Floral transcription factor AGAMOUS interacts in vitro with a leucine-rich repeat and an acid phosphatase protein complex.

We are interested in identifying potential protein interactors of MADS domain transcription factors during Arabidopsis thaliana flower development. We based our biochemical search on a conserved motif in the MADS domain that includes putative phosphatase and phosphorylation sites that may mediate protein interactions. An affinity column with this motif and a few surrounding hypervariable amino acids derived from the AGAMOUS sequence was prepared and used to isolate potential interactors from floral crude extracts. Only two proteins were specifically bound to the affinity column. The first corresponds to a carpel specific storage protein, VSP1, that presents acid phosphatase activity, and the second is a novel leucine-rich repeat protein that we have named FLOR1. Coimmunoprecipitation, two-hybrid yeast, and affinity column assays show that the FLOR1-VSP1 complex interacts with AGAMOUS and that this transcription factor directly interacts with FLOR1. This is the first assay to show an interaction between plant MADS domain factors and non-MADS proteins.

Arginine-vasopressin in nucleus of the tractus solitarius induces hyperglycemia and brain glucose retention.

Hypothalamic arginine-vasopressin (AVP) plays an important role both as a neurotransmitter and hormone in the regulation of blood glucose and feeding behavior. AVP-containing axons from the parvocellular subdivision of paraventricular nucleus of the hypothalamus terminate in the nucleus of the tractus solitarius (NTS), but the function of this projection is not known. Interestingly, the NTS also receives afferent information from the carotid body and other peripheral receptors involved in glucose homeostasis. We have previously reported that stimulation of the carotid body receptors initiates a hyperglycemic reflex and increases brain glucose retention. Here we show that direct administration of micro-doses of AVP into the NTS of anesthetized or awake rats rapidly increased the levels of blood glucose concentration and brain arterio-venous (A-V) glucose difference. This effect was not observed when the same doses of AVP were injected in the brainstem outside NTS. Arginine-vasopressin antagonist microinjections alone produced a small but significant reduction in brain A-V glucose. Pre-administered VP1-receptor antagonist [beta-mercapto-beta,beta-cyclopentamethylene-propionyl(1),O-Me-Tyr(2),Arg(8)]vasopressin blocked the effects of AVP. These results indicate that AVP acting on its receptors locally within the NTS participates in glucose homeostasis, increasing both blood glucose concentration and brain A-V glucose differences. Hypothalamic AVP may facilitate hyperglycemic responses initiated by peripheral signals processed at the level of the NTS.

Parotid gland tissue is able partially to assume pituitary functions under the influence of hypothalamic factors: in vivo and in vitro studies.

To test whether salivary tissue can secrete pituitary hormones, female Sprague-Dawley rats were hypophysectomized (hypox) and the following were transplanted to the sella turcica: parotid gland (group 3, n=33), adrenal gland (group 4, n=30), muscle (group 5, n=24). Group 2 (n=21) had the sella turcica filled with dentist's cement. In addition a group of rats (group 1, n=22) remained intact as controls. All groups were followed for 8 months. Daily vaginal smears showed normal cyclicity in controls and constant dioestrus in all hypox groups. Blood samples, taken once every 30 days before and after LHRH stimulation, showed significantly lower (P<0.001) plasma LH values in all hypox groups compared with controls. In group 3, a gradual and significant increase (P<0.05) was observed in the LH response to LHRH in parallel with a partial recovery of oestrous smears. No LH modification was observed in the other hypox groups. Plasma prolactin (PRL) levels were also very low in all hypox groups and were unaltered throughout the study. At the end of the experiments, half the animals were killed by decapitation and the hypothalamic-pituitary areas carefully dissected, homogenized and analysed for LH and PRL content. The remaining animals were perfused with 4% paraformaldehyde to obtain fixing of the whole body tissues. Hypothalamic and transplant areas were carefully dissected, frozen, cut and submitted to immunochemical procedures. LH content in the graft of group 3 animals was markedly (P<0.001) lower than in the control pituitary, but significantly higher (P<0.05) than in the other hypox groups. Immunochemistry showed LH and PRL positive cells in the graft of group 3 animals, whereas neither positive cells, nor LH content were observed in the parotid gland in situ. Experiments were completed with in vitro cultures of parotid glands in the presence or absence (controls) of synthetic hypothalamic hormones or rat hypothalamic extracts. After 1.5 weeks of culture, a significantly higher LH concentration (P<0.05) was observed in the wells treated with synthetic hypothalamic hormones (216+/-46 pg/ml vs 41+/-6 pg/ml in controls). When hypothalamic extracts were used, the LH levels increased more markedly (1834+/-190 pg/ml vs 36+/-6 pg/ml in controls) and those values were maintained during 3 weeks of culture. Immunostaining of these cultures showed a positive LH reaction in the epithelial cells found in the hypothalamic extract-treated wells. Both in vivo and in vitro studies confirm the transdifferentiation of parotid gland tissue to pituitary hormone-producing cells under hypothalamic influence.

Pituitary and adrenals are required for hyperglycemic reflex initiated by stimulation of CBR with cyanide.

We have previously shown that stimulation of carotid body receptors (CBR) with sodium cyanide (NaCN) elicits a rapid hyperglycemic reflex. Here we explore whether the pituitary and adrenals, two glands involved in glucose homeostasis, are necessary for this reflex. Experiments were performed on anesthetized rats that were artificially ventilated. Measurements of hepatic venous-arterial glucose difference indicated that CBR stimulation with a bolus of 5 micrograms/100 g NaCN produced an immediate increase in the output of glucose by the liver. The same dose of NaCN failed to increase hepatic output of glucose in rats with bilateral adrenalectomy or in rats 1 wk after surgical removal of neurohypophysis. Reflex glucose output by the liver was maintained after adenohypophysectomy or in adrenalectomized rats after adrenal autotransplantation to epiploon. Measurements of epinephrine in plasma and in the grafted adrenal tissue showed that the adrenal autograft can store and secrete catecholamines Immunocytochemical observations indicated that the grafted adrenals retain medullary cells. These results indicate that neurohypophysis and adrenals are necessary for the hyperglycemic reflex initiated by CBR stimulation with NaCN and that the participation of these two organs in this reflex is probably humoral.

Influence of the pituitary gland on the immune response in young rats.

The response of hypophysectomized (HYPOX) and sham-operated (S-HYPOX) female and male Wistar young rats (8 weeks old) to antigenic stimulation was compared. Humoral antigenic responses against hemocyanin were measured by ELISA. [3H]thymidine incorporation into cultured spleen cells was used to determine proliferative response to concanavalin A (ConA) or antigenic stimulation. Anti-hemocyanin serum titers in the HYPOX animals was about half of that observed in control S-HYPOX rats. Similarly, the cellular proliferative response was significantly decreased in HYPOX animals when compared to S-HYPOX rats; the blastogenic response to hemocyanin in UC rats (which did not receive the antigen injection) was close to zero. S-HYPOX control rats responded to direct ConA stimulation as UC controls. Body weight and the weight of pituitary target organs (adrenal, thyroid, ovary and testes) was about 1/4 of that of controls. Hypophysectomy also resulted in a striking reduction in spleen weight. These results indicate that the pituitary gland is involved in cellular and humoral immune regulation in young rats.

Changes in blood glucose concentration in the carotid body-sinus modify brain glucose retention.

To test whether blood glucose concentration in the carotid body-sinus may influence the amount of glucose retained by the brain, the isolated carotid sinus was perfused with glucose-rich blood or glucose-poor blood from a second animal. The circulation of the right carotid body-sinus was temporarily isolated in rat A, and perfused with blood coming from rat B. Blood glucose in rat B was modified by injections of glucose or insulin. Changes in glucose retention by the brain were measured in rat A. When the isolated carotid body-sinus in rat A was perfused with hyperglycemic blood (16.7 mM), brain glucose retention in rat A decreased significantly from 0.14 +/- 0.02 mumol/g/min (t = 0) to 0.08 +/- 0.01 mumol/g/min at 4 min after the beginning of perfusion. In contrast, the perfusion of the isolated carotid body-sinus of rat A with hypoglycemic blood (2.7 mM) from rat B, had the opposite effect. Brain glucose retention in rat A increased (0.23 +/- 0.03 mumol/g/min) at t = 4 min in comparison to control values (0.13 +/- 0.01 mumol/g/min). Chemoreceptor activity was also manipulated by the injection of cyanide (NaCN) in rat B, under these conditions, brain glucose retention in rat A increased from 0.13 +/- 0.01 mumol/g/min to 0.28 +/- 0.03 mumol/g/min between 4 to 8 min after the beginning of perfusion. These results indicate that chemosensory activity within the carotid body-sinus, superfused in vivo with different glucose concentrations, modify glucose retention by the brain.

Developmental changes in blood glucose and tissue carbohydrates in the fetal rat: effects of insulin and adrenaline.

The ontogeny of glucose regulation was studied in the rat by measuring the levels of plasma glucose, tissue glucose and tissue glycogen from fetal day 15 (E15) to adulthood. Since insulin and adrenaline are important glucose regulators in the adult, we also tested the effects of these hormones on above variables. The main findings are the following: 1) Umbilical blood glucose was very low (25 mg/100 ml) from E15 to E19, increasing to 66 mg/100 ml by E21 but still below maternal levels (110 mg/100 ml). 2) Umbilical venous-arterial (VEN-ART) glucose differences were very small (1 mg/100 ml) from E15 to E17, increased to 6 mg/100 ml by E19, but dropped again becoming negative (-15 mg/100 ml) just before birth when umbilical arterial blood glucose rose above venous blood glucose. 3) Glucose and glycogen concentrations rose drastically in liver towards the end of gestation. 4) Tissue glycogen and, to a much lesser degree, glucose, fell after birth to rise again in adulthood. 5) Insulin injection caused an increase in liver glycogen from E17 onwards, and also increased glycogen in brain and placenta on E19. However, insulin decreased glycogen in brain and kidney by E21. 6) Adrenaline caused an increase in the umbilical venous-arterial glucose difference at E15 and E17 with a concomitant increase in liver, brain and heart glycogen at E15. By E21 the response of liver glycogen to adrenaline was drastically reversed. Our data suggest that the mechanism regulating glucose homeostasis changes half way through fetal development. Tissue self-regulation is replaced with a centralized mechanism similar to that of the adult.(ABSTRACT TRUNCATED AT 250 WORDS)

Developmental changes in blood glucose and tissue carbohydrates in the fetal rat: effects of insulin and adrenaline.

The ontogeny of glucose regulation was studied in the rat by measuring the levels of plasma glucose, tissue glucose and tissue glycogen from fetal day 15 (E15) to adulthood. Since insulin and adrenaline are important glucose regulators in the adult, we also tested the effects of these hormones on above variables. The main findings are the following: 1) Umbilical blood glucose was very low (25 mg/100 ml) from E15 to E19, increasing to 66 mg/100 ml by E21 but still below maternal levels (110 mg/100 ml). 2) Umbilical venous-arterial (VEN-ART) glucose differences were very small (1 mg/100 ml) from E15 to E17, increased to 6 mg/100 ml by E19, but dropped again becoming negative (-15 mg/100 ml) just before birth when umbilical arterial blood glucose rose above venous blood glucose. 3) Glucose and glycogen concentrations rose drastically in liver towards the end of gestation. 4) Tissue glycogen and, to a much lesser degree, glucose, fell after birth to rise again in adulthood. 5) Insulin injection caused an increase in liver glycogen from E17 onwards, and also increased glycogen in brain and placenta on E19. However, insulin decreased glycogen in brain and kidney by E21. 6) Adrenaline caused an increase in the umbilical venous-arterial glucose difference at E15 and E17 with a concomitant increase in liver, brain and heart glycogen at E15. By E21 the response of liver glycogen to adrenaline was drastically reversed. Our data suggest that the mechanism regulating glucose homeostasis changes half way through fetal development. Tissue self-regulation is replaced with a centralized mechanism similar to that of the adult.(ABSTRACT TRUNCATED AT 250 WORDS)

Developmental changes in blood glucose and tissue carbohydrates in the fetal rat: effects of insulin and adrenaline.

The ontogeny of glucose regulation was studied in the rat by measuring the levels of plasma glucose, tissue glucose and tissue glycogen from fetal day 15 (E15) to adulthood. Since insulin and adrenaline are important glucose regulators in the adult, we also tested the effects of these hormones on above variables. The main findings are the following: 1) Umbilical blood glucose was very low (25 mg/100 ml) from E15 to E19, increasing to 66 mg/100 ml by E21 but still below maternal levels (110 mg/100 ml). 2) Umbilical venous-arterial (VEN-ART) glucose differences were very small (1 mg/100 ml) from E15 to E17, increased to 6 mg/100 ml by E19, but dropped again becoming negative (-15 mg/100 ml) just before birth when umbilical arterial blood glucose rose above venous blood glucose. 3) Glucose and glycogen concentrations rose drastically in liver towards the end of gestation. 4) Tissue glycogen and, to a much lesser degree, glucose, fell after birth to rise again in adulthood. 5) Insulin injection caused an increase in liver glycogen from E17 onwards, and also increased glycogen in brain and placenta on E19. However, insulin decreased glycogen in brain and kidney by E21. 6) Adrenaline caused an increase in the umbilical venous-arterial glucose difference at E15 and E17 with a concomitant increase in liver, brain and heart glycogen at E15. By E21 the response of liver glycogen to adrenaline was drastically reversed. Our data suggest that the mechanism regulating glucose homeostasis changes half way through fetal development. Tissue self-regulation is replaced with a centralized mechanism similar to that of the adult.(ABSTRACT TRUNCATED AT 250 WORDS)

Changes in brain glucose retention produced by the stimulation of an insulin-sensitive reflexogenic zone in rats.

Although it has been reported that insulin decreases glucose efflux from the brain causing an increase in brain glucose retention, its mechanism of action is still unknown. The present results indicate that peripheral insulin may act through the stimulation of insulin-sensitive receptors localized in the region irrigated by the coeliac trunk and innervated by the vagus nerve. Stimulation of this zone in anaesthetized, artificially ventilated rats with a bolus millidose of insulin (50 mU) caused a significant increase in brain glucose retention as a result of decreased glucose efflux from the brain. The same dose of insulin injected 1-2 cm caudally in the abdominal aorta below the coeliac trunk failed to increase brain glucose retention. The effects of insulin above the coeliac trunk disappear when the vagus nerve is sectioned, suggesting that the vagus participates as the afferent pathway of this reflex.

Technical note: removal of the unfragmented pituitary gland (hypophysectomy) in the rat.

A technique to excise the pituitary gland (hypophysis) in rats is described. The basisphenoid bone is reached from the ventral neck and is perforated to expose the pituitary gland and its stalk. An aspirator allows the removal of the hypophysis and the stalk, including pars tuberalis, in one piece. The advantages of this new technique include: 1) immediate verification of the entirety of hypophysectomy; 2) broad operating field which exposes the pituitary stalk up to the hypothalamus; 3) the use of tracheal intubation and artificial respiration to improve postoperative recovery and to allow expanded operation field even during prolonged surgery. Pre- and postoperative care are described. The mean survival rate after this type of operation was 79% in rats weighing 50 to 130 g and 90% in rats larger than 130 g.

Compensation by fetal erythrocytes of plasma glucose changes in rats.

Changes in plasma glucose and glucose and glycogen content in fetal erythrocytes (FRBCs) were studied in rats between days 15 and 21 of gestation and in adult rats. Plasma and FRBC glucose concentrations increased during fetal life and were higher in erythrocytes than in plasma. Glycogen was higher in FRBCs than in adult erythrocytes and tended to decrease from day 15 to 19 of gestation and to increase again on day 21. When FRBCs were incubated in vitro in different glucose concentrations to study their capacity to compensate for changes in plasma glucose concentration, younger cells showed better glucose-buffering capacities. Glucose and glycogen levels in FRBCs increased when they were incubated in high-glucose medium, and the glycogen concentration reached was higher in the early fetal stage than by the end of gestation. Nevertheless, adult erythrocytes accumulated more glycogen in high-glucose medium than cells from any of the fetal-aged erythrocytes. When glucose was injected intraperitoneally into fetuses of different ages, there was an increase of 3.7 microM/ml in glucose concentration in blood from the umbilical artery and 2.5 microM/ml in blood from the umbilical vein. FRBCs buffered some of this change, as evident by an increase in glycogen content. Again, buffering capacity was greater for erythrocytes in younger fetuses. Epinephrine diminished glycogen concentration in venous FRBCs on days 19 and 21 of gestation even in hyperglycemia. Insulin diminished glucose concentration in arterial plasma on days 17 and 21 of gestation, but there were no changes in glucose and glycogen in FRBCs.(ABSTRACT TRUNCATED AT 250 WORDS)

Erythrocytes and glucose homeostasis in rats.

The capacity of erythrocytes to modify their glycogen stores to compensate for changes in glucose concentration in plasma was studied. Experiments in vitro and in vivo demonstrated that erythrocytes absorbed and incorporated glucose into their glycogen stores when glucose concentration in the medium was high and liberated it when the concentration was low. Epinephrine administration inhibited glucose absorption by erythrocytes, and in its presence, erythrocytes liberated glucose from their glycogen stores, being unable to compensate for this rise in glucose concentration in plasma. Similar results were obtained when endogenous secretion of epinephrine was enhanced by carotid sinus-chemoreceptor stimulation. Insulin had no effect on the capacity of erythrocytes to absorb glucose. These data suggest a role for erythrocytes in the transport of glucose to different regions in the organism's circulation and in the regulation of glucose concentration in plasma.

Carotid sinus receptors participate in glucose homeostasis.

This paper describes (a) the influence of glucose on carotid chemoreceptor activity, and (b) the participation of carotid receptors in glucose homeostasis. After eliminating the carotid body baroreceptors in anesthetized cats, the injection of glucose to the vascularly isolated carotid sinus region reduced by 20% the electrical activity of carotid body chemoreceptors and increased their threshold to hypoxia. Mannitol in the same concentration did not change the chemoreceptor activity. A decrease in baroreceptor activity elicited by carotid occlusion, or carotid chemoreceptor stimulation with 50 micrograms/kg cyanide (NaCN), produced an immediate increase in the output of hepatic glucose, raising the hepatic venous-arterial glucose difference above basal levels. Bilateral adrenalectomy eliminated these reflex responses. Cyanide injected in the same conditions caused a sharp increase in glucose retention by the brain. In control experiments, after sectioning the carotid nerve, NaCN injections were ineffective. However, electrical stimulation of the central stump of carotid nerve elicited reflex effects similar to those obtained with NaCN stimulation.

Effects of intracisternal glucose or insulin injections on glucose homeostasis in cat.

The injection of glucose (100 mg) into the cisterna magna of intact anesthetized cats elicited immediate glycosuria and natriuresis without significant changes in blood glucose concentration. Immunoreactive insulin (IRI) increased 140% in plasma, and Na+ concentration decreased in cerebrospinal fluid (CSF). After kidney denervation there was a significant decrease in glucose and Na+ concentrations in urine. Control injections with mannitol did not elicit changes in the studied parameters. Abdominal vagotomy abolished the rise in IRI levels and the decrease in Na+ concentration in CSF. Vagotomy or adrenalectomy also attenuated the glycosuria and the rise in urine Na+ concentration. The intracisternal injection of insulin (0.5 U/kg) caused first, a decrease in glucose concentration in CSF and afterwards a longer latency in plasma. Again, these responses were significantly attenuated when insulin was administered in vagotomized cats. These experiments indicate that the nervous system, through the vagi, adrenal glands, and kidneys, plays an important role in glucose homeostasis after increasing glucose or insulin levels in the CSF above physiologic concentrations. The results obtained with a denervated kidney confirm the participation of nervous system in the effector mechanism that brings the sugar and Na+ into the urine. Evidence is presented for an interrelationship between glucose and Na+ concentrations in blood, urine, and CSF.

Reflex hypoglycemia initiated by insulin.

The injection of a bolus of insulin (40 millimicrons) in the coeliac trunk in anesthetized rabbits elicits an immediate rapid rise of arterial IRI. Inferior vena cava and jugular glucose levels drop precipitously 2 min after insulin injection, increasing the A-V glucose difference. The same amount of insulin injected via the coeliac trunk in abdominal-vagotomized rabbits, failed to induce any significant changes in venous glucose concentration and A-V glucose, although there was a similar rise of IRI concentration in arterial plasma. Electrical stimulation of the central stump of the abdominal vagi does not alter the IRI levels in arterial plasma, however, arterial blood glucose increases suddenly, venous blood glucose drops in the first 2 min of stimulation and the A-V glucose difference increases; there are no significant changes in blood flow, arterial pressure and oxygen saturation in cephalic circulation. These data suggest that small amounts of insulin injected or secreted in a zone irrigated by the coeliac trunk, trigger a hypoglycemic reflex. Evidence is provided to suggest that this is by causing a rapid increase in glucose both by the brain and leg muscle mass.