Rhythmic contractions in chick amnio-yolk sac and snake amnion during embryogenesis

The rhythmic movements of fetal membranes in chick and reptile embryos were studied to explore the developmental role of the extra-embryonic motor activity. In the snakes Lamprophis fuliginosus and Elaphe radiata, rhythmic contractions of amnion inside the developing egg were recorded from the 11th incubation day until pre-hatching stages (ca. day 60-72). The duration of these contractions averaged 2.02+/-0.27 min. The frequency ranged from 2 to 6 per 10 min and averaged 4.61+/-0.57 per 10 min. A tendency of frequency to increase toward the end of embryogenesis was observed. Lowering the temperature from 28 to 20 degrees C significantly decreased the frequency of amnion contractions to 2.85+/-0.91 per 10 min. The isolated snake amnion retained its capacity for spontaneous contraction. Noradrenaline inhibited, acetylcholine stimulated and serotonin did not affect the rhythmic activity of the isolated snake amnion. Similar effects were found when these agents were applied into the snake amniotic cavity. In the chick, yolk sac rhythmic contractions were recorded from the fifth until the 12th incubation days. The duration of these contractions ranged from 15 to 60 s, their frequency averaged 11.8+/-3.18 per 10 min and depended on temperature. The low temperature threshold was approximately 30 degrees C. After surgical removal of the amnion and embryo, the yolk sac continued contracting inside the egg. The yolk sac rhythmic contractions likely participate in the space movement of the embryo inside the egg during embryogenesis.     

Catecholamines and DOPA in the amniotic fluid and amnion of the chick embryo

Identification and quantitative fluorimetric assay have been made on the content of DOPA, dopamine, noradrenaline and adrenaline in the amniotic fluid and amnion of the developing chick embryos. Significant increase in the content of DOPA, noradrenaline and adrenaline in the amniotic fluid was observed between the 6th and the 13th days of incubation; dopamine content sharply decreases at the 13th day. The content on amines in the amnion tissue remained essentially constant throughout the investigated period. The role of catecholamine in amniotic fluid in regulation of contractile activity of amniotic membrane in the developing chick embryo is discussed.     

The motor activity of the chick embryo and amnion during embryogenesis

Studies have been made on the motor activity of amnion and chick embryo from the 5th to the 14th day of development. Between the 5th and the 8th day of embryogenesis, when embryonic movements are rather poor, amnion contractions are mainly observed, their frequency being maximum to the 7th day. On further development (8-14 days), with the increase in the mass of the limbs which account for embryonic movements (body extremities), the increase in the intensity of their motor activity is paralleled by the decrease in the frequency of amnion contractions. Therefore, during the intensive growth and development of mainly frontal part of the embryo, the deficiency of motor activity of rather undeveloped body and extremities is presumably compensated by temporal motor activity of the amnion. Between the 8th and the 10th day, synchronous movements of embryo and amnion are observed. Possible mechanisms of synchronization are discussed.     

The effect of temperature on the motor activity of the chick embryo and amnion at 5-14 days of development]

It has been shown that cooling the developing eggs from 37.7 degrees C results cessation of motor activity of the amnion in 5-14-day embryos at 36-33 degrees C, whereas motor activity of the embryo remains unaffected up to 31-26 degrees C. Immobilization of the embryo was observed on cooling up to 22-18 degrees C. The recovery of motor activity after cooling during heating takes place in a reverse order. Embryonic movements are observed at 18-23 degrees C, contractions of the amnion--at 28-33 degrees C. These experiments reveal complete independence of embryonic movements from the amnion. Motor activity of the amnion is related to that of the embryo only between the 8th and the 10th day of incubation.     

The acute and the chronic effects of imipramine on the spontaneous motility in chick embryos

The effect of imipramine on the spontaneous motility and development of chick embryos was studied from the 4th to the 19th day of incubation. On acute administration (a single dose of 12.5 of 25 mg/kg egg weight), imipramine already induced significant depression of spontaneous motility in 11-day embryos--an effect which increased significantly after the 15th day of incubation. The similar effect of imipramine in spinal embryos testifies to its direct action on the spinal cord and draws attention to certain details of the role of supraspinal structures of the CNS in the acute effect of imipramine. The chronic administration of imipramine showed that it had an almost 100% lethal effect from 4th to the 7th day of incubation. Between the 8th and the 10th day it caused longlasting depression of spontaneous motility. When it was administered between the 11th and 16th day of incubation, no significant effect on the development of spontaneous motor activity was found in chick embryos.     

Sensitivity of embryonic spontaneous motility to the GABA agonists baclofen and muscimol

The development of the sensitivity of spontaneous motor activity to the GABA agonists baclofen (10 mg/kg egg weight, systemic administration) and muscimol (0.8 mg/kg e.w., systemic administration) was tested in 11-day to 19-day-old chick embryos. 1) Baclofen already significantly depressed the frequency of spontaneous movements in 11-day embryos; its effect attained the maximum (85% depression of spontaneous motility) in 13-day embryos. After the 15th day of incubation, it reduced spontaneous motor activity by 50-60%. In spinal embryos, baclofen had the same, but a quantitatively more pronounced effect, demonstrated from its direct action on the spinal cord uninfluenced by supraspinal modulation, which began to be manifested after the 15th day of incubation. 2) Muscimol did not begin to inhibit spontaneous motility significantly until the 13th day of incubation. Subsequently, the latent period of its effect shortened, its duration lengthened and, lastly, its quantitative result also increased. 3) A comparison of the effect of GABA (Sedlácek 1978), muscimol and baclofen in 17-day chick embryos showed that the depressive effect increased in the sequence baclofen less than GABA less than muscimol, but that GABA took effect faster than the others. The results testify that the maturation of the individual elements of the GABA-ergic central inhibition system is a complex process.     

An attempt to activate the spontaneous motility in chick embryos with tetanus toxin

The effect of tetanus toxin on spontaneous motor activity was studied in chick embryos between the 11th and 19th day of incubation. The toxin--dose 20 mg/kg egg weight ( = 2.86 X 10(3) mouse MLD) in 25 microliters isotonic NaCl solution--was injected into the tibial or the wing muscles. Tetanus toxin induced demonstrable activation of embryonic motility from the 15th day of incubation onwards. Activation attained 155-200% of resting activity. The activating effect was manifested for the first time by motor paroxysms in 17-day and particularly 19-day embryos. Tetanus toxin activation was effectively depressed by glycine (100 mg/kg e.w.) and GABA (100 mg/kg e.w.), the former having a stronger effect than the latter. The effect of tetanus toxin on spinal embryos was relatively more pronounced, while the depressant effect of the inhibitory amino acids (especially glycine) was weaker. The results are evaluated as further evidence that central inhibitory mechanisms are connected up in regulation of the spontaneous motor output activity of chick embryos on about the 15th day of incubation.     

Development of spontaneous motility in chick embryos. Normal development and the activating effect of strychnine and picrotoxin.

The longitudinal development of spontaneous motility in chick embryos was studied by Kovach's method (Kovach 1970) from the 10th day of incubation up to hatching, in completely intact eggs. From the 10th to 12th day of incubation, very low amplitude movements of a burst character predominated in spontaneous motility. From the 13th day, both low and high amplitude movements could be distinguished. From the 18th day, high amplitude movements alternating with intervals of motor inactivity preponderated. This discontinuous motility, which was most pronounced on the 20th day of incubation, changed to periodic strong hatching movements. Reduction of spontaneous motility after the 17th day of incubation was not confirmed. Strychnine already activated spontaneous motility in 11-day embryos, but typical convulsions did not appear until the 15th incubation day. With picrotoxin, motility was likewise stimulated in 11-day embryos and paroxysmal activation did not occur until the 15th incubation day. In older embryos, convulsions were gradually succeeded by a continuous increase in spontaneous motility. The effect of picrotoxin had a much longer latent period than the effect of strychnine.     

Positive inotropic action of acetylcholine on the heart ventricles of the chick embryo

Acetylcholine increased twitch tension in the whole ventricle or in ventricular strips from 2-10-day chick embryos. The effect of acetylcholine was mediated by muscarinic receptors, since it was prevented by atropine, but not by tubocurarine or propranolol. Prostigmine significantly increased the sensitivity to acetylcholine in the strips from 7-day embryos, being almost ineffective in the strips from 3-day embryos. The decrease in acetylcholine sensitivity in the developing chick embryo is presumably associated with the increase in cholinesterase activity of the myocardial tissue.     

Cholinesterase in the amnion of chick embryos

Cholinesterase (ChE) activity in amnion was studied in developing chick embryos and the enzyme's substrate-inhibitory characteristics were established. The enzyme activity increased until the 8th day of incubation and then gradually decreased; on day 12-15 the activity is 40% only of the maximal one. On the basis of substrate-inhibitory analysis the enzyme was referred to propionyl-cholinesterases. Relations between age changes in ChE activity and morphological structure of smooth-muscle amnion tissue, its differentiation during development and functional activity of amnion are discussed.     

Development of spontaneous motility in chick embryos. Sensitivity to aminergic transmitters.

The consequences of systemic administration of aminergic transmitters (n-adrenaline 16 microgram/kg egg weight; serotonin 2.5 and 5 mg/kg e.w.; dopamine 2.5 and 5 mg/kg e.w.) for the spontaneous motility and heart rate of 11- to 19-day chick embryos were studied intack eggs. The following results were characteristic for all three transmitters: a) when administered to 11- and 13-day embryos their effect was non-significant; the first signs of activity did not appear until the 15th day of incubation. The effect on 17- and 19-day embryos was stronger. b) After the 15th day of incubation, all these transmitters had a predominantly inhibitory effect on spontaneous motility; in 17- and 19-day embryos this acquired a periodic character. c) The changes in spontaneous motility did not correlate significantly in any way with the relatively small heart rate changes. It is concluded from the results that aminergic mechanisms begin to participate in regulation of the spontaneous motility of chick embryos from the 15th day of incubation, and not before.     

Changes in the development of spontaneous motility in chick embryos after the chronic administration of GABA

From the 4th to the 16th day of incubation, GABA was administered continuously to chick embryos in a mean dose of 9.04 +/- 0.98 mg/kg e.w./24 h. On the 17th day of incubation, spontaneous motility was evaluated from the frequency of spontaneous movements as resting motility and motility after the acute administration of GABA (100 mg/kg e.w.), bicuculline (1 mg/kg e.w.) and oxazepam (10 mg/kg e.w.). 1) The chronic administration of GABA reduced the spontaneous motor activity of the experimental embryos to 38.4-47.8% of the control value. To obtain this effect it was sufficient to administer GABA between the 4th and the 8th day of incubation. 2) The inhibitory effect of the acute administration of GABA in the experimental embryos was only half its effect in the controls. Conversely, the relative size of bicuculline activation of motility was distinctly greater in the experimental embryos, which were also significantly more sensitive to oxazepam. The results show that GABA has a dual effect during embryogenesis--a) an early effect between the 4th and 8th day of incubation causing a chronic debt in the development of spontaneous motor activity, and b) an inhibitory effect as a central transmitter, which begins to be manifested in embryonic spontaneous motility of chick embryos on about the 15th day of incubation.     

Development of spontaneous motility in chick embryos. Interaction of strychnine, glycine and GABA.

The interaction of strychnine (1 mg/kg egg weight), glycine (100 mg/kg egg weight) and GABA (103 mg/kg egg weight) on spontaneous motor activity recorded by the method of Kovach (1970) in intact eggs was studied in chick embryos from the 11th to 21st day of incubation. In 11- and 13-day embryos, neither of the amino acids influenced strychnine activation of spontaneous motility. From the 15th incubation day, strychnine activation was distinctly affected by both amino acids, but the maximum effect was observed on the 19th day. Glycine had a stronger inhibitory effect, since it prevented strychnine convulsions from developing, whereas GABA only modified them. It can be concluded from the results that glycine-sensitive and GABA-sensitive mechanisms of embryonal spontaneous motility do not begin to take effect in chick embryos until the 15th day of incubation.     

Effects of the acute and chronic administration of chlordiazepoxide on the development of spontaneous motility in chick embryos

The effects of the acute and chronic administration of chlordiazepoxide on spontaneous motility and on the reactivity of the generator of embryonic motility were studied in chick embryos from the 4th to the 19th day of incubation. 1. The acute administration of chlordiazepoxide (5 mg/kg e.w.) significantly depressed spontaneous motility from the 13th day of incubation. 2. The chronic administration of chlordiazepoxide (12.2 mg/kg e.w./24 h) from the 4th to the 8th, 12th and 16th day of incubation enhanced the reduction of the spontaneous motility of 17-day-old embryos. 3. The chronic administration of chlordiazepoxide significantly modified the activity of both activators (strychnine, metrazol, bicuculline, picrotoxin) and inhibitors (GABA, chlordiazepoxide) of the spontaneous motility of chick embryos.     

Penicillin activates spontaneous motility in chick embryos

The development of the motor reaction to i.v. injection of the sodium salt of penicillin G in a dose of 0.9 x 10(6) I.U./kg egg weight was studied in chick embryos (normal and spinal) from the 11th to the 19th day of incubation. Penicillin first caused standard activation of embryonal motility from the 15th day of incubation, in both normal and spinal embryos. Activation was at first continuous in character (a twofold increase in the frequency of spontaneous movements). In 17- and particularly in 19-day embryos a typical paroxysmal reaction developed, with pronounced intervals of motor rest. The proportion of the spinal component in the penicillin reaction was abut 40% and of the supraspinal component about 60% of total motor activity. In older embryos (after the 15th day of incubation), the motor reaction to penicillin could be effectively modified by the systemic administration of glycine and GABA. It is concluded from the results that penicillin does not activate embryonal motor activity until a given stage of development of the CNS has been attained. It is a developmental phenomenon with a spinal and a supraspinal component, in which central inhibitory mechanisms participate.     

Role of motility in embryonic development I: Embryo movements and amnion contractions in the chick and the influence of illumination

This study provides a quantitative analysis of the active movements of the chick embryo and of the contractions of the amnion over the entire developmental period of 21 days. Four types of embryo movements are distinguished. The motor activity of the embryo shows two characteristic peaks, with maximum contraction frequencies on the 12th and on the 16th day. In contrast, the amnion activity is higher at earlier stages and decreases as the body activity increases. The amnion activity is largely independent of the body activity. Illumination has a strong influence on embryo movements. It is shown that increases of light intensity affect the patterns of activity of both the embryo and the amnion. While the effect of light on the embryo can be interpreted as being transmitted via the optic system, the mechanism of the amniotic response is unclear. The results suggest that the amnion itself may be sensitive to light. J. Exp. Zool. (Mol. Dev. Evol.) 291:186-194, 2001.     

Cholinoreception of chick embryo myocardial explants]

The effects of acetylcholine, subecholine (selective nicotinomimetic) and methylfurmetide (selective muscarinomimetic) on the spontaneous contractions of atrial and ventricular explants from the heart of 408 day embryos as well as of mixed explants, have been studied by means of a special photoelectric device. In most of the experiments, acetylcholine reduced the rate of contractions, the sensitivity of preparations being increased with the age of embryos. Preliminary atropine treatment reversed or significantly decreased acetylcholine effect. Subecholine usually increased the contraction rhythm, whereas methylfurmetide decreased the spontaneous activity.     

Bicuculline activation of embryonic spontaneous motility

The activating effect of bicuculline on spontaneous central motor output activity was studied in chick embryos from the 11th to the 19th day of incubation by means of spontaneous motility. When applied onto the embryonic membranes, bicuculline [1 mg X kg-1 egg weight] significantly activated embryonic motility from the 15th day of incubation. In 15-day embryos it increased spontaneous motility 2.5-fold and in 17- and 19-day embryos 3.5-fold. The role of supraspinal factors in the activating effect of bicuculline increased with development. In 15-day embryos it accounted for 56.7% and in 17-day embryos for already 84.6% of the total effect of bicuculline. Antagonism was manifested between bicuculline and the inhibitory amino acids glycine and GABA; in the case of GABA it was quantitatively more pronounced. The results of this study of development of the activating effect of bicuculline and its antagonism with gamma-aminobutyric acid are evaluated from the aspect of the connecting-up and development of central GABA-ergic components in the regulation of embryonic motility.     

The significance of extracellular Ca<Superscript>2+</Superscript> in contractile responses of chick amnion

Neurotransmitter receptors are formed during chick embryo development in the amnion, an avascular extraembryonic membrane devoid of innervation. Carbachol induces phasic and tonic contractions mediated by M₃ cholinoceptors in an amniotic membrane strip isolated from 11–14-day-old chick embryo. The carbachol effect on the amnion contractile activity was studied in normal physiological salt solution, during depolarization by K⁺, exposure to nifedipine, and in calcium-free medium. Voltage-dependent and receptor-operated Ca²⁺ channels as well as calcium from intracellular stores are involved in the contractile response to carbachol. Phasic contractions of the amnion are mainly induced by calcium ions entering through voltage-dependent calcium channels, while tonic contractions are also maintained by receptor-operated channels. Ca²⁺-activated potassium channels can serve as a negative feedback factor in regulation of the amnion contractile responses.     

Naturally occurring wounds and wound healing in chick embryo wings

Summary Spontaneous cutaneous wounds occur in avian embryos (chick, duck, quail) in various prominent parts of the body, notably the elbow, the knee and the outer face of feather buds. The frequency and size and the light and electron microscopic morphology of elbow wounds in the chick embryo are described. The cutaneous lesion appears in over 80% of the embryos at around 7 days of incubation, persists through 14 days, and finally heals completely at around 16 days of incubation. No trace of the wound is visible after that age. Wound healing of these spontaneous lesions was analysed with light microscopy (using indirect immunofluorescence for the localization of type I collagen, fibronectin and laminin) and electron microscopy. The main feature of the very slow healing process, as compared with the rapid cicatrization of experimental excision wounds, appears to be a continuous damage of the healing epidermis, until, finally, definitive wound closure occurs between 14 and 16 days of incubation. In the damaged region, where the epidermis is absent, the dermis exhibits an increased density of type I collagen fibres and of fibronectin. The upper face of the bare dermis is deprived of laminin. Spontaneous lesions do not occur in isolated wings explanted on the chick chorioallantoic membrane, where the wings do not become mobile and are not in contact with the amnion. The observations and explantation experiments suggest that the skin damage is caused by friction and abrasion of the bending elbow against the amnion or the amniotic fluid.