Developmental changes of glycine transport in the dog

The renal clearance of amino acids was measured in canine pups between 5 days and 12 weeks of age. The reabsorption of glycine was incomplete at 5 and 21 days, indicating a physiologic aminoaciduria of immaturity. An adult pattern of 97–100% reabsorption appeared by 8 weeks of age. The uptake of glycine by isolated renal tubules from 5-day-old, 3-month-old and adult dogs was examined towards an understanding of the events underlying this aminoaciduria. The initial uptake of 0.042 mM glycine by isolated tubules from the newborn was lower than that of the adult, but after 30 min of incubation the newborn surpassed the adult. A steady state of uptake was not achieved by the newborn even after 90 min of incubation, while it was achieved in the adult after 30 min. The uptake by the 3-month-old tubules resembled the adult at the early time points and the newborn at later points. With 1.032 mM glycine, a similar relationship of uptake between adult and newborn tubules was found, except with this concentration, the uptake by both the newborn and adult tubules reached a steady state. The concentration dependence of glycine uptake showed two saturable transport systems with similar apparent $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ and $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ values after 30 min of incubation for all three age groups. Determination of glycine flux by compartmental analysis revealed decreased influx and efflux in the newborn, but with a greater decrease in efflux, compared to adult. These changes of influx and efflux which accompany renal tubule maturation could contribute to the increased intracellular amino acid levels and decreased reabsorption of amino acids seen in the immature dog.     

DEVELOPMENTAL AND OTHER ASPECTS OF [35S]CYSTEINE TRANSPORT BY RAT BRAIN SYNAPTOSOMES

Abstract— Cysteine uptake by rat brain synaptosomes occurs by active transport. The uptake by synaptosomes isolated from newborn brain is slower and the concentration gradient achieved is lower than that observed in adult tissue. Synaptosomal fractions from both adult and newborn rat brains accumulate cysteine by two saturable systems. The calculated parameters show that the maximum rates of cysteine uptake in adult synaptosomes are approximately twice that observed in newborn synaptosomes for both the high and low affinity systems. The uptake by the high affinity system is sodium dependent and is inhibited by glycine and dibasic amino acids. Uptake by synaptosomes from 14-day-old animals is close to that observed in adult tissue. The uptake of cysteine differs greatly from that of cystine since the oxidized form, cystine, is taken up more slowly by systems with low affinities which are sodium independent, do not interact with dibasic amino acids and are independent of age.     

On the transport of sugars and amino acids by newborn kidney: use of isolated proximal tubule

While the newborn Sprague-Dawley rat has evidence of hyperglycinuria without glycosuria transport studies employing renal cortical slices $\text{in}$$\text{vitro}$ have shown paradoxically no impairment of glycine uptake by tubule cells but an inability to actively transport sugars. In order to eliminate the architecture of the cortical slice as a complicating factor in measuring cellular uptake isolated proximal tubule fragments have been prepared from newborn rats and the cellular uptake of glycine and α-methyl-D-glucoside has been measured. The entry of glycine into the cells of newborn tubules is similar to that in adult tubules and confirms data obtained with slices. On the other hand, concentrative uptake of glucoside though impaired in newborn tubules is easily demonstrable. Isolated tubules of the newborn should provide a model $\text{in}$$\text{vitro}$ system to assess the changing characteristics of sugar transport during development.     

Developmental pattern of cystine transport in isolated rat renal tubules

Isolated renal cortical tubule fragments from rats ranging in age from less than 48 h to 15 weeks were used to examine the pattern of cystine uptake with development. Immature tubules took up cystine with a faster initial rate than mature tubules and did not reach a steady state by 60 min. By eight weeks of age, the timed uptake of cystine began to approach a steady state and between 8 and 11 weeks the uptake pattern achieved its adult form of reaching a steady state by 30 min of incubation. Analysis of the intracellular metabolism of the cystine taken up by the newborn tubules revealed that the majority had been reduced to cysteine with the formation of small amounts of reduced glutathione. Cystine entered the renal cortical tubule cell from the newborn via two saturable transport systems similar to the mature animal. The kinetic parameters of initial uptake of these two transport systems were similar in the mature and newborn animal except for a higher maximum transport velocity for the low K_m, low capacity system in the newborn. Lysine inhibited cystine uptake by newborn tubules and this inhibition appeared to occur on the low K_m, low capacity transport system similar to the adult. Cystine uptake was sodium dependent with an apparent affinity for sodium of 36 mequiv./l. From this data, the physiologic cystinuria of the immature animal does not appear to be referrable to a lower rate of influx as previously observed with the cortical slice. Other mechanisms should be sought to explain this phenomenon of immaturity.     

POSTNATAL CHANGES IN THE HIGH AFFINITY UPTAKE OF GLYCINE and GABA IN THE RAT CENTRAL NERVOUS SYSTEM

Abstract— High affinity uptake systems for GABA into slices of cerebral cortex and for glycine into slices of spinal cord have been demonstrated in rats of 1 and 10 days postnatal age and compared with the systems in tissue slices from adult rats. For both systems there was an increase in the maximal rate of uptake of the substrate with development. For glycine uptake there was no significant change in apparent K_m during development, whereas there was a four-fold increase in the apparent K_m for GABA uptake. There were some changes with development in the apparent substrate specificity of the two systems suggesting increased specificity with maturation. Bicuculline and strychnine, antagonists of the postsynaptic inhibitory actions of GABA and glycine, produced convulsions in 1-, 2- and 10-day-old rats following intraperitoneal injection of doses somewhat lower than those required to convulse adult rats. These findings are consistent with other evidence that glycine and GABA are functioning as inhibitory transmitters at least as soon as 1 day after birth.     

Changes in amino acid transport in the rat pancreas in response to fasting and feeding

Transport of amino acids (in vitro) in the rat pancreas is affected by the nutritional state of the animal. A fast of 24 h (young animals) or 48 h (adult animals) reduces the rate of amino acid uptake in the isolated rat pancreas in vitro. In contrast, refeeding of animals after a fast shows an increase in transport in young as well as adult animals.The effects of refeeding after a fast are mimicked to a significant extent by injection of mixtures of pancreozymin and carbamylcholine. Addition of these agents in vitro has no effect.The incorporation of amino acids into the total proteins of the rat pancreas follows the pattern of amino acid uptake. Even at high external levels of glycine (5 mM), incorporation increases although the glycine level in the cell is in excess of 25 mM. Reduction of glycine uptake by ouabain by 75% results in a substantial (44%) diminution of amino acid incorporation into proteins. The data suggest that inhibition of amino acid incorporation under the various metabolic conditions examined is due largely to a decreased availability of amino acids.     

Changes in amino acid transport in the rat pancreas in response to fasting and feeding.

Transport of amino acids (in vitro) in the rat pancreas is affected by the nutritional state of the animal. A fast of 24 h (young animals) or 48 h (adult animals) reduces the rate of amino acid uptake in the isolated rat pancreas in vitro. In contrast, refeeding of animals after a fast shows an increase in transport in young as well as adult animals. The effects of refeeding after a fast are mimicked to a significant extent by injection of mixtures of pancreozymin and carbamylcholine. Addition of these agents in vitro has no effect. The incorporation of amino acids into the total proteins of the rat pancreas follows the pattern of amino acid uptake. Even at high external levels of glycine (5 mM), incorporation increases although the glycine level in the cell is in excess of 25 mM. Reduction of glycine uptake by ouabain by 75% results in a substantial (44%) diminution of amino acid incorporation into proteins. The data suggest that inhibition of amino acid incorporation under the various metabolic conditions examined is due largely to a decreased availability of amino acids.     

Further characterization of the process of in vitro uptake of radiolabeled copper by the rat brain

We have previously demonstrated that hypothalmic slices obtained from adult male rats accumulate 67Cu by two ligand-dependent, saturable processes: a high and low affinity process. To further establish the generality of these uptake processes, we defined the ligand requirements and the saturation kinetics of 67Cu uptake by tissue slices obtained from the newborn hypothalamus (HT); adult male hypothalamus, hippocampus, cortex, median eminence, and caudate nucleus; hypothalamus and hippocampus of castrated (14 days) males and of pregnant (19 days) and ovariectomized (14 days) females. It was found that ionic 67Cu2+ was poorly taken up by newborn HT and adult caudate, complexation with His enhanced 67Cu uptake 3-4-fold, and complexation with albumin inhibited 67Cu uptake. These ligand requirements are identical to those we have previously shown for the adult HT. When 67Cu uptake was evaluated under conditions optimal for the high or the low affinity process, for each process the dose response curves generated from these various tissues were very similar. In addition, we assessed the uptake of both components of the CuHis2 complex by incubating tissues with 67Cu3 H-His2 and found that the tissue ratio of 67Cu:3H was a sigmoidal function of the concentration of the Cu complex such that at greater than 5 microM, the ratio was about 3-fold greater than the medium ratio; indicating preferential uptake of 67Cu relative to 3H-His. The changes in isotope ratios were observed in newborn HT and adult HT, as well as caudate. These similarities in the ligand requirements and saturation kinetics of 67Cu uptake establish the generality of these two processes of in vitro uptake of copper in the rat brain.     

Developmental and other characteristics of lysine uptake by rat brain synaptosomes.

Synaptosomes isolated from adult or newborn rat cerebrum take up L-lysine by two saturable systems, one with a high affinity low capacity and the other with a low affinity high capacity. Initial rate of uptake for low lysine concentrations is mort tissue. Analysis of kinetic data indicates that synaptosomes of the newborn have a higher Vmax than those of the adult for high affinity system but adult for high affinity system but adult synaptosomes have a higher Vmax than newborn for low affinity system. At a physiological lysine concentration of 0.5 mM, the calculated contributions of two systems indicate that the adult uptake occurs for about 71% by low affinity system but the newborn utilizes both systems to the same extent. The uptake is sodium independent but pH dependent. Lysine uptake is inhibited by other dibasic amino acids, arginine and ornithine but not cystine. Kinetic analysis indicates that arginine specifically inhibits the high affinity, low Km system for lysine uptake.     

Sodium-dependent phosphate transport in primary cultures of renal tubule cells from young and adult rats

The transport of phosphate by primary cultures of renal cells from young (5-6 weeks) and adult (10-12 months) rats was studied. Renal tubule cells isolated from young and adult groups exhibited typical epithelial morphology and similar growth rates. The Na-dependent phosphate uptake was saturable with a Km of 5-7 microM over a substrate range of 1-500 microM. A decrease in Na-dependent phosphate uptake in adult cells (30%) was found compared to that of young cells. The Na-independent component of phosphate uptake did not vary with age. In addition, the inhibition of phosphate uptake by a variety of compounds (ouabain, gramicidin, 2,4-dinitrophenol, KCN, and arsenate) were similar in both age groups. Kinetic analysis showed that a significant reduction in Vmax (4.4 +/- 0.4 vs. 3.1 +/- 0.2 nmol Pi/mg protein/10 min in young and adult cells, respectively), but not Km, resulted in this decreased uptake of phosphate in adult groups. There was no difference in the efflux of phosphate from both age groups. When cells were preincubated in a phosphate-free medium for 24 hours, the uptake of phosphate was increased to 46% and 24% of their corresponding controls in young and adult cells, respectively. The decreased phosphate uptake and limited adaptation to a phosphate-free medium by the adult renal cells may account for the hypophosphatemia and phosphaturia seen in adult and old animals in vivo.     

Regulatory characteristics of amino acid transport in newborn rat renal cortex cells.

The uptaken of alpha-aminoisobutyric acid by slices of kidney cortex from newborn rats is enhanced by a preliminary incubation of the tissue in buffer at 37 degrees C. This effect is abolished by anaerobiosis, the presence of dinitrophenol or the removal of Na+ during the preliminary incubation. Cycloheximide (50 muM) and purimycin (1 mM) as well as alpha-aminoisobutyric acid, glycine and proline (5 mM) in the preincubation buffer also abolish the effect, while actinomycin D (0.8 muM) partially the phenomenon indicates that the enhanced uptake is due to an increased entry rate into the cells without a change in effux. There is no alteration in the apparent transport Km but an increase in the V for entry. The effect is dependent on tissue age being observed between birth and 22 days, after which there is a decrease in response to preliminary incubation with no effect seen in adult tissues.     

Newborn Rabbit Blood–Brain Barrier Is Selectively Permeable and Differs Substantially from the Adult

Abstract: Examination of blood-brain barrier (BBB) function by the intracarotid injection technique has been utilized in studies of newborn (6–30 h) and adult rabbits. The exclusion of mannitol (mol. wt. 182), dextran (mol. wt. 60,000–90,000) and indium-bound EDTA indicate that the newborn BBB has restrictive properties similar to the adult. At birth, saturable, carrier-mediated transport mechanisms are present, regulating the entry of glucose, amino acids, organic acids, purines, nucleosides and choline. No difference in brain uptake of glucose was observed between adult and newborn, but considerably higher uptake rates for arginine, choline and adenine were seen in the newborn. In contrast to suggestions of an immature barrier in young animals, these studies indicate that a sophisticated, selective BBB is operative at birth. Furthermore, the specific selectivity and dramatic increases seen for certain metabolites imply a vital function in the newborn for these carrier systems.     

Metabolism of [3H]Nipecotic Acid in the Rabbit Retina

Nipecotic acid has been demonstrated to block the gamma-aminobutyric acid transport systems. Previous studies have shown that the uptake system is the first transmitter-specific parameter to appear during the development of the rabbit retina. Use of these observations has been made to study the influence on the development of gamma-aminobutyric acid receptors of altering the uptake mechanism by treating newborn pups with nipecotic acid to block GABA transport. The present study of the in vivo metabolism of [3H]nipecotic acid in the CNS measured the changes in the levels of [3H]nipecotic acid in both adult and newborn rabbit retinas after injection of the label into the vitreal chamber. It was found that the effective half-life of [3H]nipecotic acid in the vitreous is about 5 h for adult tissue and 3 h for newborn. In contrast, all retinal fractions retained the label longer, the effective half-lives being about 60 h (adult) and 45 h (newborn). Further, no labeled metabolites of nipecotic acid were detected in either adult or newborn tissue. This study gives evidence that the degradation of nipecotic acid in nervous tissue is minimal and suggests that, although the rate of clearance is faster in neonates, the fate of nipecotic acid in vivo may be similar in both adult and newborn tissues.     

Primary Culture of Neural Cells Isolated from the Cerebellum of Newborn and Adult Mucopolysaccharidosis Type IIIA Mice

In order to evaluate the mechanisms leading to neuropathology in Mucopolysaccharidosis type IIIA (MPS-IIIA, Sanfilippo syndrome), we have harvested and cultured primary neural cells isolated from the cerebellum of newborn and adult MPS-IIIA and unaffected mice. Cell viability and plating efficiency were comparable for brain tissue obtained from either newborn or adult MPS-IIIA and unaffected mice. Cultures (newborn and adult) comprised a mixed brain cell population including astrocytes, oligodendrocytes, and neurons. Newborn MPS-IIIA cells contained inclusions and vacuoles consistent with the pathology present in affected brain tissue. Newborn and adult MPS-IIIA brain cells had approximately 5–7% of the sulfamidase activity present in primary neural cells cultured from unaffected newborn and adult mice. In addition, high levels of glucosamine-N-sulfate[α-1,4]hexuronic acid, a heparan sulfate-derived disaccharide, were detected in both newborn and adult MPS-IIIA brain cells. These results suggest that the primary MPS-IIIA brain cells exhibit characteristics of MPS-IIIA phenotype at the histopathological and biochemical level in culture.     

Capacity of a low calcium diet to induce the renal vitamin D 1a-hydroxylase is decreased in adult rats

Young animals adapt to a low calcium diet by increasing renal production of 1,25-dihydroxyvitamin D [1,25(OH)2D], the active metabolite of vitamin D. However, the capacity of adult animals to adapt is markedly diminished. With the recent cloning of the cytochrome P450 component (CYP1a) of the renal 1-hydroxylase enzyme complex, it is now possible to determine directly the effect of dietary calcium and maturation on the expression of renal 1-hydroxylase. Using a ribonuclease protection assay, it was found that feeding a low Ca diet markedly increased renal CYP1a mRNA levels in young rats. However, feeding this diet to adult rats produced an increase in CYP1a mRNA that was only 10% that of the young rats. These studies demonstrate that a low calcium diet increases renal 1,25-dihydroxyvitamin D production in young animals but not in adult animals by increasing CYP1a expression. Since the low calcium diet increased plasma parathyroid hormone levels to similar levels in both age groups, this suggests that in the adult there is a renal refractoriness to parathyroid hormone.     

Is tissue maturation necessary for flight? Changes in body composition during postnatal development in the big brown bat

Patterns of offspring development reflect the availability of energy and nutrients, limitations on an individual’s capacity to use available resources, and tradeoffs between the use of nutrients to support current metabolic demands and tissue growth. To determine if the long period of offspring dependency in bats is associated with the need for an advanced state of tissue maturation prior to flight, we examined body composition during postnatal growth in the big brown bat, Eptesicus fuscus. Despite their large size at birth (22% of maternal mass), newborn bats are relatively immature, containing 82% body water in fat-free mass. However, the total body water content of newborn bat pups decreases to near-adult levels in advance of weaning, while concentrations of total body fat and protein exceed adult values. In contrast to many other mammals, postnatal growth of bat pups was characterized by relatively stable concentrations of calcium and phosphorus, but declining concentrations of magnesium. These levels remained stable or rebounded in late postnatal development. This casts doubt on the hypothesis that low rates of mineral transfer necessitate an extended lactation period in bats. However, our finding of near-adult body composition at weaning is consistent with the hypothesis that extended lactation in bats is necessary for the young to achieve sufficient tissue maturity to undertake the active flight necessary for independent feeding. In this respect, bats differ from most other mammals but resemble birds that must engage in active flight to achieve nutritional independence.     

Characteristics of lysine uptake by isolated renal cortical tubule fragments from mature and immature dogs

The uptake of L-lysine was examined in isolated renal cortical tubule fragments from adult and 1-week-old dogs. Lysine uptake by adult tubules was initially more rapid than that by the immature tubules. This uptake by mature tubules reached a steady state after 30 min of incubation, while the newborn tubules still had not reached a steady state by 90 min of incubation. Because a steady state of lysine uptake was not attained with the immature tubules, their uptake of lysine exceeded that of the adult after 60 min of incubation. Kinetic studies revealed that lysine was taken up by one saturable transport system with a Km of 0.56 mM and Vmax of 6.18 mmol/liter intercellular fluid per 5 min in the adult and one saturable transport system in the 1-week-old with a Km of 0.38 mM and Vmax of 3.66 mmol/l intracellular fluid per 5 min. Lysine also entered the renal tubule cells in both age groups via a diffusional pathway with a kd of 0.35 min-1 in the adult and 0.30 min-1 in the newborn. Cystine competitively inhibited lysine uptake by adult dog tubules with a Ki of 0.61 mM. The other dibasic amino acids, ornithine and arginine, also inhibited lysine uptake in both the adult and the newborn.     

The influence of glutathione oxidation on renal cortex taurine transport

The interaction of diamide, a rapidly reversible thioloxidizing re reagent, with the taurine accumulation system was examined in rat kidney cortex slices from animals of different ages. Diamide at 10 mM lowered renal cortex glutathione content by 80% at a time that taurine accumulation was inhibited by 65%. Although the addition of equimolar GSH overcame diamide inhibition of taurine uptake, GSH per se inhibited taurine accumulation at 0.01 mM, but not at 0.2 or 1.0 mM. Dithiothreitol (DTT) also overcame diamide inhibition of uptake. As previously shown by Pillion et al (Eur. J. Biochem. $\text{79}$, 73, 1977) diamide inhibited gluconeogenesis by cortex slices.Diamide inhibited taurine accumulation by 85% by the low Km taurine transport site in cortex from newborn, 2 week, 4 week and adult animals, but only 50% at the high Km site. In contrast to the situation in adult tissue, efflux of taurine from preloaded slices of immature animals was not increased by diamide. Accordingly, one maturational event identified by these studies is that diamide-enhanced efflux was found only in mature cortex.     

High-affinity glycine and glutamate transport in pig forebrain white and gray matter: a quantitative study

High-affinity uptake of glycine and glutamate modulates glutamatergic neurotransmission in gray matter. N-Methyl-D-aspartate (NMDA) receptors were recently described on white matter oligodendrocytes, therefore uptake of glutamate and glycine in white matter may also modulate NMDA receptor function. We found that glycine uptake in white structures of pig forebrain (corpus callosum, fimbria, subcortical pyramidal tracts, and occipital subcortical white matter) was similar to that in gray structures (frontal and temporal cortices and hippocampus), and that it was sensitive to sarcosine, a GLYT1 inhibitor (IC(50) 15 microM). Glutamate uptake in white matter was approximately 10% of that in gray; it was sensitive to dihydrokainate, an EAAT2 inhibitor. The levels of glycine and its precursor serine were similar in white and gray matter: approximately 2 and 1 nmol/mg tissue, respectively. The white matter level of glutamate was approximately 7.6 nmol/mg tissue, or approximately 74% of gray matter levels. The activity of serine hydroxymethyl transferase, which converts serine into glycine, was similar in white and gray matter (11-18 pmol/(mg tissue)min), whereas the white matter activity of phosphate-activated glutaminase, which converts glutamine into glutamate, was approximately 100 pmol/(mg tissue)min, or approximately 34% of gray matter activity. The white matter activity of glutamine synthetase, the glial enzyme that converts glutamate into glutamine, was 20-40 nmol/(mg tissue)min in neocortex and 5-6 nmol/(mg tissue)min in white matter. The data show that forebrain white matter is equipped to regulate extracellular levels of glycine and glutamate, functions that may modulate white matter NMDA receptor function.     

Regulatory characteristics of amino acid transport in newborn rat renal cortex cells

The uptake of α-aminoisobutyric acid by slices of kidney cortex from newborn rats is enhanced by a preliminary incubation of the tissue in buffer at 37 °C. This effect is abolished by anaerobiosis, the presence of dinitrophenol or the removal of Na⁺ during the preliminary incubation. Cycloheximide (50 μM) and purimycin (1 mM) as well as α-aminoisobutyric acid, glycine and proline (5 mM) in the pre- incubation buffer also abolish the effect, while actinomycin D (0.8 μM) partially inhibits the enhancement due to preliminary incubation. A kinetic examination of the phenomenon indicates that the enhanced uptake is due to an increased entry rate into the cells without a change in efflux. There is no alteration in the apparent transport $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ but an increase in the $\text{V}$ for entry. The effect is dependent on tissue age being observed between birth and 22 days, after which there is a decrease in response to preliminary incubation with no effect seen in adult tissues.