Developmental changes in glycosaminoglycans,collagen and collagenase activity in embryonic chick skin

In order to study remodelling of connective tissue during development, changes in glycosaminoglycans, collagen and collagenase activity in embryonic chick skin at various stages have been studied.Collagen content in the skin increased rapidly during days 14 to 18, then leveled off until hatching. Prior to the increase of collagen deposition in the skin, a sharp decrease in chondroitin sulfate was observed between days 11 and 14, while dermatan sulfate increased almost 4 fold during days 12 to 14, then increased steadily until hatching. Hyaluronic acid decreased progressively during the stages investigated (days 11 to 20).At the same stage as the rate of collagen deposition in the tissue became maximal (day 16), the amount of dialyzable hydroxyproline showed a maximum indicating that an increased rate of collagen deposition in the tissue was accompanied by accelerated collagenolysis.Culture of skin from various stages of embryonic development revealed that 16 day old tissue was potentially capable of secreting the highest levels of collagenase. This collagenase was mostly inactive against soluble collagen and collagen fibrils but could be activated by 3 M NaSCN treatment.     

Hyaluronidase activity and hyaluronate content of the developing chick embryo heart.

Hyaluronidase activity and hyaluronate content were measured in the developing chick heart from embryonic day 3 through posthatching stages. High levels of both enzyme and substrate were found during the earliest stages examined. Hyaluronidase activity gradually declined to 63% of the initial (day 3) level by embryonic day 16. Enzyme activity decreased more sharply during the next 4 days to 30% of the initial level and remained constant through 2 weeks after hatching. Low levels of enzyme activity (about 10% initial levels) were still detectable in 10-week-old chicken hearts. The heart hyaluronidase is an endoglycosidase with an estimated molecular weight of 62,000, which degrades hyaluronate and, to a lesser extent, chondroitin sulfate at an acid pH optimum. Hyaluronate constituted approximately 50% of the total glycosaminoglycan content at embryonic day 5. Between embryonic days 5 and 12, the concentration of hyaluronate decreased to 25–30% of the initial level and remained constant thereafter. The level of other glycosaminoglycans decreased more gradually than hyaluronate and did not reach a constant level until hatching. This pattern of hyaluronidase activity and hyaluronate concentration presumably reflects the extensive tissue remodeling which transforms the developing heart from a thin-walled tube containing extensive regions of extracellular matrix to a compact, thick-walled myocardium having a limited extracellular compartment.     

Ontogenic change in tissue osmolality and developmental sequence of mitochondria-rich cells in Mozambique tilapia developing in freshwater

We investigated a change in tissue fluid osmolality and developmental sequences of mitochondria-rich (MR) cells during embryonic and larval stages of Mozambique tilapia, Oreochromis mossambicus, developing in freshwater. Tissue osmolality, representing body fluid osmolality, ranged from 300 to 370 mOsm/kg during embryonic and larval stages. This suggests that tilapia embryos and larvae are also able to regulate body fluid osmolality to some extent, although the levels are somewhat higher and fluctuate more greatly in embryos and larvae than in adults. Na⁺/K⁺-ATPase-immunoreactive MR cells were first detected in the yolk-sac membrane 3 days before hatching (day − 3), followed by their appearance in the body skin on day − 2. Subsequently, MR cells in both the yolk-sac membrane and body skin increased in number, and most densely observed on days − 1 and 0. Whereas yolk-sac and skin MR cells decreased after hatching, MR cells in turn started developing in the gills after hatching. Thus, the principal site for MR cell distribution shifted from the yolk-sac membrane and body skin during embryonic stages to the gills during larval stages, and tilapia could maintain continuously their ion balance through those MR cells during early life stages.     

Changes in sterol metabolism in the skin of developing chick embryo and alterations in the presence of an anticholesterolemic agent and a chemical carcinogen

Changes in sterol metabolism in the skin of chick embryo during its development were studied with embryonal chick skin and with the cultured skin tissues. Changes in sterol metabolism of the skin of chick embryo began to appear at day 17, as observed by the accumulation of dihydrolanosterol, and the ratio of dihydrolanostrol:cholesterol increased thereafter until hatching. A similar change in sterol metabolism was also observed with the cultured skin tissue of chick embryo, although the stages of development seem to have been delayed by 3 days. The active sterol metabolism of the cultured skin tissue was also confirmed by studies of incorporation of [2-14C]acetate into sterols. 20,25-Diazacholesterol almost completely inhibited the incorporation of [2-14C]acetate into C27 sterols, whereas a chemical carcinogen, 4-hydroxyaminoquinoline 1-oxide, inhibited the incorporation of [2-14C]acetate into lathosterol but not that into cholesterol.     

Variation of DNA polymerase activities in chick neural retina as a function of age

The activities of DNA polymerases alpha, beta, and gamma and of thymidine kinase were determined in the chick neural retina at different stages of embryonic development (starting at seven days) and after hatching (up to five years). Crude extracts of neural retinae were fractionated by centrifugation on sucrose gradients and the enzymatic activities measured using specific assays. The DNA polymerase alpha activity decreases greatly between 7 and 11 days of incubation. This decrease parallels the decline in mitotic activity. However, a constant residual activity remains after hatching, even in the oldest animals. DNA polymerase beta activity increases slightly between 7 and 14 days of incubation; it then decreases slowly until seven days after hatching and remains constant thereafter. DNA polymerase gamma activity is maximal between 7 and 14 days of incubation and then decreases until hatching. The activity of thymidine kinase increases slightly during the embryonic life until hatching and remains almost constant thereafter. The implication of these enzymes in DNA replication and repair processes is discussed.     

Variation of DNA Polymerase Activities in Chick Neural Retina as a Function of Age

The activities of DNA polymerases α, β, and γ and of thymidine kinase were determined in the chick neural retina at different stages of embryonic development (starting at seven days) and after hatching (up to five years). Crude extracts of neural retinae were fractionated by centrifugation on sucrose gradients and the enzymatic activities measured using specific assays. The DNA polymerase a activity decreases greatly between 7 and 11 days of incubation. This decrease parallels the decline in mitotic activity. However, a constant residual activity remains after hatching, even in the oldest animals. DNA polymerase β activity increases slightly between 7 and 14 days of incubation; it then decreases slowly until seven days after hatching and remains constant thereafter. DNA polymerase γ activity is maximal between 7 and 14 days of incubation and then decreases until hatching. The activity of thymidine kinase increases slightly during the embryonic life until hatching and remains almost constant thereafter. The implication of these enzymes in DNA replication and repair processes is discussed.     

Collagen synthesis in the muscle of developing chick embryos.

Radioactive protein was prepared from the leg muscle of chick embryos, 11, 14, 16 and 17 days old, each injected with radioactive proline and incubated for 30, 60 or 90 min afterwards. The radioactive protein was incubated with collagenase purified by chromatography on a Sephadex G-100 column. Under this condition, only collagen is digested into products soluble in trichloroacetic acid. The relative rate of collagen synthesis was determined by comparing the amount of radioactivity released into the supernatant fraction and that in the residue, by the method of Diegelmann & Peterkofsky [(1972) Dev. Biol. 28, 443--453]. The results show that the rate of collagen synthesis remains at approx. 10% of the rate of synthesis of other non-collagenous proteins during the development of chick embryonic muscle from 11 to 17 days. This suggests that the synthesis of collagen and that of other proteins are co-ordinately regulated at these stages of development.     

Hepatic zinc,copper, and iron in the developing turkey embryo and newly hatched poult

The ontogeny of hepatic tissue growth and trace metal deposition was examined in the developing turkey embryo and newly hatched poult. Hepatic concentrations of zinc and iron in the embryo declined by about twofold between day 16 of incubation and hatching. Hepatic copper concentration increased approximately fourfold by day 23 of incubation and then declined rapidly through hatching. During the post-hatching period, hepatic zinc concentration increased twofold by day 10, whereas a small increase in hepatic iron concentration occurred just prior to hatching and continued through the third day post-hatching. A significant positive correlation existed between hepatic zinc and iron concentrations in the developing embryo. The concentrations of both these metals were inversely correlated with hepatic copper concentration during the same time. Total hepatic zinc and iron content increased throughout the entire time studied, whereas total copper content increased up to hatching and then declined during the first week post-hatching. The most rapid phase of hepatic metal accretion differed for each metal, with zinc being rapidly accumulated during the post-hatching period, copper during the last half of incubation and iron at about the time of hatching and the first few days post-hatching. Each of these metals demonstrated a specific relationship to hepatic tissue growth that changed between the embryonic and neonatal periods of development.     

Effect of the sex-linked dwarf gene on thyrotrophic and somatotrophic axes in the chick embryo

Plasma concentrations of thyroxine (T4), triiodothyronine (T3), reversed triiodothyronine (rT3), and insulin-like growth factors I and II (IGF-I, IGF-II) together with peripheral 5'-monodeiodination activity were measured in both normal and sex-linked dwarf embryos between day 14 of incubation and day 1 posthatch. Plasma T4 levels increased gradually during embryonic development while T3 concentrations remained low until day 20, when a sharp increase was observed. rT3 levels also increased from day 14 and dropped on day 20 when T3 levels started to increase. 5'-monodeiodination activity was high on day 14 of incubation, decreased thereafter, and showed an increase at the time of air sac penetration together with increased T3 levels. At this stage, differences between normal and dwarf embryos were observed; the latter had lower nonsignificant 5'-Monodeiodination activity and lower (P less than 0.01) plasma T3 levels. Plasma IGF-II levels were high during the whole embryonic period studied. Dwarf embryos had lower (P less than 0.05) IGF-II levels at the time of hatching. IGF-I levels were high on days 14 and 16, declined afterwards, and started to increase again around hatching. With the exception of T3 and IGF-II levels, introduction of the dwarf gene did not cause major changes in the hormonal parameters studied. This may explain the identical body weight at hatching.     

Long-term measurement of heart rate in chicken eggs

Taking advantage of acoustocardiogram (ACG), we measured the heart rate (HR) of chick embryos continuously from day 12 until hatching and then investigated the development of HR irregularities (HRI), HR variability (HRV), and the existence of a circadian rhythm in mean HR (MHR). HRI comprised transient bradycardia and tachycardia, which first developed on day 14 and 16 in most embryos, respectively. Transient bradycardia increased in frequency and magnitude with embryonic development and occurred over periods of up to 30 min in some embryos. MHR was maximal on around days 14-15 and thereafter decreased to about 250-260 bpm on days 16-18. Baseline HRV, which is an oscillation of the MHR baseline, occurred as HR decreased from days 15-16 and became predominant on days 17-18. The magnitude of the baseline oscillations reached up to 50 bpm in some embryos and the period ranged between about 40-90 min (ultradian rhythm). A circadian rhythm of MHR was not found in late chick embryos. On days 18-19, embryonic activities were augmented and then breathing movements began to occur, disturbing ACG signals and thus making it difficult to measure the HR. Instead, the development of breathing activities was recorded. Breathing frequency was irregular at first and then increased to a maximum of about 1.5 Hz prior to hatching.     

Meiotic prophase in the left embryonic testis of the Japanese quail (Coturnix coturnix japonica L.)

Spontaneous, transitory feminization of the left embryonic testis occurs in the majority of male Japanese quails from day 11 of incubation until the 2nd day after hatching. The feminized gonad is composed of a testicular part and of an ovarian-like cortical region, which develops outside the tunica albuginea. The cortical region contains numerous germ cells some of which enter meiosis on day 11 (i.e. at the time characteristic of female germ cells) and reach pachytene on day 14. Cortical regions are best developed on day 16 (day of hatching), but regression, accompanied by degeneration of many germ cells, begins shortly afterwards. The mechanism of feminization of the left embryonic testis is discussed.     

Expression of murine Ia antigens during embryonic development.

An immunochemical analysis of the kinetics of appearance of Ia antigens during embryonic development was performed. Ia antigens first appear on the surface of embryonic cells 11 days postconception and their expression between days 11 and 16 of gestation is confined to the fetal liver. Ia antigen synthesis by fetal liver cells is detectable at day 14. Ia seems to precede Ig as a surface marker of embryonic liver cells, since Ig cannot be detected until day 16 of gestation. H-2 antigens may be immunoprecipitated from day 10 whole embryo cells. F9 primitive teratocarcinoma cells are Ia negative and H-2 negative.     

Ontogeny of the carotid body and glomus cells distributed in the wall of the common carotid artery and its branches in the chicken

Summary Developmental patterns of immunoreactivity for serotonin and neuropeptide Y were investigated immunohistochemically in the carotid body and glomus cells in the wall of the common carotid artery and around its branches of chickens at various developmental ages. The development of peptidergic nerve fibers was also studied. Serotonin immunoreactivity began to appear in the glomus cells of the carotid body and around arteries at 10 days of incubation and became very intense from 12 days onwards. Neuropeptide Y immunoreactivity also appeared in these cells at 10 days, became intense at 14 days, and was sustained until 20 days. After hatching, neuropeptide Y immunoreactivity in the carotid body rapidly decreased with age and almost cisappeared at posnatal day 10. However, it persisted for life in the glomus cells distributed in the wall of the common carotid artery. Substance P- and calcitonin gene-related peptide (CGRP)-immunoreactive fibers first penetrated into the carotid body parenchyma at 12 days of incubation. These peptidergic nerve fibers in the carotid body and glomus cell groups in and around arteries gradually increased with age, and approached the adult state at 18 days of incubation. Only a few galanin-and vasoactive intestinal peptide (VIP)-immunoreactive fibers were observed in the late embryonic carotid bodies. They rapidly developed after hatching and reached adult numbers at postnatal day 10. During late embryonic and neonatal development, considerable numbers of met-enkephalin-immunoreactive fibers were detected in the connective tissue encircling the carotid body.     

Procollagen intermediates during tendon fibrillogenesis

The purpose of this study was to correlate ultrastructural features of tendon collagen fibrils at various stages of development with the presence of procollagen, pN-collagen, pC-collagen, and the free amino propeptides and carboxyl propeptide of type I procollagen. Tendons from 10-, 14-, and 18-day chicken embryos reveal small, well-defined intercellular compartments containing collagen fibrils with diameters showing a unimodal distribution. At 21 days (hatching) and 9 days (post hatching) and at 5 weeks (post hatching), the compartments are larger, less well-defined, and there is multimodal distribution of tendon fibril diameters. Procollagen and the intermediates pN-collagen and pC-collagen are present in tendons up to 18 days. Thereafter there is a marked reduction in procollagen, whereas the intermediates persist throughout all stages of development. Similarly, free amino propeptides and carboxyl propeptides of type I procollagen were found at all stages. The amino propeptide of type III procollagen was restricted to the peritendineum until 7 weeks post hatching. At that time, a network of fibrils containing the amino propeptide of type III procollagen was seen delineating well-circumscribed compartments of collagen fibrils throughout the entire tendon. This study supports the notion that pN- and pC-collagen have an extracellular role and participate in collagen fibrillogenesis.     

Histochemical analysis of newly synthesized and accumulated sulfated glycosaminoglycans during musculogenesis in the embryonic chick leg

The leg musculature from 11, 14, and 17 day chick embryos was analyzed histochemically to investigate the temporal and spatial distribution of various types of sulfated glycosaminoglycans present during skeletal muscle development. Types of glycans were identified by selective degradation with specific glycosidases and nitrous acid coupled with Alcian blue staining procedures for sulfated polyanions and with [35S]sulfate autoradiography. On day 11, radiolabeled chondroitin sulfate glycosaminoglycans are localized extracellularly in both the myogenic and connective tissue cell populations. By day 17, incorporation of [35S]sulfate into chondroitin sulfate is substantially reduced, although Alcian blue-stained chondroitin sulfate molecules are still detectable. With increasing age and developmental state of the tissues, radiolabeled and stained dermatan sulfate and heparan sulfate progressively increase in relative quantity compared to chondroitin sulfate both in muscle and in associated connective tissue elements. These changes in glycosaminoglycans correlate well with similar changes previously determined biochemically and further document the alterations in extracellular matrix components during embryonic skeletal myogenesis.     

Co-ordinated induction of beta-carotene cleavage enzyme and retinal reductase in the duodenum of the developing chicks

The developmental patterns of expression of beta-carotene cleavage enzyme activity were compared with those of retinal reductase and NAD-dependent retinol dehydrogenase activities in chick duodenum during the perinatal period. The beta-carotene cleavage enzyme activity was not detected in the duodenum before hatching, but it increased rapidly during 24 h after hatching. On the other hand, a considerable level of beta-carotene cleavage enzyme activity was observed in the liver of embryonic stages and its activity gradually rose during the perinatal period. Comparison of kinetic constants for the beta-carotene cleavage enzyme activities in the duodenum and the liver indicated that the enzyme in the duodenum possessed a lower affinity for beta-carotene than that in the liver. The retinal reductase activity was detected in the microsomes of the duodenum at the earliest time examined, i.e. day 16 of embryogenesis and its activity began to rise on the last day of embryogenesis, which was followed by a gradual increase until 1 day of age. The NAD-dependent retinol dehydrogenase activity was also seen in the microsomes of the duodenum in embryonic stages and its activity increased in parallel with the retinal reductase activity around the hatching period. These developmental inductions of beta-carotene cleavage enzyme and retinal reductase activities in the duodenum coincided with those of cellular retinol-binding protein, type II (CRBPII) and lecithin: retinol acyltransferase (LRAT). These results suggest that a co-ordinated induction mechanism should be operative for beta-carotene cleavage enzyme and retinal reductase, both of which are inevitable in the process of beta-carotene absorption and metabolism.     

Changes in catecholamines and dopaminergic metabolites in pigeon brain during development from the late embryonic stage toward hatch

While brain development during embryogenesis has been extensively studied in precocial birds, there is no information available on altricial birds. Thus, the concentrations of the catecholamines norepinephrine (NE), epinephrine (E), and dopamine (DA), and the dopaminergic metabolites 3,4-dihydroxyphenylacetic acid (DOPAC) and 4-hydroxy-3-methoxyphenylacetic acid (HVA) were determined at several stages during the late embryonic period (E13, E14, E15, E16, E17 and E18) and the day-of-hatch (P0) in the pigeon telencephalon, cerebellum, optic lobe, and brainstem. The concentrations of all catecholamines were higher than those reported in chicken embryos. During embryogenesis, NE, E, DOPAC and HVA concentrations in the various brain parts increased throughout embryonic development until shortly before hatching at which time they decreased. DA, however, continued to increase through hatching in the brainstem, and the changes in DA concentrations varied in several brain parts. In conclusion, catecholamine concentrations in the various brain parts tended to increase with embryonic age, and the concentrations were higher than those in chickens. Furthermore, brain catcholamine metabolism changed at hatch in pigeons.     

CHICK BRAIN CREATINE KINASE ONTOGENY BEFORE THE ADVENT OF CREATINE AND INSULIN

The ontogeny of brain creatine kinase (CK) was studied during chick embryo development. The cytosolic activity increased 270% in 10 h from the 2nd to the 3rd days of incubation; this was followed by a plateau phase throughout development and at the end of incubation there appeared to be another increase of cytosolic and mitochondrial CK activities. Therefore, early embryonic chick brain CK is another‘constitutive’enzyme like the early embryonic chick heart CK since creatine has not been enzymatically detected in the embryo until day 4 of incubation. Insulin does not appear to stimulate the early increase of brain CK activity since the hormone is not present in the embryo until day 5 of incubation. It is likely that CK increase is associated with neuronal multiplication at early stages and possibly to neuronal maturation before hatching.