M (P less than 0.05). When [3H]Phe was added for only the last 3 h or incubation with T3, the action was inhibitory at both 10(-11) M and 10(-7) M. Trichloroacetic acid precipitable material decreased in a dose response manner between T3, 10(-11) M and 10(-7) M. These findings suggest that at this time of brain development, SRIF synthesis by cortical and hypothalamic cells is affected by TH.

Growth hormone induces somatostatin and insulin-like growth factor I gene expression in the cerebral hemispheres of aging rats.

The neuropeptide somatostatin (SS) plays a role as a modulator of cognitive functions and as a potential tropic factor in the central nervous system. A reduction in SS levels has been demonstrated in the aging brain and in dementia. In addition, insulin-like growth factor I (IGF-I) acts as a paracrine factor in multiple GH actions and is also found in the cerebral hemispheres, where it exerts neurotropic effects. We used aging rats as an in vivo model of GH deficiency to study the possible participation of exogenous GH in the modulation of the cerebral hemispheric SS and IGF-I. Two sets of experiments were carried out. In the first set, the age-related patterns of GH, IGF-I, and SS in the serum, pituitary, and cerebral hemispheres were established. In the second experimental set, 90-day-old (adult) and 2-yr-old (aging) male rats received recombinant human GH (200 micrograms/ sc-day) or vehicle for 7 consecutive days. The serum levels of rat GH and IGF-I as well as pituitary GH messenger RNA decreased in 2-yr-old rats compared with those in adult rats. After GH treatment, pituitary GH messenger RNA levels decreased markedly in the 90-day-old and 2-yr-old rats. Serum immunoreactive GH decreased in the adult animals, whereas it remained unaffected in the aging ones, whereas serum IGF-I levels were not altered by GH treatment in either group. Immunoreactive levels and messenger RNA of both SS and IGF-I were low in the cerebral hemispheres of aging rats, but were restored to the levels found in adult rats after GH treatment. As treatment did not induce changes in the serum IGF-I levels, these results provide evidence of a stimulatory action of peripherally administered GH on the regulation of SS and IGF-I genes in the aging rat in the central nervous system. These data also show a new target action for GH and could provide a molecular basis for the improvement of some symptoms of GH deficiency that occurs after recombinant human GH treatment.

Autocrine and/or paracrine action of vasoactive intestinal peptide on thyrotropin-releasing hormone induced prolactin release.

Several in vitro studies have demonstrated that vasoactive intestinal peptide (VIP) modulates basal PRL release in normal and hypothyroid anterior pituitary (AP) cells through an autocrine or paracrine action. As thyroid hormone is an important factor in the regulation of pituitary VIP synthesis and secretion, we analyzed the influence of the absence of thyroid hormone on basal PRL release in vitro to study whether the release of PRL induced by TRH might be mediated by a local action of pituitary VIP. When normal AP cells were cultured in a medium supplemented with a near-physiological concentration of free T2 (0.5 nM), basal PRL and VIP release decreased and PRL secretion was not altered by the blockade of VIP action. This finding allowed us to establish the culture conditions in which basal PRL secretion is apparently not under VIP influence. Consequently, we were able to study whether pituitary VIP may be implicated in TRH-induced PRL release. TRH (100 nM) increased PRL and VIP release in a parallel manner and decreased PRL and VIP intracellular content in incubations from 15-180 min. When AP cells wee incubated simultaneously with TRH and a VIP receptor antagonist, TRH-induced PRL release decreased when incubation lasted more than 30 min, whereas the depletion of PRL intracellular content induced by TRH was unchanged. TRH also slightly increased VIP messenger RNA levels at 3 and 24 h, but PRL messenger RNA levels were not modified. These data demonstrate that pituitary VIP participates in in TRH-induced PRL release and that the effect of thyroid hormone on basal pituitary VIP secretion should be borne in mind when studies on its effect, through autocrine and/or paracrine mechanisms, on PRL release stimulated by PRL-releasing factors are conducted.

Autoparacrine action of vasoactive intestinal peptide on dopaminergic control of prolactin secretion.

We have previously reported that pituitary vasoactive intestinal peptide (VIP) mediates through autoparacrine mechanisms insulin-like growth factor-I and TRH-stimulated PRL release. In the present study, we have investigated whether VIP might also be implicated in the PRL increase that follows dopamine (DA) withdrawal. The experiments were carried out in defined medium supplemented or not with T3, as in a previous study we had found that PRL release increases under low T3 culture conditions due to mediation by concomittant stimulus of VIP. Anterior pituitary (AP) cells from adult male rats were incubated for 1 h in the presence of DA (10 microM), a VIP-receptor antagonist (VIP-At) (200 nM), or DA plus VIP-At. Then media were removed and the cells were washed with PBS and reincubated under the same conditions but without the addition of DA. In the first incubation, DA inhibited PRL release by 80%, and VIP release by 20% in both T3-free and T3 medium. In the second period of incubation, PRL and VIP release were increased in AP cells previously exposed to DA. These effects were greater when the cells were cultured in T3-free medium than in T3-medium (225% and 150%, respectively for PRL release; and 155 and 135%, respectively for VIP release). PRL response to DA withdrawal was inhibited by the simultaneous presence of VIP-At. This inhibition was again greater when the cells were incubated in medium supplemented with T2. Thus, the stimulus of DA withdrawal was inhibited by 88% in T2-free medium and by 37% in T3-medium. To investigate whether pituitary VIP messenger RNA (mRNA) expression is under dopaminergic control, AP cells were incubated in the presence or absence of bromocriptine (BC) (10 nM) for 2 and 24 h. After 24 h of incubation, BC decreased mRNA levels of PRL and of the two transcripts which VIP expresses in AP. As with DA, BC also inhibited PRL and VIP release both at 2 and 24 h. These data demonstrate that VIP, at least partially, mediates DA withdrawal-induced PRL release through an autoparacrine action. They also suggest that simultaneous inhibition of pituitary VIP mRNA expression and VIP release may be a necessary mechanism for the dopaminergic inhibition of PRL mRNA expression and PRL release.

Growth hormone gene expression and secretion in aging rats is age dependent and not age-associated weight increase related.

GH secretion declines with age in rats and humans and a reduction in GH gene expression has been demonstrated in aging rats. GH secretion also diminishes in obesity; thus, the aim of this study was to determine whether GH decrease in aging rats is due to body weight gain or to aging. Three groups of male Wistar rats of different ages were studied (young, 3 months; middle-aged, 11 months; old, 27 months). The middle-aged group was established on a statistical analysis and corresponded to the youngest age at which body weight was not significantly different from the old (27 month) group. Thus, by using this group as control for comparison with animals with the same weight and an older age, the effects due to aging itself could be determined. Body weight (g, mean +/- sD) 3 months: 361 +/- 5.6; 11 months: 713 +/- 39; 27 months: 635 +/- 38. In comparison with 3-month-old rats, the 11-month-old animals showed no difference in pituitary GH messenger RNA (mRNA) accumulation and pituitary and serum IR-GH levels. Similarly IGF-I.a, IGF-I.b mRNA transcripts and IG-FBP-3 mRNA accumulation in the liver showed no significant differences between the two groups. On the contrary, when the 27-month-old rats were compared with the 11-month-old animals, lower levels of pituitary GH mRNA and serum and pituitary IR-GH were found. Pituitary GH mRNA decreased 37.5 +/- 7.7% P < 0.001, pituitary IR-GH content diminished (5.2 +/- 3.4 vs. 55 +/- 10.7 ng/mg of protein, P < 0.001) and serum IR-GH decreased (3.5 +/- 1.8 vs. 12.5 +/- 4.2 ng/ml, P < 0.01). Liver IGF-I.a and IGF-I.b mRNA transcripts accumulation and serum IGF-I were significantly diminished. IGF-I.b mRNA accumulation decreased 35.8 +/- 1.2% P < 0.05 and IGF-I.a 36 +/- 5.6% P < 0.05; serum IR-IGF-I levels diminished (759 +/- 152 vs. 1327 +/- 67 ng/ml, P < 0.05). Liver IGFBP-3 mRNA accumulation decreased 79 +/- 4.2% P < 0.001. These results indicate that the decrease in GH gene expression and secretion, as well as the expression of genes induced by GH such as IGF-I and IGFBP-3, is due to aging and not to the increase in body weight that takes place with aging.

Role of dopamine and vasoactive intestinal peptide in the control of pulsatile prolactin secretion.

The present studies were designed to obtain a detailed characterization of pulsatile PRL secretory patterns under basal conditions and to explore the role of dopamine (DA) and vasoactive intestinal peptide (VIP) in the genesis of PRL pulses. Adult intact male rats received chronic indwelling jugular canula and were bled at 3-min intervals for periods ranging from 90-150 min. Pulse analysis was performed using the algorithm Detect. Blockade of DA receptors with domperidone, pimozide, or haloperidol resulted in a 2-fold increase in PRL pulse frequency, with no change in pulse duration. All quantitative parameters, i.e. peak and trough values, pulse amplitude, and area under the pulse, were significantly increased after dopaminergic blockade. Blockade of endogenous VIP activity was achieved by passive immunization with a potent VIP antiserum. This treatment, by itself, did not modify basal PRL levels or PRL pulsatility parameters. However, when VIP antiserum was administered in combination with domperidone, a reduction in all quantitative pulse parameters was observed. Heterogeneity of PRL pulses was evaluated by frequency distribution analysis, using the area under the pulse divided by basal secretion, to evaluate the mass of hormone secreted per pulse normalized to the basal rate of secretion. Untreated animals presented pulses within a range of different masses. Dopaminergic blockade resulted in a great reduction in big mass pulses, and the distribution of pulses was restricted primarily to small mass pulses. The increased pulse frequency after dopaminergic blockade, therefore, results mainly from an increase in the appearance of small mass pulses. These results indicate that DA exerts a tonic inhibitory action on the frequency as well as the qualitative parameters of PRL pulses. They also suggest that big mass PRL pulses are dopaminergic in origin, i.e. they may result from temporary interruptions in DA activity. Small mass PRL pulses appear to result from other neural stimulatory inputs. Endogenous VIP enhances quantitative PRL pulse parameters, but this activity is only apparent after removal of DA inhibition.

Synthesis and secretion of vasoactive intestinal peptide by rat fetal cerebral cortical and hypothalamic cells in culture.

To establish the neurosecretory activity of brain vasoactive intestinal peptide (VIP)ergic neurons and to characterize the molecular forms of secretion of these cells, fetal cerebrocortical and hypothalamic cells were grown in primary cultures for periods up to 4 weeks, their regulation by depolarization and calcium and sodium channel active agents was studied, and the chromatographic patterns of cell and medium VIP were determined. Mechanically dispersed cultured fetal telencephalic and diencephalic cells showed a progressive increase in immunoreactive VIP in both cells and media, reaching maximum values between 110-290 pg/mg protein.culture plate on days 15-20. Immunoreactive VIP in both cells and media corresponded almost exclusively to VIP-28 on exclusion chromatography and HPLC, and was identical to the form extracted from whole fetal brain. This indicates that both the stored and secreted forms of VIP are the mature 28-amino acid-containing peptide. To determine the influence of membrane depolarization on VIP release, the potassium concentration in the medium was increased to 30 and 56 mM, inducing a marked increase in medium VIP concentrations. The effects of K+ were dependent on Ca2+ transport, since release was blocked by the addition of verapamil, a Ca2+ channel blocker (20 microM). VIP release was stimulated by Na+ channel activation using the drug veratridine (100 microM); this effect was blocked by tetrodoxin. The influence of GH-releasing factor (GRF) on VIP release was studied by adding GRF (10(-9)-10(-7) M), alone or in the presence of anti-rGRF immunoglobulins (antirat GRF immunoglobulin G) to the incubation medium. Rat GRF stimulated VIP release and the simultaneous addition of antirat GRF immunoglobulin G blocked this effect. These findings confirm that VIP regulation by brain cells corresponds to the well defined patterns of membrane activation observed in other neuronal systems. They, furthermore, demonstrate that VIP release is under GRF influence.

Induction of vasoactive intestinal peptide gene expression and prolactin secretion by insulin-like growth factor I in rat pituitary cells: evidence for an autoparacrine regulatory system.

The effects of recombinant human insulin-like growth factor I (IGF-I) on both vasoactive intestinal peptide (VIP) and PRL production and gene expression were studied using rat anterior pituitary cell cultures grown in serum-free defined medium. We also examined whether pituitary VIP could be involved in the PRL response to IGF-I and hence in a paracrine regulatory system. Exposure of cultured anterior pituitary cells to IGF-I (2.6 nM) for 3 h caused a significant decrease in both VIP content and media PRL. Treatment with IGF-I (from 0.65-5.2 nM) for 48 h increased VIP production and VIP messenger RNA (mRNA) accumulation, whereas only an increase in media and intracellular PRL content without changes in mRNA was observed. In all these experiments, IGF-I led to a decrease in both GH secretion and expression. Immunoglobulins G purified from VIP antiserum inhibited IGF-I-induced PRL release without affecting intracellular and mRNA levels. The inhibition of both GH secretion and gene expression induced by IGF-I was not blocked by VIP antiserum. In conclusion, these results indicate that IGF-I induces VIP gene expression, and its secretion and also increases PRL secretion. The effect of IGF-I on PRL release is specifically mediated by VIP through a paracrine or autocrine mechanism.

Growth hormone-releasing factor production by fetal rat cerebrocortical and hypothalamic cells in primary culture.

Recent data from our laboratory and others have shown radioimmunoassayable GRF (IR-GRF) in the rat brain cortex. In the present study the ontogenesis of immunoreactive rat(r) GRF (IR-GRF) in long term dissociated fetal rat cerebrocortical and hypothalamic cell cultures and the regulation of its secretion by potassium depolarization and calcium channel-blocking agents were investigated. The chromatographic profiles of IR-rGRF from cell extracts were determined and compared with those from in vivo cerebrocortical and hypothalamic tissues. Mechanically dispersed cultured telencephalic and diencephalic cells from 17- to 21-day-old fetal rats showed a progressive increase in IR-rGRF, reaching maximum values (media plus cells) between 775-1020 (pg/mg protein) in hypothalamic cells on days 10-20 and between 450 and 950 pg/mg protein in cortical cells on days 25-30. IR-rGRF from acidic extracts of cells and adult cortical and hypothalamic tissues adsorbed onto octadecylsilyl-silica columns corresponds primarily to rGRF-(1-43)OH on HPLC. In gel filtration chromatography, almost all IR-rGRF from cultured cerebrocortical cells and fetal and adult cortical tissues coeluted with rGRF-(1-43)OH. IR-rGRF from cultured hypothalamic cells showed an additional component with a higher mol wt eluting in the void volume. To determine the influence of membrane depolarization of rGRF release, potassium (K+) concentrations in the medium were increased to 30 and 56 mM, inducing a marked increase in medium rGRF concentrations. Verapamil, a Ca2+ channel blocker (20 microns) reverses the effect of 56 mM potassium depolarization, suggesting that it is at least partially dependent upon Ca2+ transport. These data indicate that fetal rat cerebrocortical and hypothalamic cells in culture produce and release rGRF in response to depolarizing agents. The presence of rGRF in cortical tissue suggests that there are other physiological roles besides those implicated in the stimulation of GH secretion.

Changes in the prolactin response to thyrotropin-releasing hormone (TRH) during the menstrual cycle of normal women.

Serum prolactin (PRL) and thyrotropin (TSH) levels were measured after iv administration of 200 microng of synthetic thyrotropin-releasing hormone (TRH) in 20 normal women ages 18 to 34. Ten women received TRH on days 7 to 8 of the menstrual cycle and 10 women received TRH on days 21-22. Although there was no difference in the dose of TRH relative to body weight in the two groups of women, the peak PRL level after TRH stimulation was greater in the women studied on day 21-22 (48.5+/-5.7 ng/ml, mean+/-SE) than on day 7-8 (35.2+/-4.2 ng/ml) of the cycle (P less than 0.05). In contrast, TSH rose to a greater degree in the preovulatory phase (13.8+/-1.8 micronU/ml) than the luteal phase (7.7+/-0.7 micronU/ml of the cycle (P less than .01). Studies of the PRL and TSH response after TRH administration should take the phase of the menstrual cycle into account.

PIP: The effects of synthetic thyrotropin-releasing hormone (TRH), administered iv in a dose of 200 mcg, on serum prolactin and thyrotropin levels were measured in 20 women aged 18-34 years. 10 subjects received TRH on Days 7-8 of the menstrual cycle, and the remaining 10 were treated on Days 21-22. The dose/body weight ratio was similar in both groups. The peak prolactin level following TRH administration was 48.5 + or -5.7 ng/ml in women treated on Days 21-22 and 35.2 + or -4.2 ng/ml in those treated on Days 7-8 (p less than .05). Conversely, serum levels of thyrotropin were significantly (p less than .01) higher in the preovulatory phase than the luteal phase (13.8 + or -mcU/ml and 7.7 + or -.7 mcU/ml, respectively). It is recommended that the interpretation of the prolactin response to TRH should take the phase of the menstrual cycle into account.

A novel peculiar mutation in the sodium/iodide symporter gene in spanish siblings with iodide transport defect.

Previously, we reported two Spanish siblings with congenital hypothyroidism due to total failure of iodide transport. These were the only cases reported to date who received long-term iodide treatment over 10 yr. We examined the sodium/iodide symporter (NIS) gene of these patients. A large deletion was observed by long and accurate PCR using primers derived from introns 2 and 7 of the NIS gene. PCR-direct sequencing revealed a deletion of 6192 bases spanning from exon 3 to intron 7 and an inverted insertion of a 431-base fragment spanning from exon 5 to intron 5 of the NIS gene. The patients were homozygous for the mutation, and their mother was heterozygous. In the mutant, deletion of exons 3-7 was suggested by analysis using programs to predict exon/intron organization, resulting in an in-frame 182-amino acid deletion from Met(142) in the fourth transmembrane domain to Gln(323) in the fourth exoplasmic loop. The mutant showed no iodide uptake activity when transfected into COS-7 cells, confirming that the mutation was the direct cause of the iodide transport defect in these patients. Further, the mutant NIS protein was synthesized, but not properly expressed, on the cell surface, but was mostly accumulated in the cytoplasm, suggesting impaired targeting to the plasma membrane.

IGF-I inhibits apoptosis through the activation of the phosphatidylinositol 3-kinase/Akt pathway in pituitary cells.

In previous studies we demonstrated that IGF-I induces proliferation of pituitary lactotrophs. In addition to its mitotrophic actions, IGF-I is known to prevent apoptosis induced by diverse stimuli in several cell types. In this study, we investigated the action of IGF-I on pituitary cell survival and the intracellular signaling transduction pathway implicated in this effect. Treatment of cultured male rat pituitary cells with IGF-I (10(-7) M) for 24 h prevented pituitary cell death induced by serum deprivation. The protective effect of IGF-I was blocked by phosphoinositide 3-kinase (PI3-kinase) inhibitor, LY294002, but was unaffected by PD98059, which inhibits MAP/ERK kinase (MEK1). IGF-I activation of PI3-kinase induced the phosphorylation and activation of the serine/threonine kinase Akt. Moreover, IGF-I increased the phosphorylation of the pro-apoptotic factor Bad and the levels of the anti-apoptotic protein Bcl-2 through the PI3-kinase pathway in primary pituitary cells.

Blockade by met-enkephalin antiserum of analgesia induced by substance P in mice.

In the tail-flick test in mice, the intraventricular administration of Substance P (10-5,000 ng/mouse) produced a naloxone-reversible analgesic effect of rapid onset and long duration. The dose-response curve was bell-shaped, the analgesic effect being smaller after the largest doses. The analgesia was blocked by concomitant intraventricular administration of the antibody against met-enkephalin but not by the antibody against beta-endorphin. In the hot plate assay, Substance P produced analgesia in mice with high sensitivity to pain, and hyperalgesia in mice with lower sensitivity to pain than normal. The analgesia was blocked by the antibody against met-enkephalin but the hyperalgesia or the scratching response were not modified by the antiserum. The results appear to indicate a dual effect, analgesic or hyperalgesic, of Substance P in mice, the former probably being mediated by release of met-enkephalin.

Insulin-like growth factor I-immunoreactive peptide in adult human cerebellar Purkinje cells: co-localization with low-affinity nerve growth factor receptor.

It has been proposed that Insulin-like growth factor I is involved in the development, growth and maintenance of the central nervous system possibly interacting with other trophic factors. High levels of insulin-like growth factor I have been detected in the cerebellum during development and adulthood suggesting a specific role for insulin-like growth factor I in this brain area. While there is ever increasing data regarding the cell types containing endogenous insulin-like growth factor I in the rat brain, no information on the human brain is yet available. In the present study we sought to analyse the precise location of insulin-like growth factor I peptide in the adult human cerebellum using a specific antiserum against recombinant human insulin-like growth factor I. After immunocytochemistry, numerous Purkinje cells exhibited intense positive staining occupying the cell soma, dendrites and dendritic spines as well as axons. Occasionally, immunoreactive Purkinje cell axons were arciform and exhibited bulbous dilatations along their proximal length. Putative recurrent collaterals of Purkinje cell axons were also insulin-like growth factor I reactive. Double-staining immunocytochemistry in the same sections consistently showed, as expected, co-expression of insulin-like growth factor I and calbindin, although a few calbindin containing Purkinje cells lacked insulin-like growth factor I immunostaining suggesting there are insulin-like growth factor I positive Purkinje cell subsets in the human cerebellum. In addition, co-expression of insulin-like growth factor I and low-affinity nerve growth factor receptor-immunoreactive protein was found in a subpopulation of insulin-like growth factor I positive Purkinje cells. The results of this study prove the presence of insulin-like growth factor I immunoreactivity in a Purkinje cell subpopulation of the adult human cerebellum suggesting that insulin-like growth factor I may participate in paracrine or autocrine regulatory systems in the adult human brain.

Tissue-specific response of IGF-I mRNA expression to obesity-associated GH decline in the male Zucker fatty rat.

Diminished GH secretion is a well known association of obesity. As in obese humans, Zucker fatty rats develop a progressive GH deficiency, present at 6 weeks of age and maximal at 10 to 12 weeks. The aim of this study was to investigate the GH dependence of IGF-I gene expression in liver and extrahepatic tissues of the obese Zucker rat as a model of progressive GH reduction during adult life. Six- and 11-week-old obese Zucker rats and their lean littermates were used to compare body weight, glycemia, insulinemia, serum GH and IGF-I levels and IGF-I mRNA expression in liver, heart, aorta, kidney and skeletal muscle. In comparison with lean controls, obese Zucker rats showed at both ages comparable glycemia, severe hyperinsulinemia (mU/ml, mean+/-s.e.m.; 6 weeks 138+/-10 vs 45+/-6 P<0.001; 11 weeks 147+/-14 vs 46+/-3, P<0.001) and lower GH (ng/ml; 6 weeks 1.7+/-0.9 vs 2.7+/-1.1; 11 weeks 1.5+/-0.9 vs 4.2+/-1.2) in the presence of similar circulating IGF-I levels (ng/ml; 6 weeks 774+/-26 vs 694+/-28; 11 weeks 1439+/-182 vs 1516+/-121). Hepatic IGF-I mRNA expression was already reduced at 6 weeks of age due to a significant decrease in the IGF-Ib transcript compared with lean controls (relative units; IGF-Ia: 99+/-2% vs 100+/-5%; IGF-Ib: 69+/-10% vs 100+/-2%, P<0.05) and this reduction was more marked in 11-week-old animals when both IGF-I transcripts were significantly diminished (relative units; IGF-Ia: 80+/-6% vs 100+/-1%, P<0.05; IGF-Ib: 65+/-5% vs 100+/-2%, P<0.01). Extrahepatic tissues expressed almost exclusively the IGF-Ia transcript, the amount of which relative to controls was: (1) similar at 6 weeks and decreased at 11 weeks in kidney and skeletal muscle extracts (relative units; kidney: 6 weeks 88+/-10% vs 100+/-2%; 11 weeks 76+/-3% vs 100+/-4%, P<0.05; vastus lateralis: 6 weeks 95+/-7% vs 100+/-10%; 11 weeks 59+/-4% vs 100+/-2%, P<0.001); (2) similar at both ages in thoracic aorta (relative units; 6 weeks 121+/-6% vs 105+/-5%; 11 weeks: 91+/-14% vs 100+/-4%); and (3) increased at both ages in left ventricle extracts (relative units; 6 weeks 114+/-2% vs 99+/-9%, P<0. 05; 11 weeks 119+/-7% vs 95+/-3%, P<0.05). -specific dependence of IGF-I mRNA on GH levels during adulthood, reflected by the different behavior of IGF-I expression for each tissue in conditions of progressive decrease of GH levels.