The ultrastructure of the neurons of a graft developing in the brain of rats experiencing hypoxia

Fragments of the brain cortex of 17- or 18-day-old rat embryos were allotransplanted into the brain cortex of rats subjected to hypoxia. Four days later the graft consisted of mixed differentiating neuroblasts. By the 100th to 130th day after transplantation the graft contained mature neurons, differentiating neurons and neuroblasts. Hypochromic neurons showing the signs of intracellular reparation were also detected. A well-developed neuropile was localized inside the graft. In contrast to the normal brain, neurons in the graft were not organized in layers.     

Na+,K+-ATPase in developing fetal guinea pig brain and the effect of maternal hypoxia

Na⁺,K⁺-ATPase activity was determined in fetal guinea pig brain at 35, 40, 45, 50, 55, and 60 days of gestation. The activity remained at a constant level during the early periods (35–45 days) of gestation and increased significantly during 45–60 days. Following maternal hypoxia, the activity of Na⁺,K⁺-ATPase in the term (60 days) fetal brain was reduced by 50% whereas the preterm (50 days) brain activity was unaffected. Under identical hypoxic conditions, the enzymatic activity of adult brain was significantly reduced by 20%. Na⁺,K⁺-ATPase obtained from fetal brain (50 days of gestation) has both a low and a high affinity for ATP (K _m values =0.50 and 0.053 mM and correspondingV _max values =10.77 and 2.82 umoles Pi/mg protein/hr), whereas the enzyme in the adult brain has only a low affinity (K _m=1.67 mM andV _max=20.32 umoles Pi/mg protein/hr). The high and low affinity sites for ATP in the fetal brain suggests a mechanism essential for the maintenance of cellular ionic gradients at low concentrations of ATP and which would provide the fetal brain with a greater tolerance to hypoxia. The high sensitivity of Na⁺,K⁺-ATPase activity to hypoxia in guinea pig brain at term suggests that the cell membrane functions of the fetal brain may be more susceptible to hypoxia at term than it is earlier in gestation.     

Assessment of energy metabolism in the developing brain following aglycemic hypoxia by1H and31P NMR

The role played by external calcium and calcium channels in the recovery from aglycaemic hypoxia in cortical brain slices from 10-day old rats was investigated by¹H and³¹P NMR. 30 minutes of aglycaemic hypoxia significantly decreased the levels of phosphocreatine (PCr), ATP, lactate and intracellular pH (pH_i). After a 30 minute recovery period there was incomplete recovery of PCr and ATP with lactate increasing by 50% with pH_i normal. When the aglycemic hypoxia was carried out in media which had no added calcium (≈10 μM) the PCr and ATP recovery was significantly greater. Application of diltiazem or verapamil but not nifedipine significantly improved the recovery from the aglycemic hypoxia. These data suggest that calcium influx through L-type voltagegated calcium channels is involved in the ischemic damage in neonatal brain which manifests itself as a decrease in the energy state and an increase in lactate. Dedication This article is dedicated to our friend and colleague Herman Bachelard. We wish to thank him for his comradeship, advice and support over many years. Our hope for him is a long and fruiful retirement and that he will remain active in the neurosciences for many years, even though the establishment has blown for “full time”.     

Intelligence and the developing human brain

Determining the brain properties that make people 'brainier' has moved well beyond early demonstrations that increasing intelligence correlates with increasing grey and white matter volumes. Both structural and functional in vivo neuroimaging techniques delineate a distributed network of brain regions, perhaps with a focus in the lateral prefrontal cortex, which varies in extent and connectivity with individual differences in intelligence. Longitudinal studies further show that the neuroanatomic correlates of intelligence are dynamic, changing most rapidly in early childhood. Several promising candidate genes affecting neuronal development and neurotransmission have been proposed that might begin to explain the marked genetic overlap between cortical morphology and intelligence. A major future challenge is to determine the cellular events that underpin the neuroanatomic differences correlated with intelligence.     

Gasping and autoresuscitation in the developing rat: effect of antecedent intermittent hypoxia.

Gasping is a critically important mechanism for autoresuscitation and survival during extreme tissue hypoxia. Evidence of antecedent hypoxia in sudden infant death syndrome suggests that intermittently occurring hypoxic episodes may modify gasping and autoresuscitation. To examine this issue, an intermittent hypoxia (IH) profile consisting of alternating room air and 10% O(2)-balance N(2) every 90 s was applied to pregnant Sprague-Dawley rats (IHRA; n = 50) and to pups after a normal pregnancy (RAIH; n = 50) as well as to control pups (RARA; n = 50). At postnatal day 5, pups were exposed to 95% N(2)-5% CO(2), and gasping and the ability to autoresuscitate were assessed. Compared with RARA, IHRA- and RAIH-exposed pups had a reduced number of gasps, decreased overall gasp duration, and were less likely to autoresuscitate on introduction of room air to the breathing mixture during the last phase of gasping (P < 0.001 vs. RARA). We conclude that both prenatal and early postnatal IH adversely affect gasping and related survival mechanisms.     

Myelination in the developing human brain: Biochemical correlates

To delineate the biochemical sequences of myelination in the human brain, we analyzed the protein and lipid composition of white matter in 18 baseline cases ranging in age from midgestation through infancy, the critical period in human myelination when the most rapid changes occur. Three adult cases were used as indices of maturity, and 4 cases with major disorders of CNS myelination (maple syrup urine disease, severe periventricular leukomalacia, idiopathic central hypomyelination, and metachromatic leukodystrophy) were analyzed. Brain samples were obtained 24 hours after death. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and high performance thinlayer chromatography were used to separate and identify proteins and polar and neutral lipids in an average of 10 sites/brain; computer-based densitometry was used to quantify polar lipids. Biochemical sequences, as manifested by the appearance of the myelin-associated lipids and myelin-specific proteins, closely followed previously described anatomic sequences both temporally and by region, and were identical in all sites sampled: sphingomyelin was followed simultaneously by cerebrosides, MBP, PLP, and nonhydroxy-sulfatide, followed by hydroxy-sulfatide. The onset and tempo of the expression of individual constituents, however, were quite variable among sites, suggesting a wide differential in vulnerable periods to insult in biochemically-specific pathways in early life. Cholesterol ester was transiently elevated during late gestation and early infancy, prior to and around the time of the appearance of cerebrosides, sulfatides, PLP, and MBP. Distinctive lipid and protein abnormalities were detected in idiopathic central hypomyelination and metachromatic leukodystrophy. This study underscores the feasibility of the combined biochemical approaches in pediatric brains and provides guidelines for the assessment of disorders of myelination in early human life.Special issue dedicated to Dr. Marjorie B. Lees.     

Pathological apoptosis in the developing brain

More than half of the initially-formed neurons are deleted in certain brain regions during normal development. This process, whereby cells are discretely removed without interfering with the further development of remaining cells, is called programmed cell death (PCD). The term apoptosis is used to describe certain morphological manifestations of PCD. Many of the effectors of this developmental cell death program are highly expressed in the developing brain, making it more susceptible to accidental activation of the death machinery, e.g. following hypoxia-ischemia or irradiation. Recent evidence suggests, however, that activation and regulation of cell death mechanisms under pathological conditions do not exactly mirror physiological, developmentally regulated PCD. It may be argued that the conditions after e.g. ischemia are not even compatible with the execution of PCD as we know it. Under pathological conditions cells are exposed to various stressors, including energy failure, oxidative stress and unbalanced ion fluxes. This results in parallel triggering and potential overshooting of several different cell death pathways, which then interact with one another and result in complex patterns of biochemical manifestations and cellular morphological features. These types of cell death are here called "pathological apoptosis," where classical hallmarks of PCD, like pyknosis, nuclear condensation and caspase-3 activation, are combined with non-PCD features of cell death. Here we review our current knowledge of the mechanisms involved, with special focus on the potential for therapeutic intervention tailored to the needs of the developing brain.     

Effect of transient hypoxia on oxygenation of the developing rat brain: relationships among haemoglobin saturation, autoregulation of blood flow and mitochondrial redox state

Multi-wavelength, differential spectroscopy was used to examine the effects of transient hypoxia on oxygen delivery and intracellular utilization in the brain of developing rats. The in vivo redox status of cytochrome a,a3 was compared simultaneously with changes in relative haemoglobin saturation and blood volume in the cerebral cortex during lowered FiO2. During hypoxia, neonates maintained their intracellular cytochrome a,a3 redox state as well as did adults, but did so through unusual characteristics, including: (1) maintenance of haemoglobin oxygenation at lower FiO2; (2) regulation of cerebral blood volume at blood pressures below the point at which autoregulation would fail in the adult; and (3) the capacity to tolerate a greater reduction of cytochrome a,a3 relative to haemoglobin desaturation at lowered FiO2. These data suggest that mechanisms which protect the neonate from hypoxic insult involve preservation of oxygen delivery, increased respiratory compensation for metabolic acidosis, and maintenance of cellular energy requirements predominantly through anaerobic metabolism.     

Chronic hypoxia modulates diaphragm function in the developing rat.

We studied the effect of chronic hypoxia on contractile properties and neuromuscular transmission in the developing rat diaphragm. We hypothesized that chronic hypoxia delays maturation of neuromuscular transmission. Phrenic nerve hemidiaphragm preparations were harvested from 3- to 26-day-old rats and littermates raised in 9.5% oxygen. Specific force, contraction time, and one-half relaxation time were measured. Each diaphragm was stimulated directly or via its nerve with 1-s trains at 10-100 Hz. Contraction time and one-half relaxation time decreased with advancing age in both groups, with a greater rate of decrease in hypoxic diaphragms. Specific force was lower for hypoxic diaphragms compared with controls. Diaphragms from the 3- to 10-day-old control and hypoxic groups generated less force in response to stimulation at frequencies >40 Hz but did so to a greater degree with nerve stimulation. Nerve stimulation of diaphragms from 11- to 18-day-old hypoxic rats showed a greater decrease in force with increasing frequency compared with age-matched controls. Diaphragms from 19- to 26-day-old rats showed no difference between the hypoxic and control groups. We conclude that chronic hypoxia leads to diaphragms that generate lower specific force as well as to a delayed maturation of mechanisms involved in neuromuscular transmission.     

Ultrastructural changes in the brain capillaries after hypoxia

The authors describe ultrastructural changes in and around rat brain capillaries after hypoxia. The experimental animals breathed a mixture of 5% oxygen and 95% nitrogen for two or for three hours; a third group, which spent three hours in this atmosphere, was treated 24 h later. Cytoplasm processes and vesicles were observed on the luminal side in the endothelial cells, while the cytoplasm contained vacuoles and altered mitochondria. The basement membrane of the brain capillaries was uneven and longitudinal clear zones were formed in it. Altered mitochondria were present in the pericytes and astrocytes. The most pronounced changes were found in the astrocyte processes, which were light and hydrated and contained destroyed mitochondria and lamellar bodies resembling myelin. After 24 h, morphological changes still persisted, especially in the astrocyte 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.     

Modulation of respiration during brain hypoxia

This review is a summary of the effects of brain hypoxia on respiration with a particular emphasis on those studies relevant to understanding the cellular basis of these effects. Special attention is given to mechanisms that may be responsible for the respiratory depression that appears to be the primary sequela of brain hypoxia in animal models. Although a variety of potential mechanisms for hypoxic respiratory depression are considered, emphasis is placed on changes in the neuromodulator constituency of the respiratory neuron microenvironment during hypoxia as the primary cause of this phenomenon. Hypoxia is accompanied by a net increase in neuronal inhibition due to both decreased excitatory and increased inhibitory neuromodulator levels. A survey of hypoxia-tolerant cellular systems and organisms suggests that hypoxic respiratory depression may be a manifestation of the depression of cellular metabolism, which appears to be a major adaptation to limited oxygen availability in these systems.     

Ethanol-induced apoptotic neurodegeneration in the developing brain

It has been known for three decades that ethanol, the most widely abused drug in the world, has deleterious effects on the developing human brain, but progress has been slow in developing animal models for studying this problem, and the underlying mechanisms have remained elusive. Recently, we have shown that during the synaptogenesis period, also known as the brain growth spurt period, ethanol has the potential to trigger massive neuronal suicide in the in vivo mammalian brain. The brain growth spurt period in humans spans the last trimester of pregnancy and first several years after birth. The NMDA antagonist and GABAmimetic properties of ethanol may be responsible for its apoptogenic action, in that other drugs with either NMDA antagonist or GABAmimetic actions also trigger apoptotic neurodegeneration in the developing brain. Our findings provide a likely explanation for the reduced brain mass and neurobehavioral disturbances associated with the human fetal alcohol syndrome. Furthermore, since NMDA antagonist and GABAmimetic drugs are sometimes abused by pregnant women and also are used as anticonvulsants, sedatives or anesthetics in pediatric medicine, our findings raise several complex drug safety issues. In addition, the observation that ethanol and several other drugs trigger massive neuronal apoptosis in the developing brain provides an unprecedented opportunity to study both neuropathological aspects and molecular mechanisms of apoptotic neurodegeneration in the in vivo mammalian brain.