Pharmacological control of ciliary activity in the young sea urchin larva. Studies on the role of Ca2+ and cyclic nucleotides

The ciliary stimulation by monoamines is enhanced by adenylcyclase activators and a phosphodiesterase inhibitor indicating that cAMP is a mediator, a conclusion supported by the effects of db-cAMP. The role of cGMP is also examined. When stimulation exceeds certain levels, it is overpowered by some inhibitory feedback mechanism. The effects of altered Ca2+ concentrations, Ca2+ antagonists and a Ca2+ ionophore suggest that Ca2+ is involved in ciliary excitation as well as in the inhibitory mechanism. These suggestions are examined by experiments on the influence of altered Ca2+ concentrations and of the phosphodiesterase inhibitor on the response to various agents.     

Pharmacological control of ciliary activity in the young sea urchin larva: chemical studies on the role of cyclic nucleotides

Distinct peaks in cAMP and cGMP content during early development, partly opposite to each other, may be correlated with the two main phases of gastrulation and ciliary activity. Monoamines increases cAMP formation. A transient or extended decrease follows, presumably reflecting some feedback mechanism. Muscarinic agents and Ca2+ interfere. The developmental variation in cyclic nucleotides may reflect a temporal shift in the role of various signal substances as well as feedback regulation related to Ca2+ influx. The opposite changes in cAMP and cGMP during early gastrulation may reflect a mutual dependency of the two nucleotide cyclases related to changes in Ca2+ influx.     

Studies on the effect of monoamine antagonists on the morphogenesis of the newt

The effects of three monoamine antagonists, p-chlorophenylalanine, diethyldithiocarbamate and propranolol on the morphogenesis of newt embryos were studied. Antagonists were administered during late blastula through neurula stages. In a concentration of 1 mM, all three arrested gastrulation and caused disintegration of the embryos. Lower concentrations (0.1-0.5 mM) retarded morphogenetic movements in the gastrulation and caused malformations especially in the anterior parts of the embryos; pigmentation was delayed by 1 or 2 days. In addition, p-CIPhe inhibited yolk granule degradation in the notochord and DEDTC caused notochordal hypertrophy. The results show that interference with synthesis or action of catecholamines and serotonin affects morphogenesis. With the methods used it is not possible to discover exactly how monoamines regulate the morphogenetic events because of the unspecific side effects of the antagonists and the feedback interactions between the monoamines.     

Perturbations in brain monoamine systems during stress

Monoamines modulate the activity of many neurons and there is evidence that a balanced synthesis of central nervous monoamines is a prerequisite for normal brain functioning. Stress accelerates both release and turnover of brain monoamines and the resulting fluctuations in concentrations affect various parameters within neurotransmitter systems. Acute stress leads to only transient alterations in monoamine systems so that homeostasis can be restored, in contrast, chronic stress accompanied by repetitive and/or prolonged stimulation of monoaminergic neurons can induce a long-lasting imbalance in central nervous neurotransmitter systems. Accordingly, stress-induced changes in brain monoamine systems are suspected to contribute to psychiatric diseases such as depression. The present paper gives a short overview of stress effects on brain monoamines and their receptors.The work presented in this review was in part supported by the German Science Foundation (SFB406, C4 to G.F.). M.J.M. was supported by the DFG grant Fu 174/17–1 and EC Training Through Research (ERBFMBICT 961829).     

The roles of monoaminergic neurotransmitters in thermoregulation

Recent studies of the organization of the thermoregulatory system and evaluation of experimental evidence from electrophysiological, neuropharmacological, and neuroanatomical studies suggest that the monoamines noradrenaline and 5-hydroxytryptamine are involved in modulations of thermoregulation rather than in thermoregulation per se: they do not seem to transfer specific thermal information but rather modulate the signals passing from thermosensors to thermoregulatory effectors. Theoretically, the central monoamines could be modulating the input from thermosensors, or the central integration of thermal signals, or the outflow of signals to thermoregulatory effectors. The modulatory action of the monoamines on thermosensitive and thermointegrative hypothalamic neurons is best documented. There, the monoamines 5-hydroxytryptamine and noradrenaline seem to act as antagonists, which enhance or diminish the effects of thermal afferents mediated by other transmitters. Moreover, the antagonistic monoaminergic systems are apparently interconnected and can influence each other at a lower brain stem level. The activity in central monoaminergic systems can also be modified by neurohumoral feedback mechanisms from the periphery. By means of these interrelations the vegetative responses of the organism can be corrected and optimized.     

Effects of Suanzaorentang on behavior changes and central monoamines

Previously, it was found that the ancient Chinese remedy of Suanzaorentang could be a promising anxiolytic drug (Chen and Hsieh, 1985a, Chen and Hsieh, 1985b). To understand the mechanism of the action of Suanzaorentang, the effects of Suanzaorentang on behavior changes and central monoamines and their metabolites were studied in rats. It was found that Suanzaorentang significantly (1) prolonged the period from the onset of clonic to tonic convulsions induced by pentylenetetrazol or picrotoxin, (2) prolonged the sleep duration induced by hexobarbital, (3) reduced locomotor activity, (4) enhanced the hypomotility induced by alpha-MT, (5) reduced the locomotor stimulation produced by levodopa plus benserazide, and (6) reduced central HVA, VMA, and 5-HIAA, but had no significant effects on central DA, NA, and 5-HT. These facts implied that Suanzaorentang decreased the turnover rate of central monoamines and central catecholaminergic activity.     

Effects of the afferent stimulation on neurons in the medial septal region slices and their modulation by biologically active compounds in hibernating and waking ground squirrels

Responses of the medial septal (MS-DB) neurons to electrical stimulation of the medial forebrain bundle (MFB) and their modulation by some neuropeptides and monoamines were investigated in brain slices taken from two groups of ground squirrels-hibernating (HGS) and waking (WGS). Electrical stimulation evoked mostly inhibitory effects of various duration. Besides, responses by phase reset of the background rhythmic bursts and short-latency single spike responses were observed. The neuropeptides identified in the brain of hibernators differentially and reversibly modulated responses even in those neurons where they did not influence the level and pattern of the background activity. Effects of the peptides were state-dependent. E.g., the peptide TSKYR increased the duration of inhibitory effects in the HGS but shortened them in the WGS, while TSKY which had low efficacy in the HGS, increased the duration of inhibition in the WGS. Dipeptide DY depressed inhibitory components and augmented excitatory components of responses in the HGS but was much less effective in the WGS. Effects of noradrenaline and serotonin had stronger correlation with their influence on spontaneous activity. It is suggested that endogenous substances provide for the increased latent excitability and reactivity of the MS-DB neurons during seasonal hibernation. Thus, the MS-DB may function as a "sentry post" participating in signal detection and urgent arousal during hibernation.     

Modulation of protein phosphorylation by a factor purified from adipocytes.

1. A factor which modulates the activity of cyclic AMP-dependent protein kinase copurifies from rat adipocytes with an inhibitor of adenylate cyclase. Purification and stability studies suggest that both effects reside in a single factor previously referred to as a feedback regulator. 2. The magnitude and direction of the feedback regulator effect on cyclic AMP-dependent protein kinase activity was dependent on the concentration of feedback regulator and the concentration and type of protein substrate. Using histone type IIA as substrate, feedback regulator was inhibitory at low histone concentrations and stimulatory at high concentrations. Preincubation of protein kinase with feedback regulator resulted in inhibition at all histone concentrations. With some protein substrates, e.g. histone f2b and casein, inhibition was observed at all histone concentrations. 3. The stimulation of histone type IIA phosphorylation resulted from an increased V with no effect on either the apparent Ka for cyclic AMP or the Km for ATP. Time course studies suggest that feedback regulator increased the rate of phosphorylation without increasing the total number of phosphorylation sites. Increased histone phosphorylation was observed regardless of whether the cyclic AMP-dependent protein kinase was peak I or peak II (off Deae-cellulose), isolated from bovine or rabbit skeletal muscle or rat heart. A small stimulation was observed using cyclic GMP-dependent protein kinase. 4. These results indicate that feedback regulator can inhibit or stimulate protein kinase, an effect which is probably substrate directed, and depends on the reaction conditions. Whether feedback regulator modulated protein phosphorylation in vivo in addition to its inhibition of adenylate cyclase is unknown. However, stimulation of protein kinase activity in the presence of cyclic AMP is a valuable and rapid assay for monitoring feedback regulator fractions during purification procedures.     

Archenteron elongation in the sea urchin embryo is a microtubule-independent process

Earlier studies using colchicine (L. G. Tilney and J. R. Gibbins, 1969, J. Cell Sci. 5, 195-210) had suggested that intact microtubules (MTs) are necessary for archenteron elongation during the second phase of sea urchin gastrulation (secondary invagination), presumably by allowing secondary mesenchyme cells (SMCs) to extend their long filopodial processes. In light of subsequently discovered effects of colchicine on other cellular processes, the role of MTs in archenteron elongation in the sea urchin, Lytechinus pictus, has been reexamined. Immunofluorescent staining of ectodermal fragments and isolated archenterons reveals a characteristic pattern of MTs in the ectoderm and endoderm during gastrulation. Ectodermal cells exhibit arrays of MTs radiating away from the region of the basal body/ciliary rootlet and extending along the periphery of the cell, whereas endodermal cells exhibit a similar array of peripheral MTs emanating from the region of the apical ciliary rootlet facing the lumen of the archenteron. MTs are found primarily at the bases of the filopodia of normal SMCs. beta-Lumicolchicine (0.1 mM), an analog of colchicine which does not bind tubulin, inhibits secondary invagination, indicating that the effects previously ascribed to the disruption of MTs are probably due to the effects of colchicine on other cellular processes. The MT inhibitor nocodazole (5-10 micrograms/ml) added prior to secondary invagination does not prevent gastrulation or spontaneous exogastrulation, even though indirect immunofluorescence indicates that cytoplasmic MTs are completely disrupted in drug-treated embryos. Transverse tissue sections indicate that a comparable amount of cell rearrangement occurs in nocodazole-treated and control embryos. Significantly, SMCs in nocodazole-treated embryos often detach prematurely from the tip of the gut rudiment and extend abnormally large broad lamellipodial protrusions but are also capable of extending long slender filopodia comparable in length to those of control embryos. These results indicate that cytoplasmic MTs are not essential for either filopodial extension by SMCs or for the active epithelial cell rearrangement which accompanies elongation during sea urchin gastrulation.     

Aspartokinase of Myxococcus xanthus: "feedback stimulation" by required amino acids

The aspartokinase activity found in extracts of the bacterium Myxococcus xanthus was subject to feedback inhibition and feedback repression by l-threonine and l-lysine. Both types of inhibition were essentially additive. The required amino acids, l-isoleucine and l-methionine, caused considerable increase in the activity of the enzyme. This phenomenon is referred to as "feedback stimulation." The polyamine, spermidine, exerted strong enhancement of the activity even at 0.1 mM. Meso-diaminopimelate, although not inhibitory by itself, abolished the activation exerted by either l-isoleucine or l-methionine. The possible physiological significance of interactions between the various effectors is discussed.     

The secreted Frizzled-related protein Sizzled functions as a negative feedback regulator of extreme ventral mesoderm

The prevailing model of dorsal ventral patterning of the amphibian embryo predicts that the prospective mesoderm is regionalized at gastrulation in response to a gradient of signals. This gradient is established by diffusible BMP and Wnt inhibitors secreted dorsally in the Spemann organizer. An interesting question is whether ventrolateral tissue passively reads graded levels of ventralizing signals, or whether local self-organizing regulatory circuits may exist on the ventral side to control cell behavior and differentiation at a distance from the Organizer. We provide evidence that sizzled, a secreted Frizzled-related protein expressed ventrally during and after gastrulation, functions in a negative feedback loop that limits allocation of mesodermal cells to the extreme ventral fate, with direct consequences for morphogenesis and formation of the blood islands. Morpholino-mediated knockdown of Sizzled protein results in expansion of ventral posterior mesoderm and the ventral blood islands, indicating that this negative regulation is required for proper patterning of the ventral mesoderm. The biochemical activity of sizzled is apparently very different from that of other secreted Frizzled-related proteins, and does not involve inhibition of Wnt8. Our data are consistent with the existence of some limited self-organizing properties of the extreme ventral mesoderm.     

Low sensitivity of ciliary activity in the gills of Anodonta cygnea to some ecotoxicals

1. The effects of some ecotoxical model substances on the activity of frontal gill cilia of freshwater mussel Anodonta cygnea were studied in 1 and 24 hr experiments with the particle transport method. The effects were compared with the results of standard Daphnia magna ec₅₀ tests with the same substances.2. Variations of pH between 4.8 and 8.1 affected the ciliary activity by less than 30%.3. Ciliary activity was less sensitive to heavy metal salts, sodium lauryl sulphate and to two pulp industry waste model substances than D. magna.4. Compared to D. magna, the ciliary activity was more sensitive to formalin and 2,4-dinitrophenol, and as sensitive to ethanol.5. Ciliary activity in bivalve gills is a well regulated and/or a relative insensitive function, but it may be used as a rapid screening test for some cell ecotoxicals.     

Venom effects on monoaminergic systems

The monoamines, dopamine, epinephrine, histamine, norepinephrine, octopamine, serotonin and tyramine serve many functions in animals. Many different venoms have evolved to manipulate monoaminergic systems via a variety of cellular mechanisms, for both offensive and defensive purposes. One common function of monoamines present in venoms is to produce pain. Some monoamines in venoms cause immobilizing hyperexcitation which precedes venom-induced paralysis or hypokinesia. A common function of venom components that affect monoaminergic systems is to facilitate distribution of other venom components by causing vasodilation at the site of injection or by increasing heart rate. Venoms of some scorpions, spiders, fish and jellyfish contain adrenergic agonists or cause massive release of catecholamines with serious effects on the cardiovascular system, including increased heart rate. Other venom components act as agonists, antagonists or modulators at monoaminergic receptors, or affect release, reuptake or synthesis of monoamines. Most arthropod venoms have insect targets, yet, little attention has been paid to possible effects of these venoms on monoaminergic systems in insects. Further research into this area may reveal novel effects of venom components on monoaminergic systems at the cellular, systems and behavioral levels.     

Differential effects of UTP, ATP, and adenosine on ciliary activity of human nasal epithelial cells

The purinergic regulation of ciliary activity was studied using small, continuously superfused explants of human nasal epithelium. The P2Y(2) purinoceptor (P2Y(2)-R) was identified as the major purinoceptor regulating ciliary beat frequency (CBF); UTP (EC(50) = 4.7 microM), ATP, and adenosine-5'-O-(3-thiotriphosphate) elicited similar maximal responses, approximately twofold over baseline. ATP, however, elicited a post-peak sustained plateau in CBF (1.83 +/- 0.1-fold), whereas the post-peak CBF response to UTP declined over 15 min to a low-level plateau (1.36 +/- 0.16-fold). UDP also stimulated ciliary beating, probably via P2Y(6)-R, with a maximal effect approximately one-half that elicited by P2Y(2)-R stimulation. Not indicated were P2Y(1)-R-, P2Y(4)-R-, or P2Y(11)-R-mediated effects. A(2B)-receptor agonists elicited sustained responses in CBF approximately equal to those from UTP/ATP [5'-(N-ethylcarboxamido)adenosine, EC(50) = 0.09 microM; adenosine, EC(50) = 0.7 microM]. Surprisingly, ADP elicited a sustained stimulation in CBF. The ADP effect and the post-peak sustained portion of the ATP response in CBF were inhibited by the A(2)-R antagonist 8-(p-sulfophenyl)theophylline. Hence, ATP affects ciliary activity through P2Y(2)-R and, after an apparent ectohydrolysis to adenosine, through A(2B)AR.     

Cholinergic nerves stimulate mucociliary transport,ciliary activity,and mucus secretion in the frog palate

Summary Mucociliary transport, ciliary activity, and mucus secretion were studied in the palate of the frog Rana pipiens by direct observation, stroboscopic synchronization of ciliary beating, and histochemistry. Excised palates were studied in vitro, and intact palates were studied in vivo. Electrical stimulation of the glossopharyngeal nerve in vivo or of the palatine nerve in vitro stimulated all three activities. The effect was mimicked by acetylcholine and pilocarpine, enhanced by physostigmine, and blocked by atropine but unaffected by d-tubocurarine. Stimulation increased the number of cilia beating and their rate of beating, the number of goblet cells secreting and, for small acidic cells, the amount of mucus secreted, and the rate and extent of particle transport. The response to tactile stimulation was locally restricted in vitro but widespread in vivo. It was concluded that, although there is a low basal rate of mucus secretion and ciliary activity that is independent of nervous control, stimulation of these activities in the intact animal is mediated through the central nervous system and cholinergic nerves to the palate.Supported in part by Grant HL-16730 from the U.S. Public Health Service     

Simultaneous measurement of ciliary beating and intracellular calcium.

A novel system for measuring, simultaneously, ciliary beating and intracellular free calcium is presented. The advantages and dynamic nature of the system are demonstrated by measuring the effects of the calcium ionophore lonomycin and of extracellular ATP on ciliated rabbit trachea. The results are discussed with regard to the ciliary and calcium stimulation.     

Stimulus-response coupling in mammalian ciliated cells. Demonstration of two mechanisms of control for cytosolic [Ca2+]

Changes of cytosolic [Ca2+] have been proposed to couple stimulation of ciliary movement, however, quantitative measurements of fluctuations of intracellular free [Ca2+] associated with stimulation of ciliated cells have not been investigated. In primary cultures of rabbit oviductal ciliated cells, the stimulation of ciliary activity produced by micromolar concentrations of adenosine triphosphate (ATP) and prostaglandin F2 alpha (PGF2 alpha) was associated with a transient increase of intracellular [Ca2+]. Whereas the increase of cytosolic [Ca2+] and beat frequency produced by ATP were inhibited by the Ca-channel blocker LaCl3, the rise of cytosolic [Ca2+] and frequency of ciliary beat produced by PGF2 alpha was not affected by LaCl3. These results are the first direct demonstration that fluctuations of cytosolic [Ca2+] are associated with increased ciliary beat frequency in mammalian epithelial cells. The present findings suggest two different calcium-dependent mechanisms for stimulus-coupling in ciliary epithelium: ATP acting via purinergic receptor coupled to transmembrane influx of Ca2+, and PGF2 alpha acting via receptor-mediated release of intracellular sequestered Ca.     

Na+/K(+)-ATPase as an effector of synaptic transmission.

Evidence is presented in support of the hypothesis that transmitter monoamines can exert their post-synaptic effects by stimulation or inhibition of Na+/K(+)-ATPase in neuronal or glial cell plasma membranes. Stimulation of electrogenic sodium pumping, causing a hyperpolarization with an increase in membrane resistance, could account for the depression of neuronal spontaneous firing and the signal/noise enhancing actions of these amines. Conversely, inhibition of an electrogenic sodium pump in neuronal plasma membranes would lead to depolarization and enhanced excitability.     

Localization of Thermoreceptor Systems that Induce Step-Up and Step-Down Thermophobic Responses and Switching in the Dominance of These Systems in Blepharisma

The distribution of thermoreceptor systems that initiate step-up and step-down thermophobic responses in bisected cells of Blepharisma was examined. Anterior cell fragments responded by ciliary reversal to a step-down in temperature and by repression of spontaneous ciliary reversal to a step-up. Posterior fragments responded by ciliary reversal to a step-up in thermal stimulation and by repression of spontaneous ciliary reversal in response to step-down stimulation. Results indicate that two kinds of thermoreceptor systems exist in the anterior half of each cell; one is responsible for ciliary reversal induced by step-down stimulation, and the other is responsible for repression of the ciliary reversal caused by step-up thermal stimulation. Likewise, there are also two kinds of thermoreceptor systems in the posterior half of the cell; one is responsible for ciliary reversal in response to a step-up in temperature, and the other is responsible for the repression of ciliary reversal on a step-down in thermal stimulation. Below about 27°C, intact cells showed ciliary reversal only when a step-down in thermal stimulation occurred, while above about 27°C cells only responded to a step-up in thermal stimulation. At about 27°C there was a switch in the dominant response from the anterior to the posterior half of an individual cell.