Hostname: page-component-cd9895bd7-lnqnp Total loading time: 0 Render date: 2024-12-20T10:07:31.101Z Has data issue: false hasContentIssue false

Tracers to investigate protein and amino acid metabolism in human subjects

Published online by Cambridge University Press:  12 June 2007

Anton J. M. Wagenmakers*
Affiliation:
Department of Human Biology, NUTRIM, Maastricht University, PO Box 616, 6200 MD Maastricht, The Netherlands
*
Corresponding Author: Dr Anton Wagenmakers, fax +31 43 3670976, email A.Wagenmakers@HB.Unimaas.NL
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Three tracer methods have been used to measure protein synthesis, protein breakdown and protein oxidation at whole-body level. The method using L-[1-13C]leucine is considered the method of reference. These methods have contributed greatly to the existing knowledge on whole-body protein turnover and its regulation by feeding, fasting, hormones and disease. How exercise and ingestion of mixed protein-containing meals affect whole-body protein metabolism is still open to debate, as there are discrepancies in results obtained with different tracers. The contribution of whole-body methods to the future gain of knowledge is expected to be limited due to the fact that most physiological disturbances have been investigated extensively, and due to the lack of information on the relative contribution of various tissues and proteins to whole-body changes. Tracer amino acid-incorporation methods are most suited to investigate these latter aspects of protein metabolism. These methods have shown that some tissues (liver and gut) have much higher turnover rates and deposit much more protein than others (muscle). Massive differences also exist between the fractional synthesis rates of individual proteins. The incorporation methods have been properly validated, although minor disagreements remain on the identity of the true precursor pool (the enrichment of which should be used in the calculations). Arterio-venous organ balance studies have shown that little protein is deposited in skeletal muscle following a protein-containing meal, while much more protein is deposited in liver and gut. The amount deposited in the feeding period in each of these tissues is released again during overnight fasting. The addition of tracers to organ balance studies allows the simultaneous estimation of protein synthesis and protein breakdown, and provides information on whether changes in net protein balance are caused primarily by a change in protein synthesis or in protein breakdown. In the case of a small arterio-venous difference in a tissue with a high blood flow, estimates of protein synthesis and breakdown become very uncertain, limiting the value of using the tracer. An additional measurement of the intracellular free amino acid pool enrichment allows a correction for amino acid recycling and quantification of the inward and outward transmembrane transport. However, in order to obtain reliable estimates of the intramuscular amino acid enrichment and, therefore, of muscle protein synthesis and breakdown in this so-called three-pool model, the muscle should be freeze-dried and the resulting fibres should be freed from connective tissue and small blood clots under a dissection microscope. Even when optimal precautions are taken, the calculations in these tracer balance methods use multiple variables and, therefore, are bound to lead to more variability in estimates of protein synthesis than the tracer amino acid incorporation methods. In the future, most studies should focus on the measurement of protein synthesis and breakdown in specific proteins in order to understand the mechanisms behind tissue adaptation in response to various stimuli (feeding, fasting, exercise, trauma, sepsis, disuse and disease). The tracer laboratories, therefore, should improve the methodology to allow the measurement of low tracer amino acid enrichments in small amounts of protein.

Type
Meeting Report
Copyright
The Nutrition Society

References

Ahlborg, G, Felig, P, Hagenfeldt, L, Hendler, R & Wahren, J (1974) Substrate turnover during prolonged exercise in man – Splanchnic and leg metabolism of glucose, free fatty acids, and amino acids. Journal of Clinical Investigation 53, 10801090.Google Scholar
Attaix, D & Taillandier, D (1998) The critical role of the ubiquitin-proteasome pathway in muscle wasting in comparison to lysosomal and Ca2+-dependent systems. Advances in Molecular and Cell Biology 27, 235266.Google Scholar
Balagopal, P, Ford, GC, Ebenstein, DB, Nadeau, DA & Nair, KS (1996) Mass spectrometric methods for determination of [13C]leucine enrichment in human muscle protein. Analytical Biochemistry 239, 7785.CrossRefGoogle ScholarPubMed
Balagopal, P, Rooyackers, OE, Adey, DB, Ades, PA & Nair, KS (1997) Effects of aging on in vivo synthesis of skeletal muscle myosin heavy-chain and sarcoplasmic protein in humans. American Journal of Physiology 273, E790E800.Google Scholar
Barle, H, Nyberg, B, Essén, P, Andersson, K, McNurlan, MA, Wernerman, J & Garlick, PJ (1997) The synthesis rates of total liver protein and plasma albumin determined simultaneously in vivo in humans. Hepatology 25, 154158.Google ScholarPubMed
Barrett, EJ, Revkin, JH, Young, LH, Zaret, BL, Jacob, R & Gelfand, RA (1987) An isotopic method for measurement of muscle protein synthesis and breakdown in vivo. Biochemical Journal 245, 223228.CrossRefGoogle ScholarPubMed
Biolo, G, Fleming, RYD, Maggi, SP & Wolfe, RR (1995a) Transmembrane transport and intracellular kinetics of amino acids in human skeletal muscle. American Journal of Physiology 268, E75E84.Google ScholarPubMed
Biolo, G, Maggi, SP, Williams, BD, Tipton, KD & Wolfe, RR (1995b) Increased rates of muscle protein turnover and amino acid transport after resistance exercise in humans. American Journal of Physiology 268, E514E520.Google Scholar
Calder, AG, Anderson, SE, Grant, I, McNurlan, MA & Garlick, PJ (1992) The determination of low d5phenylalanine enrichment (0.002–0.09 atom percent excess), after conversion to phenylethylamine, in relation to protein turnover studies by gas chromatography/electron ionization mass spectrometry. Rapid Communications in Mass Spectrometry 6, 421424.CrossRefGoogle ScholarPubMed
Cheng, KN, Dworzak, F, Ford, GC, Rennie, MJ & Halliday, D (1985) Direct determination of leucine metabolism and protein breakdown in humans using L-[1-13C,15N]leucine and the forearm model. European Journal of Clinical Investigation 15, 349354.CrossRefGoogle ScholarPubMed
Cheng, KN, Pacy, PJ, Dworzak, F, Ford, GC & Halliday, D (1987) Influence of fasting on leucine and muscle protein metabolism across the human forearm determined using L-[1-13C, 15N]leucine as the tracer. Clinical Science 73, 241246.CrossRefGoogle ScholarPubMed
Clowes, GHA, Randall, HT & Cha, C-J (1980) Amino acid and energy metabolism in septic and traumatized patients. Journal of Parenteral and Enteral Nutrition 4, 195205.CrossRefGoogle ScholarPubMed
Darmaun, D, Matthews, D & Bier, D (1986) Glutamine and glutamate kinetics in humans. American Journal of Physiology 251, E117E126.Google Scholar
Fagan, JM, Waxman, L & Goldberg, AL (1987) Skeletal muscle and liver contain a soluble ATP+ubiquitin-dependent proteolytic system. Biochemical Journal 243, 335343.CrossRefGoogle ScholarPubMed
Fearon, KCH, McMillan, DC, Preston, T, Winstanley, FP, Cruickshank, AM & Shenkin, A (1991) Elevated circulating interleukin-6 is associated with an acute-phase response but reduced fixed hepatic protein synthesis in patients with cancer. Annals of Surgery 213, 2631.CrossRefGoogle ScholarPubMed
Fern, EB, Garlick, PJ, McNurlan, MA & Waterlow, JC (1981) The excretion of isotope in urea and ammonia for estimating protein turnover in man with [15N]glycine. Clinical Science 61, 217228.CrossRefGoogle ScholarPubMed
Fern, EB, Garlick, PJ & Waterlow, JC (1985) Apparent compartmentation of body nitrogen in one human subject: its consequences in measuring the rate of whole-body protein synthesis with 15N. Clinical Science 68, 271282.CrossRefGoogle ScholarPubMed
Fryburg, DA, Jahn, LA, Hill, SA, Oliveras, DM & Barrett, EJ (1995) Insulin and insulin-like growth factor-1 enhance human skeletal muscle protein anabolism during hyperaminoacidemia by different mechanisms. Journal of Clinical Investigation 96, 17221729.CrossRefGoogle ScholarPubMed
Garlick, PJ & Fern, EB (1985) Whole body protein turnover: theoretical considerations. In Substrate and Energy Metabolism, pp. 715 [Garrow, JS and Halliday, D, editors]. London: John Libbey.Google Scholar
Garlick, PJ, McNurlan, MA, Essén, P & Wernerman, J (1994) Measurement of tissue protein synthesis rates in vivo: a critical analysis of contrasting methods. American Journal of Physiology 266, E287E297.Google ScholarPubMed
Garlick, PJ, Wernerman, J, McNurlan, MA, Essén, P, Lobley, GE, Milne, E, Calder, AG & Vinnars, E (1989) Measurement of the rate of protein synthesis in muscle of postabsorptive young men by injection of a ‘flooding dose’ of [1-13C]leucine. Clinical Science 77, 329336.Google Scholar
Gelfand, RA & Barrett, EJ (1987) Effect of physiologic hyperinsulinemia on skeletal muscle protein synthesis and breakdown in man. Journal of Clinical Investigation 80, 16.Google Scholar
Gersovitz, M, Munro, HN, Udall, J & Young, VR (1980) Albumin synthesis in young and elderly subjects using a new stable isotope methodology: response to level of protein intake. Metabolism 29, 10751086.CrossRefGoogle Scholar
Halliday, D, Pacy, PJ, Cheng, KN, Dworzak, F, Gibson, JNA & Rennie, MJ (1988) Rate of protein synthesis in skeletal muscle in normal man and in patients with muscular dystrophy: a reassessment. Clinical Science 74, 237240.CrossRefGoogle Scholar
Halliday, D, Venkatesan, S & Pacy, P (1993) Apolipoprotein metabolism: a stable isotope approach. American Journal of Clinical Nutrition 57, 726S731S.CrossRefGoogle ScholarPubMed
Hasselgren, P-O (1995) Counter-regulatory hormones and the role of cytokines in the control of amino acid metabolism. In Amino Acid Metabolism and Therapy in Health and Nutritional Disease, pp. 139156 [Cynober, LA, editor]. New York: CRC Press Inc.Google Scholar
Heys, SD, Park, KGM, McNurlan, MA, Keenan, RA, Miller, JDB, Eremin, O & Garlick, PJ (1992) Protein synthesis rates in colon and liver: stimulation by gastrointestinal pathologies. Gut 33, 976981.Google Scholar
Jahoor, F, Burrin, DG, Reeds, PJ & Frazer, M (1994) Measurement of plasma protein synthesis rate in infant pig: an investigation of alternative tracer approaches. American Journal of Physiology 267, R221R227.Google Scholar
Jahoor, F, Sivakumar, B, Del Rosario, M, Burrin, D, Wykes, L & Frazer, M (1996) Chronic protein deficiency differentially affects the kinetics of plasma proteins in young pigs. Journal of Nutrition 126, 14891495.Google Scholar
Lichtenstein, AH, Cohn, JS, Hachey, DL, Millar, JS, Ordovas, JM & Schaefer, EJ (1990) Comparison of deuterated leucine, valine and lysine in the measurement of human apolipoprotein A-I and B-100 kinetics. Journal of Lipid Research 31, 16931701.Google Scholar
Macdonald, I (1999) Arterio–venous differences to study macronutrient metabolism: introduction and overview. Proceedings of the Nutrition Society 58, 000000.Google Scholar
McNurlan, MA, Essén, P, Thorell, A, Calder, AG, Anderson, SE, Ljungqvist, O, Sandgren, A, Grant, I, Tjäder, I, Ballmer, PE, Wernerman, J & Garlick, PJ (1994) Response of protein synthesis in human skeletal muscle to insulin: an investigation with l-[2H5]phenylalanine. American Journal of Physiology 267, E102E108.Google Scholar
McNurlan, MA, Sandgren, A, Hunter, K, Essén, P, Garlick, PJ & Wernerman, J (1996) Protein synthesis rates of skeletal muscle, lymphocytes, and albumin with stress hormone infusion in healthy man. Metabolism 45, 13881394.Google Scholar
Marchini, JS, Castillo, L, Chapman, TE, Vogt, JA, Ajami, A & Young;, VR (1993) Phenylalanine conversion to tyrosine: comparative determination with l-[ring-2H5]phenylalanine and L-[1-13C]phenylalanine as tracers in man. Metabolism 42, 13161322.Google Scholar
Marliss, EB, Aoki, TT, Pozefsky, T, Most, AS & Cahill, GF (1971) Muscle and splanchnic glutamine and glutamate metabolism in postabsorptive and starved man. Journal of Clinical Investigation 50, 814817.CrossRefGoogle Scholar
Matthews, DE, Marano, M & Campbell, RG (1993) Splanchnic bed utilization of glutamine and glutamic acid in humans. American Journal of Physiology 264, E848E854.Google Scholar
Matthews, DE, Motil, KJ, Rohrbaugh, DK, Burke, JF, Young, VR & Bier, DM (1980) Meausurement of leucine metabolism in man from a primed, continuous infusion of L-[1-13C]leucine. American Journal of Physiology 238, E473E479.Google Scholar
Matthews, DE, Schwarz, HP, Yang, RD, Motil, KJ, Young, VR & Bier;, DM (1982) Relationship of plasma leucine and α-ketoisocaproate during a L-[1-13C]leucine infusion in man: a method for measuring human intracellular tracer enrichment. Metabolism 31, 11051112.Google Scholar
Nair, KS, Halliday, D & Griggs, RC (1988) Leucine incorporation into mixed skeletal muscle protein in humans. American Journal of Physiology 254, E208E213.Google Scholar
Olufemi, OS, Humes, P, Whittaker, PG, Read, MA, Lind, T & Halliday, D (1990) Albumin synthetic rate: a comparison of arginine and alpha-ketoisocaproate precursor methods using stable isotope techniques. European Journal of Clinical Nutrition 44, 351361.Google Scholar
Pacy, PJ, Price, GM, Halliday, D, Quevedo, MR & Millward, DJ (1994) Nitrogen homeostasis in man: the diurnal responses of protein synthesis and breakdown and amino acid oxidation to diets with increasing protein intakes. Clinical Science 86, 103118.Google Scholar
Pannemans, DLE, Wagenmakers, AJM, Westerterp, KR, Schaafsma, G & Halliday, D (1997) The effect of an increase of protein intake on whole-body protein turnover in elderly women is tracer dependent. Journal of Nutrition 127, 17881794.Google Scholar
Patterson, BW, Zhang, XJ, Chen, Y, Klein, S, Wolfe, RR (1997) Measurement of very low isotope enrichments by gas chromatography/mass spectrometry: application to measurement of muscle protein synthesis. Metabolism 46, 943948.CrossRefGoogle ScholarPubMed
Read, WW, Read, MA, Rennie, MJ, Griggs, RC & Halliday, D (1984) Preparation of CO2 from blood and protein-bound amino acid carboxyl groups for quantification and 13C-isotope measurements. Biomedical Mass Spectrometry 11, 4044.Google Scholar
Reeds, PJ, Hachey, DL, Patterson, BW, Motil, KJ & Klein, PD (1992) VLDL apolipoprotein B-100, a potential indicator of the isotopic labeling of the hepatic protein synthetic precursor pool in humans: Studies with multiple stable isotopically labeled amino acids. Journal of Nutrition 122, 457466.Google Scholar
Rennie, MJ (1985) Muscle protein turnover and the wasting to injury and disease. British Medical Bulletin 41, 257264.Google Scholar
Rennie, MJ (1996) Influence of exercise on protein and amino acid metabolism. In Handbook of Physiology. Section 12, Exercise: Regulation and Integration of Multiple Systems, pp. 9951035 [Rowell, LB and Shepherd, JT, editors]. Oxford: Oxford University Press.Google Scholar
Rennie, MJ, Edwards, RHT, Halliday, D, Matthews, DE, Wolman, SL & Millward, DJ (1982) Muscle protein synthesis measured by stable isotope techniques in man: the effects of feeding and fasting. Clinical Science 63, 519523.CrossRefGoogle ScholarPubMed
Rennie, MJ, Smith, K & Watt, PW (1994) Measurement of human tissue protein synthesis: an optimal approach. American Journal of Physiology 266, E298E307.Google Scholar
Rooyackers, OE, Adey, DB, Ades, PA & Nair, KS (1996a) Effect of age on in vivo rates of mitochondrial protein synthesis in human skeletal muscle. Proceedings of the National Academy of Sciences USA 93, 1536415369.Google Scholar
Rooyackers, OE, Kersten, AH & Wagenmakers, AJM (1996b) Mitochondrial protein content and in vivo synthesis rates in skeletal muscle from critically ill rats. Clinical Science 91, 475481.Google Scholar
Rooyakers, OE & Nair, KS (1997) Hormonal regulation of human muscle protein metabolism. Annual Review of Nutrition 17, 457485.Google Scholar
Sivakumar, B, Jahoor, F, Burrin, DG, Reeds, PJ & Frazer, M (1994) Fractional synthetic rates of retinol binding protein and transthyretin measured by stable isotope techniques in neonatal pigs. Journal of Biological Chemistry 269, 2619626200.CrossRefGoogle Scholar
Smith, K, Barua, JM, Watt, PW, Scrimgeour, CM & Rennie, MJ (1992) Flooding with L-[1-13C]leucine stimulates human muscle protein incorporation of continuously infused L-[1-13C]valine. American Journal of Physiology 262, E372E376.Google Scholar
Smith, K, Downie, S, Barua, JM, Watt, PW, Scrimgeour, CM & Rennie, MJ (1994) Effect of a flooding dose of leucine in stimulating incorporation of constantly infused valine into albumin. American Journal of Physiology 266, E640E644.Google Scholar
Stein, TP, Mullen, JL, Oram-Smith, JC, Rosato, EF, Wallace, HW & Hargrove, WC III (1978) Relative rates of tumor, normal gut, liver and fibrinogen protein synthesis in man. American Journal of Physiology 234, E648E652.Google Scholar
Thompson, GN, Pacy, PJ, Merritt, G, Ford, GC, Read, MA, Cheng, KN & Halliday, D (1989) Rapid measurement of whole body and forearm protein turnover using a [2H5]phenylalanine model. American Journal of Physiology 256, E631E639.Google Scholar
Van Acker, BAC, Hulsewé, KWE, Wagenmakers, AJM, Deutz, NEP, Van Kreel, BK, Halliday, D, Matthews, DE, Soeters, PB & Von Meyenfeldt, MF (1998a) Absence of glutamine isotopic steady state: Implications for studies on glutamine metabolism. Clinical Science 95, 339346.Google Scholar
Van Acker, BAC, Hulsewé, KWE, Wagenmakers, AJM, Deutz, NEP, Von Meyenfeldt, MF & Soeters, PB (1998b) Effect of surgery on albumin synthesis rate in humans. Clinical Nutrition 17, 1415.CrossRefGoogle Scholar
Van Eijk, HMH, Rooyakkers, DR, Wagenmakers, AJM, Soeters, PB & Deutz, NEP (1997) Isolation and quantitation of isotopically labeled amino acids from biological samples. Journal of Chromatography 691, 287296.Google Scholar
van Hall, G (1999) Correction factors for 13C-labelled substrate oxidation at whole-body and muscle level. Proceedings of the Nutrition Society 58, 979986.Google Scholar
van Hall, G, González-Alonso, J, Sacchetti, M & Saltin, B (1999a) Skeletal muscle substrate metabolism during exercise: methodological considerations. Proceedings of the Nutrition Society 58, 899912.CrossRefGoogle ScholarPubMed
van Hall, G, MacLean, DA, Saltin, B & Wagenmakers, AJM (1996) Mechanisms of activation of muscle branched-chain a-keto acid dehydrogenase during exercise in man. Journal of Physiology 494, 899905.Google Scholar
van Hall, G, Saltin, B, van der Vusse, GJ, Söderlund, K & Wagenmakers, AJM (1995) Deamination of amino acids as a source for ammonia production in human skeletal muscle during prolonged exercise. Journal of Physiology 489, 251261.CrossRefGoogle Scholar
van Hall, G, Saltin, B & Wagenmakers, AJM (1999b) Muscle protein degradation during prolonged one leg cycle exercise in man. Clinical Science (In the Press).Google Scholar
Venkatesan, S, Cullen, P, Pacy, P, Halliday, D & Scott, J (1993) Stable isotopes show a direct relation between VLDL ApoB overproduction and serum triglyceride levels and indicate a metabolically and biochemically coherent basis for familial combined hyperlipidemia. Arteriosclerosis and Thrombosis 13, 11101118.Google Scholar
Volpi, E, Ferrando, AA, Yeckel, CW, Tipton, KD & Wolfe, RR (1998) Exogenous amino acids stimulate net muscle protein synthesis in the elderly. Journal of Clinical Investigation 101, 20002007.Google Scholar
Wagenmakers, AJM (1998a) Protein and amino acid metabolism in human muscle. Advances in Experimental Medicine and Biology 441, 307319.CrossRefGoogle ScholarPubMed
Wagenmakers, AJM (1998b) Muscle amino acid metabolism at rest and during exercise: role in human physiology and metabolism. Exercise and Sports Science Reviews 26, 287314.CrossRefGoogle Scholar
Wagenmakers, AJM & Soeters, PB (1995) Metabolism of branched-chain amino acids. In Amino Acid Metabolism and Therapy in Health and Nutritional Disease, pp. 6783 [Cynober, LA, editor]. New York: CRC Press Inc.Google Scholar
Wagenmakers, AJM, Beckers, EJ, Brouns, F, Kuipers, H, Soeters, PB, Van der Vusse, GJ & Saris, WHM (1991) Carbohydrate supplementation, glycogen depletion, and amino acid metabolism during exercise. American Journal of Physiology 260, E883E890.Google ScholarPubMed
Wagenmakers, AJM, Brookes, JH, Coakley, JH, Reilly, T & Edwards, RHT (1989) Exercise-induced activation of the branched-chain 2-oxo acid dehydrogenase in human muscle. European Journal of Applied Physiology and Occupational Physiology 59, 159167.Google Scholar
Wagenmakers, AJM, Pannemans, DLE, Jeukendrup, AE, Gijsen, AP, Senden, JMG, Halliday, D & Saris, WHM (1998) Protein metabolism during exercise and recovery. Proceedings of the Nutrition Society 57, 7A.Google Scholar
Waterlow, JC (1984) Protein turnover with special reference to man. Quarterly Journal of Experimental Physiology 69, 409438.Google Scholar
Waterlow, JC, Garlick, PJ & Millward, DJ (1978a) Protein Turnover in Mammalian Tissues and in the Whole Body.Amsterdam: Elsevier North Holland.Google Scholar
Waterlow, JC, Golden, MH & Garlick, PJ (1978b) Protein turnover in man measured with 15N: comparison of end products and dose regimes. American Journal of Physiology 235, E165E174.Google Scholar
Watt, PW, Corbett, ME & Rennie, MJ (1992) Stimulation of protein synthesis in pig skeletal muscle by infusion of amino acids during constant insulin availability. American Journal of Physiology 263, 453460.Google Scholar
Welle, S & Thornton, CA (1998) High protein meals do not enhance myofibrillar synthesis after resistance exercise in 62- to 75-yr-old men and women. American Journal of Physiology 274, E677E683.Google Scholar
Yarasheski, KE, Smith, K, Rennie, MJ & Bier, DM (1992) Measurement of muscle protein fractional synthetic rate by capillary gas chromatography/combustion isotope ratio mass spectrometry. Biological Mass Spectrometry 21, 486490.Google Scholar
Zhang, X-J, Chinkes, DL, Sakurai, Y & Wolfe, RR (1996) An isotopic method for measurement of muscle protein fractional breakdown rate in vivo. American Journal of Physiology 270, E759E767.Google Scholar