Structure and function of the hydropyle of the egg of the bug, Sphaerodema molestum

Changes in the wet weight, dry weight, and volume of the egg of Sphaerodema molestum during embryonic development have been studied. Also, experiments have been carried out to ascertain the route of entry of water from the environment into the egg.During development the eggs considerably increase their volume and wet weight while their dry weight progressively decreases. When the eggs of S. molestum are incubated in dye solutions, the latter penetrate through the chorionic hydropyle and reach the outer surface of the serosal hydropyle. This indicates that water enters in significant quantity through the chorionic and serosal hydropyles. The behaviour of 48-hr-old experimental eggs of S. molestum, in which the entry of water is blocked, further confirms that the intake of water is effected only through the hydropyles. The significance of the uptake of water in the eggs is discussed in relation to protein metabolism during embryogenesis.     

Histomorphological study on embryogenesis of the honeybee Apis cerana

As important pollination species, honeybees play substantial impacts on the balance of global ecosystem, including two best-known honeybees Apis mellifera and Apis cerana. Embryogenesis is a fundamental stage of honeybee development and plays important roles in supporting the whole-life developmental process. However, few studies were reported on honeybee embryonic morphology using egg section, possibly due to the fragility of honeybee eggs and the difficulty of making embryonic sections. In this study, we reported a simply equipped method of frozen sectioning and PI (propidium iodide) staining to show the inner structure and cell distribution of A. cerena embryos at the different embryonic developmental stages. We found that the stages of A. cerena embryogenesis could also be typically classified into ten developmental stages, which are similar with the sister honeybee species, A. mellifera. To be noted, besides the cell distribution in the whole egg, we clearly observed the migration route of embryonic cells during the early embryonic development in A. cerena. This study provides a new insight into the whole process of honeybee embryogenesis from the perspective of egg sectioning, a histological basis for genetic manipulation using A. cerena eggs, and a reference method for egg sectioning for other insect species.     

Changes in lipid and fatty acid composition of eggs during development of the beet armyworm, Spodoptera exigua

The dry weight of Spodoptera exigua eggs decreased by 15·9 μg/egg or 64% of initial weight during embryogenesis and development of pharate first instar larvae. Lipid depletion accounts for 36% of this total dry weight loss and this occurs at an essentially constant rate throughout development. This marks S. exigua as an exception since most insects utilize lipids more rapidly during later developmental stages. Lipid depletion is due primarily to triglyceride catabolism, although phospholipids also decrease significantly.Fatty acid composition remains stable during development. In triglycerides, 18:1 is most common followed by 16:0 and 18:2; in the phospholipids, the order of abundance is 18:1, 18:2, and 16:0. Egg fatty acids differ from dietary fatty acids: 16:1 comprises 7% of triglyceride fatty acids although it is not present in the larval media; 18:1 predominates in the egg whereas 18:2 is most abundant in the diet.     

Occurrence of d-alanine in the eggs and the developing embryo of the sea urchin Paracentrotus lividus

• 1.1. d-Alanine has been found in appreciable amounts in the eggs and embryos of the sea urchin Paracentrotus lividus.
• 2.2. The content of d-alanine, expressed as pmol/egg or embryo, is 1.32 in the egg, 0.81 in the blastula, 0.54 in the gastrula and 0.60 in the pluteus.
• 3.3. The percentage of d-alanine with respect to the total alanine (d + l) decreases during embryonic development.
• 4.4. d-Amino acid oxidase, d-alanine transaminase and d-alanine racemase activities were found neither in eggs nor in embryos.
• 5.5. Therefore, it does not appear likely that d-alanine is subject to oxidative metabolism.
• 6.6. The decrease in this d-amino acid during development may be due to its utilization in the synthesis of a more complex molecule.

     

Repair of a genetically-caused defect in oogenesis in Drosophila melanogaster by transplantation of cytoplasm from wild-type eggs and by injection of pyrimidine nucleosides

Eggs produced by homozygous mutant rudimentary (r⁹, 154.5) females of Drosophila melanogaster die during embryogenesis, apparently because the mutant female fails to incorporate certain substances into the egg during oogenesis. These eggs can be rescued by injecting them at the preblastoderm stage with wild-type nuclei and cytoplasm or wild-type cytoplasm alone from unfertilized eggs. Some preblastoderm eggs injected with 1.5% of egg volume of cytoplasm from unfertilized wild-type eggs were able to complete both embryonic and postembryonic development and emerged as adults, whereas not a single uninjected control egg was able to complete embryonic development. The eggs of rudimentary mothers can also be rescued by injecting each egg at the blastoderm stage with 0.01 μg of pyrimidine nucleosides. The results demonstrate that a pyrimidine deficiency is the cause of abortive embryogenesis, and confirm the previous finding that the rudimentary mutation leads to pyrimidine auxotrophy.     

Effect of elevated carbon dioxide on chicken eggs during the early and late incubation periods

Carbon dioxide (CO₂) is always maintained at ambient levels by ventilation in commercial egg incubators. However, elevated CO₂ levels during the early and late periods have been reported to improve the quality of chicks and shorten the hatch window. This study investigated the effect of precise CO₂ supplementation during the early and late periods of incubation on embryo growth and incubation performance by developing and using a CO₂ supplementation system to increase the CO₂ level in an experimental egg incubator. The CO₂ level was maintained at 1% in the early period (from the beginning to the 10th day of incubation, E0–E10) and in the late period (from internal pipping (IP) to the 21st day of incubation (E21), IP–E21) in an incubator for the treatment group, whereas the CO₂ level was maintained at the ambient level in the other incubators for the control group. A comparative assessment of embryonic development, hatching characteristics, and hormone and nutrient levels was conducted for each trial. The experiment comprised three trials, with 300 Jing Hong No. 1 breeding eggs in each incubator. The elevated CO₂ treatment significantly shortened the chick hatching time (H0) by 4 h (P < 0.05) and the hatch window by 3 h (P < 0.05) without affecting hatchability, chick weight at 1 d of age, brooding period, or quality score. At external pipping (EP), the heart weight, intestinal weight, relative intestinal weight, and relative heart weight in the treatment group were significantly higher than those in the control group (P < 0.05). In addition, the embryonic intestine, relative intestine, and relative heart weights of the newly hatched chicks in the treatment group were significantly higher than those in the control group (P < 0.05) at H0. The treatment significantly increased the concentration of corticosterone in the embryonic plasma during the period from IP to EP (P < 0.05), promoted the secretion of triiodothyronine and tetraiodothyronine (P < 0.05), and increased the glycogen content of the embryonic liver on E21 (P < 0.05). This result indicates that elevated CO₂ (1%) during the early and late periods of incubation accelerated embryonic organ development and shortened the chick hatching time and hatch window without affecting hatchability or hatchling quality, which can be explained by the synergistic functions of the secretion of plasma corticosterone and thyroid hormones and the accumulation of liver glycogen between the early and late periods of incubation.     

Effect of a development-stimulating pheromone on the embryo of Chironomus dorsalis

A physiological active substance was found in the egg mass of Chironomus dorsalis contained in the proximal adhesive cap of the egg mass. It promoted embryonic development by penetrating gradually into the egg part. As a result, embryonic development in the proximal part of the egg mass usually appeared earlier than that in the distal part. We name this substance a development-stimulating pheromone because it acts to the whole process of development up to hatching.     

The cooling time of fertile chicken eggs at different stages of incubation

We asked whether or not the thermal characteristics of fertile avian eggs changed throughout incubation. The cooling and warming times, expressed by the time constant τ of the egg temperature response to a rapid change in ambient temperature, were measured in fertile chicken eggs at early (E7), intermediate (E11) and late (E20) stages of embryonic development. Same measurements were conducted on eggs emptied of their content and refilled with water by various amounts. The results indicated that (1) the τ of a freshly laid egg was ~50 min; (2) τ decreased linearly with the drop in egg water volume; (3) the dry eggshell had almost no thermal resistance but its wet inner membrane contributed about one-third to the stability of egg temperature; (4) the egg constituents (yolk, albumen and embryonic tissues) and the chorioallantoic circulation had no measurable effect on τ; (5) the presence of an air pocket equivalent in volume to the air cell of fertile eggs reduced τ by about 3 min (E7), 5 min (E11) and 11 min (E20). Hence, in response to warming the egg τ at E20 was slightly shorter than at E7. In response to cooling, the egg τ at E20 was similar to, or longer than, E7 because embryonic thermogenesis (evaluated by measurements of oxygen consumption during cold) offset the reduction in τ introduced by the air cell. In conclusion, until the onset of thermogenesis the thermal behavior of a fertile egg is closely approximated by that of a water-filled egg with an air volume equivalent to the air cell. It is possible to estimate the cooling τ of avian eggs of different species from their weight and incubation time.     

Glycogen and Glucose Metabolism Are Essential for Early Embryonic Development of the Red Flour Beetle Tribolium castaneum

Control of energy metabolism is an essential process for life. In insects, egg formation (oogenesis) and embryogenesis is dependent on stored molecules deposited by the mother or transcribed later by the zygote. In oviparous insects the egg becomes an isolated system after egg laying with all energy conversion taking place during embryogenesis. Previous studies in a few vector species showed a strong correlation of key morphogenetic events and changes in glucose metabolism. Here, we investigate glycogen and glucose metabolism in the red flour beetle Tribolium castaneum, an insect amenable to functional genomic studies. To examine the role of the key enzymes on glycogen and glucose regulation we cloned and analyzed the function of glycogen synthase kinase 3 (GSK-3) and hexokinase (HexA) genes during T. castaneum embryogenesis. Expression analysis via in situ hybridization shows that both genes are expressed only in the embryonic tissue, suggesting that embryonic and extra-embryonic cells display different metabolic activities. dsRNA adult female injection (parental RNAi) of both genes lead a reduction in egg laying and to embryonic lethality. Morphological analysis via DAPI stainings indicates that early development is impaired in Tc-GSK-3 and Tc-HexA1 RNAi embryos. Importantly, glycogen levels are upregulated after Tc-GSK-3 RNAi and glucose levels are upregulated after Tc-HexA1 RNAi, indicating that both genes control metabolism during embryogenesis and oogenesis, respectively. Altogether our results show that T. castaneum embryogenesis depends on the proper control of glucose and glycogen.     

Accumulation and storage sites of uric acid in the developing egg of Schistocerca gregaria (Forskål) (Orthoptera: Acrididae)

An account is given of uric acid accumulation in the egg of Schistocerca gregaria during the course of embryonic development and its storage sites in the egg.     

Cytidinediphosphate diacylglycerol synthase—Mediated phosphatidic acid metabolism is crucial for early embryonic development of Arabidopsis

Embryonic development is a key developmental event in plant sexual reproduction; however, regulatory networks of plant early embryonic development, particularly the effects and functional mechanisms of phospholipid molecules are still unknown due to the limitation of sample collection and analysis. We innovatively applied the microspore-derived in vitro embryogenesis of Brassica napus and revealed the dynamics of phospholipid molecules, especially phosphatidic acid (PA, an important second messenger that plays an important role in plant growth, development, and stress responses), at different embryonic developmental stages by using a lipidomics approach. Further analysis of Arabidopsis mutants deficiency of CDS1 and CDS2 (cytidinediphosphate diacylglycerol synthase, key protein in PA metabolism) revealed the delayed embryonic development from the proembryo stage, indicating the crucial effect of CDS and PA metabolism in early embryonic development. Decreased auxin level and disturbed polar localization of auxin efflux carrier PIN1 implicate that CDS-mediated PA metabolism may regulate early embryogenesis through modulating auxin transport and distribution. These results demonstrate the dynamics and importance of phospholipid molecules during embryo development, and provide informative clues to elucidate the regulatory network of embryogenesis.     

Organic,inorganic, and caloric composition of eggs,pentaculae, and adults of the brooding sea cucumber Cucumaria curata cowles (Echinodermata: Holothuroidea)

Levels (percentage composition) of water, ash, carbohydrate, lipid, protein, and calories were determined for eggs, pentaculae, and adults of the sea cucumber Cucumaria curata Cowles. Component contents (μg/individual) were calculated for eggs and pentaculae. During the 28 days of development to hatching, the large yolky eggs gain water and ash, the total dry weight increasing from 169 to 190 μg/egg during embryogenesis. There were no statistically significant changes in lipid, protein, and caloric contents during embryogenesis, but carbohydrate decreased by 0.82 μg/egg.The decrease in carbohydrate is sufficient to account for estimated embryonic energy requirements. Based on the utilization of carbohydrate, embryos of C. curata show a nutritional pattern similar to that of the planktonic embryos of sea urchins and different from that of embryos developing from terrestrial eggs, freshwater eggs, and planktonic and demersal marine eggs.Although broods varied widely in egg number and mean egg dry weight, C. curata gives eggs which contain a constant proportion of organic components.Levels of ash, water, and protein in the adults exceeded those in the pentacula, and lipid comprises a much smaller proportion of the adult body than it did of the pentacula.     

Energetics during embryonic development in kurosoi,Sebastes schlegeli Hilgendorf

Studies on the live-bearing scorpaenid genus Sebastes have recently shown that embryos of one species receive nutrition in addition to that supplied in the yolk. In this large genus, however, reproductive characteristics may differ among species. Energetics of embryonic development in kurosoi, Sebastes schlegeli Hilgendorf, were analyzed to determine the patterns of embryonic nutrition. The egg of this species is larger and contains over three times the energy content of that in S. melanops, another species which has been studied. Catabolism during the 51 days of embryonic development required 88% of the original energy in the egg, but the embryo at birth contained 93% of the initial egg energy. Thus the total energy required for development from fertilization to birth requires ≈1.8 times the initial, endogenous energy supply. Histological studies demonstrate that uptake occurs through ingestion and absorption of ovarian fluid in the hindgut. Protein and nitrogen budgets during development suggest that the primary substance taken up is nitrogenous.No distinct structures are apparent in the ovarian system to supply nutrients to the developing embryos. Analysis of fecundity-at-length, however, shows that post-fertilization fecundity estimates are significantly lower than pre-fertilization values; the reduction apparently occurs through resorption of ova or early embryos. Along with catabolism, this results in an overall decrease in the energy content of the ovaries during development, but the total amounts of protein and nitrogen remain nearly static. We thus suggest that resorption of unfertilized ova or early embryos which die may enrich the ovarian fluid and supply energy to the surviving embryos. This is a primitive form of embryonic nutrition in viviparous species and may be common in the genus Sebastes.     

Dynamics of the growth,life history transformation and photosynthetic capacity of Oophila amblystomatis (Chlorophyceae), a green algal symbiont associated with embryos of the northeastern yellow spotted salamander Ambystoma maculatum (Amphibia)

The recent discovery that the unicellular green alga Oophila amblystomatis, invades embryonic tissues and cells of the salamander Ambystoma maculatum prompted us to investigate the growth and life history transformations of the algal symbionts in egg capsules. During embryonic development, symbionts were first detected microscopically as a cohesive population of swimming cells in the vicinity of the blastopore around embryonic stage 17. This population of cells grew and at embryonic stage 25, a fraction of the population began to affix to the inside of the egg capsule. Cells then underwent syngamy, lost flagella, and transformed into non-motile cells. We observed a linear increase in the accumulation of such capsule-associated cells from embryonic stage 25 to 40. The population of zoospores did not grow over this period and showed a declining trend between stage 39 and 40. We verified the population growth by measuring relative chlorophyll a content and also measured quantum yield (QY) of photosystem II (PS II) using pulse amplitude modulated (PAM) fluorometry. The population, but not the cell size, of non-motile capsule membrane-bound cells increased modestly during a one-month period after hatching, and continued to contain high levels of chlorophyll a and photosynthetic capacity. We conclude that O. amblystomatis undergoes a life history transition in egg capsules and speculate that many of these symbionts become zygotes, rather than invading the embryo.     

Biometrical relationships in developing eggs and neonates of Octopus vulgaris in relation to parental diet

Captive Octopus vulgaris adults were fed three mono-diets based on pilchard, crab and squid and allowed to grow until reproduction under controlled temperature. Spawns from each dietary treatment were isolated, and the embryonic development, egg length, width and wet weight, in addition to neonate dry weight, dorsal mantle length and ventral mantle length were monitored. Pilchard-diet spawns developed faster in terms of thermal time. Initial egg wet weight was higher for squid and crab diets. Irrespective of the parental diet, eggs passed through a swelling process so that egg width and wet weight increased in a nonlinear way, whereas egg length was left nearly unaffected. Egg length and initial wet weight showed a high correlation with neonate dry weight. Egg length, even at advanced incubation, can be used as a good proxy for neonate dry weight, this fact having potential implications for the ecological and aquaculture research on O. vulgaris.     

Modelling and quantification of the thermoregulatory responses of the developing avian embryo: Electrical analogies of a physiological system

Homeothermic animals, including birds, try to keep their body temperature at a constant level within certain boundaries by using thermoregulatory mechanisms. However, during incubation, the thermoregulatory system of the chicken embryo evolves through different stages from a poikilothermic to a homeothermic system. Hence, the thermal response of the fertile egg to changes in ambient temperature is different from one day to another during the embryonic development. The incubated egg can be considered as a physical (thermal) system, which transfers energy (heat) down a potential gradient (temperature difference). The heat flow between the micro-environment and the eggshell under a thermal driving force (temperature difference) has been studied in the past by using the analogy to the flow of electric charge under an electromotive-force. In this work, the thermal-response of incubated eggs to a step-increase in ambient-air temperature is studied and modelled. It is shown that the incubated egg is reacting as a first-order system between embryonic days ED01 and ED13, while, starting from ED14, the egg is reacting as a second-order system. This extends the existing RC (resistor–capacitor) circuit analogue to an RLC (resistor–inductor–capacitor) circuit analogue at the later stage of incubation. The concept of considering the fertile egg and its surrounding environment as an energy-handling device is introduced in this paper. It is suggested that the thermoregulation of the embryo has a thermal induction-like effect starting from ED14 and increasing gradually till hatching.     

Ecdysone titre and metabolism in relation to cuticulogenesis in embryos of Locusta migratoria

Eggs of Locusta migratoria contain remarkably high concentrations of ecdysone and several other ecdysteroids. During the time-span of embryonic development (11 days) 4 distinct peaks of ecdysone concentration (up to 8 μM) are observed in the egg, demonstrating the ecdysiosynthetic capacity of the embryo. Only during postblastokinetic development, is ecdysone efficiently hydroxylated to 20-hydroxyachieved through conjugation. On the basis of optical and electron microscopic observations, we have been able to correlate precisely each of the four peaks of ecdysone concentration in the egg with the time of deposition of a cuticle by the embryonic tissues (peak 1: serosal cuticle; peak 2: first embryonic cuticle; peak 3: second embryonic cuticle; peak 4: third embryonic cuticle).     

A comparison of the geometric configurations adopted by radiation-induced chromatid interchanges in animals and plants

An analysis of radiation-induced chromatid interchanges in four animal and five plant species indicates that polarised (P) and X-type interchanges occur relatively more frequently in the plants, but non-polarised (N) and U type interchanges occur more frequently in the animals. An explanation of this difference, compatible with the observed geometric shapes of these interchanges and their differing propensity to incompleteness, is that; (a) in all the organisms examined, U- and X-type exchanges are formed during interphase between polarised chromosomes, i.e. they are notional ‘PU’ and ‘PX’ types, (b) the ratio ‘PU’ : ‘PX’ is similar in both animals and plants, (c) a proportion of these exchanges is established during interphase between looped and unlooped (and possibly terminal overlapping) segments, and this proportion is greater in animals; as a result of subsequent chromatin condensation these ‘PU’ and ‘PX’ exchanges may be converted to NU and NX types respectively, (d) ‘PX’ exchanges which are not converted by this mechanism, and NX exchanges which arise in late prophase as a result of this mechanism, are unstable and may be converted during prometaphase to the more stable NU and PU configurations respectively, (e) transformations (d) are relatively more frequent in the animal species because the flexural and tensional regidities of the chromosomes are greater than in the plant chromosomes.