Neurohypophyseal hormones and analogues: magnesium dependence and contraction of arterial smooth muscle.

The present quantitative results, using isolated rat aorta, demonstrate that different [Mg2+]o (i.e. 0.2, 1.2 and 6.0 mM) potentiate the contractile actions of a variety of neuohypophyseal hormones and synthetic analogues on vascular smooth muscle. [Mg2+]o can alter both the hormone-receptor affinities (H-RA) and intrinsic (contractile) activities (i.a.) of these peptides on vascular muscle; 1.2 mM [Mg2+]o (approximately that found in rat plasma) appears to optimize H-RA and i.a. on rat aortic smooth muscle. The presence of [Mg2+]o not only steepens the concentration-effect curves to the neurohypophyseal peptides but increases the maximum contractile responses as well. The present findings question that [Mg+]o potentiates responses to neurohypophyseal peptides by vascular muscle solely by affecting H-RA. The present study supports the notion that Mg2+ potentiates responses to these peptides by acting at sites other than the receptor in mammalian vascular muscle. In addition, the present experiments suggest that the [Mg2+]o dependence of neurohypophyseal peptides on at lesast one mammalian vascular muscle-rat aorta- is directly rather than inversely proportional to the rat pressor potency of the molecules. Further, the vasopressin receptor which subserves contraction in mammalian blood vessels may differ in this respect from that in uterine smooth muscle.     

Neurohypophyseal hormones and behavior: effects of intracerebroventricularly injected hormone analogs in mice.

Neurohypophyseal hormones evoke spontaneous behavioral changes in mice. This study compares the potency of four naturally occuring neurohypophyseal hormones and of ten analogs with amino acid residue replacements selected in such a manner as to cover each residue position of the hormones with the exception of the cystine residue. Peptides were administered intraventricularly and the sum of foraging, scratching and squeaking, recorded at 30 second intervals during a 30 min session, was measured as a function of peptide dose. The most potent group of peptides is represented by the neurohypophyseal hormones as well as the five analogs [Hly⁸] vasopressin, [Δ³-Pro⁷]AVP, [Thi³]LVP, [Abu⁴]AVP and [Abu⁴]LVP. [Leu⁴]LVP showed significant activity but was far less potent than the natural hormones. None of the remaining analogs enhanced activity with an increase in peptide dose. This group included both peptides with C-terminal modifications and those in which the tyrosine (position 2) or the asparagine residue (position 5) of the hormones were substituted by alanine. The neurohypophyseal hormone-induced behavioral results of this study reveal a structure-function relationship, which is in its most important conclusions, identical to the conformation-activity model proposed for endocrine activities of neurohypophyseal peptides.     

Neurohypophyseal hormones protect against pentylenetetrazole-induced seizures in zebrafish: Role of oxytocin-like and V1a-like receptor

Oxytocin (OT) and arginine-vasopressin (AVP) are involved in the physiological response to different stressors like the occurrence of seizures which is regarded as a severe stress factor. Zebrafish (Danio rerio) is recently featured as a model of epilepsy but the role of neurohypophyseal hormones on this teleost is still unknown. We attempted to determine whether non-mammalian homologues like isotocin (IT) and vasotocin (AVT) affected pentylenetetrazole (PTZ)-induced seizures in adult zebrafish in comparison with OT/AVP. The mechanism was studied using the most selective OT and AVP receptor antagonists. Zebrafish were injected i.m. with increasing doses (0.1-40ng/kg) of the neuropeptides 10min before PTZ exposure. DesGly-NH2-d(CH2)5-[D-Tyr2,Thr4]OVT (desglyDTyrOVT) for OT receptor and SR49059 for V1a subtype receptor, were injected together with each agonist 20min before PTZ exposure. All the peptides significantly decreased the number of seizures, increased the mean latency time to the first seizure and decreased lethality. This protective effect led to a dose-response curve following a U-shaped form. IT was approximately 40 times more active than OT while AVT was 20 times more potent than AVP in reducing the number of seizures. DesglyDTyrOVT was more effective in antagonizing OT/IT, while SR49059 mainly blocked AVP/AVT-induced protection against PTZ-induced seizures. The present findings provide direct evidence of an important involvement of IT/OT and AVP/AVT as anticonvulsant agents against PTZ-induced seizures with a receptor-mediated mechanism in zebrafish. These data reinforce zebrafish as an emerging experimental model to study and identify new antiepileptic drugs.     

Neurohypophyseal principles and memory.

The neurohypophyseal hormones vasopressin and oxytocin modulate memory processes. Vasopressin facilitates, while oxytocin attenuates memory consolidation and retrieval. These influences are located in different regions of the molecules. Thus, the neurohypophyseal hormones act as precursor molecules for neuropeptides involved in memory processes. The covalent ring structures of both vasopressin and oxytocin mainly affect consolidation; the linear parts, retrieval processes; while nearly the whole oxytocin or vasotocin molecule is needed for attenuation of consolidation and retrieval. Regional studies, utilizing microdissection techniques in combination with a sensitive radioenzymatic catecholamine assay, revealed a distinct pattern of effects on cerebral alpha-methyl-p-tyrosine methylester-induced catecholamine disappearance following intraventricular vasopressin administration in limbic midbrain structures. In situations in which the amount of bioavailable vasopressin in the brain is absent, as is the case in the Brattleboro rat with hereditary diabetes insipidus, or neutralized in normal Wistar rats following the intraventricular administration of antivasopressin serum, regional catecholamine disappearance in most cases is altered in a direction opposite to that observed after intracerebroventricular vasopressin administration. These results indicate that vasopressin modulates memory processes by modulation of neurotransmission in distinct catecholamine systems. Recent experiments suggest that the influence of vasopressin on memory consolidation is mediated by the dorsal noradrenergic bundle via terminal regions of this bundle.     

Intracellular sodium activity and sodium transport inNecturus gallbladder epithelium

Summary Ion-sensitive glass microelectrodes, conventional microelectrodes and isotope flux measurements were employed inNecturus gallbladder epithelium to study intracellular sodium activity, [Na] _i , electrical parameters of epithelial cells, and properties of active sodium transport. Mean control values were: [Na] _i : 9.2 to 12.1mm; transepithelial potential difference, _ms : –1.5 mV (lumen negative); basolateral cell membrane potential, _es : –62 mV (cell interior negative); sodium conductance of the luminal cell membrane,g _Na: 12 mho cm^–2; active transcellular sodium flux, 88 to 101 pmol cm^–2 sec^–1 (estimated as instantaneous short-circuit current). Replacement of luminal Na by K led to a decrease of the intracellular sodium activity at a rate commensurate to the rate of active sodium extrusion across the basolateral cell membrane. Mucosal application of amphotericin B resulted in an increase of the luminal membrane conductance, a rise of intracellular sodium activity, and an increase of short-circuit current and unidirectional mucosa to serosa sodium flux. Conclusions: (i) sodium transport across the basolateral membrane can proceed against a steeper chemical potential difference at a higher rate than encountered under control conditions; (ii) the luminal Na-conductance is too low to accommodate sodium influx at the rate of active basolateral sodium extrusion, suggesting involvement of an electrically silent luminal transport mechanism; (iii) sodium entry across the luminal membrane is the rate-limiting step of transcellular sodium transport and active sodium extrusion across the basolateral cell membrane is not saturated under control conditions.     

Plant hormones: Ins and outs of auxin transport

Regulated transport has long been known to play a key part in action of the plant hormone auxin. Now, at last, a family of auxin efflux carriers has been identified, and the characterisation of one family member has provided strong evidence in support of models that have been proposed to explain gravitropic curvature in roots.     

Lymphatics in intestinal transport of nutrients and gastrointestinal hormones

The lymph fistula rat has been used for studying intestinal absorption of nutrients, especially lipids. Lipid absorption begins with the digestion of triacylglycerol (TAG) to form 2-monoacylglycerol (2-MAG) and fatty acids (FA), which are then incorporated in bile salt-mixed micelles. The mixed micelles deliver these digestion products to enterocytes for uptake. There, 2-MAG and FA are re-esterified to form TAG, which is then incorporated into chylomicrons (CMs) to be carried by the lymphatic system. Coincident with CMs' secretion into lymph, the small intestine also secretes incretin hormones. Advantages of the lymph fistula model in studying CMs and incretin secretion include the following: (1) the animal being conscious, (2) much less dilution of CMs and incretins than in portal blood, and (3) fewer degrading enzymes than portal blood, e.g., dipeptidyl peptidase-IV. Examples of the lymph fistula model being used for studying CMs' transport in normal and pathophysiologic states are presented. Recently, the lymph fistula rat has also been used for studying the secretion of incretins by the small intestine.     

Neurohypophyseal ectopy in growth hormone insufficiency

Nuclear magnetic resonance imaging of the hypothalamohypophyseal tract allows the detection and identification of ectopic posterior pituitary lobe tissue by its characteristic high signal intensity. We found this anomaly in 2 boys with growth hormone insufficiency. Neurohypophyseal ectopy may be misdiagnosed as subhypothalamic tumor and such patients risk to be subjected to unnecessary neurosurgery.     

Regulation of sodium transport in erythrocytes

The kinetic response of swine erythrocyte (Na + K)-ATPase to Na⁺ concentration was hyperbolic in low KCl (5–25 mm) but became increasingly sigmoidal (n = 2.2) as KCl was increased to 150 mm. The addition of 150 mm LiCl did not cause an increase in sigmoidicity although it decreased the apparent affinity for Na⁺. The dependence of ouabain-inhibited efflux of Na⁺ on internal Na⁺ concentration was measured in intact cells with intracellular cation concentrations altered by incubation in p-ehloromercuriphenyl sulfonate. The response to Na⁺ was sigmoidal (n = 2.2) in cells containing high K⁺ but hyperbolic in preparations in which most of the intracellular K⁺ was replaced by Li⁺, even in the presence of 150 mm external KCl. The data are consistent with a model in which internal K⁺ is an allosteric (feedback) inhibitor of Na⁺ efflux and there are three Na⁺ sites which interact cooperatively.     

Mechanisms of sodium transport in bacteria

In some bacteria, an Na+ circuit is an important link between exergonic and endergonic membrane reactions. The physiological importance of Na+ ion cycling is described in detail for three different bacteria. Klebsiella pneumoniae fermenting citrate pumps Na+ outwards by oxaloacetate decarboxylase and uses the Na+ ion gradient thus established for citrate uptake. Another possible function of the Na+ gradient may be to drive the endergonic reduction of NAD+ with ubiquinol as electron donor. In Vibrio alginolyticus, an Na+ gradient is established by the NADH: ubiquinone oxidoreductase segment of the respiratory chain; the Na+ gradient drives solute uptake, flagellar motion and possibly ATP synthesis. In Propionigenium modestum, ATP biosynthesis is entirely dependent on the Na+ ion gradient established upon decarboxylation of methylmalonyl-CoA. The three Na(+)-translocating enzymes, oxaloacetate decarboxylase of Klebsiella pneumoniae, NADH: ubiquinone oxidoreductase of Vibrio alginolyticus and ATPase (F1F0) of Propionigenium modestum have been isolated and studied with respect to structure and function. Oxaloacetate decarboxylase consists of a peripheral subunit (alpha), that catalyses the carboxyltransfer from oxaloacetate to enzyme-bound biotin. The subunits beta and gamma are firmly embedded in the membrane and catalyse the decarboxylation of the carboxybiotin enzyme, coupled to Na+ transport. A two-step mechanism has also been demonstrated for the respiratory Na+ pump. Semiquinone radicals are first formed with the electrons from NADH; subsequently, these radicals dismutate in an Na(+)-dependent reaction to quinone and quinol. The ATPase of P. modestum is closely related in its structure to the F1F0 ATPase of E. coli, but uses Na+ as the coupling ion. A specific role of protons in the ATP synthesis mechanism is therefore excluded.     

Angiotensin II and proximal tubule sodium transport.

As a target site for angiotensin II (A-II), renal proximal tubule is unique in that it may be equipped with a local A-II generating system and that both basolateral and apical membranes may be accessible for A-II's action. We have recently conducted studies to examine these possibilities. With in vitro cultured proximal tubular cells, we have demonstrated de novo synthesis of angiotensinogen and renin. With isolated renal brush border membrane (BBM), we have confirmed the presence of A-II receptors and found that A-II directly stimulated BBM Na(+)-H+ exchange. In search of the signal transduction mechanism, we have found that A-II also activated BBM phospholipase A2 (PLA) and that BBM contained a pertussis toxin-sensitive guanine nucleotide binding protein (G-protein) which mediates the effects of A-II. Further studies showed that prevention of PLA activation abolished A-II's effect on Na(+)-H+ exchange, and that activation of PLA by mellitin and addition of arachidonic acid similarly enhanced Na(+)-H+ exchange activity, suggesting that PLA activation may mediate the stimulatory effect of A-II on Na(+)-H+ exchange. These results thus indicate that a local signal transduction mechanism involving G-protein mediated PLA activation exists in renal BBM which mediates A-II's effect on Na(+)-H+ exchange. Taken together, we propose that, independent of A-II in the circulation, local luminal A-II may serve as an important regulatory system on sodium transport in renal proximal tubule.