Cerebral leucine uptake and protein synthesis in the near-term ovine fetus: relation to fetal behavioral state

doi:10.1152/ajpregu.00190.2002

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Cerebral leucine uptake and protein synthesis in the near-term ovine fetus: relation to fetal behavioral state

Marie J. Czikk, John C. Sweeley, Jacobus H. Homan, J. Ross Milley, and Bryan S. Richardson

Canadian Institute of Health Research Group in Fetal and Neonatal Health and Development, Departments of Obstetrics and Gynaecology and Physiology, Lawson Health Research Institute, University of Western Ontario, London, Ontario, Canada N6A 4V2; and Department of Pediatrics, Division of Neonatology, University of Utah, Salt Lake City, Utah 84132

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Behavioral/sleep state activity may impact on synthetic processes within the brain, thus accounting for the developmentalchange in such activity and suggesting a role in the brain's growthand development. We have therefore determined the cerebral uptakeof leucine and [¹⁴C]leucine during continuous tracer infusion as measures of leucinemetabolism in relation to behavioral state activity, as well asthe regional flux of leucine into brain tissue in the ovine fetusnear term. The cerebral fractional protein synthetic rate andthe absolute protein synthetic rate averaged ~20%/day and ~1 g/day,respectively, as measured for the whole brain, which is considerablyhigher than anticipated protein accretion and indicates a highrate of protein turnover with protein synthesis closely linkedto protein degradation. Measures of protein synthesis were significantlyhigher in the pituitary gland, which may be attributed to theactive synthesis and export of peptide hormones from this region.Cerebral leucine and [¹⁴C]leucine uptakes averaged ~630 and ~1,000 nmol · 100 g¹ · min¹, with the latter higher than leucine unidirectional flux andthus supporting a degree of leucine oxidation by the brain. Cerebralleucine metabolism as studied was affected by behavioral stateactivity, with uptake measurements for both leucine and [¹⁴C]leucine significantly increased during the high-voltage electrocortical/non-rapideye movement state by 1.7-fold and 2.8-fold, respectively, indicatingthat protein synthesis and degradation must also be increasedat this time, and supporting a role for behavioral state activityin the brain's growth anddevelopment.

brain development; leucine metabolism

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

CEREBRAL PROTEIN SYNTHESIS has been studied during brain growth and development, both pre- and postnatally in sheep (1,24) and postnatally in the rat (6, 26), because proteinsare integral components of structural elements in brain tissueand with the metabolism of brain protein directly related to maturationalevents (26). Initial study in the near-term ovine fetus by Schaeferand Krishnamurti (24) using a tyrosine isotopic-dilution techniqueshowed high rates of cerebral protein synthesis with a fractionalprotein synthetic rate between 14 and 37%/day and an absoluterate of synthesis of ~1 g/day. A subsequent study in fetal sheepby Abrams and colleagues (1) using [¹⁴C]leucine autoradiography reported a rate of leucine incorporationinto brain protein of ~5 nmol · g¹ · min¹, with an overall increase through the latter part of gestationand into the early postnatal period likely reflecting cerebralmyelination. Postnatal studies in rats have similarly shown highrates of brain protein synthesis during early development, withpeak values occurring shortly after birth and gradually decreasingthereafter (6, 26). While high rates of cerebral proteinsynthesis are thus evident during early life in both sheep andrats in support of the brain's growth and development, these ratesare considerably greater than anticipated protein accretion, indicatingthat protein degradation must also play an active role in thedevelopment of the brain (6).

The increase in brain weight for the ovine species during early development occurs in two phases, one up to 90 days postconceptionfollowed by a more rapid and larger increase thereafter that continuesto birth at ~145 days, leading to the classification of sheepas a prenatal brain developer (14). These two phases appearto reflect an increase in neuroblast multiplication, followedby neuroglial multiplication and myelination, and with growthand development of the cerebral hemispheres in advance of thatin the cerebellum. For the ovine species, well-differentiatedelectrocortical (ECOG) patterns as a measure of neurobehavioraldevelopment are evident from 120 days gestation onward, with initiallya high proportion of time in the low-voltage (LV) ECOG state inthe presence of rapid eye movements (REM), and with a progressivedecrease in this activity thereafter (27). Observations on thematuration of electrocortical patterns in utero or of behavioralactivity from birth indicate a similar trend in the developmentof sleep-wakefulness patterns in humans and other mammals (22,27), with the rate of such development in relation to birthwell correlated with the neuroanatomic maturity of the brain (20).

A behavioral state effect on cerebral metabolic rate is evident for the ovine fetus near term, with a significant increasein cerebral blood flow and in oxygen and glucose uptake duringthe LV/REM state compared with that of the high-voltage (HV) ECOGstate with no rapid eye movements [non-rapid eye movement (NREM)](21), presumably reflecting an increase in neuronal functionalactivity and/or synthetic processes within the brain. The relationshipof behavioral state activity to biosynthetic processes withinthe brain during development remains unclear, although recentstudies in adult animals have shown higher rates of cerebral proteinsynthesis to be positively correlated with the occurrence of NREMsleep rather than REM sleep (16, 19). We have therefore determinedthe cerebral uptake of leucine and of [¹⁴C]leucine during continuous tracer infusion as measures of leucinemetabolism in relation to behavioral state activity in the ovinefetus near term. Regional fractional protein synthetic rates andflux of leucine into protein within the brain were also determinedfrom the specific activity of protein-bound [¹⁴C]leucine within brain tissues as additional measures of cerebralproteinsynthesis.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Surgical procedure. Nine fetal sheep were surgically prepared at ~129 days gestation (term = 145 days). Anesthesia was induced with an intravenousinjection of thiopental sodium (1 g in 40 ml solution; AbbottLaboratories, Montreal, Canada) and was maintained with 1-1.5%halothane in oxygen (Halocarbon Laboratories, Hackensack, NJ).Before fetal surgery, a polyvinyl catheter (V11, Bolab, Lake HavasuCity, AZ) was placed in the maternal femoral vein. Using steriletechnique, a midline incision was made in the ewe's lower abdominalwall, and the uterus was palpated to determine fetal position.An incision was then made in the uterus, and the fetal head, neck,and upper body were exteriorized. Polyvinyl catheters (V4, Bolab)were placed in the axillary artery for blood sampling, in thecephalic vein for administration of antibiotics and radiolabeledleucine, in the trachea for monitoring of fetal breathing movements,and in the amniotic cavity for pressure recording. Electrodesof teflon-coated stainless steel wire (Cooner Wire, Chatsworth,CA) were placed biparietally on the dura for ECOG recording, throughthe lateral orbital ridge of the zygomatic bone of each eye forelectroocular (EOG) recording, and on the nuchal muscle for electromyographic(EMG) recording. A midline window of bone (~2 cm²) was removed from the fetal skull, immediately anterior to thecoronal suture; the dura on either side of the superior sagittalsinus was incised, and a transit time flow probe (3 mm, S-series,Transonic Systems, Ithaca, NY) was secured around the vessel.The cavity surrounding the probe was filled with bone wax to preventleakage of cerebral spinal fluid. Another small midline windowof bone (~0.5 cm²) was removed between the coronal and lambdoid sutures and rostralto the bifurcation of the superior sagittal sinus. A nonocclusivepolyvinyl catheter (V4, Bolab) was inserted into the vessel forblood sampling and was directed caudally by ~1 cm. Sagittal sinusblood flow (Q_ss) was briefly monitored intraoperatively to ensurethat the flow probe was functioning properly and to observe theeffects of subsequent catheter placement in the sagittal sinuson Q_ss. After placement of the probe and catheter, the scalp wassewn over. The uterus and abdomen were closed in layers, and allcatheters, electrodes, and the Transonic flow probe lead wereexteriorized to the flank of the ewe and secured to the ewe'sback in a plastic pouch. The ewes received a long-acting, broad-spectrumantibiotic immediately before surgery (1.2 g oxytetracycline im;LA-200, Rogar, STB, London, Canada) and were given intravenousfluids throughout the surgery (1,000 ml 0.9% salinesolution).

Postoperative care. After surgery, ewes were placed in metabolic cages suitable for continuous monitoring and were given an analgesic (1.5 mlBanamine). Antibiotics were administered for 3 days postoperativelyto the fetus (1,000,000 IU sodium penicillin G iv; Ayerst, Montreal,Canada) and to the amniotic cavity (1,000,000 IU sodium penicillinG). The ewes were allowed 4 days of postoperative recovery, duringwhich maternal and fetal catheters were flushed daily with heparinizedsaline to maintain patency, and fetal arterial blood was collectedfor blood gas analysis. Animals were allowed food and water adlibitum, and all surgical, postoperative, and experimental proceduresfollowed the guidelines provided by the Canadian Council on AnimalCare and the University of Western Ontario Council on AnimalCare.

Physiological measurements. On the day of experimental study, strain-gauge transducers (Statham model P-2310, Gould, Oxnard, CA) and a physiograph recorder(model 78D, Grass Instrument, Quincy, MA) were used to recordamniotic and tracheal pressures. Fetal ECOG, EOG, and EMG potentialswere displayed directly on the chart recorder after passing througha passive band-pass filter, 0.3-30 Hz on the preamplifier forECOG and EOG recordings, and 10-90 Hz on the preamplifier forEMG recordings. The amplified, filtered ECOG signal was furtherprocessed by means of a frequency integrator with the ECOG frequencyshift displayed separately on the chart recorder. The mean volumeblood flow measurement derived from the flow probe was processedusing a Transonic flowmeter (model T208, Transonic Systems) andwas displayed on the chart recorder with the normal scale calibrationset at 0-50 ml/min. Animals were studied over a 6-h period, witha continuous infusion of L-[1-¹⁴C]leucine in sterile normal saline into the fetal cephalic veinat 0.15 µCi/min (in 30 ml normal saline at a rate of 5 ml/h).Arterial blood samples (1 ml) were drawn at 15, 30, 60, and 90min of infusion to determine that the specific activity of leucinehad reached steady state. An arterial blood sample (1 ml) wasadditionally drawn before initiation of the infusion and was analyzedfor blood gases and pH as a measure of fetal well being. Afterthe first 2 h of infusion, spontaneous changes in behavioral statewere scored and four LV/REM and four HV/NREM epochs were studied.Cerebral arterial-venous (A-V) difference samples were collectedfrom the axillary artery (1.5 ml) and the sagittal sinus (1.5ml) at least 5 min into each state epoch, with LV measurementsmade only if EOG activity was present and in the absence of nuchalmuscle EMG activity, and HV measurements made only if EOG activitywas absent and in the presence of nuchal muscle EMG activity.The remaining whole blood was then spun (4°C, 10 min at 9,000g), and the plasma was titrated off and divided into two equalaliquots for duplicate measurements. All plasma aliquots werefrozen at $-$ 80°C for subsequent measurement of leucine concentrationand specific activity and $alpha$ -ketoisocaproic acid ( $alpha$ -KIC)concentration.

After completion of the 6-h infusion period, the ewe and fetus were immediately euthanized by an overdose of barbiturate (30mg pentobarbital sodium iv, MTC Pharmaceuticals, Cambridge, Canada),and an autopsy was performed to verify placement of cathetersand to retrieve the flow probe. The fetal brain was rapidly removed,weighed, and dissected into cerebral cortex, brain stem, cerebellum,spinal cord, and pituitary. Dissected regions were fast frozenin liquid nitrogen and stored at $-$ 80°C for later analysis of protein-boundand intracellular free leucine specificactivity.

Chemical analysis. Blood gases and pH were measured using an ABL-500 blood gas analyzer with temperature corrected to 39.5°C (Radiometer, Copenhagen,Denmark).

Methods for measurement of plasma leucine concentration and specific activity and $alpha$ -KIC concentration have been describedpreviously (15). Briefly, plasma (~350 µl) was combined withan equal volume of 6% sulfosalicylic acid containing norleucine(250 µM) and $alpha$ -ketocaproic acid (50 µM) (internal standards forleucine and $alpha$ -KIC, respectively). Samples were vortexed and centrifugedfor 6 min at 10,000 g, and the supernatant was collected. Plasmaconcentration of leucine or $alpha$ -KIC was determined by injectingderivatized samples onto an HPLC column (150 × 3.9-mm ID, ResolveC₁₈, 5-mm particle size, column temperature 42°C, Waters, Milford,MA; and 250 × 4.6-mm ID, Ultrasphere ODS, 5-mm particle size,42°C, Beckman, respectively). The leucine/ $alpha$ -KIC eluate peak wascollected and counted for radioactivity (model LS 5000 TD, BeckmanInstruments, Fullerton CA). Blood leucine or $alpha$ -KIC concentrationwas calculated by the method of peak-height ratio to the internalstandards.

Tissue concentrations and specific activity of leucine were measured using a modification of the method described by Horberand colleagues (10). Frozen tissue samples were weighed (~0.07-1.3g), and 6% sulfosalicylic acid was added. Samples were homogenizedon ice for ~40 s and then centrifuged for 40 min at 1,500 g and4°C, with this procedure repeated two additional times. The pooledsupernatant was then frozen for later analysis of intracellularfree leucine. The pellet (containing the protein-bound leucine)was dried overnight in a drying oven at 60°C, accurately weighed,hydrolyzed overnight, and then resuspended in 4 mlwater.

The supernatant and hydrolyzed protein samples were placed on ion-exchange columns, washed four times with 2 ml 0.01 N HCl,drained to waste, washed with 4 ml water, drained to waste, andfinally the leucine fraction was collected by washing four timeswith 2 ml 25% NH₄OH, and dried overnight. To the dried residue,exactly 2 ml of water was added, and the vials were capped, vortexed,and sonicated for 20 min to promote dissolution. Exactly 1 mlwas then transferred to a scintillation vial and then countedfor radioactivity. For the intracellular free samples (supernatant),0.5 ml of remaining sample was added to 0.5 ml 250 µM norleucine,and samples were taken to dryness. For the protein-bound samples(hydrolyzed protein), a fraction of the remaining sample was accuratelydiluted, 0.5 ml of 250 µM norleucine was added, and then it wasevaporated to dryness. All samples were then derivatized and processedfor HPLC in a similar manner to that previously described forplasmaleucine.

Data analysis and mathematical calculations. Q_ss as a relative measure of cerebral blood flow was determined every 10 s and averaged over the duration of each A-V differenceblood sample draw (~60 s) using a computerized data-acquisitionsystem (CADA, Hartronix Computer Solutions, Toronto,Canada).

The cerebral A-V difference for unlabeled leucine (µmol/l) was added to the A-V difference for unlabeled $alpha$ -KIC (µmol/l) as $alpha$ -KIC is a freely interconvertible metabolite of leucine and couldpossibly contribute to the intracellular leucine pool that isdestined to be incorporated into protein (15). This sum wasthen multiplied by the corresponding value obtained for Q_ss determinedevery 10 s and averaged over the duration of the cerebral A-Vdifference sample to determine relative cortical leucine uptake

cortical leucine uptake<IT>=</IT>Q<SUB>SS</SUB><IT>×</IT>{([Leu]<SUB>a</SUB><IT>−</IT>[Leu]<SUB>v</SUB>)

<IT>+</IT>([<IT>&agr;</IT>-KIC]<SUB>a</SUB><IT>−</IT>[<IT>&agr;</IT>-KIC]<SUB>v</SUB>)}

where subscripts "a" and "v" refer to arterial and venous concentrations,respectively.

The superior sagittal sinus drains regions of the frontal cortex and anterior regions of the parietal cortex as measured inthe newborn lamb and represents ~20% of total brain blood flow(7). Cerebral blood flow and leucine uptake per unit mass ofbrain tissue were then calculated assuming the respective relativevalues to be reflective of ~20% of brain tissue mass (7), thusallowing for comparison with previous studies. Relative cortical[¹⁴C]leucine uptake and cerebral [¹⁴C]leucine uptake per unit mass of brain tissue were determinedin a similar fashion to that described for the unlabeled leucineusing the cerebral A-V difference for [¹⁴C]leucine + $alpha$ -[¹⁴C]KIC (dpm/ml)

cortical [<SUP>14</SUP>C]leucine uptake<IT>=</IT>Q<SUB>SS</SUB><IT>×</IT><FENCE><FENCE><FENCE>[<SUP>14</SUP>C]Leu</FENCE><SUB>a</SUB></FENCE></FENCE>

<IT>−</IT><FENCE><FENCE><FENCE>[<SUP>14</SUP>C]Leu</FENCE><SUB>v</SUB></FENCE><IT>+</IT><FENCE><IT>&agr;-</IT>[<SUP>14</SUP>C]KIC</FENCE><SUB>a</SUB><IT>−</IT><FENCE><IT>&agr;-</IT>[<SUP>14</SUP>C]KIC</FENCE><SUB>v</SUB></FENCE>

Fractional extraction of leucine and [¹⁴C]leucine was calculated as the cerebral A-V difference for leucine or [¹⁴C]leucine divided by the respective leucine or [¹⁴C]leucine arterial concentration. The cortical metabolic valuesdetermined for each of the four LV/REM and four HV/NREM stateepochs studied were averaged to obtain mean LV/REM and HV/NREMvalues for eachanimal.

The specific activity of plasma (SA_P) leucine (in dpm/nmol) was determined by dividing the concentration of [¹⁴C]leucine (dpm/ml) by the corresponding concentration of leucine(nmol/ml). The specific activity of brain tissue protein-bound(SA_PB) leucine and intracellular free (SA_IF) leucine were similarlydetermined from the concentration of [¹⁴C]leucine (dpm/g) and the corresponding concentration of leucine(nmol/g) in the tissue pellet and supernatant,respectively.

Tissue fractional protein synthetic rate (FSR), which is the percentage of brain protein that is newly synthesized per day,was then calculated for each brain region using respective SA_PBand SA_IF values and the total infusion time (days) in the followingformula (3, 24)

FSR (<IT>%/</IT>day)<IT>=</IT>([SA<SUB>PB</SUB><IT>/</IT>SA<SUB>IF</SUB>]<IT>/</IT>infusion time)<IT>×</IT>100<IT>%</IT>

At the time of tissue leucine analysis, both the wet weight of the thawed tissue aliquot and the corresponding dried proteinpellet weight were accurately determined. The ratio of dried pelletweight to aliquot wet weight was then multiplied by the wet weightof the entire region as determined at the time of postmortem todetermine the total dry weight (estimate of the protein content)of that particular region. Estimated absolute protein syntheticrate (g/day) was then calculated for each region as the productof the regional dry weight (g) and the corresponding regionalfractional synthetic rate (per day). The rate at which leucineenters fetal protein (unidirectional leucine flux) (µmol · 100g¹ · min¹) was calculated for each brain region as the product of the fractionalsynthetic rate for that region (per day) and the amount of leucinein protein in that region (Leu_protein) (nmol/100 g) divided by1,440

unidirectional leucine flux<IT>=</IT>[FSR<IT>×</IT>Leu<SUB>protein</SUB>]<IT>/</IT>1,440

Results obtained for the nine animals are presented as grouped means ± SE. The leucine uptake data reported were analyzedby a Student's paired t-test for differences between the LV/REMand HV/NREM states, with significance taken at P < 0.05. The regionalfractional protein synthetic data, estimated absolute syntheticrate, and leucine flux data were each analyzed using a one-wayANOVA for repeated measures with a post hoc Tukey test for differencesbetween regions, with significance taken at P < 0.05.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Fetal arterial blood gases and pH measured within the normal range, with an average PO₂ of 23.3 ± 1.2 mmHg, PCO₂ of 50.3 ±1.4 mmHg, and pH of 7.37 ± 0.01, indicating that all animals werein good health at the time of experimental study. SA_P leucinereached steady-state values by 120 min of infusion. Figure 1 illustratesmean SA_P leucine at time 0 and at 15, 30, 60, and 90 min of infusionand throughout the blood sampling period, demonstrating the attainmentof plateau values, which averaged 6.7 ± 0.7 dpm/nmol. SA_IF leucinevalues measured in the fetal brain tissue at the end of the 6-hinfusion period were lower than SA_P leucine plateau values, averaging5.3 ± 0.4 dpm/nmol, while SA_PB values were considerably lower,averaging 0.27 ± 0.02 dpm/nmol.

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Fig. 1. Arterial plasma leucine specific activity as measured throughout the infusion period with attainment of plateau specific activity values by 120 min of infusion.

Cerebral leucine and [¹⁴C]leucine uptake. Blood flow in the superior sagittal sinus was affected by behavioral state activity, as studied at the time of cerebral A-Vdifference leucine measurements, and was increased in each ofthe animals during the LV/REM state compared with the HV/NREMstate, 19.8 ± 2.3 vs. 15.0 ± 1.7 ml/min (P < 0.001) (Table 1).Accordingly, cerebral blood flow per unit mass of brain tissuewas similarly increased, 206 ± 27 vs. 156 ± 20 ml · 100 g¹ · min¹ (P < 0.002) (Table 1). Conversely, the A-V difference for leucineand leucine fractional extraction were increased and to a greaterextent during the HV/NREM state, 4.7 ± 1.0 vs. 2.0 ± 0.8 µmol/l(P < 0.001) and 2.1 ± 0.4 vs. 0.8 ± 0.5% (P < 0.02), respectively,but with no measurable A-V difference for $alpha$ -KIC during eitherbehavioral state (Table 1). As such, cortical leucine uptakeand thus cerebral leucine uptake were both increased during theHV/NREM state compared with the LV/REM state, 77 ± 25 vs. 44 ±30 nmol/min and 796 ± 266 vs. 467 ± 315 nmol · 100 g¹ · min¹, respectively (both P < 0.02) (Table 1). The A-V differencefor [¹⁴C]leucine and [¹⁴C]leucine fractional extraction were also increased during theHV/NREM state and more so than their unlabeled counterparts, 62± 9 vs. 20 ± 10 dpm/ml and 4.4 ± 0.5 vs. 1.6 ± 0.8%, respectively(both P < 0.01), but again with no measurable A-V difference for $alpha$ -[¹⁴C]KIC during either behavioral state (Table 1). As such, cortical[¹⁴C]leucine uptake and thus cerebral [¹⁴C]leucine uptake were also increased during the HV/NREM stateand more so than their unlabeled counterparts, 971 ± 199 vs. 341± 218 dpm/min and 10,149 ± 2,266 vs. 3,460 ± 2,303 dpm · 100 g¹ · min¹, respectively (both P = 0.05) (Table 1).

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Table 1. Cerebral leucine and [¹⁴C]leucine metabolism

Regional cerebral protein synthesis. Cerebral fractional synthetic rates for protein averaged ~20%/day and were similar as measured for the cerebral cortex, cerebellum,brain stem, and spinal cord, but significantly higher as measuredfor the pituitary gland at 29 ± 3%/day (P < 0.05) (Fig. 2). Theunidirectional flux of leucine into cerebral protein averaged~0.7 µmol · 100 g¹ · min¹ and was again similar as measured for the cerebral cortex, cerebellum,and brain stem, but significantly lower as measured for the spinalcord at 0.41 ± 0.03 µmol · 100 g¹ · min¹, and significantly higher as measured for the pituitary glandat 1.40 ± 0.12 µmol · 100 g¹ · min¹ (both P < 0.05) (Fig. 2). The estimated absolute synthetic ratefor the brain as a whole was ~1 g/day, constituting mainly thatfrom the cerebral cortex at 1.0 ± 0.1 g/day, and with considerablysmaller contributions from the cerebellum and brain stem at 0.12± 0.01 and 0.06 ± 0.01 g/day, respectively.

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Fig. 2. Fractional synthetic rate (A) and unidirectional flux of leucine into cerebral protein (B). Different letters indicate significance at P < 0.05.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The present study utilized a continuous intravenous infusion of L-[1-¹⁴C]leucine to investigate leucine metabolism in the near-term ovinefetal brain. This was accomplished with the measurement of tissueprotein leucine specific activity, which reflects the unidirectionalflux of leucine into cerebral protein, i.e., protein synthesis,and using Fick methodology to measure the uptake of labeled/unlabeledleucine by the brain, which reflects that utilized for proteinsynthesis/accretion, plus any leucine that is oxidized. A-V differenceswere collected in both the LV/REM and HV/NREM behavioral statesto determine the relationship between cerebral leucine metabolismand behavioral state activity during brain development. The labelon L-[1-¹⁴C]leucine at the carboxyl position can be measured in leucinethat has been incorporated into protein, or it can be followedthrough the catabolic pathway, which involves the reversible transaminationwith $alpha$ -ketoglutarate to form $alpha$ -KIC, followed by oxidative decarboxylationto form ¹⁴CO₂, which diffuses out of the tissue (8). The measurementof tissue SA_PB leucine along with that of the precursor pool ata defined time from the start of the tracer infusion providesa means of estimating the fractional synthetic rate of brain proteins,i.e., the percentage of brain proteins newly synthesized per unittime. The accretion of proteins within the brain in turn representsthe difference between the synthesis of protein and the degradation,or breakdown, of protein. The measurement of unlabeled leucineuptake by the brain here studied using Fick methodology will reflectthat leucine directed toward protein accretion and any leucinethat is oxidized. The infused labeled leucine will also be takenup by the brain and will equilibrate with the intracellular freeleucine pool (25). However, depending on the half-life of proteins,which approximates 4 days for the adult brain (12), relativeto the infusion time (6 h), there should be limited recyclingof labeled leucine out of brain proteins due to degradation overthe course of the study. Thus the measurement of labeled leucineuptake by the brain should mainly reflect that leucine directedtoward protein synthesis as well as any that isoxidized.

Measures of cerebral protein synthesis in the present study were determined using tissue SA_IF leucine for the precursor pooland, although likely to be more representative than SA_P, may infact underestimate the actual specific activity values of theimmediate precursor amino acyl-tRNA. This could occur due to recyclingof unlabeled leucine into the intracellular free leucine poolfrom protein degradation and tRNA species that are preferentiallycharged from the plasma extracellular rather than intracellularfree pool (5). As such, measures of cerebral protein synthesismay be overestimated; however, this should be minimal, since theSA_IF leucine values were only slightly lower than the SA_P leucineplateau values, averaging 5.3 vs. 6.7 dpm/nmol, i.e., an ~20%difference between the maximum and minimum measures of cerebralprotein synthesis when using the SA_IF and SA_P leucine values forthe precursor pool, respectively. The cerebral fractional syntheticrate for protein as measured averaged ~20%/day for the brain asa whole, which is within the range of values previously reportedfor the ovine fetus at a slightly younger gestational age by Schaeferand Krishnamurti (24) using tyrosine rather than leucine asthe tracer amino acid. The unidirectional flux of leucine intocerebral protein, as measured using the fractional synthetic rateand the concentration of leucine in protein, averaged ~0.7 µmol· 100 g¹ · min¹, which is similar to that reported by Abrams and colleagues (1)using leucine autoradiography at ~5 nmol · g¹ · min¹ for animals at 130-135 days gestation. The estimated absoluteprotein synthetic rate here measured for the brain as a wholeusing the fractional synthetic rate and the dry weight of thebrain as an estimate of protein content was ~1 g/day, which isthe same as that reported by Schaefer and Krishnamurti (24).This value is much higher than anticipated protein accretion at~36 mg/day as calculated for the cerebral hemispheres, brain stem,and cerebellum of the ovine fetus between 121 and 150 days gestationfrom the data reported by McIntosh and colleagues (14) relatingto protein content within the brain at these developmental timepoints. As such, the high rate of protein synthesis noted forthe ovine fetal brain near term must be closely linked to a rateof protein degradation, which is almost as high as that for synthesis.Study of protein metabolism in the rat brain at 10-20 days postnataland thus at a developmental stage comparable to that of the near-termovine fetal brain (14) likewise reveals that protein accretionis the result of a relatively small difference between a highrate of degradation and an even higher synthesis rate, but withthese rates now slowing and converging from that evident duringthe first week postnatal, with a resultant slowing of proteinaccretion (6).

In the present study, there were no regional differences in the measures of protein synthesis from the cerebral cortex, cerebellum,or brain stem, which one might expect given the heterogeneousmakeup of each of these structures and random tissue sampling.However, the findings of Abrams and colleagues (1) with thedetailed study of regional protein synthesis within the brainusing leucine autoradiography would also indicate that the compositerates for these brain regions will be similar albeit with subregionaldifferences with rates higher in the pineal body and hypothalamicnuclei, and lower in the white matter. Of interest, measures ofprotein synthesis here studied were significantly higher in thepituitary gland, with the fractional synthetic rate at ~30%/dayand the unidirectional flux of leucine into protein at ~1.4 µmol· 100 g¹ · min¹, which may be attributed to the active synthesis and export ofpeptide hormones from this region (25). Conversely, the unidirectionalflux of leucine into protein was significantly lower in the spinalcord at ~0.41 µmol · 100 g¹ · min¹, which is similar to that reported by Abrams and colleagues (1)and may reflect slower turnover of structural components withinthe nervous system compared with those involved in functionalattributes.

Cerebral leucine uptake in the present study was determined using A-V differences for plasma leucine because the plasma transportof this amino acid across tissues per unit volume is reportedto be at the same rate as blood cellular transport in sheep (9).It is also recognized that $alpha$ -KIC is interconvertible with leucinewithin the cell and can move freely between the intra- and extracellularpools. As such, the uptake of $alpha$ -KIC could potentially contributeto the intracellular leucine precursor pool (15). However, therewas no measurable uptake of $alpha$ -KIC by the ovine fetal brain, indicatingthat the contribution of $alpha$ -KIC to the intracellular leucine poolwas minimal. Cerebral leucine uptake as measured for those corticalareas drained by the superior sagittal sinus averaged ~60 nmol/minand, assuming that this blood flow represents ~20% of total brainflow (7), results in a cerebral leucine uptake of ~630 nmol· 100 g¹ · min¹. This value is threefold higher than that previously reportedfor the adult sheep brain (18) and is in keeping with a greateramino acid requirement during brain development due to proteinaccretion and possibly to some degree of oxidative metabolism,although glucose uptake as a metabolic fuel is sufficient to accountfor the oxidative needs of the ovine fetal brain (4, 11).Of interest, cerebral [¹⁴C]leucine uptake averaged ~6,800 dpm · 100 g¹ · min¹, which is equivalent to 1,000 nmol · 100 g¹ · min¹ as calculated using the plateau SA_p leucine value of 6.7 dpm/nmol.This uptake of labeled leucine is ~2-fold greater than the unidirectionalflux of leucine into cerebral protein as measured here and byAbrams and colleagues (1). To the extent that this uptake measurementreflects leucine directed toward protein synthesis as well asthat which is oxidized, a degree of oxidative metabolism is therebysupported.

Cerebral leucine uptake as studied was effected by behavioral state activity, with uptake measurements for both leucine and[¹⁴C]leucine significantly increased during the HV/NREM state by1.7-fold and 2.8-fold, respectively, compared with that of theLV/REM state. Cerebral uptake values were in fact not significantlydifferent from zero during the LV/REM state. Conversely, thesevalues during the HV/NREM state were all significantly differentfrom zero with [¹⁴C]leucine uptake at 10,149 dpm · 100 g¹ · min¹ or 1,514 nmol · 100 g¹ · min¹ as calculated using the plateau SA_P leucine value, ~2-fold higherthan unlabeled leucine uptake at 796 nmol · 100 g¹ · min¹. It is unlikely that the increased uptake of leucine during HV/NREMis attributable to changes in the transport of leucine via theblood-brain barrier (BBB) neutral amino acid transporter, as leucinehas a high BBB permeability (17) and as there is no change inthe arterial plasma concentration of leucine (as measured here)or the other neutral amino acids (23) between the two behavioralstates. Assuming that [¹⁴C]leucine uptake reflects mainly protein synthesis whereas unlabeledleucine uptake reflects protein synthesis plus degradation, i.e.,accretion as previously discussed, then both synthesis and degradationmust also be increased during the HV/NREM state compared withthe LV/REM state. However, the increase in synthesis will alsobe dependent on the extent of any leucine oxidation by the brain.For example, if 50% of the cerebral leucine uptake were to beoxidatively metabolized, i.e., ~400 nmol · 100 g¹ · min¹, with the remainder directed toward protein accretion, then thatattributed to synthesis vs. degradation would measure ~1,115 and715 nmol · 100 g¹ · min¹, respectively. While this degree of oxidative metabolism wouldaccount for <2 µmol of oxygen · 100 g¹ · min¹, it is of interest that Chao and colleagues (4) found measuredoxygen uptake by the ovine fetal brain during the HV/NREM stateto be somewhat higher than that accounted for by glucose oxidationalone, 127 vs. 114 µmol · 100 g¹ · min¹, with the probability of additional metabolic substrates includingthat of lactate at this time. These findings now add to thosein adult animals where higher rates of cerebral protein synthesishave been shown to be positively correlated with the occurrenceof NREM sleep (16, 19) and further support a role for behavioralstate activity in the brain's growth and development. Together,these studies would also indicate that the decrease in the brain'smetabolic demand during NREM sleep as seen in the ovine fetus(21) and in other species postnatally, including humans (13),does not result from a decrease in biosynthetic activity and may,in fact, favor the synthesis of new proteins. This would supportthe restorative theory of sleep (2) whereby energy conservationduring NREM sleep favors the anabolic restoration of tissuecomponents.

Perspectives

Brain growth and development are characterized by a series of events that include the proliferation and migration of nervecells, the growth of axons and dendrites, the formation of functionalsynapses, cell death, myelination of axons, and the fine tuningof neuronal specificity. These maturational events in turn willbe intricately linked to protein synthesis in the brain for theprovision of structural components and the signaling processesto direct these events. The high rates of protein synthesis hereinreported point to a high rate of protein turnover within the brainduring development and indicate that growth processes leadingto protein accretion at this time must involve extensive tissueremodeling. Behavioral state activity, which is well delineatedin the ovine fetus near term as a prenatal brain developer, appearsto impact on protein metabolism within the brain with an increasein both synthesis and degradation during the HV/NREM state andfurther supporting a role for behavioral state activity in thebrain's growth anddevelopment.

	ACKNOWLEDGEMENTS

We thank J. Homan, L. Carmichael, and R. Wallace for technical assistance, and Drs. F. Possmayer and V. Han for interest andinput to thisstudy.

	FOOTNOTES

This work was supported by grants from the Canadian Institute of Health Research (B. S. Richardson) and an Ontario GraduateScholarship in Science and Technology (M. J. Czikk). B. S. Richardsonis currently the recipient of the Wyeth-Ayerst Clinical ResearchChair for Women's Health inPerinatology.

Address for reprint requests and other correspondence: B. S. Richardson, Dept. of Obstetrics and Gynaecology, St. Joseph'sHealth Centre, 268 Grosvenor St., London, Ontario, Canada N6A4V2 (E-mail:brichar1{at}uwo.ca).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

10.1152/ajpregu.00190.2002

Received 28 March 2002; accepted in final form 18 September 2002.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

1. Abrams, RM, Burchfield DJ, Sun Y, and Smith CB. Rates of local cerebral protein synthesis in fetal and neonatal sheep. Am J Physiol Regul Integr Comp Physiol 272: R1235-R1244, 1997[Abstract/Free Full Text].

2. Adam, K. Sleep as a restorative process and a theory to explain why. Prog Brain Res 53: 289-305, 1980[Medline].

3. Battaglia, FC, and Meschia G. Fetal and placental metabolism. II. Amino acids and lipids. In: An Introduction to Fetal Physiology. Orlando, FL: Academic, 1986, p. 100-135.

4. Chao, CR, Hohimer AR, and Bissonnette JM. The effect of electrocortical state on cerebral carbohydrate metabolism in fetal sheep. Dev Brain Res 49: 1-5, 1989[Medline].

5. Davis, SR, Barry TN, and Hughson GA. Protein synthesis in tissues of growing lambs. Br J Nutr 46: 409-419, 1981[ISI][Medline].

6. Dunlop, DS, van Elden W, and Lajtha A. Protein degradation rates in regions of the central nervous system in vivo during development. Biochem J 170: 637-642, 1978[ISI][Medline].

7. Grant, DA, Franzini C, Wild J, and Walker AM. Continuous measurements of blood flow in the superior sagittal sinus of the lamb. Am J Physiol Regul Integr Comp Physiol 269: R274-R279, 1995[Abstract/Free Full Text].

8. Hawkins, RA, Huang SC, Barrio JR, Keen RE, Feng D, Mazziotta JC, and Phelps ME. Estimation of local cerebral protein synthesis rates with L-[1-¹¹C]leucine and PET: methods, model and results in animals and humans. J Cereb Blood Flow Metab 9: 446-460, 1989[ISI][Medline].

9. Heitman, RN, and Bergman EN. Transport of amino acids in whole blood and plasma of sheep. Am J Physiol Endocrinol Metab 239: E242-E247, 1980[Free Full Text].

10. Horber, FF, Horber-Feyder CM, Krayder S, Schwenk WF, and Haymond MW. Plasma reciprocal pool specific activity predicts that of intracellular free leucine for protein synthesis. Am J Physiol Endocrinol Metab 257: E385-E399, 1989[Abstract/Free Full Text].

11. Jones, MC, Burd LI, Makowski EL, Meschia G, and Battaglia FC. Cerebral metabolism in sheep: a comparative study of the adult, the lamb and the fetus. Am J Physiol 229: 235-239, 1975[Abstract/Free Full Text].

12. Lajtha, A, Latzkovits L, and Toth J. Comparison of turnover rates of proteins of the brain, liver and kidney in mouse in vivo following long term labeling. Biochim Biophys Acta 425: 511-520, 1976[Medline].

13. Madsen, PL, and Vorstrup S. Cerebral blood flow and metabolism during sleep. Cerebrovasc Brain Metab Rev 3: 281-296, 1991[ISI][Medline].

14. McIntosh, GH, Baghurst KI, Potter BJ, and Hetzel BS. Foetal brain development in the sheep. Neuropathol Appl Neurobiol 5: 103-114, 1979[ISI][Medline].

15. Milley, JR, and Sweeley JC. High-performance liquid chromatographic measurement of leucine and $alpha$ -ketoisocaproate in whole blood: application to fetal protein metabolism. J Chromatogr 613: 23-33, 1993[ISI][Medline].

16. Nakanishi, H, Sun Y, Nakamura RK, Mori K, Ito M, Suda S, Nambe H, Storch FI, Dang TP, Mendelson W, Mishkin M, Kennedy C, Gillen JC, Smith CB, and Sokoloff L. Positive correlations between cerebral protein synthesis rates and deep sleep in Macaca mulatta. Eur J Neurosci 9: 271-279, 1997[ISI][Medline].

17. Oldendorf, WH. Brain uptake of radiolabeled amino acids, amines, and hexoses after arterial injection. Am J Physiol 221: 1629-1639, 1971[Free Full Text].

18. Pell, JM, and Bergman EN. Cerebral metabolism of amino acids and glucose in fed and fasted sheep. Am J Physiol Endocrinol Metab 244: E282-E289, 1983[Abstract/Free Full Text].

19. Ramm, P, and Smith CT. Rates of cerebral protein synthesis are linked to slow wave sleep in the rat. Physiol Behav 48: 749-753, 1990[Medline].

20. Richardson, BS. Metabolism of the fetal brain: biological and pathological development. In: The Fetal and Neonatal Brain Stem, edited by Hanson MA.. Cambridge, UK: Cambridge Univ. Press, 1991, p. 87-105.

21. Richardson, BS. The effect of behavioural state on fetal metabolism and blood flow circulation. Semin Perinatol 16: 227-233, 1992[ISI][Medline].

22. Richardson, BS. Ontogeny of behavioural states in the fetus. In: Textbook of Fetal Physiology, edited by Thornburn G, and Harding R.. Oxford, UK: Oxford Univ. Press, 1994, p. 322-328.

23. Richardson, B, Carmichael L, Homan J, Morrison J, and Rupar T. The uptake of amino acids by the ovine fetal brain: relationship to electrocortical state. J Soc Gynecol Investig 2: P267, 1995.

24. Schaefer, AL, and Krishnamurti CR. Whole body and tissue fractional protein synthesis in the ovine fetus in utero. Br J Nutr 52: 359-369, 1984[ISI][Medline].

25. Smith, CB. The measurement of regional rates of cerebral protein synthesis in vivo. Neurochem Res 16: 1037-1045, 1991[ISI][Medline].

26. Sun, Y, Deibler GE, Jehle J, Macedonia J, Dumont I, Dang T, and Smith CB. Rates of local cerebral protein synthesis in the rat during normal postnatal development. Am J Physiol Regul Integr Comp Physiol 268: R549-R561, 1995[Abstract/Free Full Text].

27. Szeto, HH, and Hinman DJ. Prenatal development of sleep-wake patterns in sheep. Sleep 8: 347-355, 1985[ISI][Medline].

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