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Ergebnisse der Biologie: Zweiundzwanzigster Band PDF

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ERGEBNISSE DER BIOLOGIE HERAUSGEGEBEN VON H. AUTRUM· E. BUNNING· K. v. FRISCH E. HADORN . A. KUHN· E. MAYR . A. PIRSON J. STRAUB· H. STUBBE· W. WEIDEL REDIGIERT VON HANSJOCHEM AUTRUM ZWEIUNDZWANZIGSTER BAND MIT 55 ABBILDUNGEN SPRINGER-VERLAG BERLIN GOTTINGEN· HEIDELBERG 1960 ISBN-\3: 978-3-540-02510-8 e-ISBN-\3: 978-3-642-94769-8 DOl: 10.1007/978-3-642-94769-8 Aile Rechte, insbesondere das der Obersetzung in fremde Sprachen, vorbehalten Ohne ausdriickliche Genehmigung des Verlages ist es auch nicht gestaltet, dieses Buch oder Teile daraus auf photomechanischem Wege (Photokopie, Mikrokopie) zu vervielfaltigen © by Springer-Verlag oHG. Berlin' G6ltingen . Heidelberg 1960 Die Wiedergabe von Gebrauchsnamen, Handelsnamen, Warenbezeichnungen u')w. in diesem Werk berech tigt auch ohne besondere Kennzeichnung nich t zu der Annahme, daB solche Namen im Sinn der Warenzeichen- und Markenschutz- Gesetzgebung als frei zu betrachten waren und daher von jedermann benutzt werden diirfen Inhal tsverzeichnis JORGENSEN, C. BARKER, Dr., and LARSEN, LIS OLESEN, mag. sc., Copenhagen (Denmark). Comparative aspects of hypothalamic-hypophysial relationships. With 3 Figures. . . . . . . . . . . . . . . . . . . . . . . . . . . . BRAND, THEODOR VON, Professor Dr., Bethesda (USA). Der Stoffwechsel der Trypanosomen. Mit 3 Abbildungen . . . . . . . . . . . . . . . . . . . 30 HAGBARTH, KARL-ERIK, Dr., Uppsala (Sweden). Centrifugal mechanisms of sensory control 47 MOHR, HANS, Dr., Tiibingen. Photomorphogenetische Reaktionssysteme in Pflanzen. 1. Teil: Das reversible Hellrot-Dunkelrot-Reaktionssystem und das Blau-Dunkelrot-Reaktionssystem. Mit 16 Abbildungen1 • 67 REHM, SIGMUND, Dr., Pretoria (Siidafrikanische "C"nion). Die Bitterstoffe der Cucurbitaceen. Mit 2 Abbildungen. 108 PANITZ, REINHARD, Gatersleben. Die cytologischen und genetischen Kon- sequenzen von Inversionen. Mit 27 Abbildungen 138 KARLSON, PETER, Dr., Miinchen. Pheromones . 212 BURKHARDT, DIETRICH, Dr., Miinchen. Die Eigenschaften und Funktionstypen der Sinnesorgane. Mit 4 Abbildungen . 226 N amen verzeic h n is 268 S ach verzeich nis 282 Berichtigung zum Band XXI 1m Inhaltsverzeichnis des Bandes XXI muB es heiBen: SCHONE, HERMANN, Dr., SeewiesenjObb. Die Lageorientierung mit Statolith en- organen und Augen. Mit 5 Abbildungen ................ 161 1 Der 2. Teil dieses Artikels, in dem Reaktionssysteme besprochen werden, bei denen ausschlieBlich kurzwelliges Licht und nahes Citrav iolett wirksam sind, folgt im nachsten Band. Comparative aspects of hypothalamic-hypophysial relationships By C. BARKER J0RGENSEN and LIS OLESEN LARSEN Zoophysiological Laboratory, University of Copenhagen, Denmark With 3 Figures Contents Introduction Evidence of hypothalamic control of pars distalis function 2 Nervous or humoral hypothalamic control? . . . . . . 5 Chemical nature of hypothalamic hormone-releasing factors 6 Comparative anatomy of the hypothalamic-hypophysial region 10 Neurosecretion and site of formation of neurohypophysial hormones 14 Regeneration of neurohypophysial structures . . . . . . . . . . 17 Comparative physiology and evolution of the functions of the neurohypo- physis . . . . . . . . 17 Summary and conclusions 21 Literature . . . . . . . 22 Introduction Until recently studies on hypothalamic-hypophysial relationships almost exclusively dealt with the hypothalamic control of the release of the antidiuretic and oxytocic hormones from the pars nervosa of the neuro- h ypophy sis.1 However, since the late 1940' s a rapidly growing literature has unequivocally demonstrated a hypothalamic control of at least some of the functions of the pars distalis in higher vertebrates, for instance gonadotropic, adrenocorticotropic and thyrotropic functions. Strong evidence supports the theory that this control is mediated by substances 1 The division and nomenclature of the hypophysial region is similar to that used by GREEN (1951) and VVINGSTRAND (1951). The vertebrate hypophysis con- sists of the adenohypophysis and the neurohypophysis. The adenohypophysis can generally be subdivided into a pars distalis and a pars intermedia. The neurohypo- physis is closely connected with the hypothalamus through the hypothalamic- hypophysial tract. It is undivided in cyclostomes and most groups of fishes. In the higher vertebrates, the neurohypophysis is differentiated into a pars nervosa and a median eminence (see p. 13). The following abbreviations and synonyms have been used in the text: ACTH = adrenocorticotropic hormone = corticotropin; CRF = corticotropin-releasing fac- tor; TSH = thyrotropic hormone. Ergebnisse der Biologie XXII 2 C. BARKER J 0RGENSEN and LIS OLESEN LARSEN released in the median eminence and carried with the blood to the pars distalis. Further evidence obtained during the last few years favours the concept that these substances are chemically closely related to the pars nervosa hormones. In the present paper these new discoveries are considered in the light of previous knowledge of the various aspects of hypothalamic-hypophysial relationships in vertebrates, and some consequences to theories on the evolution of neurohypophysial functions are pointed out. Evidence of hypothalamic control of pars distalis function Cyclostomes and fishes. Nothing definite is known about hypothalamic control of pars distalis function in these groups (see p. 15 and 17). Amphibians. Investigations on the effect of transplantation of the pars distalis to other parts of the body have been of great importance in the elucidation of the hypothalamic control of pars distalis function. A few experiments of this kind have been performed on amphibians. In the toad Bufo bufo hypophysectomy immediately causes abnormal appearance of the skin. Moulting is inhibited and the epidermis hyper- keratinizes. The condition of the skin can therefore be used to evaluate hypophysial function. When pars distalis was autografted under the recessus opticus of the brain the toads behaved like hypophysectomized animals, whereas when the gland was exstirpated and regrafted onto the original site, the toads showed normal hypophysial functions as judged from the appearance of the skin. The graft at the heterotopic site was richly vascularized and viable, but cytologically dedifferentiated [JACOB- SOHN and ]0RGENSEN (1956)J. The loss of function of grafts outside the range of hypothalamic influence is not due to irreversible damage of the pars distalis tissue, because regrafting of non-functional autografts from the eye muscle to the original site under the median eminence can result in resumed functioning of the pars distalis (own unpublished results). Frogs, Rana temporaria, with autografted pars distalis in the eye muscle did not reproduce during the spring, whereas frogs with autografts under the median eminence were capable of normal reproduction. Thus gonadotropic secretion of the pars distalis depends upon hypothalamic control. Similar results were obtained with the urodele Triton cristatus [VIVIAN and SCHOTT (1958)]. Hypothalamic influence on the pars distalis has also been revealed in experiments using properly placed hypothalamic lesions. In Triton cristatus lesions in the preoptic area were found to inhibit gonadotropic secretion as shown by loss of spermatogenesis [MAZZI (1952)J. Toads with lesions in the same region ceased moulting (SCHARRER (1934)J. Birds. Hypothalamic control of pars distalis function has not been investigated in reptiles, but in birds gonadotropic activity has been Comparative aspects of hypothalamic-hypophysial relationships 3 found to be under nervous control. Increasing light intensity and day length activate the resting gonads in ducks, but light stimulation (of testes) was inhibited by lesions in the anterior hypothalamus [ASSEN- MACHER (1957)] or by transplanting pars distalis to the anterior eye chamber in hypophysectomized ducks [ASSENMACHER and BENOIT (1958)]. Obviously stimulation by light depends upon intact hypo- thalamic structures and upon close connection between the hypo- thalamus and the pars distalis. In the domestic fowl the timing of release of the ovulation-inducing hormone is apparently under control of the central nervous system [FRAPS (1954, 1955)]. Mammals. From the extensive literature on hypothalamic dependance of pars distalis function in mammals, only a few examples will be cited. Pars distalis grafts placed under the median eminence of hypo- physectomized rats often showed normal gonadotropic activity as judged by oestrus cycles and pregnancy in females and spermatogenesis in males. Even pars distalis tissue of immature donors or of adult male donors was capable of maintaining normal oestrus cycles and pregnancy when placed under the median eminence of female rats. By way of contrast, grafts placed under the temporal lobe of the brain, even when richly vascularized, showed no gonadotropic activity [HARRIS and JACOBSOHN (1952)]. Gonadotropic activity likewise ceased in hypo- physes transplanted to the kidney in female rats. The grafts, however, could resume functioning, as shown by a recurrence of sexual cycles, when retransplanted under the median eminence. In rats with grafts retransplanted from the kidney to the temporal lobe, sexual cycles never recurred. Histologically, the grafts under the temporal lobe, like the kidney grafts, were dedifferentiated, whereas the grafts under the median eminence became redifferentiated with basophils of normal appearance. The loss of cytological differentiation and gonadotropic secretion in pars distalis transplanted to other parts is therefore not due to injury of the tissue but to its loss of contact with the hypothalamus [NIKITOVITCH-WINER and EVERETT (1957)]. The nature of the hypo- thalamic control of gonadotropic activity of the pars distalis in the spontaneously ovulating rat has been studied by means of agents capable of blocking the nervous activation of the pars distalis [EVERETT and SAWYER (1950, 1953), EVERETT (1956)]. In order to block gonadotropin release and accordingly normal ovulation a blocking agent, e. g. atropin, has to be administered within a period of two hours on the day before the expected ovulation. Administration prior to or after this period does not prevent the hypothalamic activation of the pars distalis. Hypothalamic influence on the adrenocorticotropic activity of the pars distalis is obvious from the following examples. Normal rabbits respond to such stimuli as restraint or exposure to cold by releasing ACTH 1* 4 C. BARKER J0 RGENSEN and LIS OLESEN LARSEN from the pars distalis as is evidenced by a reduction of the number of circulating lymphocytes. This lymphopenic response is reduced or abolished by effective separation of the pars distalis from the hypothalamus by section of the hypophysial stalk and insertion of a waxed-paper plate between the cut ends [FORTIER et al. (1957)J. In dogs hypothalamic lesions can reduce the normal rate of adrenal corticoid secretion as is shown by measurements on blood drawn from a permanent canula in the adrenal vein. Less ACTH is released following operative trauma [HUME (1958)]. Appropriate hypothalamic lesions in guinea pigs likewise reduce normal levels of ACTH secretion and abolish the increased secretion which normally follows administration of diphtheria-toxin [SCHMID et al. (1957), WINKLER et al. (1958)J. Liberation of ACTH can also be induced by electrical stimulation of hypothalamus [ENDROCZI et al. (1957), rats; MASON (1958), monkeys]. In normal mammals exposure to cold stimulates the thyrotropic activity of the pars distalis, causing increased release of thyroid hormone. This response to cold was abolished in hypophysectomized rabbits with grafts of pars distalis in the anterior eye chamber [VON EULER and HOLM- GREN (1956a and b)J and in hamsters with grafts in the cheek pouch [KNIGGE and BIERMAN (1958)]. In rabbits, stalk sections that effectively destroyed connections between hypothalamus and pars distalis, also abolished the inhibition of TSH secretion as was shown by normal rabbits in response to restraint ("psychic stress") [BROWN-GRANT et al. (1957)J. It is thus evident that gonadotropic, adrenocorticotropic and thyro- tropic function of the pars distalis is under hypothalamic control. It remains to be discussed whether, and to what extent, these pars distalis functions are independent of the central nervous system. The question is still a matter of controversy and will not be treated in detail here. Probably gonadotropic activity of the pars distalis is low or absent when the gland is deprived of its normal hypothalamic connections. However, it is generally agreed that the transplanted pars distalis or the pars distalis isolated from hypothalamic control by stalk section or hypothalamic lesions, possesses considerable ability to autonomously produce ACTH and TSH. Thus certain forms of stress ("systemic stress") can still induce ACTH release. The thyroids function at a level much above that of hypophysectomized controls [BROWN-GRANT et al. (1957), D'ANGELO (1958), FLORSHEIM (1958), FORTIER et al. (1957), GREER (1957), Scow and GREER (1955), VON EULER and HOLMGREN (1956 a and b)J. Several attempts have been made by means of lesions to localize the hypothalamic areas or structures that may take part in the neural control of the release of the various tropic hormones from the pars distalis. Lesions mostly inhibit secretion of more than one of the hormones. The Comparative aspects of hypothalamic-hypophysial relationships 5 structures therefore seem to overlap. However in the rat, the preferred experimental animal, lesions in the anterior hypothalamus mainly inhibit thyroid function [BOGDANOVE (1957), D'ANGELO (1958), FLORS- HElM (1958), GREER (1957), SLUSHER (1958)J, whereas ACTH-regulating structures are generally supposed to be placed in the mid hypothalamus [GREER (1957), SLUSHER (1958)]. In the guinea pig SCHMID et al. (1957) found the ACTH-regulating structures localized around the nucleus hypothalamus ventromedialis and dorsomedialis. Gonadotropin secretion has been inhibited by lesions in the median hypothalamus. These lesions did not influence TSH secretion [BOGDANOVE (1957), D'ANGELO (1958), SLUSHER (1958)]. However, the anterior hypothalamus may also contain structures involved in the sexual cycle of the rat [GREER (1957), FLERKO and SZENTAGOTHAI (1957)]. Nervous or humoral hypothalamic control? Some investigators state that the vertebrate pars distalis is richly innervated and that consequently its function is probably under direct nervous control [METUZALS (1956, 1958), VAZQUES-LoPEZ (1948)]. However, only a scanty nerve supply is generally found, and it is argued that when a dense net of fibres has been observed it has not been sub- stantiated that these fibres are nerves and not reticular fibres [GREEN (1951), HARRIS (1955), SMITH (1956), WINGSTRAND (1951)J. The negative results of direct electrical stimulation of the hypophysis certainly does not support the claim that there are secretory nerves whereas stimulation of the hypothalamus or median eminence can cause release of ACTH, TSH or gonadotropins [HARRIS (1948b), HARRIS and WOODS (1958), MARKEE et al. (1946)]. If the pars distalis does not contain secretory nerves its function must be controlled humorally. Peculiar vascular connections between hypo- thalamus and pars distalis are, indeed, suitable for such humoral control (Fig. 2 and 3, p. 12 and 14). In higher vertebrates blood passing through a dense capillary plexus in the median eminence is drained through portal vessels directly into the blood sinuses of the pars distalis. POPA and FIELDING (1930) discovered this hypophysial portal system in mammals and WISLOCKI (1937) described the true direction of the blood flow. The portal circulation is also characteristic of birds [WINGSTRAND (1951)J and amphibians [GREEN (1947), HOUSSAY et al. (1935), anurans; MAZZI and PEYROT (1957), urodelesJ. In lower vertebrates the vascular connections between hypothalamus and pars distalis are simpler, but fundamentally similar. Blood flows through capillaries of the neurohypophysis into the pars distalis (and pars intermedia) before passing into the systemic circulation [GREEN (1951)]. 6 C. BARKER J 0RGENSEN and LIS OLESEN LARSEN The hypophysial portal circulation has therefore been assumed to mediate the hypothalamic control by carrying hormone-releasing factors to the pars distalis. In higher vertebrates the factors are supposed to be liberated in the median eminence from the nerve endings of the hypo- thalamic tract and to diffuse into the primary plexus of the portal system [HARRIS (1948a)]. A corticotropin-releasing factor (CRF) has in fact been demonstrated in brain blood from rats subjected to stress. CRF was not present in brain blood from non-stressed rats nor in blood drawn from the carotid of stressed rats [SCHAPIRO et al. (1958)]. Blood from the portal region, but not from the carotid, of the dog likewise stimulated ACTH secretion when injected into intact rats. In hypo- physectomized rats no effect was observed [PORTER and JONES (1956)J. Birds are especially suitable. for demonstrating the significance of humoral control of the pars distalis, because it is possible to sever the portal vessels without interrupting the nervous connections between the hypothalamus and hypophysis. Section of the portal vessels abolishes the hypothalamic control of the gonadotropic function of the pars distalis in the duck as judged from the failure of the operated birds to respond to light. Section of the nervous connections to the hypophysis does not prevent light-induced sexual maturation [BENOIT and ASSEN- MACHER (1953)J. Substances that can release hormones from the pars distalis and thus be the mediators of hypothalamic control are therefore most probably transmitted with the portal blood. Their number, chemical nature, and site of origin are not yet definitely known, but are the subject of much current research. Chemical nature of hypothalamic hormone-releasing factors Several well known physiologically active substances such as hist- amine, adrenaline and serotonine are present in high concentrations in the hypothalamus or neurohypophysis and have been considered as possible natural factors causing hormone release from the pars distalis. Histamine was found to stimulate ACTH release in the rabbit; injection of histamine solutions caused lymphopenia. The response was abolished by hypophysectomy [FUCHE and KAHLSON (1957)J. Apparently, however, histamine acts indirectly via the hypothalamus because the ACTH-releasing effect could be abolished in rats by hypothalamic lesions [MCCANN (1957)J or by transplanting the pars distalis to the anterior eye chamber [MARTINI (1958)J. Adrenaline, too, induced ACTH release from the pars distalis in the rat, but, as in the case of histamine, the response disappeared after lesion of the hypothalamus or median eminence [MCCANN (1957), SMELIK and DE WIED (1958)J. Injection of Comparative aspects of hypothalamic-hypophysial relationships 7 adrenaline or nor-adrenaline into the primary plexus of the portal vessels of female rabbits frequently produced ovulation. The effect was apparently not due to adrenaline itself, however, but to the acidity of the solution injected, because after adjustment to neutrality only one of eight rabbits ovulated after receiving the large dose of 150 y of adrenaline [DONOVAN and HARRIS (1955)J. Adrenaline is, therefore, most probably not a natural ACTH-or gonadotropin-releasing agent. Acetylcholine has also been investigated as to its pars distalis-stimulating activity. No ACTH-releasing effect was found on the pars distalis tissue transplanted to the anterior eye chamber in the rat [MARTINI (1958)J. On theoretical grounds, acetylcholine is unlikely to be a humoral transmitter in the portal blood, because it is rapidly broken down in the blood stream [HARRIS (1955)J. Serotonine caused ACTH release in normal rats, but not after destruction of the median eminence [SMELIK and DE WIED (1958)J or after transplantation of the pars distalis to the anterior eye chamber of hypophysectomized rats [MARTINI (1958)]. Also substance P [see GUILLEMIN (1957)J is stated to release ACTH, but the response could be abolished byhypothalamiclesions [MCCANN (1957)]. Serotonine and substance P are therefore presumably ruled out as natural ACTH- releasing factors. A lipid extracted from the hypothalamus was found to cause eosino- penia and adrenal ascorbic acid depletion - other symptoms of ACTH release - when injected into intact rats, but not when injected into hypophysectomized rats [SLUSHER and ROBERTS (1954)J. The lipid was not found in the cortex of the brain. It is stated to cause release not only of ACTH, but also of TSH and gonadotropins from the pars distalis of several mammals [CURRI (1958)]. It is doubtful, however, whether this interesting lipid fraction represents natural humoral links between the hypothalamus and the pars distalis since its ACTH-releasing activity can be abolished by destruction of the median eminence [DE WIED et al. (1958) ]. Special interest attaches to the mammalian antidiuretic hormone which has been found to stimulate the pars distalis directly. The hormone acts not only in mammals but also in amphibians. Injections of synthetic vasopressin induced moulting in toads (Bufo bufo) in which moulting had been inhibited by isolation of the pars distalis from the hypo- thalamus. Presumably, vasopressin caused moulting by stimulating the inactivated pars distalis, because the hormone had no effect in hypo- physectomized toads [J0RGENSEN and NIELSEN (1958)]. In mammals the ACTH-releasing activity of vasopressin has been extensively studied. In rats pitressin or synthetic vasopressin causes adrenal ascorbic acid depletion even in animals with hypothalamic lesions [MCCANN (1957), MCCANN and FRUIT (1957), SMELIK and DE WIED

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Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.