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Methionine kinetics are altered in the elderly both in the basal state and after vaccination^1,2,3

¹ From the Unité de Nutrition et Métabolisme Protéique, INRA Theix, Saint Genès Champanelle, France (SB, IP, PPM, and CO), and the Centre de Recherches Nestlé, Lausanne, Switzerland (DB, CB, and JG)

² Supported by the Institut National de la Recherche Agronomique, France, and Nestlé, Switzerland.

³ Reprints not available. Address correspondence to C Obled, Unité de Nutrition et Métabolisme Protéique, INRA Theix, 63122 Saint Genès Champanelle, France. E-mail: obled{at}clermont.inra.fr.

	ABSTRACT

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Background: Inflammation is known to affect sulfur amino acid metabolism. Aging is associated with an increased prevalence of inflammatory conditions, but the metabolism of methionine has been poorly explored in the elderly.

Objectives: The aims of this study were to compare methionine kinetics between elderly and young subjects and to explore the effect of aging on the response to a mild inflammatory challenge induced by a vaccination.

Design: Seven elderly volunteers aged 66–76 y and 8 young volunteers aged 22–26 y were studied before and 2 d after a vaccination (diphtheria, tetanus, poliomyelitis, and typhoid vaccines). Methionine kinetics were measured by using an infusion of L-[1-¹³C, methyl-²H₃]methionine in the postabsorptive and fed states.

Results: Before vaccination, the contribution of homocysteine remethylation to methionine-methyl flux (Q_m) and the ratio of remethylation to homocysteine transsulfuration were significantly lower in the elderly subjects than in the young subjects (P < 0.05). In contrast, the contribution of transsulfuration to methionine transmethylation was higher in the elderly (P < 0.05). Vaccination significantly increased the ratio of transsulfuration to transmethylation and decreased the ratio of remethylation to Q_m (P < 0.05).

Conclusions: The preferential methionine metabolism toward cysteine synthesis observed after vaccination suggests an increased requirement of sulfur amino acids even in mild inflammatory situations. The main finding of this study is a higher proportion of methionine entering the transsulfuration pathway in elderly subjects before vaccination. This finding suggests an increased cysteine demand during aging.

Key Words: Methionine kinetics • vaccination • elderly

	INTRODUCTION

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Aging is associated with increased concentrations of inflammatory components in the blood, including acute phase proteins and cytokines. Indeed, modest changes in acute phase proteins occur even among apparently healthy elderly individuals. Concentrations of C-reactive protein, ₁-acid glycoprotein, or fibrinogen have been found to be slightly but significantly elevated in animals and humans (1-3). Moreover, concentrations of the negative acute phase protein albumin are low (2-4). Such changes are representative of subclinical inflammation. Indeed, a deregulation of the immune system occurs in the elderly (5). Elevated circulating concentrations of interleukin 6 and an imbalance between proinflammatory and antiinflammatory cytokines have been reported during aging (6, 7). However, the metabolic and nutritional implications of this low-grade inflammatory state are unclear.

The low-grade inflammation present in the elderly could affect the immune response to additional injury or diseases. An increased risk of death or of developing diseases has been reported in elderly persons with elevated concentrations of cytokines or acute phase proteins (8, 9). Several studies have suggested an altered acute phase response during infection or endotoxemia. Elderly patients with pneumonia had lower plasma cytokine concentrations and production by peripheral blood monocytes during the acute phase of the infection than did young subjects but had prolonged inflammatory activity (10, 11). Similar results were found in endotoxemia (12).

It is well established that the acute phase response leads to important metabolic changes in general and in protein and amino acid metabolism in particular (13-15), ie, the metabolism of individual amino acids, especially methionine and cysteine, is altered (14). Methionine is mainly metabolized in the liver through the transmethylation-transsulfuration pathway. The transmethylation pathway leads to homocysteine synthesis; homocysteine can then be remethylated to form methionine or catabolized via the transsulfuration pathway, which ultimately forms cysteine. Under normal circumstances, this pathway constitutes a significant source of cysteine (16, 17). In injury, the contribution of the transsulfuration pathway to methionine flux increases, which suggests an increased cysteine requirement in diseases (18, 19). Indeed, cysteine is required for the synthesis of taurine and mainly glutathione, which are important compounds for host defense against oxidative stress (15).

In humans, methionine kinetics has been widely studied in healthy young subjects in relation to the intakes of methionine, cysteine or folate, and vitamin B-6 (20-23). By contrast, to our knowledge, only one study has been devoted to methionine metabolism in the elderly (24), and the influence of inflammation has never been explored in elderly subjects. Therefore, the aims of this study were to compare methionine kinetics between elderly and young subjects and to explore the effect of aging on the response to a mild inflammatory challenge induced by a vaccination. The data on inflammatory markers and whole-blood cytokine production of these subjects were published previously (25).

	SUBJECTS AND METHODS

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Subjects and protocol
The subjects and the study protocol were previously described in detail (25). Briefly, 7 elderly volunteers (3 women and 4 men) aged 66–76 y were compared with 8 young volunteers (4 women and 4 men) aged 22–26 y (Table 1). The volunteers gave their informed consent to participate in the study, which was approved by the local ethical committee for biomedical research (CCPRB Auvergne). The subjects were studied at 2 time points: 6–8 d before vaccination and 2 d after vaccination (Figure 1). The vaccination consisted of an intramuscular injection of a combination of diphtheria, tetanus, and poliomyelitis vaccines and a typhoid vaccine (DT-Polio and Typhim Vi, respectively; Institut Merieux, Lyon, France).

View larger version (27K): [in this window] [in a new window]   FIGURE 1.. Study protocol. D, day.

To determine whether the experimental diet altered breath ¹³CO₂ baseline enrichment during the fed state, 6 additional subjects were studied under the same conditions as in the experiment, except that no isotope was infused. The subjects drank the same meal as in the experimental trial, and breath samples were analyzed for ¹³CO₂ enrichment. Data for these 6 subjects were averaged for the last 90 min of the fed period, and this value was applied to the carbon-13 enrichment determined for each half-hourly period during the fed state.

Analytic methods
The free amino acids were isolated from a 1-mL plasma sample as previously described (26). However, 50 µL ß-mercaptoethanol was added to the sample to preserve methionine. Plasma enrichment of free methionine was measured by using a tert-butyldimethylsilyl derivative and gas chromatography–mass spectrometry under electron impact ionization (Automass; Thermo Quest Finnigan, Paris, France). Methionine, [1-¹³C]methionine, and [1-¹³C, methyl-²H₃]methionine were monitored at mass-to-charge ratios of 320, 321, and 324, respectively. Calibration graphs were prepared from standard mixtures of either [1-¹³C]methionine or [1-¹³C, methyl-²H₃]methionine. ¹³CO₂ enrichment was measured by gas chromatography–isotope ratio mass spectrometry (Microgas; Micromass, Manchester, United Kingdom).

Total, free, and bound cysteine were measured in plasma according to the method of Gaitonde (27) adapted by Malloy et al (28). Briefly, total free cysteine was measured in plasma treated with dithiothreitol before deproteinization. Total free cysteine (free cysteine and cystine) was measured in plasma treated with dithiothreitol after deproteinization. Free cysteine was measured in deproteinized plasma without any reducing treatment. Cystine was then calculated as the difference between unbound cysteine and free cysteine. Total erythrocyte glutathione was measured according to a standard enzymatic recycling procedure as described previously (29). Plasma total homocysteine was measured as described by Pfeiffer et al (30) and plasma folates as described by Wright et al (31).

Experimental model
Methionine kinetics were calculated according to the model of Storch et al (16) and Raguso et al (32) (Figure 2). Briefly, the whole-body methionine-methyl flux rate (Q_m) and the whole body methionine-carboxyl flux rate (Q_c) were calculated as follows:

(1)

(2

where I and E_i are the infusion rate and the isotope enrichment, respectively, of [1-¹³C, methyl-²H₃]methionine, and E₁ and E₄ are the plateau plasma enrichments of [1-¹³C]methionine (M + 1) and [1-¹³C, methyl-²H₃]methionine (M + 4), respectively. The correction factor R was used for the plasma intracellular gradient in methionine enrichment. The value used was 0.8 according to Storch et al (16) because we do not succeed in homocysteine enrichment determination.

View larger version (21K): [in this window] [in a new window]   FIGURE 2.. A schematic description of the methionine cycle with its components: transmethylation (TM), remethylation (RM), and transsulfuration (TS). If methionine is labeled on the methyl group and the carboxyl group, the methyl label will be lost during TM, and homocysteine RM will produce methionine labeled only on the carboxyl group. The carboxyl label will be lost during TS and will appear in carbon dioxide in the breath.

(3)

and in the fed state

(4)

where B_met is the rate of methionine appearance from protein breakdown, S_met is the rate of methionine disappearance via non oxidative metabolism (an index of the rate of protein synthesis), TS is the transsulfuration rate, and A is the total methionine entry from the tracer and the alimentary input.

In steady state conditions, the whole-body methionine-methyl flux rate can also be related to its individual components as follows:

(5)

where RM is the remethylation rate and TM is the transmethylation rate.

Therefore

(6)

TS was calculated as follows

(7)

where ¹³CO₂ is the rate of ¹³C output in expired air corrected for the retention of ¹³CO₂ according to Hoerr et al (33).

Finally, methionine balance, the difference between S_met and B_met, was calculated from the difference between transsulfuration and I or A.

Statistical methods and data evaluation
Differences in plasma folates and acute phase protein concentrations, measured in the postabsorptive state before vaccination, between the young and old subjects were tested by unpaired t test. For amino acid concentrations obtained only in the postabsorptive state before the tracer infusion began, differences were tested by repeated-measures analysis of variance (STATVIEW; SAS Institute Inc, Cary, NC) for the effect of age (between-subject factor) and vaccination (within-subject factor). Otherwise, the effects of age, vaccination, and nutritional state (postabsorptive or fed) were analyzed by using a repeated-measures analysis of variance (with age as the between-subject factor and vaccination and nutritional state as the within-subject factors). Differences were considered to be significant when P < 0.05.

	RESULTS

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Subjects
The elderly subjects included in our study were stringently selected for good health, and clinical and biological features matched the admission criteria of the SENIEUR protocol (25). However, as reported previously (25), these subjects had greater plasma concentrations of some acute phase proteins, such as ₁-acid glycoprotein and fibrinogen and tended to have higher concentrations of C-reactive protein (P = 0.077) than did the young subjects, which suggested a low-grade inflammatory state. In contrast, the plasma concentration of folates was not significantly different between the 2 groups (Table 1).

There was no significant effect of age or of vaccination on plasma methionine and erythrocyte glutathione concentrations. Vaccination had no effect on plasma cysteine and homocysteine concentrations. In contrast, the plasma concentration of the various forms of cysteine and of total homocysteine were greater in the elderly than in the young subjects (Table 2).

Table 3

Table 4

Figure 3

View larger version (25K): [in this window] [in a new window]   FIGURE 3.. Mean (±SE) relative activities of various components of the methionine cycle in the young (Y; n = 8) and elderly (E; n = 7) subjects before and 2 d after vaccination in the postabsorptive and fed states. TM, transmethylation; RM, remethylation; TS, transsulfuration; Qm, methionine-methyl flux. Measurements were made in the postabsorptive and fed states. TS/TM: main effects of age (P < 0.05), vaccination (P < 0.001), and nutritional state (P < 0.001). RM/TS: main effects of age (P < 0.05), vaccination (P < 0.001), and nutritional state (P < 0.001); there was a significant interaction between vaccination and nutritional state (P < 0.01). RM/Qm: main effects of age (P < 0.05) and vaccination (P < 0.05).

	DISCUSSION

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The model used to calculate methionine kinetics has several limits. The main point is the uncertainty of the true intracellular tracer enrichment. The approach generally used is the measurement of the plasma enrichment of an intracellular-derived metabolite of the tracer, such as -ketoisocaproate, when labeled leucine is used as tracer (34). The enrichment of plasma -ketoisocaproate has been found about 20% lower than plasma leucine enrichment (34) and Storch et al (16) have proposed to use this correction for methionine. Plasma homocysteine or cystathionine enrichments can be used to estimate intracellular methionine enrichment and some data have been reported recently. Values of 40 to 84% have been found for the ratio of plasma homocysteine to methionine enrichments (20, 21, 35) and 54 to 66% for that of cystathionine to methionine (21, 35). These results suggest that methionine fluxes calculated with a correction factor of 0.8 would be underestimated. Moreover, it was found that the ratio of -ketoisocaproate to leucine enrichment did not change in subjects and conditions similar to those explored in this study (26, 36, 37). We hypothesized that the same correction factor could be applied in all groups and conditions in our study. Therefore, we can assume that the corrections based on homocysteine enrichments would change the absolute values of methionine fluxes but not our conclusions. The second limit of the model is the indirect estimation of transsulfuration. A better estimate would be provided by cysteine synthesis. However, only sulfur from methionine appears in cysteine and such measurements requiring radioactive tracers are not possible in humans.

The methionine fluxes found in the group of young subjects were in the range of those previously reported with a similar correction factor for intracellular methionine enrichment (16, 17, 38). Methionine-methyl and methionine-carboxyl fluxes and the components of the methionine cycle were increased in response to feeding as already shown with similar sulfur amino acid intakes (16). The rate of homocysteine converted to cysteine (transsulfuration) increased more than its rate of remethylation in response to feeding, and the ratio of transsulfuration to transmethylation was increased during the fed state, in contrast with previous data. However, the fasted and fed states were not explored in the same subjects in the study by Storch et al (16), and other studies were performed with smaller intakes of sulfur amino acids (23). Indeed, a review of the data from several studies combined indicated that the ratio of transsulfuration to transmethylation depends on the total sulfur amino acid intake and on the proportion of sulfur amino acid intake as methionine (Figure 4). At a sulfur amino acid intake close to that of our study, values of 64% and 27% were reported in the fed state in young adults consuming a diet without cysteine or without methionine, respectively (17).

View larger version (13K): [in this window] [in a new window]   FIGURE 4.. Influence of methionine intake as a percentage of the sulfur amino acid intake on the proportion of methionine entering the methionine cycle that is oxidized [transsulfuration (TS)/transmethylation (TM)] at various intakes (in mg · kg–1 · d–1) of sulfur amino acids (, 32; •, 24; , 13; , 6.6; and , 0). Data were obtained in young subjects in the fed state with intravenous labeled methionine infusion (17, 23, 32, 39, and the present study).

Vaccination, used as a model of moderate inflammatory stress, was also associated with changes in the methionine cycle in favor of a predominance of homocysteine transsulfuration over remethylation with no change in the transmethylation rate. These results are in general agreement with the perturbation of sulfur amino acid metabolism found in acute diseases. The contribution of the transsulfuration pathway to methionine flux was shown to be greater in burn patients than in control subjects, and an increased cysteine synthesis from methionine was found in septic rats (18, 19). In addition, cysteine catabolism was reduced, whereas its utilization for glutathione synthesis was increased (29, 44-46). All these data strongly suggest increased cysteine utilization, even under a mild inflammatory stress such as vaccination.

Homocysteine metabolism was oriented in favor of cysteine synthesis after vaccination in young and elderly subjects. However, this change seemed to be less pronounced in the elderly than in the young subjects. For example, the ratio of transsulfuration to transmethylation increased by 21% and 11% after vaccination in the postabsorptive and fed states, respectively, in the young subjects instead of 11% and 8%, respectively, in the elderly subjects. These results suggest that methionine utilization may be preserved in the elderly subjects after vaccination so that homocysteine remethylation was better maintained than in young subjects. Therefore, the competition between homocysteine remethylation and transsulfuration seems to be more severe in the elderly, which leads to a trend for a decrease in blood glutathione. Another explanation could be defective metabolic adaptation to an inflammatory challenge, as already established for the immune system with advancing age (5). In the same subjects, we found lower increases in acute phase proteins and cytokine production in blood cultures in response to vaccination in the elderly subjects than in the young subjects (25). It can be hypothesized that the age-related differences in the metabolic response to vaccination could be linked to alterations in the inflammatory response, and studies in more severe inflammatory states could help to test this hypothesis.

In conclusion, methionine metabolism was affected after vaccination in agreement with previous data obtained in acute diseases. The preferential methionine metabolism toward cysteine synthesis confirms an increased requirement of sulfur amino acids in these situations. The main finding of this study was a higher proportion of methionine entering the transsulfuration pathway in elderly subjects before vaccination, probably because of a low-grade inflammatory state in these subjects. These data suggest that healthy aging may be associated with an increased cysteine requirement related to a low-grade inflammatory state. Moreover, in elderly subjects, the increased cysteine requirement in response to any inflammatory stress occurs in a situation in which the cysteine requirement is already elevated. The consequences of these findings relative to sulfur amino acid requirements during aging warrant further study.

	ACKNOWLEDGMENTS

 
We are grateful to the physician, dietitian, and nurse of the Human Nutrition Unit for conducting the experiment; to P Brachet for conducting the folate measurements; and to J Prugnaud for the mass spectrometry analyses.

SM was responsible for the planning and implementation of the study and was involved in the sample and data collection and analysis. CB and JG were involved in the sample collection and analysis. PPM was involved in the study design, statistical analysis, and critical revision of the manuscript. DB, IP and CO were involved in the study design, data interpretation, and writing of the manuscript. The authors had no conflicts of interest.

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TOP ABSTRACT INTRODUCTION SUBJECTS AND METHODS RESULTS DISCUSSION REFERENCES

 

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