Essential amino acids and muscle protein recovery from resistance exercise

doi:10.1152/ajpendo.00466.2001

Essential amino acids and muscle protein recovery from resistance exercise

Elisabet Børsheim, Kevin D. Tipton, Steven E. Wolf, and Robert R. Wolfe

Metabolism Unit, Department of Surgery, Shriners Hospital for Children/Galveston, University of Texas Medical Branch, Galveston, Texas 77550

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This study tests the hypothesis that a dose of 6 g of orally administered essential amino acids (EAAs) stimulates net muscleprotein balance in healthy volunteers when consumed 1 and 2 hafter resistance exercise. Subjects received a primed constantinfusion of L-[²H₅]phenylalanine and L-[1-¹³C]leucine. Samples from femoral artery and vein and biopsies fromvastus lateralis were obtained. Arterial EAA concentrations increasedseveralfold after drinks. Net muscle protein balance (NB) increasedproportionally more than arterial AA concentrations in responseto drinks, and it returned rapidly to basal values when AA concentrationsdecreased. Area under the curve for net phenylalanine uptake abovebasal value was similar for the first hour after each drink (67± 17 vs. 77 ± 20 mg/leg, respectively). Because the NB responsewas double the response to two doses of a mixture of 3 g of EAA+ 3 g of nonessential AA (NEAA) (14), we conclude that NEAA arenot necessary for stimulation of NB and that there is a dose-dependenteffect of EAA ingestion on muscle proteinsynthesis.

muscle protein metabolism; essential amino acids; stable isotopes

	INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

MUSCLE PROTEIN SYNTHESIS is stimulated in the recovery period after resistance exercise (4, 8). However, the rate ofmuscle protein breakdown is also increased, thereby blunting thechange in the net balance between synthesis and breakdown. Althoughnet muscle protein balance is generally improved after resistanceexercise, it remains negative. Therefore, nutrient intake is necessaryto achieve positive net muscle proteinbalance.

The optimal composition and amount of nutrient ingestion to maximally stimulate muscle protein synthesis after resistanceexercise are not known. It is clear that amino acids or proteinshould be a component, as we have previously shown that eitherthe infusion (5) or ingestion of a large amount (17) (30-40g) of amino acids after exercise stimulates muscle protein synthesis.Furthermore, muscle protein synthesis was increased 3.5-fold whenonly a small amount (6 g) of a mixture of essential amino acids(EAAs) was given along with 35 g of carbohydrate after resistanceexercise (16). The latter results (16) suggest that a relativelysmall amount (i.e., 6 g) of EAAs can effectively stimulate muscleprotein synthesis, but the independent effects of amino acidsand carbohydrate were not assessed. Thus a principal goal of thisstudy was to determine the independent effect of ingestion ofa bolus of 6 g of EAAs on net muscle protein synthesis after resistanceexercise.

The proportional contributions of individual amino acids to a mixture ingested after resistance exercise can potentially affectthe response. In an earlier study (17), we concluded that theingestion of only EAAs was necessary for stimulation of muscleprotein synthesis, because the effect on net muscle protein synthesiswas similar when subjects were given either 40 g of a balancedmixture [21.4 g EAAs and 18.6 g nonessential amino acids (NEAAs),roughly in proportion to their relative contributions to muscleprotein], or 40 g of only EAAs. However, if the NEAAs are notnecessary for stimulation of synthesis, it is unclear why ingestionof the EAAs alone did not stimulate muscle protein synthesis toa greater extent than did the balanced mixture. It could be that,in fact, the NEAAs served no function, but the amount of EAAsin the balanced mixture (21 g) exceeded the maximal effectivedose. In this case, intake of more than 21 g of EAAs (i.e., 40g) would have no further effect than that already elicited by21 g. If true, then comparison of less than the maximally effectivedose of EAAs with a comparable amount of a balanced mixture ofEAAs + NEAAs should reveal a significantly greater effect of theEAAs. Thus a secondary goal of this project was to compare theresponse to 6 g of an EAA mixture with the response to 6 g ofa balanced mixture of amino acids, which included ~3 g of EAAsand 3 g of NEAAs. We speculated that 6 g of EAA would be lessthan the maximally effective dose of EAA, and thus there wouldbe a greater response to the EAAs than to the mixture of EAAsand NEAAs. The results of the response to 6 g of the balancedmixture have been published previously (14).

The composition of the mixture of EAAs we have tested in this and previous studies (16) was originally based on the compositionof muscle protein, with the idea being to increase the availabilityof each EAA in proportion to its requirement for the synthesisof muscle protein. However, different clearance rates of individualamino acids could result in rates of uptake that do not directlycorrespond to the composition of the ingested mixture. This wouldbe reflected by disproportionate changes in concentrations ofblood amino acids compared with the composition of the ingestedmixture. Therefore, another goal of the current study was to measureblood and intramuscular concentrations of all amino acids beforeand after ingestion of the mixture to determine whether the mixtureachieved the goal of causing proportional increases in all EAAs,and if any NEAA dropped sufficiently to become potentially ratelimiting for protein synthesis. This information could help toformulate a new mixture that might be more effective than theEAA mixture we haveused.

Not only is the composition of nutrient ingestion after exercise potentially important, but also the pattern of ingestionmay affect the response of muscle protein synthesis. We have previouslyshown that amino acid concentration, per se, is not a direct determinantof muscle protein synthesis. Thus, when blood amino acid concentrationswere elevated to a steady-state level about twice the basal valuesfor 6 h, muscle protein synthesis was stimulated over the first2 h but thereafter returned to the resting level despite persistentelevations in blood amino acid concentrations (6). Similarly,in our earlier study after exercise (16), the rate of net muscleprotein synthesis returned to the basal level 60 min after theingestion of a bolus of EAAs + carbohydrate, even though the bloodamino acid concentrations were still approximately double thebasal level. These observations are best explained by the musclebecoming refractory to a persistent elevation in amino acid concentrations.If true, it follows that the synthetic response to ingestion ofa bolus of amino acids would be refractory to a second dose untilthe concentrations from the first dose returned to the basal level.It was therefore a further goal of this study to determine whetherthe response of net muscle protein synthesis to a second doseof amino acids would be affected by the ingestion of an initialdose 1 hearlier.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Subjects. Six healthy subjects (3 men and 3 women), 19-25 yr of age, participated in the study (Table 1). Subjects were recreationallyactive but were not involved in a consistent resistance or endurance-trainingprogram. They were fully informed about the purpose and proceduresof the study before written consent was obtained. Before participationin the experiments, each subject had a complete medical screening,including vital signs, blood tests, urine tests, and a 12-leadelectrocardiogram, for determination of health status at the GeneralClinical Research Center (GCRC) of the University of Texas MedicalBranch (UTMB) at Galveston, TX. The protocol was approved by theInstitutional Review Board of the UTMB.

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Table 1. Physical characteristics and exercise data for all subjects

Preexperimental procedures. At least 1 wk before an experiment, subjects were familiarized with the exercise protocol, and their one repetition maximum(1RM, the maximum weight that can be lifted for one repetition)was determined by the procedure described by Mayhew et al. (13)(Table 1). The leg volume of each subject was estimated fromanthropometric measures of leg circumference and height at multiplepoints down the length of the leg (Table 1).

Experimental protocol. Each subject was studied once. The subjects were instructed not to exercise for 2 days before an experiment, not to make anychanges in their dietary habits, and not to use tobacco or alcoholduring the last 24 h before an experiment. The subjects reportedto the GCRC in the evening before an experiment for an overnightstay and were fasted from 10:00PM.

The experimental protocol is shown schematically in Fig. 1. At ~6:00 AM, an 18-gauge polyethylene catheter (Cook, Bloomington,IN) was inserted into an antecubital arm vein for the primed continuousinfusion of stable isotopes of amino acids. After obtaining ablood sample for measurement of background amino acid enrichment,a primed, constant infusion of [¹⁵N₂]urea was started at $-$ 180 min (~6:30 AM). At $-$ 120 min (~7:30AM), a primed, constant infusion of L-[ring-²H₅]phenylalanine and L-[1-¹³C]leucine was started. The following infusion rates (IR) and primingdoses (PD) were used

<SC>l</SC>-[<SUP>2</SUP>H<SUB>5</SUB>]phenylalanine: IR=0.10 &mgr;mol · kg<SUP>−1</SUP> · min<SUP>−1</SUP>,

<SC>l</SC>-[1-<SUP>13</SUP>C]leucine: IR=0.12 &mgr;mol · kg<SUP>−1</SUP> · min<SUP>−1</SUP>,

[<SUP>15</SUP>N<SUB>2</SUB>]urea: IR=0.2267 &mgr;mol · kg<SUP>−1</SUP> · min<SUP>−1</SUP>,

Isotopes were purchased from Cambridge Isotopes (Andover, MA). They were dissolved in 0.9% saline and were filtered througha 2-µm filter before infusion. The infusion protocol was designedto allow the quantification of the effect of the drink on muscleprotein synthesis and breakdown. The net balance between proteinsynthesis and breakdown (net muscle protein synthesis) was consideredto be the primary end point of the study, and urea productionwas measured isotopically to assess short-term changes in totalamino acid oxidation.

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Fig. 1. Infusion protocol. ICG, indocyanine green; D, drink; *, blood sample; B, biopsy.

At ~7:30 AM, 3-Fr 8-cm polyethylene catheters (Cook) were inserted into the femoral vein and the femoral artery with the subjectunder local anesthesia. Both femoral catheters were used for bloodsampling, and the femoral arterial catheter was also used forindocyanine green dye (ICG) infusion for determination of legblood flow (3). A constant infusion of ICG (0.5 mg/min) wasgiven at intervals during the experiment (Fig. 1). The infusionran for $>=$ 10 min before peripheral and femoral venous blood sampleswere drawn for measurement of blood flow. The peripheral venousblood samples were drawn from an 18-gauge polyethylene catheterinserted into an antecubital vein of the arm opposite that intowhich the amino acids were infused. Patency of catheters was maintainedby salineinfusion.

Subjects rested in bed until the exercise started at $-$ 45 min (8:45 AM). Subjects performed 10 sets of 10 repetitions of legpresses and 8 sets of 8 repetitions of leg extensions at 80% ofthe 1RM. Each set was completed in ~30 s with a 2-min rest betweensets, and the entire bout was completed in ~40 min. This exercisebout was difficult for all subjects to complete. The exerciseended 3 h after the start of the urea infusion and 2 h after thestart of the amino acid infusion. Subjects then returned to bed,and the first samples were taken 30 min after the end ofexercise.

At 1 and 2 h postexercise, the subjects were given an oral supplement of 0.087 g of essential amino acids (EAA)/kg body weight.The nutritional composition was designed to increase intramuscularavailability of EAA in proportion to the composition of muscleprotein (Table 2). Each supplement solution was composed of 425ml of double-distilled water, the appropriate mixture of EAA,and an artificial sweetener. L-[ring-²H₅]phenylalanine and L-[¹³C]leucine were added to the drink in amounts to equal 8% enrichment,to allow maintenance of isotopic equilibrium during ingestionof the AA drinks.

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Table 2. Amino acid composition of drink

To measure the isotopic enrichment of free amino acid tracers in the muscle, muscle biopsies were sampled at 30, 90, 150,and 240 min after exercise (Fig. 1). With subjects under localanesthesia, the biopsies were taken from the lateral portion ofthe vastus lateralis ~10-15 cm above the knee. A 5-mm Bergstrombiopsy needle (Depuy, Warsaw, IN) was used to sample ~30-50 mgof mixed muscle tissue. The sample was quickly rinsed, blotted,immediately frozen in liquid nitrogen, and stored at $-$ 80°C forlateranalysis.

Blood samples were drawn for determination of net muscle protein balance from the femoral artery and venous catheters at 30min after exercise, at 70, 80, 90, 105, 130, 140, 150, and 165min after exercise (corresponding to 10, 20, 30, and 45 min aftereach drink), and at 180, 210, 220, and 240 min after exercise(Fig. 1). The samples were analyzed for phenylalanine and leucineenrichments and concentrations. To allow sampling from the femoralartery, the dye infusion was stopped for <10 s and then quicklyresumed.

Sample analyses. Blood samples for determination of amino acid enrichment and concentrations were immediately precipitated in preweighed tubescontaining 15% sulfosalicylic acid (SSA), and a weighed amountof an appropriate internal standard consisting of amino acidslabeled differently from the infused amino acids was added (3,4, 15). The supernatant was passed over a cation exchangecolumn (Dovex AG 50W-8X, 100-200 mesh H⁺ form; Bio-Rad Laboratories, Richmond, CA) and dried under vacuumwith a Speed Vac (Savant Instruments, Farmingdale, NY). Enrichmentsof intracellular free amino acids were then determined on thetertiary-butyldimethylsilyl (t-BDMS) derivatives using GC-MS (Hewlett-Packard5973, Palo Alto, CA) and selected ion monitoring (21). Enrichmentswere expressed as tracer-to-tracee ratios. Appropriate correctionswere made for overlapping spectra (21).

To determine muscle intracellular enrichment of infused tracers, muscle tissue was weighed and the protein precipitated withperchloroacetic acid. The tissue was then homogenized and centrifuged,and the supernatant was collected. The procedure was then repeated,and the pooled supernatant was processed in the same way as thesupernatant from the bloodsamples.

Urea production was calculated from enrichment and tracer infusion rates, as described previously (20). ICG concentrationin serum for the determination of leg blood flow was measuredspectrophotometrically at $lambda$ = 805 nm (10, 19). Plasma samplesand muscle intracellular fluid were also analyzed for amino acidconcentrations by high-performance liquid chromatography (WatersAlliance HPLC System 2690, Milford, MA). Plasma glucose concentrationwas determined enzymatically by an automated system (YSI 1500,Yellow Spring Instruments, Yellow Springs, OH). Plasma insulinconcentration was determined by a radioimmunoassay method (DiagnosticProducts, Los Angeles,CA).

Calculations. Net muscle phenylalanine balance, which was considered as the primary end point, was calculated as follows: (phenylalaninearterial concentration $-$ venous concentration) × blood flow. Becausephenylalanine is neither produced nor metabolized in muscle, netphenylalanine balance reflects net muscle protein synthesis, providedthere are no significant changes in the free intracellular poolof phenylalanine. Area under the curve (AUC) of net phenylalanineuptake was determined for each individual hour after drink ingestion,with net uptake at t = 30 min postexercise used as the zero pointfor each hour of the recovery period. This approach assumes aconstant net balance after the basal sample if amino acids arenot given. The basis for this assumption is the relatively constantnet balance for 3 h after exercise in the absence of nutrientintake that we have previously observed when using the same exerciseprotocol (16).

Leg amino acid kinetics were calculated according to a three-pool compartment model previously presented (2, 3). Hourlyaverages for blood flow and blood and muscle amino acid concentrationsand enrichments were used in the calculation of leg amino acidkinetics. Kinetic parameters calculated for both amino acid tracersincluded intracellular de novo appearance, irreversible disappearancefrom the intracellular compartment, and the rate of transportfrom blood into muscle. In the case of phenylalanine, irreversibleloss from the intracellular pool can only be to protein synthesis,because it is not oxidized in the muscle. Because leucine canbe oxidized in muscle, the irreversible loss is due to synthesis+ oxidation. Neither leucine nor phenylalanine can be synthesizedin muscle, so de novo appearance of both amino acids is due entirelyto breakdown. We also calculated the rate of release of phenylalanineand leucine from protein breakdown into blood (R_a) and incorporationof phenylalanine from blood into muscle protein (R_d). Calculationof R_a and R_d, as well as the three-pool kinetic factors, requiresan isotopic, but not physiological, steady state. By adding anappropriate amount of tracer to the ingested amino acids, we wereable to maintain a relatively stable isotopic steady state, despitechanging concentrations of plasma amino acids (see below). Thusthe difference between total protein synthesis and R_d is the amountof recycling of phenylalanine that was released from breakdownand directly incorporated into protein without entering the blood.Similarly, the difference between total protein breakdown andR_a is the amount of phenylalanine from breakdown that was directlyreincorporated into protein, rather than being released intoblood.

Statistical methods. Overall significance of differences in response with time was tested by repeated-measures analysis of variance followed byDunnett's test (SigmaStat 2.03, SPSS, Chicago, IL). The responseto the second drink was compared with the response to the firstdrink by Tukey's test. Results were considered significant ifP < 0.05. The results are presented as means ± SE unless otherwisenoted.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Phenylalanine concentration and balance. At 30 min after exercise, the arterial blood phenylalanine concentration was 59 ± 4 nmol/ml. The concentration rose significantlywithin 10 min of ingestion of the EAA drink (Fig. 2). Phenylalanineconcentration declined before the second drink but stayed significantlyabove predrink values until 240 min after exercise. The responseto the second drink was comparable to that of the first.

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Fig. 2. Changes in arterial phenylalanine concentration and net phenylalanine balance during the recovery period after a resistance exercise bout (means ± SE; n = 6). Essential amino acid (EAA) drink was consumed at 60 and 120 min after exercise.

Phenylalanine net balance followed the same time pattern as the blood concentration changes, with rapid changes in responseto arterial blood phenylalanine changes (Fig. 2). However, theearly increase of net uptake was proportionately greater thanthe change in arterial concentration, and the rate of net balancereturned to the basal value 40 min after ingestion of the firstdrink, despite persistent elevation of arterial phenylalanineconcentration. Net balance also increased significantly in responseto the second drink (Fig. 2) and returned to the basal value duringthe 3rd h. The AUC for net uptake of phenylalanine above the basalvalue was similar for the 1st h after the first drink (67 ± 17mg/leg) and the 1st h after the second drink (77 ± 20 mg/leg).However, the AUC decreased significantly by the 3rd h ( $-$ 5 ± 20mg/leg), despite the fact that the arterial concentration wassignificantly elevated until 240 min after the firstdrink.

Muscle intracellular phenylalanine concentration was 57 ± 3 nmol/ml before intake of the drinks. After intake of drinks, theconcentration increased, and the value at 150 min (115 ± 24 nmol/ml)was significantly higher than the baseline value. At 240 min,the concentration (88 ± 14 nmol/ml) was not statistically differentfrom the baselinevalue.

Phenylalanine kinetics. Enrichment of phenylalanine in blood was relatively constant throughout the experiment despite the large changes in concentration(Fig. 3). No statistical changes in enrichment were observed duringthe different calculation periods. This was accomplished by addingtracer to the ingested amino acids.

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Fig. 3. Arterial L-[²H₅]phenylalanine and L-[1-¹³C]leucine enrichments during the recovery period after a resistance exercise bout (means ± SE; n = 6). EAA drink was consumed at 60 and 120 min after exercise.

The rate of appearance of phenylalanine into the blood from the muscle (R_a) did not change during the first 2 h after thedrink but increased significantly during the 3rd h (Fig. 4). Theaverage rate of disappearance (R_d) of phenylalanine from the bloodinto the muscle (i.e., protein synthesis from plasma phenylalanine)increased significantly from the basal value during the first2 h after intake of drink but was not different from the basalvalue during the 3rd h.

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Fig. 4. Phenylalanine kinetics across leg before intake of drink and during the 1st, 2nd, and 3rd h after the first drink (means ± SE; n = 6). R_a, rate of appearance of phenylalanine into the blood; R_d, rate of disappearance of phenylalanine out of the blood. *P < 0.05, value vs. predrink value.

Ingestion of the EAA drink caused inward transport of phenylalanine from the artery to the muscle to increase (Table 3, P= 0.055). At 30 min after exercise, the total rate of intracellularphenylalanine release from protein breakdown was 43 ± 9 nmol ·min¹ · 100 ml leg¹ (Table 3). There was no change in R_a during the first 2 h afterthe first drink, but it increased significantly during the 3rdh to 75 ± 13 nmol · min¹ · 100 ml leg¹. The rate of utilization of phenylalanine for protein synthesiswas 30 ± 9 nmol · min¹ · 100 ml leg¹ at 30 min after exercise, and this value increased significantlyduring the 1st and 2nd h after drink to 121 ± 16 and 139 ± 21nmol · min¹ · 100 ml leg¹, respectively (Table 3). During the 3rd h after drink, the valuereturned to the basal level, despite the fact that the total intracellularappearance of phenylalanine (inward transport + breakdown) waselevated approximately threefold above the basal value.

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Table 3. Calculated kinetics for phenylalanine before drink and during 1st, 2nd, and 3rd h after intake of first drink

Leucine concentration and kinetics. The pattern of response of blood concentration and kinetics of leucine was similar to that of phenylalanine. As was the casefor phenylalanine, leucine tracer was added to the ingested aminoacids. Therefore, enrichment of leucine in blood was essentiallyconstant throughout the experiment despite changes in concentrations(Fig. 3).

Leucine concentration increased significantly within 10 min of ingestion of the first EAA drink, from a value of 118 ± 4 nmol/mlat 30 min after exercise to a peak of 407 ± 24 nmol/ml at 20 minafter ingestion of the drink. The concentration declined beforethe second drink, but not to the basal level. Leucine concentrationincreased again after ingestion of the second drink, and althoughthe value again began falling 30 min after ingestion of the seconddrink, it was still elevated above basal at 210 min after ingestionof the first drink. Muscle intracellular leucine concentrationincreased significantly from the basal value of 144 ± 7 to 307± 52 nmol/ml at 150 min. At 240 min, the concentration was notdifferent from basal value at 30 min afterexercise.

Leucine net uptake increased as a result of drink. No significant difference was found between the AUC value for net uptakeduring the 1st h after the first drink (159 ± 36 mg/leg) and thatduring the 1st h after the second drink (165 ± 32 mg/leg), butthe area was significantly smaller by the 3rd h (20 ± 22 mg/leg).

The average R_a of leucine into the blood over each of the hours after intake of drink did not change, whereas the averagerate of muscle protein synthesis and oxidation from plasma leucineincreased significantly from basal values during the first 2 hafter intake of drink but was not different from basal valuesduring the 3rd h (Fig. 5). As a result, leucine net balance increasedfrom a slightly negative basal value to ~250-260 nmol · min¹ · 100 ml leg¹ during the 2 h after the first drink (not significant betweenhours; Fig. 5). During the 3rd h, net balance decreased again.

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Fig. 5. Leucine kinetics across leg before intake of drink and during the 1st, 2nd, and 3rd h after the first drink (means ± SE; n = 6). *P < 0.05, value vs. predrink value.

Table 4 shows leucine kinetics. The delivery of leucine to the leg muscle increased as a result of intake of the drink. Also,the movement of leucine into the muscle increased and stayed elevatedabove the predrink value throughout the following 3 h. The rateof intracellular R_a of leucine increased slightly after the drink,and during the 1st h the value was significantly different fromthe predrink value. The rate of utilization of intracellular leucine,which includes utilization for both protein synthesis and oxidation,increased significantly during the 1st and 2nd h after drink,whereas it returned to basal value during the 3rd h.

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Table 4. Calculated kinetics for leucine before drink and during 1st, 2nd, and 3rd h after intake of first drink

The rate of incorporation of leucine into protein can be calculated from the rate of protein synthesis as calculated withthe phenylalanine tracer and the ratio between leucine and phenylalaninein mixed muscle protein. The ratio between leucine and phenylalaninein mixed muscle protein was calculated from the ratio betweenthe rates of leucine and phenylalanine release from muscle proteinbreakdown at the predrink time point (30 min). The mean ratiofor the group was 2.6 ± 0.2. When calculated accordingly, therate of leucine incorporated into protein increased significantlyduring the 1st h after each drink, but during the 3rd h it decreasedto a value not different from the predrink rate (Table 4). Therate of leucine oxidation was calculated from the difference betweenthe rate of utilization of intracellular leucine and the rateat which leucine was used for protein synthesis. This calculationshowed that leucine oxidation increased significantly during the1st h after the first drink but that, during the 2nd and 3rd h,the values were not different from the predrinkvalue.

Plasma and muscle intracellular amino acid concentrations. Intake of drinks increased the arterial plasma concentrations of total EAAs significantly. At 150 min after exercise (90 minafter the first drink and 30 min after the second drink), theconcentrations for most of the EAAs given in the drinks were increasedby ~75-150%, except for isoleucine and leucine, which showed greaterresponses (317 ± 69 and 212 ± 29% increase, respectively; Fig.6A). Arterial plasma concentrations of the amino acids not givenin the drink generally showed smaller changes (Fig. 6B). Tyrosineincreased significantly, whereas glycine, alanine, and tryptophandecreased during the study.

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Fig. 6. Percentage changes in arterial plasma concentrations of EAAs (A), arterial plasma concentrations of nonessential amino acids (NEAAs) and tryptophan (B), intracellular concentrations of EAAs (C), and intracellular concentrations of NEAAs and tryptophan (D) from 30 min to 150 min after exercise (means ± SE; n = 6). EAA drink was consumed at 60 and 120 min after exercise.

Whereas there was no change in intracellular concentration of total EAAs or in total NEAAs during the recovery period, someindividual changes were observed. Threonine was not differentbetween first and second biopsies but increased thereafter toa concentration at 150 min significantly higher than predrinkconcentration (741 ± 99 vs. 561 ± 59 nmol/ml H₂O). Similarly,valine, isoleucine, and leucine concentrations all increased afterthe first drink. The concentrations increased further at 150 minbut decreased again at the end of the study at 240 min. For valine,the values at 150 and 240 min were significantly higher than thepredrink value (228 ± 17 and 212 ± 16 vs. 168 ± 9 nmol/ml, respectively).For isoleucine, 90- and 150-min values were higher than the predrinkvalue (86 ± 5 and 98 ± 6 vs. 61 ± 2 nmol/ml, respectively). Forleucine, 90-, 150-, and 240-min values were higher than the predrinkvalue (249 ± 5, 297 ± 22, and 240 ± 15 vs. 186 ± 7 nmol/ml, respectively).For the amino acids not given in the drink, a significant fallduring the day was found for asparagine, serine, arginine, andalanine. The relative changes in intracellular concentrationsof EAAs were small compared with the changes in arterial plasma(Fig. 6).

Urea production. Plasma urea enrichment was stable at ~4% throughout the study. Thus no change in urea production was seen over time. The valuewas stable at 330 µmol · kg¹ · h¹.

Plasma glucose and insulin concentrations. Arterial glucose concentration decreased slightly during the experiment from a value of 91 ± 3 mg/dl at 30 min after exerciseto 87 ± 3 mg/dl at the end of the study (P < 0.05). No changewas found in net uptake of glucose during the study. Similarly,insulin concentrations did not change overtime.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

The principal finding of this study was that ingestion of a relatively small amount (6 g) of EAA effectively stimulated netmuscle protein balance after resistance exercise. The responseof net muscle protein balance could be explained largely by achange in synthesis, as the rate of breakdown was not significantlyaffected. The response of net balance was about twice the previouspublished response to 6 g of mixed amino acids (14), leadingto the conclusions that there is a dose response to the amountof EAAs given and that ingestion of NEAAs is not necessary tostimulate net protein synthesis. The latter conclusion is supportedby changes in NEAA concentrations after ingestion of the EAA drink.Although plasma concentrations of some individual NEAAs fell afteringestion of EAAs, intracellular concentrations of NEAAs weregenerally maintained, indicating that availability of NEAAs didnot limit the response of muscle protein synthesis. Finally, theresponse of net muscle protein synthesis to the drink ingested2 h after exercise was comparable to that of the drink ingested1 h afterexercise.

Independent effect of EAA on net protein balance. In previous studies, both intravenous infusion (5) and oral intake of amino acids (17) after resistance exercise havebeen shown to stimulate muscle protein synthesis. However, optimalproportions and amounts of individual amino acids to stimulatemuscle protein synthesis are not known. Intake of only a smallamount (6 g) of a mixture of EAA given along with 35 g of carbohydrateafter resistance exercise transiently increased muscle proteinsynthesis 3.5-fold (14), but the independent effects of aminoacids and carbohydrate were not assessed. The results of the presentstudy show that ingestion of 6 g of EAA alone without additionof carbohydrate effectively stimulated muscle protein synthesisafter resistance exercise (Figs. 4 and 5, Tables 3 and 4).

In a recent study, Miller et al. (14) compared the independent and combined effects of a balanced mixture of amino acids(i.e., EAAs + NEAAs) and carbohydrate on muscle protein synthesisafter resistance exercise. Addition of 35 g of carbohydrate to6 g of mixed AA did not cause a greater stimulation of net muscleprotein synthesis than the AAs alone. The effect of adding carbohydrateto 6 g of EAA can be seen in Fig. 7, which compares the AUC fornet phenylalanine uptake for the 1st h after intake of drink (i.e.,60-120 min) in the present study with the previously publishedresponse to 6 g of EAAs plus 35 g of carbohydrate (16). Theadditional carbohydrate provided no advantage to EAAs alone. Fromthese results, it is clear that the stimulation of protein synthesisby EAAs is not a caloric effect, because ingestion of an additional3 g of EAA (difference in EAA content between mixed AA and EAAgroups) caused a much larger effect than addition of 35 g of carbohydrateto the amino acid mixture (Fig. 7), and 35 g of carbohydrate alonehad a minimal effect (14). Although direct comparison with historicaldata may be problematic, the cited studies (14, 16) were performedin the same laboratory, approximately contemporaneously, and byuse of the same general experimental protocol and techniques.

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Fig. 7. Area under curve for net uptake of phenylalanine over 1 h after ingestion of 6 g of different amino acid drinks. MAA, mixed amino acids (n = 7; values from Ref. 14); MAA + CHO, MAA + 35 g carbohydrate (n = 7; values from Ref. 14); EAA, present study; EAA + CHO, EAA + 35 g carbohydrate (n = 6; values from Ref. 16).

The results of the current study indicate that ~3.5 ± 1.1 g of muscle protein were synthesized during the 3 h after the firstdrink in one leg, or 7.0 ± 2.0 g in both legs, on the basis ofirreversible loss of phenylalanine and the composition of muscleprotein. This represents ~27% of ingested EAAs, because each gramof muscle protein synthesized includes both EAAs and NEAAs. Whenaccount of the water content of muscle (~73%) is taken, this wouldrepresent a net gain of ~26 g of muscle tissue synthesized inresponse to the drinks. This magnitude of gain in muscle masswould therefore require many weeks of comparable response to becomedetectable by available means to quantify changes in muscle mass,during which time all variables such as activity and other nutritionalintake would have to be absolutely controlled. Thus, althoughthe stimulation in net muscle synthesis resulting from the totalof 12 g of EAA reported in this study would eventually be expectedto enhance the rate of muscle gain during a resistance trainingprogram, an outcome study based on measured differences in musclemass would have to be carefully designed and executed to demonstratean effect of an EAAsupplement.

EAA vs. NEAA. Because ingestion of 6 g of EAAs alone stimulates muscle protein synthesis after resistance exercise, NEAAs are apparentlynot required to stimulate protein synthesis. In a previous study,Tipton et al. (17) found no difference in net muscle proteinbalance response to the ingestion of 40 g of mixed AAs (roughlyin proportion to their relative contributions to muscle protein)or 40 g of EAAs. These results could also be interpreted to indicatethat NEAAs are not needed for stimulation of muscle protein synthesis.However, if the NEAAs were not necessary for stimulation of synthesis,it was unclear why ingestion of the EAAs alone did not stimulatemuscle protein synthesis to a greater extent than did the balancedmixture. The response in the present study was about twice thatwhen 6 g of mixed AAs were given after a similar exercise bout(Fig. 7) (14). Thus, it seems likely that there is a dose responseof muscle protein synthesis to the intake of EAAs and that theamount of EAAs in the balanced mixture (21 g) in the study byTipton et al. was equal to or exceeded the maximal effective dose.However, it should be noted that, in this study by Tipton et al.,the amino acids were ingested as small boluses over 3 h, and thedifferent pattern of intake may also have contributed to the lackof difference between the two mixtures of aminoacids.

Pattern of ingestion. No differences were found in the protein synthesis response between the first and the second dose (Tables 3 and 4, Figs.4 and 5), and the AUC for net phenylalanine uptake was similarafter the first and the second drinks. Net balance increased rapidlyafter intake of the drink, and the relative increase in net balancewas greater than the change in arterial phenylalanine concentrations(Fig. 2). However, when arterial AA concentrations started todrop, net balance rapidly decreased to the basal level, even thoughthe arterial AA concentrations were still elevated (Fig. 2). Infact, at 60 min after ingestion of the first drink, the phenylalanineconcentration was still higher than the maximal concentrationpreviously observed to coincide with stimulation of protein synthesiswhen 6 g of mixed amino acids were given (14). Thus muscle proteinsynthesis is apparently stimulated when there is an increase inarterial, and presumably interstitial, AA concentrations, ratherthan by the absolute AA concentration. This observation is consistentwith our previous findings (6) that, when blood amino acidconcentrations were elevated to a steady-state level about twicethe basal values for 6 h, muscle protein synthesis was stimulatedover the first 2 h but thereafter returned to the resting leveldespite the persistent elevation in blood amino acidconcentrations.

The similarity of response to both boluses suggests that there is little effect of the exact time of ingestion after exercise.This is consistent with our previous work, in which we observedsimilar responses to single doses of amino acids and glucose giveneither immediately, 1 h, or 3 h after resistance exercise (16,18). In contrast, Esmarck et al. (9) recently reported thata protein-carbohydrate-fat supplement was effective in stimulatingmuscle protein gain over a period of resistance training in elderlymen only when ingested immediately after, as opposed to 2 h after,exercise. Differences between that study and our studies includeage of subjects, ingestion of protein rather than free amino acids,and end point. Whereas we measured the acute response of muscleprotein, they measured net muscle gain, which includes the responseto all food intake over a period of time. Thus it is possiblethat ingestion of a protein-carbohydrate-fat supplement 2 h afterexercise might have interfered with either the amount eaten atthe next meal or the response to the next ingested meal. In anotherstudy that addressed the timing of intake on response, Levenhagenet al. (11) found a greater stimulation of net muscle proteinsynthesis when a protein-carbohydrate-fat supplement was givenimmediately after aerobic exercise than when it was given 2 hlater. There likely is a difference between timing after aerobicand timing after resistance exercise, as performed in the currentstudy. The stimulation of muscle protein synthesis is modest afteraerobic exercise (7). Rather, the interaction effect of exerciseand supplement ingestion may be due to increased muscle bloodflow, and thus substrate delivery, immediately after exercise.In contrast, fractional synthetic rate remains elevated for $>=$ 48h after resistance exercise (15), so an effect on timing ofsupplement ingestion after resistance exercise is lesslikely.

Composition of drink. The composition of the mixture of EAA we have tested in this and previous studies (16, 18) was originally based on thecomposition of muscle protein, with the notion of increasing theavailability of each EAA in proportion to its requirement forsynthesis of muscle protein. The results of the current studyshow that isoleucine and leucine increased more than the othersin the blood (Fig. 6), meaning that the goal of causing proportionalincreases in all EAA was not fully achieved. Different changesin concentrations of blood amino acids after ingestion of thedrink may be caused by different clearance rates of individualamino acids, thereby resulting in rates of uptake that do notdirectly correspond to the composition of the ingested mixture.Furthermore, it is possible that the effect is largely, or evenentirely, mediated by leucine alone (1). Therefore, it is possiblethat adjustments in the composition of the drink could furtherimprove the response of net musclebalance.

Whereas NEAAs can be synthesized within the body at a rate generally sufficient to meet requirements, certain amino acidsmay be limited in the rapidity with which changes in productioncan occur. Thus glycine is known to be slowly transaminated (12),and this likely explains the fall in plasma glycine concentrationas its utilization is increased because of the stimulated rateof protein synthesis after EAA, not only in muscle but also throughoutthe body. The fact that the EAA mixture alone was twice as effectiveas the same amount of the balanced mixture of AAs (14) in stimulatingmuscle protein synthesis indicates that glycine was probably notrate limiting, despite the decrease in plasma concentration, becausethe muscle concentration of free glycine was maintained. Similarly,the fall in alanine concentration in plasma probably reflectedincreased uptake elsewhere than in muscle for incorporation intoprotein, as muscle is normally highly efficient in producing alanine,and its rate of production is increased during exercise (22).

Methodological considerations. Drinks normally are ingested as boluses. However, quantifying the response to a bolus ingestion of unlabeled amino acids introducespotential methodological problems because of rapid dilution ofthe tracer. The resulting isotopic nonsteady state violates afundamental assumption of the three-pool compartment model (2,3). We therefore added tracer to the ingested amino acids sothat a relatively constant enrichment in the blood was maintained,even during absorption of the bolus. Thus the calculated valuesfor synthesis and breakdown should theoretically be accurate.Nonetheless, we used net protein balance, which is not dependenton the measurement of isotopic enrichment, as our primary endpoint, and the other variables were considered as secondary endpoints. This is not only because of methodological issues butalso because, in terms of gain or loss of muscle protein, thenet balance (i.e., synthesis minus breakdown) is the most relevantparameter. Furthermore, it can be determined in non-steady-stateconditions. In relation to net balance, the pertinent kineticparameters are the rate of synthesis from plasma amino acids (phenylalanineand leucine, respectively) and the rate of appearance of aminoacids into plasma from protein breakdown. This is because, althoughthe synthesis of protein from amino acids derived from proteinbreakdown (i.e., intracellular recycling of amino acids) is importantfrom the standpoint of understanding the regulation of the processof synthesis, it does not represent any net gain or loss of protein.The protein synthesis from plasma amino acids and appearance inplasma from protein breakdown are calculated by the two-pool model.We also have calculated rates of synthesis and breakdown by useof the three-pool model that we have described previously, whichincludes synthesis from all sources and the total rate of breakdown.However, even though we avoided changes in enrichment by addingtracer to the exogenous amino acids, the calculated values ofsynthesis and breakdown were variable. This is because calculationof the parameters from the three-pool model requires a gradientin enrichment from blood to the intracellular phenylalanine pools,and the rapid influx of amino acids from plasma caused the gradientin enrichment between compartments to narrow to the point whereaccurate measurement isdifficult.

The primary potential problem in the interpretation of net balance results in the nonsteady state is the possibility thatamino acids entered the intracellular pool from the plasma thateventually reentered the blood at some time after the final bloodsample was drawn. To the extent that this occurred in this experiment,we would have overestimated net uptake. However, the free intracellularphenylalanine concentration was not significantly elevated atthe time we drew our last sample, so the magnitude of error dueto this potential problem was likely notlarge.

Because previous studies have shown that net muscle protein balance remains slightly negative for several hours after resistanceexercise in the absence of nutrient intake (4, 8), a controlgroup was not included in this study. Furthermore, in a previousstudy from our laboratory, Rasmussen et al. (16) gave a placebodrink at 60 min after a similar resistance exercise bout. Theyfound no significant change in net balance over the first 3 hafter exercise. Hence, the significant positive net balance observedafter drinks in the present study can be ascribed to the intakeof the amino acids, rather than to changes that would have occurredanyway.

	ACKNOWLEDGEMENTS

We thank the nurses and the staff at the General Clinical Research Center (GCRC) at the University of Texas Medical Branch(UTMB) in Galveston, TX. We thank Julie M. Vargas for skillfultechnical assistance. We also thank the volunteers who participatedin thestudy.

	FOOTNOTES

This work was supported by Shriners Hospital for Children Grant 8490 and the National Institutes of Health (NIH) Grants DK-38010and AG-98-006. Studies were conducted at the GCRC at the UTMBin Galveston, funded by Grant M01 RR-00073 from the National Centerfor Research Resources,NIH.

Address for reprint requests and other correspondence: R. R. Wolfe, 815 Market St., Galveston, TX 77550 (E-mail: rwolfe{at}utmb.edu).

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/ajpendo.00466.2001

Received 15 October 2001; accepted in final form 26 May 2002.

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