scholarly journals Metabolic Changes Associated with Endocrine Activity and the Reproductive Cycle in Xenopus Laevis

1933 ◽  
Vol 10 (2) ◽  
pp. 186-195
Author(s):  
H. A. SHAPIRO ◽  
H. ZWARENSTEIN
Keyword(s):  
Xenopus Laevis ◽  
Serum Calcium ◽  
Colour Change ◽  
White Background ◽  
Ovarian Activity ◽  
Endocrine Gland ◽  
Pars Tuberalis ◽  
Posterior Lobe ◽  
Endocrine Activity ◽  
Pars Anterior

1. A new micro-method for the estimation of serum calcium requiring only 0.4 C.C. serum is described. 2. Castration causes a persistent fall (17-24 per cent.) in the calcium content of the serum in females of Xenopus laevis as soon as 2 months after operation. In males there is no effect 3 ½ months after castration but a fall (16 per cent.) 6 months after. 3. Removal of the anterior lobe (i.e.. pars anterior and pars tuberalis) of the pituitary leads to a significantly lower calcium level than removal of the entire gland. 4. Injection of antuitrin into completely hypophysectomised animals causes a rise, injection of pituitrin a fall in serum calcium. Injection of antuitrin into normal animals leads to maximal contraction of melanophores on a black background and injection of pituitrin into normal or completely hypophysectomised toads causes maximal expansion on a white background. 5. When the pars tuberalis regenerates the serum calcium returns to normal concomitantly with the reappearance of the white background response, but without regeneration of the ovaries. 6. The influence of the pituitary on ovarian activity and its effect on serum calcium are concomitant but independent activities. It is suggested that the pars tuberalis and the posterior lobe have antagonistic effects on both colour change and serum calcium, and that the pars anterior and the posterior lobe exert antagonistic influences on ovarian activity. It is further suggested that the pituitary directly controls ovarian activity, but that both the pituitary and the gonads control calcium metabolism through some other endocrine gland.

scholarly journals Metabolic changes associated with pigmentary effector activity and pituitary removal in Xenopus lævis —I. Respiratory exchange

1931 ◽  
Vol 107 (753) ◽  
pp. 486-503 ◽  
Keyword(s):  
Xenopus Laevis ◽  
Pituitary Gland ◽  
Colour Change ◽  
Great Difficulty ◽  
White Background ◽  
Ovarian Activity ◽  
Posterior Lobe ◽  
Time Curve ◽  
Field Of Vision ◽  
Effector Activity

There are various indications of connection between the pituitary gland and basal metabolism; between the pituitary gland and ovarian activity; and between ovarian activity and calcium metabolism. Progress in the study of the relationship of the pituitary to metabolism had been held back by the technical difficulties of mammalian hypophysectomy. By a method described by Hogben, the removal of the pituitary gland as a whole or of the anterior lobe alone can be performed without great difficulty and with great rapidity in adult Amphibia. The animals survive the operation indefinitely. The same author has shown that the posterior lobe of the pituitary gland plays a predominent rôle in controlling colour change, and latterly, in collaboration with Slome, has given strong indications that the anaterior lobe of the gland also plays a part in determining the pigmentary effector activity of the South African clawed toad, Xenopus lævis (Daudin). These circumstances have suggested the advisability of parallel investigation of the effects of the total or partial removal of the pituitary gland and the influence of normal agencies affecting colour change (and thereby pituitary activity) upon the metabolism of this species. The present communication is connected with two issues:— 1. Total respiratory exchange in air. 2. Dermal oxygen consumption in water. The conditions affecting colour response, and the time relations of colour response, etc., in Xenopus lævis , have been recorded thoroughly (Slome and Hogben). These authors have shown that photic stimuli are the predominant natural agencies, the condition for pallor being that the field of vision is occupied by a light-scattering surface, and the condition for darkening that the field of vision is occupied by a light-absorbing surface. Eyeless animals are intermediate in hue but the condition of eyeless animals or animals kept in the dark has been shown to be physiologically different from intermediat animals in a stage of transition from the white background to the black blackground response and vice versa . This conclusion, based on an analysis of the time curve, receives some confirmation from the data hereafter recorded.

scholarly journals Metabolic Changes Associated with Endocrine Activity and the Reproductive Cycle in XENOPUS LAEVIS

1934 ◽  
Vol 11 (3) ◽  
pp. 267-272
Author(s):  
H. A. SHAPIRO ◽  
H. ZWARENSTEIN
Keyword(s):  
Xenopus Laevis ◽  
Serum Calcium ◽  
Normal Level ◽  
Calcium Level ◽  
Calcium Metabolism ◽  
Serum Calcium Level ◽  
Intact Animal ◽  
Ovarian Tissue ◽  
Endocrine Activity ◽  
Gonadotropic Hormone

1. Experiments are described which show that active extracts of ovarian tissue minus corpus luteum can be obtained which significantly raise the lowered level of the serum calcium in ovariectomised toads; and also raise the serum calcium level in normal toads above the normal level. 2. Injection of adequate doses of antuitrin (Parke, Davis and Co.), raises the lowered level of serum calcium in hypophysectomised toads almost to normal; and of ovariectomised toads to the normal level. The effect is obtained more readily in the ovariectomised condition. 3. Injection of pituitrin (Parke, Davis and Co.), depresses the serum calcium level in normal, ovariectomised and completely hypophysectomised toads. The effect is more readily obtained in the normal intact animal than in the ovariectomised or the totally hypophysectomised state, when the ovaries have undergone involution. 4. It is suggested that there is evidence that the principles exerting a hormonelike action on calcium metabolism are not, in the case of the ovary, either oestrin or the luteal hormone, or in the case of the pituitary, the gonadotropic hormone.

Histopathology of pituitary tumours

2011 ◽  
pp. 121-127
Author(s):  
Eva Horvath ◽  
Kalman Kovacs
Keyword(s):  
Mammalian Species ◽  
Cell Types ◽  
Pars Intermedia ◽  
Pars Tuberalis ◽  
Posterior Lobe ◽  
Human Pituitary ◽  
Human Pituitary Gland ◽  
Fibre Network ◽  
Pars Anterior ◽  
A Minor

The human pituitary gland consists of two major components: the adenohypophysis comprising the hormone producing cells of the pars anterior, pars intermedia, and pars tuberalis, and the neurohypophysis, also called pars nervosa or posterior lobe (1). In contrast to most mammalian species, the human gland has no anatomically distinct pars intermedia (2). The exclusively proopiomelanocortin (POMC)-producing cells of the pars intermedia are sandwiched between the anterior and posterior lobes in the majority of mammals, whereas in the human they are incorporated within the pars anterior, thereby constituting the pars distalis (3). The pars tuberalis is a minor upward extension of the adenohypophysis attached to the exterior of the lower pituitary stalk. In this chapter we deal only with adenohypophyseal tumours. Histologically, the adenohypophysis consists of a central median (or mucoid) wedge flanked by the two lateral wings. The hormone-producing cell types are distributed in an uneven, but characteristic manner. The cells are arranged within evenly sized acini surrounded by a delicate but well-defined reticulin fibre network giving the pituitary its distinct architecture (4). In the center of the acini is the long-neglected pituitary follicle composed of the agranular nonendocrine folliculo-stellate cells (5).

scholarly journals Metabolic Changes Associated with Endocrine Activity and the Reproductive Cycle in Xenopus Laevis

1933 ◽  
Vol 10 (3) ◽  
pp. 201-203
Author(s):  
H. ZWARENSTEIN
Keyword(s):  
Serum Potassium ◽  
Potassium Level ◽  
Serum Potassium Level ◽  
Anterior Lobe ◽  
Potassium Content ◽  
Pars Tuberalis ◽  
Main Constituent ◽  
Endocrine Activity ◽  
Pars Anterior ◽  
Subsequent Regeneration

1. Removal of both lobes of the pituitary gland, or of the anterior lobe (i.e. pars anterior and pars tuberalis) alone lead to a 22 per cent. fall in the potassium content of the serum. 2. Subsequent regeneration of the pars tuberalis has no effect on the lowered serum potassium level. 3. It is suggested that the pars anterior is the main constituent of the pituitary controlling, directly or indirectly, the potassium content of the serum.

scholarly journals The pigmentary effector system VIII—The dual receptive mechanism of the amphibian background response

1936 ◽  
Vol 120 (817) ◽  
pp. 158-173 ◽  
Keyword(s):  
Normal Animal ◽  
The Other ◽  
White Background ◽  
Pars Intermedia ◽  
Pars Tuberalis ◽  
General Hypothesis ◽  
Common Path ◽  
Black Background ◽  
To Come ◽  
Stimulation Of

In a previous contribution (Hogben and Slome, 1931) evidence was brought forward to show that the white background response does not depend on the same mechanism of coordination as the black background response, which is produced by reflex liberation of a hormone (“B” substance) of the pars intermedia in the pituitary gland; and experiments pointing to the existence of another internal secretion (“W” substance), connected directly or indirectly with the activity of the pars tuberalis, were described. The existence of separate receptor components of the retina controlling the two systems was left for subsequent enquiry. Of two possible hypotheses concerning the nature of the receptive mechanism, the most likely one is illustrated diagrammatically in fig. 1. In normal situations, when an animal is illuminated on a black background, light can only fall on the floor of the retina. If it is aquatic, the maximum divergence of any two rays which strike the eye is twice the critical angle for air and water, so that in the absence of reflexion of rays from sur­rounding objects below the surface of separation all rays will presumably be brought to a sharp focus in shallow water. There are thus three distinct possibilities which arise from the way in which the animal is illuminated if, as in Xenopus , the eyes are situated on the top of the head: ( a ) in darkness no part of the retina is stimulated, the same being true of the eyeless animal; ( b ) when the animal is exposed to a black background only a sharply localized region of the retina is stimulated; ( c ) when the animal is exposed to a white background the whole of the retina is illuminated owing to the scattering of rays in all directions from the surroundings. For convenience of description the usual black back­ground situation will be described hereafter as one in which only the “floor” of the retina is stimulated, and the white background situation as one in which the floor and the “ periphery ” of the retina are both stimulated together. If then, the receptor elements of the floor and periphery initiate different systems of reflex arcs the phenomena of the background response in Amphibia and Reptiles may be interpreted as follows. In Reptiles we may suppose that stimulation of floor reflexly excites the melanophores to expand, while stimulation of peripheral photoreceptors excites them to contract, being presumably prepotent in the final common path. In Amphibia two alternatives may be con­sidered: ( a ) that floor elements reflexly excite liberation of “B” and that peripheral photoreceptors, being prepotent, reflexly inhibit libera­tion of “B"; ( b ) that floor elements reflexly excite liberation of “B”, and peripheral photoreceptors reflexly excite production of the antago­nistic substance “W” in quantity sufficient to over-ride the effect of “B”. The crucial test of the truth of the general hypothesis that the floor and peripheral elements of the retina initiate different processes of coordina­tion was suggested by Keeble and Gamble (1904-6) in their experiments on Crustacea. If it is true, a normal animal illuminated from below in a black tank with a white top should react in exactly the same way as a normal animal when illuminated in a black tank from above. On the other hand, a normal animal illuminated from below in a black tank with a black top should react like an eyeless animal in the same situation, because the floor elements would not be subject to stimulation. The experiment may be varied as indicated below. In order to obtain signi­ficant results two classes of precautions must be carefully observed. One is that the physical dimensions of the tank must not exceed certain limits, since the maximal divergence of two rays is rigidly fixed when an animal is illuminated from above. The other is that there must be no air-water interface to permit reflexion of the incident rays downwards. Aside from the fact that no bubbles must be allowed to collect, this condition presents a practical difficulty if the animal has to come to the surface to breathe.

THE RELATION OF ENDOGENOUS MELANOPHORE-EXPANDING HORMONE TO HYPERGLYCAEMIA IN XENOPUS LAEVIS

1957 ◽  
Vol 15 (2) ◽  
pp. 190-198 ◽  
Author(s):  
K. A. MUNDAY
Keyword(s):  
Xenopus Laevis ◽  
Blood Sugar ◽  
Water Injection ◽  
White Background ◽  
Glycaemic Response ◽  
Effective Agent ◽  
Black And White ◽  
Lower Blood ◽  
Effective Level ◽  
Sugar Levels

SUMMARY 1. Xenopus laevis responds to injected adrenaline by an increase in the level of blood sugar. This increased blood sugar is apparently derived from liver and not from muscle glycogen. 2. Blood-sugar levels of Xenopus equilibrated on a black background (BB) and on a white background (WB) are statistically different throughout 6 months' starvation (P<0·05). On prolonged starvation for 14–16 months the lower blood-sugar level recorded in WB animals is not statistically different from that in BB animals (P> 0·10). 3. Xenopus shows a marked excitation hyperglycaemia, which is thought to be due to secretion of endogenous adrenaline. This hyperglycaemia is greatest in animals kept on a white background. 4. Xenopus equilibrated on black and white backgrounds show different hyperglycaemic responses to similar doses of adrenaline (P < 0·01). Compared with their own 'control-distilled water injection' levels, WB animals show an increase of blood sugar 40% higher than BB animals. 5. If melanophore-expanding hormone ('B') is an effective agent in decreasing the hyperglycaemic response to adrenaline, the greater effective level of circulating hormone in BB animals, together with their relatively reduced glycaemic response, supports the view that endogenous 'B' hormone plays a role in normal carbohydrate metabolism.

scholarly journals The Murine Stanniocalcin 2 Gene Is a Negative Regulator of Postnatal Growth

Endocrinology ◽  
2008 ◽  
Vol 149 (5) ◽  
pp. 2403-2410 ◽  
Author(s):  
Andy C.-M. Chang ◽  
Jeff Hook ◽  
Frances A. Lemckert ◽  
Michelle M. McDonald ◽  
Mai-Anh T. Nguyen ◽  
...  
Keyword(s):  
Serum Calcium ◽  
Physiological Role ◽  
Postnatal Growth ◽  
Negative Regulator ◽  
Endocrine Gland ◽  
Mammalian Tissues ◽  
Igf I ◽  
Stanniocalcin 2 ◽  
Related Proteins ◽  
Similar Growth

Stanniocalcin (STC), a secreted glycoprotein, was first studied in fish as a classical hormone with a role in regulating serum calcium levels. There are two closely related proteins in mammals, STC1 and STC2, with functions that are currently unclear. Both proteins are expressed in numerous mammalian tissues rather than being secreted from a specific endocrine gland. No phenotype has been detected yet in Stc1-null mice, and to investigate whether Stc2 could have compensated for the loss of Stc1, we have now generated Stc2−/− and Stc1−/−Stc2−/− mice. Although Stc1 is expressed in the ovary and lactating mouse mammary glands, like the Stc1−/− mice, the Stc1−/−Stc2−/− mice had no detected decrease in fertility, fecundity, or weight gain up until weaning. Serum calcium and phosphate levels were normal in Stc1−/−Stc2−/− mice, indicating it is unlikely that the mammalian stanniocalcins have a major physiological role in mineral homeostasis. Mice with Stc2 deleted were 10–15% larger and grew at a faster rate than wild-type mice from 4 wk onward, and the Stc1−/−Stc2−/− mice had a similar growth phenotype. This effect was not mediated through the GH/IGF-I axis. The results are consistent with STC2 being a negative regulator of postnatal growth.

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