O2 effect on composition of chick embryonic heart and brain

Effects of Developmental Hypoxia on the Vertebrate Cardiovascular System

Developmental hypoxia has profound and persistent effects on the vertebrate cardiovascular system, but the nature, magnitude, and long-term outcome of the hypoxic consequences are species specific. Here we aim to identify common and novel cardiovascular responses among vertebrates that encounter developmental hypoxia, and we discuss the possible medical and ecological implications.

Chicken Incubation Conditions: Role in Embryo Development, Physiology and Adaptation to the Post-Hatch Environment

The chicken hatching egg is a self-contained life-supporting system for the developing embryo. However, the post-hatch performance of birds depends on several factors, including the breeder management and age, egg storage conditions and duration before incubation, and the incubation conditions. Studies have determined the effect of incubation factors on chick post-hatch growth potential. Therefore, chick physical quality at hatch is receiving increasing attention. Indeed, although incubation temperature, humidity, turning and ventilation are widely investigated, the effects of several variables such as exposure of the embryo to high or low levels, time of exposure, the amplitude of variations and stage exposures on embryo development and post-hatch performance remain poorly understood. This review paper focuses on chick quality and post-hatch performance as affected by incubation conditions. Also, chick physical quality parameters are discussed in the context of the parameters for determining chick quality and the factors that may affect it. These include incubation factors such as relative humidity, temperature, turning requirements, ventilation, in ovo feeding and delay in feed access. All these factors affect chick embryo physiology and development trajectory and consequently the quality of the hatched chicks and post-hatch performance. The potential application of adapted incubation conditions for improvement of post-hatch performance up to slaughter age is also discussed. It is concluded that incubation conditions affect embryo parameters and consequently post-hatch growth differentially according to exposure time and stage of exposure. Therefore, classical physical conditions are required to improve hatchability, chick quality and post-hatch growth.

Developing chicken cardiac muscle mitochondria are resistant to variations in incubation oxygen levels

Background

Chronic exposure to hypoxia during vertebrate development can produce abnormal cardiovascular morphology and function. The aim of this study was to examine cardiac mitochondria function in an avian model, the chicken, in response to embryonic development under hypoxic (15% O₂), normoxic (21% O₂), or hyperoxic (40% O₂) incubation conditions.

Methods

Chicken embryos were incubated in hypoxia, normoxia, or hyperoxia beginning on day 5 of incubation through hatching. Cardiac mitochondria oxygen flux and reactive oxygen species production were measured in permeabilized cardiac fibers from externally pipped and 1-day post hatchlings.

Results

Altering oxygen during development had a large effect on body and heart masses of externally pipped embryos and 1-day old hatchlings. Hypoxic animals had smaller body masses and absolute heart masses, but proportionally similar sized hearts compared to normoxic animals during external pipping. Hyperoxic animals were larger with larger hearts than normoxic animals during external pipping. Mitochondrial oxygen flux in permeabilized cardiac muscle fibers revealed limited effects of developing under altered oxygen conditions, with only oxygen flux through cytochrome oxidase being lower in hypoxic hearts compared with hyperoxic hearts. Oxygen flux in leak and oxidative phosphorylation states were not affected by developmental oxygen levels. Mitochondrial reactive oxygen species production under leak and oxidative phosphorylation states studied did not differ between any developmental oxygen treatment.

Conclusions

These results suggest that cardiac mitochondria function of the developing chicken is not altered by developing in ovo under different oxygen levels.

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Chicken heart mass is influenced by oxygen availability during development.

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Cardiac mitochondria respiration was unchanged by developing under hypoxic or hyperoxic oxygen stress.

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Cardiac mitochondria ROS production was not altered by developmental oxygen stress.

Effects of eggshell temperature and oxygen concentration on embryo growth and metabolism during incubation

Embryo development and heat production (HP) were studied in eggs of similar size (60 to 65 g) that were incubated at normal (37.8 degrees C) or high (38.9 degrees C) eggshell temperature (EST) and exposed to low (17%), normal (21%), or high (25%) O(2) concentration from d 9 through 19. High EST initially increased HP, but gradually O(2) became more important for HP than EST. Finally,HP was highest for the combination of high EST with high O(2) and lowest for the combination of high EST with low O(2). High EST decreased hatch time, BW, yolk free BW, and relative heart weight. The EST had no effect on residual yolk weight, chick length, or relative liver weight. Increased O(2) increased yolk free BW and chick length and decreased residual yolk weight at hatch. No interactions between EST and O(2) were observed with regard to embryo development and hatchling characteristics. If embryo development is reflected by HP, it can be concluded that high EST primarily increased embryonic development until the second week of incubation. During the third week of incubation, O(2) had a greater effect in determining embryo development than EST.

Organ growth in chicken embryos during hypoxia: implications on organ "sparing" and "catch-up growth"

The primary aim of this study was to establish whether or not embryonic hypoxia selectively affects the growth of specific organs. Chicken embryos were incubated either in normoxia (Nx) or in hypoxia (15% O2 from embryonic day E5, Hx). The length of the beak and third toe (as indexes of skeletal growth) and the weights of internal organs (eyes, brain, heart, lungs, liver, kidneys, stomach, and intestines) were collected at E14, E17, E19, and E20. Hypoxia reduced embryonic body weight (BW). At any given age, the specific weight (organ weight/BW) of some organs in Hx was higher, and that of others was lower, than in Nx. However, almost all differences disappeared when organ weights were compared as function of BW, rather than at fixed chronological ages. The important exception was the chorioallantoic membrane (CAM), the mass of which in Hx developed out of proportion. In a third group of embryos, hypoxic until E14 and normoxic thereafter, there was no post-hypoxic catch-up growth, differently from what known to occur postnatally. A possible interpretation is that catch-up growth does not depend on the age of the embryo but on its BW. In conclusion, at least in the chicken embryo and for the level of hypoxia tested, hypoxia has no selective effects on the growth of specific organs, except for the CAM. Qualitative differences in the weight response to hypoxia among organs observed at any given age can be explained largely by the effects of the blunted growth on the growth trajectory of the individual organs.

Hypoxic incubation creates differential morphological effects during specific developmental critical windows in the embryo of the chicken (Gallus gallus)

Hypoxia inhibits vertebrate development, but the magnitude and timing of organ-specific effects are poorly understood. Chick embryos were exposed continuously to hypoxia (15% O2) throughout Days 1-6, 6-12, 12-18 or Days 1-18 of development, followed by morphometric measurements of major organ systems. Early hypoxic exposure reduced eye mass and beak length when measured in middle development. Liver, brain, heart, kidneys, stomach, intestines and skeletal long bones were not affected by hypoxia at any developmental stage. The chorioallantoic membrane (CAM) mass was unchanged by hypoxic exposure in early or mid-development, but CAM mass on Day 18 increased strikingly (40 and 60% in late and continuous populations, respectively) in response to hypoxic exposure. The increase in CAM mass presumably enhances oxygen delivery, thus minimizing the detrimental effects of hypoxia on development and growth. Hypoxic exposure at key critical windows in development thus results in differential effects on organ development, some of which can subsequently be repaired through additional incubation (yolk mass, eye mass, beak length).

Cardiovascular development in embryos of the American alligator Alligator mississippiensis: effects of chronic and acute hypoxia

Chronic hypoxic incubation is a common tool used to address the plasticity of morphological and physiological characteristics during vertebrate development. In this study chronic hypoxic incubation of embryonic American alligators resulted in both morphological (mass) and physiological changes. During normoxic incubation embryonic mass, liver mass and heart mass increased throughout the period of study, while yolk mass fell. Chronic hypoxia(10%O2) resulted in a reduced embryonic mass at 80% and 90% of incubation. This reduction in embryonic mass was accompanied by a relative enlargement of the heart at 80% and 90% of incubation, while relative embryonic liver mass was similar to the normoxic group. Normoxic incubated alligators maintained a constant heart rate during the period of study, while mean arterial pressure rose continuously. Both levels of hypoxic incubation(15% and 10%O2) resulted in a lower mean arterial pressure at 90%of incubation, while heart rate was lower in the 10%O2 group only. Acute (5 min) exposure to 10%O2 in the normoxic group resulted in a biphasic response, with a normotensive bradycardia occurring during the period of exposure and a hypertensive tachycardic response occurring during recovery. The embryos incubated under hypoxia also showed a blunted response to acute hypoxic stress. In conclusion, the main responses elicited by chronic hypoxic incubation, namely, cardiac enlargement, blunted hypoxic response and systemic vasodilation, may provide chronically hypoxic embryos with a new physiological repertoire for responding to hypoxia.

Avian embryos in hypoxic environments

Avian embryos at high altitude do not benefit of the maternal protection against hypoxia as in mammals. Nevertheless, avian embryos are known to hatch successfully at altitudes between 4,000 and 6,500 m. This review considers some of the processes that bring about the outstanding modifications in the pressure differences between the environment and mitochondria of avian embryos in hypoxic environments. Among species, some maintain normal levels of oxygen consumption ( VO2) have a high oxygen carrying capacity, lower the air cell-arterial pressure difference ( PAO2 - PaO2 ) with a constant pH. Other species decrease VO2, increase only slightly the oxygen carrying capacity, have a higher PAO2 - PaO2 difference than sea-level embryos and lower the PCO2 and pH. High altitude embryos, and those exposed to hypoxia have an accelerated decline of erythrocyte ATP levels during development and an earlier stimulation of 2,3-BPG synthesis. A higher Bohr effect may ensure high tissue PO2 in the presence of the high-affinity hemoglobin. Independently of the strategy used, they serve together to promote suitable rates of development and successful hatching of high altitude birds in hypoxic environments.

Role of myocardial hypoxia in the remodeling of the embryonic avian cardiac outflow tract

The embryonic cardiac outflow myocardium originates from a secondary heart-forming field to connect the developing ventricles with the aortic sac. The outflow tract (OFT) subsequently undergoes complex remodeling in the transition of the embryo to a dual circulation. In avians, elimination of OFT cardiomyocytes by apoptosis (stages 25-32) precedes coronary vasculogenesis and is necessary for the shortening of the OFT and the posterior rotation of the aorta. We hypothesized that regional myocardial hypoxia triggers OFT remodeling. We used immunohistochemical detection of the nitroimidazole EF5, administered by intravascular infusion in ovo, as an indicator of relative tissue oxygen concentrations. EF5 binding was increased in the OFT myocardium relative to other myocardium during these stages (25-32) of OFT remodeling. The intensity of EF5 binding paralleled the prevalence of apoptosis in the OFT myocardium, which are first detected at stage 25, maximal at stage 30, and diminished by stage 32. Evidence of coincident hypoxia-dependent responses included the expression of the vascular endothelial growth factor (VEGF) receptor 2 by the OFT myocardium, the predominant expression of VEGF122 (diffusible) isoform in the OFT, and the recruitment of QH1-positive pro-endothelial cells to the OFT and vasculogenesis. Exposure of embryos to hyperoxia (95% O(2)/5% CO(2)) during this developmental window reduced the prevalence of cardiomyocyte apoptosis and attenuated the shortening and rotation of the OFT, resulting in double-outlet right ventricle morphology, similar to that observed when apoptosis is directly inhibited. These results suggest that regional myocardial hypoxia triggers cardiomyocyte apoptosis and remodeling of the OFT in the transition to a dual circulation, and that VEGF autocrine/paracrine signaling may regulate these processes.

Chronic hypoxia alters the physiological and morphological trajectories of developing chicken embryos

Chicken embryos were chronically exposed to hypoxia (P(O(2)) approximately 110 mmHg) during development, and assessed for detrimental metabolic and morphological effects. Eggs were incubated in one of four groups: control (i.e. 151 mmHg), or treated with continuous 110 mmHg (15% O(2)) during days 1-6 (H1-6), 6-12 (H6-12), or 12-18 (H12-18) with normoxia during the remaining incubation. Metabolism (V(O(2))), body mass, hemoglobin (Hb) and hematocrit (Hct) were measured in embryos on days 12 and 18 of incubation and in day-old hatchlings. Ability to maintain V(O(2)) was acutely measured during a step-wise decrease in P(O(2)) from normoxia to hypoxia (55 mmHg). On day 12, V(O(2)) of H1-6 eggs were significantly lower than in the control and H6-12 eggs. P(crit) in H6-12 eggs was lower than in control and H1-6 eggs. Body mass of H1-6 and H6-12 embryos on day 12 was significantly lower than in control embryos, while in H6-12 embryos, Hct and Hb were higher. On day 18, H6-12 embryos had significantly lower V(O(2)) than control eggs. Body mass of H6-12 and H12-18 embryos was significantly lower than control embryos. Hct and Hb did not differ between treatments. In hatchlings, mass, Hb and Hct had returned to values statistically identical to controls. However, H6-12 embryos had significantly lower V(O(2)). Long-term hypoxia altered V(O(2)) when hypoxic incubation occurred during the middle third of incubation, but not during earlier or later incubation. Thus, chronic hypoxic exposure during critical periods in development altered the developmental physiological trajectories and modified the phenotypes of the developing embryos.

Restriction of prenatal gas exchange impairs memory consolidation in the chick

Our aim was to assess the effects of restricting gas exchange during incubation on postnatal memory formation and growth in the chick. Gas exchange across the eggshell was restricted by covering 50% of the eggshell with an impermeable membrane for 4 or 8 days, commencing at days 14 and 10, respectively, of a 21-day incubation. Memory formation was examined postnatally at 1-2 days using a one-trial discriminated bead task, and at 5-6 days using a discriminated wheat task. For both tasks, chicks from eggs wrapped from days 14 to 18 had impaired memory retention at 60 min after training, although learning and labile memory were not impaired. Chicks from eggs wrapped from days 10-18 appeared to be poorer in their ability to form memories, and did not discriminate as well as controls in any of the tasks. Body weights of chicks from wrapped eggs were reduced from 2 days after hatching; chicks from eggs wrapped from day 10 had lower body weights at hatching. We conclude that a period of altered prenatal gas exchange can impair memory consolidation in the chick soon after hatching. The ability to form memories may be permanently altered, as this impairment is still apparent at 5-6 days after hatching. Pre- and postnatal growth was also impaired in the chicks from wrapped eggs. Our results suggest that the extent to which postnatal neurological function and growth is impaired depends on the timing and possibly the duration of the prenatal insult.

The effect of hyperoxia on embryonic and organ mass in the developing chick embryo

It is known that hyperoxia stimulates growth late in incubation when the chick embryo outgrows the O2 diffusion capacity. We wondered whether hyperoxia could have an effect in the early period prior to the stage where metabolism exceeds the oxygen diffusion capacity of the eggshell. For this we studied four groups of chicken eggs: control group (CG; n = 100) and three test groups (TGs) exposed during 48 h to 60% O2 on days 10, 14, and 18. In the CG, embryonic and organ mass (brain, heart, lungs, liver and intestine) were measured from day 10 until day 21 of incubation. In the TGs embryonic and organ mass were obtained from 24 h after the start of hyperoxia exposure until the end of incubation. In all TGs the most striking growth rate acceleration was observed in the liver and intestine, maximum growth rate accelerations were respectively, 19 and 42% in TG1, 43 and 173% in TG2 and 39% and 84 in TG3. In contrast, the brain was little affected by the hyperoxia exposure, the maximum growth rate acceleration was 14% in TG2. The results suggest that also in the middle of the incubation period O2 availability can be a limiting factor for growth, before metabolism exceeds the oxygen diffusion capacity of the eggshell.

A consideration of comparative metabolic aspects of the aetiology of sudden death syndrome and ascites in broilers

There is some evidence to suggest that the aetiology of 'Sudden Death Syndrome' (SDS) and ascites in broilers are closely related and that they may be the result of different degrees of the same metabolic condition. Many of the clinical findings, such as cardiac involvement and oedema are common to both conditions. Males are more affected than females and rapid growth, if a factor, is more related to increased oxygen demand rather than growth per se. Dietary, environmental or other factors which disrupt the balance of electrolytes, metabolites or pH may affect cardiopulmonary function and lead to SDS or ascites. The conditions can be either acute or chronic in nature and, whereas if acute, the end result is SDS, when chronic, ascites is the end result. Dietary or environmental factors that may either help to stabilize or adversely affect acid base balance may be useful avenues for future research into the aetiology of SDS and ascites. Factors that would increase the bird's capacity for supplying adequate oxygen to the tissues may also help to alleviate these two conditions which are of considerable annual cost to the poultry industry.

Effect of oxygen on ascorbic acid uptake and concentration in embryonic chick brain

The effects of oxygen on ascorbic acid concentration and transport were studied in chick embryo (Gallus gallus domesticus). During normoxic incubations, plasma ascorbic acid concentration peaked on fetal day 12 and then fell, before increasing again on day 20 when pulmonary respiration began. In contrast, cerebral ascorbic acid concentration rose after day 6, was maintained at a relatively high level during days 8-18, and then fell significantly by day 20. Exposure of day 16 embryos for 48 h to 42% ambient O2 concentration decreased ascorbic acid concentration by four-fifths in plasma and by one-half in brain, compared to values in normoxic (21% O2) or hypoxic (15% O2) controls. Hyperoxic preincubation of embryos also inhibited ascorbic acid transport, as evidenced by decreased initial rates of saturable and Na(+)-dependent [14C]ascorbic acid uptake into isolated brain cells. It may be concluded that changes in ascorbic acid concentration occur in response to oxidative stress, consistent with a role for the vitamin in the detoxification of oxygen radicals in fetal tissues. However, changing O2 levels have less effect on ascorbic acid concentration in brain than in plasma, indicating regulation of the vitamin by brain cells. Furthermore, the effect of hyperoxia on cerebral vitamin C may result, in part, from inhibition of cellular ascorbic acid transport.

Metabolic responses of chicken embryos and hatchlings to altered O2 environments

The oxygen consumption (MO2) response over a 4 h period of exposure to altered ambient O2 (air, 10, 15, 40, 60, 80 and 100%), helium (He) and sulfur hexafluoride (SF6) environments was determined for young (12 days old) and late (16 and 18 days old) embryos, externally pipped (EP) eggs and just hatched chicks (hatchlings) of the domestic fowl. The young embryos were insensitive to hyperoxic gas mixtures and to He exposure, while the late embryos increase their MO2 in hyperoxic environments, independently of O2 concentration, and also in a He atmosphere. Both the young and late embryos responded to SF6 exposure with decreasing MO2, as SF6 reduces O2 diffusivity through the eggshell. The MO2 of EP eggs and hatchlings in He and SF6 varied very widely, the effects of altered diffusivity being insignificant. In hypoxic environments in which the MO2 decreased, the fall of MO2 became smaller as embryos developed and particularly after they pipped the shell and hatched. In an atmosphere of 10% O2, the MO2 of all embryos in the egg before hatching decreased to below 10% of the control after 4 h, while in hatchlings the MO2 remained above 80% of the control. As all embryos in situ in the egg depend entirely or partly on diffusion in order to obtain O2, this emphasizes the limitation of the diffusive process. A 4 h exposure to 10% O2 was lethal for embryos in the egg even if they had pipped the shell and were breathing air with the lungs.

Prenatal oxidative stress: I. Malondialdehyde in hypoxic and hyperoxic chick embryos

Evidence suggests a positive correlation between metabolic rate (VO2), or ambient oxygen (O2) tension, and the rate of formation of free radicals from O2. We have previously demonstrated that the rates of growth, VO2, protein and DNA accumulation, and the activity of cytochrome oxidase (a key mitochondrial respiratory enzyme), are increased significantly by exposing the chick embryo to 72 h of hyperoxia (60% O2) late in incubation. To test the hypothesis that the chick embryo responds to a prenatal alteration in O2 availability in such a way as to protect its tissues from oxidative damage, we have used the thiobarbituric acid assay to estimate lipid peroxidation (a major form of free radical damage) in selected organs from chick embryos exposed to altered O2 availability. We found significantly higher concentrations of malondialdehyde (MDA, a secondary product of lipid peroxidation) in liver than in chorioallantoic membrane, brain, or heart. However, embryos exposed to brief (72 h) hypoxia (15% O2) or hyperoxia (60% O2) late in incubation, or 48 h of such exposure followed by 24 h of incubation in pure O2, exhibited no significant difference in MDA levels compared to normoxic (21% O2) controls in any of the tissues examined. We conclude that the increase in aerobic metabolism induced in the chick embryo by 3 days of hyperoxia is not accompanied by an increase in lipid peroxidation. We postulate that the chick embryo adapts to hyperoxia in such a way as to escape additional free radical damage, perhaps by increasing the capacity of its antioxidant defenses to compensate for a potential increase in the rate of free radical generation.