Hostname: page-component-cd9895bd7-dk4vv Total loading time: 0 Render date: 2024-12-23T14:16:20.584Z Has data issue: false hasContentIssue false

High dietary fat and cholesterol exacerbates chronic vitamin C deficiency in guinea pigs

Published online by Cambridge University Press:  28 September 2010

Henriette Frikke-Schmidt
Affiliation:
Section of Biomedicine, Department of Veterinary Disease Biology, Faculty of Life Sciences, University of Copenhagen, Ridebanevej 9, DK-1870Frederiksberg C, Denmark
Pernille Tveden-Nyborg
Affiliation:
Section of Biomedicine, Department of Veterinary Disease Biology, Faculty of Life Sciences, University of Copenhagen, Ridebanevej 9, DK-1870Frederiksberg C, Denmark
Malene Muusfeldt Birck
Affiliation:
Section of Biomedicine, Department of Veterinary Disease Biology, Faculty of Life Sciences, University of Copenhagen, Ridebanevej 9, DK-1870Frederiksberg C, Denmark
Jens Lykkesfeldt*
Affiliation:
Section of Biomedicine, Department of Veterinary Disease Biology, Faculty of Life Sciences, University of Copenhagen, Ridebanevej 9, DK-1870Frederiksberg C, Denmark
*
*Corresponding author: Professor J. Lykkesfeldt, fax +45 35 35 35 14, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Vitamin C deficiency – or hypovitaminosis C defined as a plasma concentration below 23 μm – is estimated to affect hundreds of millions of people in the Western world, in particular subpopulations of low socio-economic status that tend to eat diets of poor nutritional value. Recent studies by us have shown that vitamin C deficiency may result in impaired brain development. Thus, the aim of the present study was to investigate if a poor diet high in fat and cholesterol affects the vitamin C status of guinea pigs kept on either sufficient or deficient levels of dietary ascorbate (Asc) for up to 6 months with particular emphasis on the brain. The present results show that a high-fat and cholesterol diet significantly decreased the vitamin C concentrations in the brain, irrespective of the vitamin C status of the animal (P < 0·001). The brain Asc oxidation ratio only depended on vitamin C status (P < 0·0001) and not on the dietary lipid content. In plasma, the levels of Asc significantly decreased when vitamin C in the diet was low or when the fat/cholesterol content was high (P < 0·0001 for both). The Asc oxidation ratio increased both with low vitamin C and with high fat and cholesterol content (P < 0·0001 for both). We show here for the first time that vitamin C homoeostasis of brain is affected by a diet rich in fat and cholesterol. The present findings suggest that this type of diet increases the turnover of Asc; hence, individuals consuming high-lipid diets may be at increased risk of vitamin C deficiency.

Type
Full Papers
Copyright
Copyright © The Authors 2010

For many years, the sole accepted clinical consequence of vitamin C deficiency has been an increased risk of developing the rare but potentially mortal disease scurvy. In contrast, many epidemiological studies have found an association between chronic vitamin C deficiency and increased risk of developing a range of age-associated conditions such as CVD, type 2 diabetes and cancer(Reference Khaw, Bingham and Welch1Reference Fairfield and Fletcher5). More recently, vitamin C deficiency has been linked to impaired brain development and cognitive deficits in experimental animal studies(Reference Lykkesfeldt, Trueba and Poulsen6Reference Harrison, Hosseini and Dawes8), consequences that may also be relevant in humans(Reference Tveden-Nyborg and Lykkesfeldt9). The intracellular concentration of ascorbate (Asc) in neurons is up to tenfold higher than in reference tissues such as the liver. Also the brain is capable of retaining and recycling vitamin C during states of deficiency, leaving it to be the last of tissues to become depleted(Reference Lykkesfeldt, Trueba and Poulsen6, Reference Rice and Russo-Menna10, Reference Kuo, Yonehara and Yoshida11). The functions of vitamin C in the brain are numerous(Reference Tveden-Nyborg and Lykkesfeldt9). Not only is Asc directly involved in the biosynthesis of neurotransmitters and as a modulator of neurotransmission, but it is also an essential factor for neural maturation(Reference Diliberto and Allen12Reference Lee, Chang and Park14). Hence, during vitamin C deficiency, functional consequences are expected to occur, and recent in vivo data support this hypothesis by finding impaired memory, decreased number of neurons in hippocampus, as well as sensorimotor deficits in vitamin C-deficient mice and guinea pigs(Reference Tveden-Nyborg, Johansen and Raida7, Reference Harrison, Hosseini and Dawes8, Reference Harrison, Yu and Van Den Bossche15).

In humans, the subpopulations with the lowest intake of vitamin C – and therefore the highest risk of developing deficiency – are people of low socio-economic status who tend to eat a poor diet low in fruits and vegetables(Reference Mosdol, Erens and Brunner16Reference Wrieden, Hannah and Bolton-Smith18). However, an unhealthy diet not only lacks fruits and vegetables, i.e. the primary dietary sources of vitamin C, but also tends to contain high levels of TAG and cholesterol. In fact, blood levels of cholesterol and TAG are apparently affected by the concentration of vitamin C since both the activity of the rate-limiting enzyme, 7α-hydroxylase, (Reference Bjorkhem and Kallner19) in the production of bile acids from cholesterol and the fatty acid transport rate via the carnitine transport system show vitamin C dependency(Reference Dunn, Rettura and Seifter20). This association has been confirmed by reports showing increased plasma concentrations of cholesterol and fatty acids during vitamin C deficiency(Reference Dunn, Rettura and Seifter20Reference Ha, Otsuka and Arakawa22). In contrast to these previous studies, our interest has been vitamin C status per se, and in the present paper, we report the effect of a poor diet rich in fat on the vitamin C homoeostasis of the brain. For the purpose of combining vitamin C deficiency with diet-induced hypercholesterolaemia, we have used guinea pigs as they are considered validated models for the human state of both conditions(Reference Fernandez23, Reference Frikke-Schmidt and Lykkesfeldt24).

Experimental methods

Materials

All chemicals were of the highest quality available. Specifically, Asc, dehydroascorbic acid (DHA), GSH, dansyl chloride, α- and γ-tocopherol, and t-butyl hydroperoxide were obtained from Fluka (Milwaukee, IL, USA). meta-Phosphoric acid and disodium EDTA were obtained from Merck (Darmstadt, Germany).

Animals

The study was approved by the Danish Animal Experimentation Inspectorate under the Ministry of Justice. Female Dunkin Hartley Guinea pigs (12 weeks of age) were obtained from HP-Lidkjöbing Kaninfarm (Lidkjöbing, Sweden). Upon arrival at the University animal facility, the animals were left for 2 weeks of acclimatisation after which each animal was tagged with a 12 mm microchip inserted subcutaneously in the neck for identification (PET-Id; Danworth Farm, West Sussex, UK). The animals were housed in floor bins allowing approximately 0·2m2 per animal and equipped with toys and hiding places to ensure a proper environment. Animals were attended daily by trained staff, checked regularly for clinical signs of disease and weighed every 4 weeks. Also the animals were routinely observed for weight loss, paralysis of the rear legs and haemorrhages in order to rule out the presence of scurvy symptoms. Before the experiment, the animals were randomised into four weight-stratified groups each receiving one of four experimental diets given below. The guinea pigs were followed for up to 6 months under the above conditions with monthly blood samplings (4 × 70 μl) drawn by puncturing of v. saphena lateralis. After 1, 2, 3 and 6 months, guinea pigs were anaesthetised using 0·08 ml/100 g body weight of supplemented zoletil solution (0·48 mg/ml Zoletil 50 vet. (Virbac S.A., Carros Cedex, France)), 2 mg/ml xylazine (Narcoxyl, Intervet Int., Boxmeer, Holland) and 0·5 mg/ml butorphanol tartrate (Torbugesic, ScanVet, Fredensborg, Denmark), in isotonic NaCl). Animals were briefly supplemented with CO2 inhalation (70 % CO2:30 % O2) until disappearance of (interdigital and palpebral) reflexes, immediately after which thoracotomy was performed followed by intracardial blood sampling. A 5 ml syringe with an 18G needle previously flushed with 15 % tripotassium EDTA was used. Ultimately, the animals were euthanised by exsanguination while still anaesthetised. The blood samples were carefully handled to avoid haemolysis and were immediately processed as described below. Brains were removed and immediately frozen to − 80°C until further analysis. Liver was used as a reference tissue and also stored at − 80°C.

Diets

The animals were fed diets that combined adequate/insufficient amounts of vitamin C with low/high amounts of fat and cholesterol in a 2 × 2 factorial design, i.e. high C/low fat (fifteen animals), low C/low fat (sixteen animals), high C/high fat (thirty-two animals) and low C/high fat (thirty-four animals). The diets consist of quality-controlled conventional cereal-based formulations (low fat; product codes 829 415 (low C) and 829 427 (high C)) or synthetic foods (high fat; product codes 824 163 (low C) and 824 158 (high C); Special Diet Services, Dietex, Witham, UK), and the vitamin C levels in the diets were chosen in order to reflect the plasma concentrations found in human subjects receiving adequate and inadequate vitamin C, respectively, but without resulting in scurvy symptoms. By analysis the ‘high C’ diets contained 691 mg per kg feed of vitamin C (as a stable phosphate derivative, Stay-C; Roche, Basel, Switzerland) and the deficient (‘low C’) diets contained 100 mg of vitamin C per kg feed. The exact composition of the low-fat and the high-fat diets can be seen in Table 1. The high-fat diet was formulated to resemble the diet given in the study by Cos et al. (Reference Cos, Ramjiganesh and Roy25).

Table 1 Composition of experimental diets

* 100 mg/kg vitamin C in the ‘low C’ diets and 691 mg/kg vitamin C in the ‘high C’ diets.

Biochemical analysis

Blood samples were immediately centrifuged (2000 g for 5 min at 4°C). For total Asc (total Asc = Asc+DHA measured after reduction with Tris (2-carboxyethyl) phosphine hydrochloride) and DHA analysis, one 50 μl aliquot of plasma was acidified with an equal volume of 10 % meta-phosphoric acid containing 2 mm-EDTA, briefly vortex mixed and centrifuged (16 000 g for 1 min), and the supernatant was frozen at − 80°C. The analytical procedure using HPLC with coulometric detection has been described in detail elsewhere(Reference Lykkesfeldt26, Reference Lykkesfeldt, Maines, Costa, Hodson and Reed27). The remaining plasma was stored neat at − 80°C. α-and γ-Tocopherol concentrations were measured in plasma samples by HPLC with amperometric detection following hexane extraction as described by Sattler et al. (Reference Sattler, Mohr and Stocker28).Total GSH level of brain was measured after derivatisation with dansyl chloride by HPLC with fluorescence detection(Reference Martin and White29).

Plasma total cholesterol and TAG were measured spectrophotometrically by use of commercial kits (CHOD-PAP and GPO-PAP, respectively; Roche, Hvidovre, Denmark).

Statistics

Statistical analysis was carried out by using Statistical Analysis Systems software package version 9.1 (SAS Institute, Cary, NC, USA). Plasma total Asc and Asc oxidation ratio (%DHA of total Asc) over time were logarithm-transformed and analysed statistically using a linear mixed model with a two-way interaction between diet combinations (vitamin C and fat/cholesterol) and observation times as the fixed effects. Random effects were used to account for variation between guinea pigs. Estimation and hypothesis testing were carried out using the restricted maximum likelihood method in SAS PROC MIXED. Brain ‘total Asc’ and ‘%DHA’ were analysed over time by a three-way ANOVA, with time, fat and vitamin C as factors. All the data in Table 2 were analysed by a two-way ANOVA with fat and vitamin C in diet as factors. A P value < 0·05 was considered statistically significant.

Table 2 Biochemical measurements in plasma, brain and liver in guinea pigs subjected to four different 6-month dietary regimens

(Mean values and standard deviations)

*  Data were logarithm transformed before statistical analysis.

Results

Plasma ascorbate and ascorbate oxidation ratio

The plasma concentrations of Asc became stable after 2 weeks on the respective diets (Fig. 1(a)). The plasma Asc concentration of the control animals (high C/low fat) did not change significantly during the study, whereas high C/high-fat animals dropped to about 70 % of the initial level. The plasma Asc concentrations of the low C/low-fat animals decreased to approximately 15 % of the initial level and even significantly lower (approximately 8 %) in the group receiving the low C/high-fat diet. The statistical analysis revealed that the plasma concentration of Asc depended on both vitamin C in the diet and on the fat/cholesterol content (P < 0·0001 in both cases). When no fat/cholesterol was added to the diets, the levels of vitamin C were about 50 % higher than those observed in the corresponding high-fat diets regardless of the vitamin C content.

Fig. 1 Vitamin C status in the plasma of guinea pigs fed the four different diets. Plasma ascorbate (Asc) is expressed as a percentage of the initial Asc concentration in control animals with high C/low-fat diet (a). Asc oxidation ratio in plasma is expressed as % dehydroascorbic acid of total ascorbate (b). Value for each data point is n 7 or more. Values are represented as means with their standard errors; if error bars are not visible, it indicates that they are smaller than dot size. Dietary regimens: high C/low fat (○), high C/high fat (●), low C/low fat (△) and low C/high fat (▲). Three-way ANOVA using time, dietary fat and dietary Asc as factors revealed significant effects of all on both plasma Asc and plasma Asc oxidation ratio (P < 0·001 in all cases).

In the first few weeks of the study, there were marked changes in the levels of the Asc oxidation ratio (Fig. 1(b)). The DHA of the sufficiently supplied animals decreased to levels below 10 %, with the high C/high-fat animals having small but significantly higher levels than the high C/low-fat group. In contrast, the Asc oxidation ratio of the deficient animals increased twofold with the low-fat diet and even threefold with the high-fat diet. After the first month, the levels gradually declined but the difference persisted. In the animals fed the sufficient vitamin C diets (high C/low or high fat), Asc oxidation ratio levels remained largely unchanged. Both vitamin C and fat/cholesterol content of the diet significantly affected Asc oxidation ratio (P < 0·0001 in both cases). Yet the relative change was larger (54 %) when the vitamin C status of the animals was deficient as compared with when they were fed sufficient vitamin C (23 %).

Brain ascorbate and ascorbate oxidation ratio

The brain tissue levels of Asc in the sufficiently supplied animals remained relatively stable at about 1200 nmol/g tissue and at 1000 nmol/g tissue for groups with low- and high-fat diets, respectively (Table 2 and Fig. 2(a)). After 6 months, the Asc level was 12 % lower in the high fat as compared with low fat-fed animals. When the animals were kept on the diets deficient in vitamin C, the levels of Asc in the brain decreased over time during the first 90 d of the study, after which they stabilised at much lower levels than those observed for the vitamin C-sufficient diets (37 and 23 % compared with controls for groups with low and high in fat, respectively; Fig. 2(a)). The pattern observed in the brain was thus largely reflected by the plasma concentrations, namely that the addition of fat and cholesterol to the respective diets significantly reduced the levels of vitamin C. A three-way ANOVA analysis revealed that both vitamin C (P < 0·001) and fat (P < 0·001) in the diet affected the vitamin C status of the brain. The Asc oxidation ratio levels (Fig. 2(b)) were higher in animals fed diets deficient in vitamin C (approximately 10 %) compared with those on vitamin C-adequate diets (approximately 5 %) (P < 0·0001). The ability of the brain to keep its Asc pool reduced was hence significantly dependent on the amount of vitamin C in the diet, whereas fat and cholesterol in the diet did not significantly affect the Asc oxidation ratio.

Fig. 2 Vitamin C status in the brains of guinea pigs fed the four different diets. Brain ascorbate (Asc) is expressed as a percentage of the initial Asc concentration in control animals with high C/low-fat diet (a). Asc oxidation ratio in brain is expressed as % dehydroascorbic acid (DHA) of total Asc (b). Value for each data point is given in parentheses in panel A. Values are represented as means with their standard errors; if error bars are not visible, it indicates that they are smaller than dot size. Dietary regimens: high C/low fat (○), high C/high fat (●), low C/low fat (△) and low C/high fat (▲). Three-way ANOVA with time, dietary content of Asc and fat revealed that brain Asc was significantly decreased by low C (P < 0·001) and high fat (P < 0·001), whereas brain Asc oxidation ratio was only significantly decreased by low C (P < 0·0001) and not high fat.

In the statistical models for both total ascorbic acid and %DHA, no interactions with vitamin C in diet, fat/cholesterol in diet or time turned out to be significant, and they were thus omitted from the model.

Plasma and tissue antioxidants, cholesterol and TAG

Table 2 shows the biochemical data from plasma, brain and liver tissue after 180 d on the respective four diets. For all the data in Table 2, effects of vitamin C and fat were tested by the two-way ANOVA analysis. As the data in Table 2 only reflect single time points in contrast to the curves in Figs. 1 and 2, the lower power of these resulted in merely near-significant tendencies for the effect of fat in the diets in some cases (Table 2).

Cholesterol increased from 0·82 to 4·29 mm when it was added to the diet indicating hypercholesterolaemia. The cholesterol level was not affected by the vitamin C content of the diet. Surprisingly, the levels of TAG were unaltered in between groups. Both α- and γ-tocopherols increased several folds when fat and cholesterol were added to the diets (Table 2). The amount of vitamin C in the diet had no effect on the plasma tocopherol levels.

After 180 d, GSH levels in brain tissue did not alter when vitamin C was insufficient in the diet but remained 1600 nmol/g tissue, whereas with fat and cholesterol in the diet, the levels decreased slightly but significantly to 1400 nmol/g tissue.

The liver was used as a reference tissue. In the liver, the levels of total ascorbic acid decreased when the vitamin C in the diet was marginally insufficient (from 1348 to 340 nmol/g tissue). High dietary fat content caused the levels to significantly decrease even further (Table 2).

Discussion

When studying the long-term effects of marginal vitamin C deficiency, it is of uttermost importance to ensure that clinical scurvy does not evolve. During scurvy, vast metabolic changes take place, which might cause inconsistent experimental findings, hence obstructing the conclusions made from the study(Reference Ginter30). As described in the experimental methods section, the guinea pigs were examined on a regular basis for symptoms of scurvy, and no animals were found to be affected.

In the present study, we examined the effect of high dietary fat and cholesterol on the vitamin C homoeostasis of brain. In spite of the effective systems maintaining high brain concentrations of vitamin C(Reference Lykkesfeldt, Trueba and Poulsen6), the addition of high fat and cholesterol to the guinea pig diets caused the levels of vitamin C to significantly decrease irrespective of the vitamin C content of the diet. Also the Asc oxidation ratio was affected by the different diets. In plasma, vitamin C deficiency as well as high fat/cholesterol increased the ratio of oxidised to reduced vitamin C, whereas oxidation ratios in the brain were affected only by vitamin C deficiency. In agreement with its use as a biomarker of redox imbalance, an increased oxidation ratio suggests that the capacity to recycle DHA to Asc is overwhelmed by the rate of Asc oxidation(Reference Odermarsky, Lykkesfeldt and Liuba31Reference Lykkesfeldt, Loft and Poulsen33). Previously, guinea pig studies have found that diets high in cholesterol caused the plasma and/or hepatic levels of vitamin C to decrease(Reference Sharma, Pramod and Sharma34Reference Ginter, Babala and Cerven40). The specific mechanism for this is still unknown, but it has been suggested that hypercholesterolaemia itself has the ability to increase systemic oxidative stress(Reference Ohara, Peterson and Harrison41, Reference Reilly, Pratico and Delanty42). The lipid metabolism in guinea pigs has been found to resemble that of humans. It has also been reported that production of reactive oxygen species increases selectively in adipose tissue of obese mice most likely through augmented expression of NADPH oxidase and decreased expression of antioxidative enzymes, supporting a link between high fat and oxidative stress(Reference Furukawa, Fujita and Shimabukuro43). Moreover, there is the possibility that the high amount of cholesterol and fat in the high-fat diet has interfered with the absorption of vitamin C in the intestines as dietary factors have been hypothesised to affect the function of the sodium-dependent vitamin C transporter 1, which is responsible for vitamin C uptake in the intestines(Reference Michels and Hagen44). As regarding factors such as cholesterol synthesis, lipoprotein content and composition, activity of enzymes involved in lipoprotein metabolism etc.(Reference Fernandez23, Reference Fernandez and Volek45, Reference West and Fernandez46), it is possible that hypercholesterolaemia could have implications for the severity of vitamin C deficiency in humans as well.

In the present study, the GSH level of brain was significantly decreased when animals were subjected to a high-fat diet (Table 2), which further supports the hypothesis that hypercholesterolaemia might increase systemic oxidative stress and burden the antioxidant defence system. The levels of the vitamin E isoforms (α- and γ-tocopherol) were also affected by the fat content of diet. They both increased substantially when the diet was high in fat, i.e. contained a fat mixture made from vegetable oils, which are well-known dietary sources of vitamin E(Reference Dietrich, Traber and Jacques47). In vivo experiments in other species have confirmed a rise in vitamin E levels as a consequence of a high-fat/high-cholesterol diet(Reference Mawatari, Ohnishi and Kaji48). The most likely reason for this increase in vitamin E is probably the dietary composition itself rather than a change in redox balance. Also, there is the possibility that inflammation in the gastrointestinal tract due to incompatibility with the high amounts of fat and cholesterol in the diet could ultimately lead to lipolysis and hence an increased release of vitamin E(Reference Bezaire and Langin49).

Yet the vitamin C status of the animals did not significantly interfere with GSH or vitamin E status. We have previously reported that brain antioxidants other than vitamin C (i.e. GSH, superoxide dismutase and vitamin E) in guinea pigs were unaffected by vitamin C deficiency or even vitamin C depletion(Reference Lykkesfeldt, Trueba and Poulsen6, Reference Tveden-Nyborg, Johansen and Raida7). Even though there is some in vivo evidence that vitamin C, glutathione and vitamin E status are linked to one another(Reference Martensson, Han and Griffith50Reference Jiang, Lykkesfeldt and Shigenaga52), there have been several reports on vitamin C deficiency showing no effect on vitamin E and glutathione levels(Reference Hill, Motley and May53Reference Burton, Wronska and Stone58). Concerning GSH, this redox modulator is endogenously produced and hence may become compensatorily up-regulated when oxidative stress is increased as a result of vitamin C depletion. Vitamin E levels could also be affected by a severe hypovitaminosis C, as vitamin C is believed to play a role in keeping vitamin E reduced(Reference Sato, Niki and Shimasaki59, Reference Frei60), yet this does not seem to always affect the actual amounts of vitamin E isoforms.

These observations together with the present findings could indicate that the oxidative stress exerted by an increased intake of dietary fat and cholesterol affects the antioxidant defence in the brain in a different manner than vitamin C deficiency alone.

The kinetics for the vitamin C deficiency to develop was different between plasma and brain tissue. The plasma reached a steady-state concentration within a few weeks, whereas the stabilisation of brain total Asc took longer. This is in agreement with the general belief that the brain is especially sensitive to lack of vitamin C and hence has developed extended ability to preserve the vitamin C pool(Reference Lykkesfeldt, Trueba and Poulsen6, Reference Hughes, Hurley and Jones61).

Another lifestyle-related factor that is known to negatively affect vitamin C status is smoking. It has successively been documented that smokers have significantly lower levels of vitamin C. This lower vitamin C status in smokers has been shown to be partly due to an increased turnover as a consequence of increased systemic oxidative stress of the smoke per se but also partly due to a generally poorer diet with less fruits and vegetables consumed by smokers compared with non-smokers(Reference Lykkesfeldt, Christen and Wallock62Reference Subar, Harlan and Mattson66). These findings have resulted in recognition of the fact that smokers may require a higher intake of vitamin C compared to healthy controls in order to keep the plasma levels of this vitamin at a sufficient level. In agreement with this rationale, special recommendations were included in the latest revision of the dietary reference intakes in which the RDA for smokers was increased with 35 mg vitamin C/d compared with non-smokers as compensation(Reference Lykkesfeldt, Halliwell and Poulsen67, 68). The present findings suggest that the dietary component of the vitamin C depletion observed in smokers may not only be attributed to a decreased consumption of dietary sources of vitamin C but also be attributed to a increased consumption of fat. Indeed, it has been reported that smokers tend to eat more fat through the diet resulting in higher levels of serum cholesterol, TAG and LDL:HDL ratios(Reference Cundiff69).

As the present study design does not allow us to distinguish between decreased absorption fraction and increased turnover of vitamin C, we can only report the decreased relative bioavailability in high-fat-fed animals compared to those consuming a low-fat diet. Also, it is not known whether the impact of fat and cholesterol on the plasma vitamin C status is comparable between the non-producing species. Thus, future studies are needed to clarify similarities and possible differences between the vitamin C homoeostasis of guinea pigs and humans. However, if the fat-induced vitamin C depletion observed in the present study also occurs in humans, it may have implications for future revisions of the dietary reference intakes suggesting that also people with a diet rich in fat should have a higher RDA of vitamin C.

Acknowledgements

Annie B. Kristensen, Jytte Nielsen, Maria Frederiksen, Line Hansen, Jane Povlsen and the LIFE animal facility are thanked for excellent technical assistance. The study was supported by Danish Research Council grant #271-05-0199 to J. L. J. L. and H. F.-S. conceived the experimental set-up. All authors contributed to handling and tissue sampling of the animals. H. F.-S. drafted the manuscript which was revised by J. L. and subsequently discussed with P. T.-N. and M. M. B. All authors declare no conflict of interest.

References

1Khaw, KT, Bingham, S, Welch, A, et al. (2001) Relation between plasma ascorbic acid and mortality in men and women in EPIC-Norfolk prospective study: a prospective population study. European Prospective Investigation into Cancer and Nutrition. Lancet 357, 657663.Google Scholar
2Ginter, E (2007) Chronic vitamin C deficiency increases the risk of cardiovascular diseases. Bratisl Lek Listy 108, 417421.Google ScholarPubMed
3Cunningham, JJ, Ellis, SL, McVeigh, KL, et al. (1991) Reduced mononuclear leukocyte ascorbic acid content in adults with insulin-dependent diabetes mellitus consuming adequate dietary vitamin C. Metabolism 40, 146149.CrossRefGoogle ScholarPubMed
4Jenab, M, Riboli, E, Ferrari, P, et al. (2006) Plasma and dietary vitamin C levels and risk of gastric cancer in the European Prospective Investigation into Cancer and Nutrition (EPIC-EURGAST). Carcinogenesis 27, 22502257.Google Scholar
5Fairfield, KM & Fletcher, RH (2002) Vitamins for chronic disease prevention in adults: scientific review. JAMA 287, 31163126.Google Scholar
6Lykkesfeldt, J, Trueba, GP, Poulsen, HE, et al. (2007) Vitamin C deficiency in weanling guinea pigs: differential expression of oxidative stress and DNA repair in liver and brain. Br J Nutr 98, 11161119.CrossRefGoogle ScholarPubMed
7Tveden-Nyborg, P, Johansen, LK, Raida, Z, et al. (2009) Vitamin C deficiency in early postnatal life impairs spatial memory and reduces the number of hippocampal neurons in guinea pigs. Am J Clin Nutr 90, 540546.Google Scholar
8Harrison, FE, Hosseini, AH, Dawes, SM, et al. (2009) Ascorbic acid attenuates scopolamine-induced spatial learning deficits in the water maze. Behav Brain Res 205, 550558.CrossRefGoogle ScholarPubMed
9Tveden-Nyborg, P & Lykkesfeldt, J (2009) Does vitamin C deficiency result in impaired brain development in infants? Redox Rep 14, 26.Google Scholar
10Rice, ME & Russo-Menna, I (1998) Differential compartmentalization of brain ascorbate and glutathione between neurons and glia. Neuroscience 82, 12131223.CrossRefGoogle ScholarPubMed
11Kuo, CH, Yonehara, N & Yoshida, H (1979) Subcellular ascorbic acid in scorbutic guinea pig brain. J Nutr Sci Vitaminol (Tokyo) 25, 913.CrossRefGoogle ScholarPubMed
12Diliberto, EJ Jr & Allen, PL (1980) Semidehydroascorbate as a product of the enzymic conversion of dopamine to norepinephrine. Coupling of semidehydroascorbate reductase to dopamine-beta-hydroxylase. Mol Pharmacol 17, 421426.Google Scholar
13Rebec, GV & Pierce, RC (1994) A vitamin as neuromodulator: ascorbate release into the extracellular fluid of the brain regulates dopaminergic and glutamatergic transmission. Prog Neurobiol 43, 537565.Google Scholar
14Lee, JY, Chang, MY, Park, CH, et al. (2003) Ascorbate-induced differentiation of embryonic cortical precursors into neurons and astrocytes. J Neurosci Res 73, 156165.CrossRefGoogle ScholarPubMed
15Harrison, FE, Yu, SS, Van Den Bossche, KL, et al. (2008) Elevated oxidative stress and sensorimotor deficits but normal cognition in mice that cannot synthesize ascorbic acid. J Neurochem 106, 11981208.Google Scholar
16Mosdol, A, Erens, B & Brunner, EJ (2008) Estimated prevalence and predictors of vitamin C deficiency within UK's low-income population. J Public Health (Oxf) 30, 456460.CrossRefGoogle ScholarPubMed
17Hampl, JS, Taylor, CA & Johnston, CS (2004) Vitamin C deficiency and depletion in the United States: the Third National Health and Nutrition Examination Survey, 1988 to 1994. Am J Public Health 94, 870875.CrossRefGoogle ScholarPubMed
18Wrieden, WL, Hannah, MK, Bolton-Smith, C, et al. (2000) Plasma vitamin C and food choice in the third Glasgow MONICA population survey. J Epidemiol Community Health 54, 355360.CrossRefGoogle ScholarPubMed
19Bjorkhem, I & Kallner, A (1976) Hepatic 7-alpha-hydroxylation of cholesterol in ascorbate-deficient and ascorbate-supplemented guinea pigs. J Lipid Res 17, 360365.Google Scholar
20Dunn, WA, Rettura, G, Seifter, E, et al. (1984) Carnitine biosynthesis from gamma-butyrobetaine and from exogenous protein-bound 6-N-trimethyl-l-lysine by the perfused guinea pig liver. Effect of ascorbate deficiency on the in situ activity of gamma-butyrobetaine hydroxylase. J Biol Chem 259, 1076410770.Google Scholar
21Nelson, PJ, Pruitt, RE, Henderson, LL, et al. (1981) Effect of ascorbic acid deficiency on the in vivo synthesis of carnitine. Biochim Biophys Acta 672, 123127.CrossRefGoogle ScholarPubMed
22Ha, TY, Otsuka, M & Arakawa, N (1990) The effect of graded doses of ascorbic acid on the tissue carnitine and plasma lipid concentrations. J Nutr Sci Vitaminol (Tokyo) 36, 227234.Google Scholar
23Fernandez, ML (2001) Guinea pigs as models for cholesterol and lipoprotein metabolism. J Nutr 131, 1020.CrossRefGoogle ScholarPubMed
24Frikke-Schmidt, H & Lykkesfeldt, J (2009) Role of marginal vitamin C deficiency in atherogenesis: in vivo models and clinical studies. Basic Clin Pharmacol Toxicol 104, 419433.Google Scholar
25Cos, E, Ramjiganesh, T, Roy, S, et al. (2001) Soluble fiber and soybean protein reduce atherosclerotic lesions in guinea pigs. Sex and hormonal status determine lesion extension. Lipids 36, 12091216.CrossRefGoogle ScholarPubMed
26Lykkesfeldt, J (2000) Determination of ascorbic acid and dehydroascorbic acid in biological samples by high-performance liquid chromatography using subtraction methods: reliable reduction with tris[2-carboxyethyl]phosphine hydrochloride. Anal Biochem 282, 8993.Google Scholar
27Lykkesfeldt, J (2002) Measurement of ascorbic acid and dehydroascorbic acid in biological samples. In Current Protocols in Toxicology, pp. 7.6.17.6.15 [Maines, M, Costa, LG, Hodson, E and Reed, JC, editors]. New York: John Wiley & Sons.Google Scholar
28Sattler, W, Mohr, D & Stocker, R (1994) Rapid isolation of lipoproteins and assessment of their peroxidation by high-performance liquid chromatography postcolumn chemiluminescence. Methods Enzymol 233, 469489.CrossRefGoogle ScholarPubMed
29Martin, J & White, IN (1991) Fluorimetric determination of oxidised and reduced glutathione in cells and tissues by high-performance liquid chromatography following derivatization with dansyl chloride. J Chromatogr 568, 219225.Google Scholar
30Ginter, E (1978) Marginal vitamin C deficiency, lipid metabolism, and atherogenesis. Adv Lipid Res 16, 167220.Google Scholar
31Odermarsky, M, Lykkesfeldt, J & Liuba, P (2009) Poor vitamin C status is associated with increased carotid intima-media thickness, decreased microvascular function, and delayed myocardial repolarization in young patients with type 1 diabetes. Am J Clin Nutr 90, 447452.Google Scholar
32Christen, S, Finckh, B, Lykkesfeldt, J, et al. (2005) Oxidative stress precedes peak systemic inflammatory response in pediatric patients undergoing cardiopulmonary bypass operation. Free Radic Biol Med 38, 13231332.Google Scholar
33Lykkesfeldt, J, Loft, S & Poulsen, HE (1995) Determination of ascorbic acid and dehydroascorbic acid in plasma by high-performance liquid chromatography with coulometric detection – are they reliable biomarkers of oxidative stress? Anal Biochem 229, 329335.Google Scholar
34Sharma, P, Pramod, J, Sharma, PK, et al. (1990) Effect of vitamin C deficiency and excess on the liver: a histopathological and biochemical study in guinea pigs fed normal or high cholesterol diet. Indian J Pathol Microbiol 33, 307313.Google Scholar
35Sharma, P, Pramod, J, Sharma, PK, et al. (1988) Effect of vitamin C administration on serum & aortic lipid profile of guineapigs. Indian J Med Res 87, 283289.Google ScholarPubMed
36Satinder, , Sarkar, AK, Majumdar, S, et al. (1987) Effect of ascorbic acid deficiency on the development of experimental atherosclerosis. Indian J Med Res 86, 351360.Google ScholarPubMed
37Kothari, LK & Sharma, P (1988) Aggravation of cholesterol induced hyperlipidemia by chronic vitamin C deficiency: experimental study in guinea pigs. Acta Biol Hung 39, 4957.Google Scholar
38Nambisan, B & Kurup, PA (1975) Ascorbic acid and glycosaminoglycan and lipid metabolism in guinea pigs fed normal and atherogenic diets. Atherosclerosis 22, 447461.CrossRefGoogle ScholarPubMed
39Ginter, E, Bobek, P, Babala, J, et al. (1969) The effect of ascorbic acid on the lipid metabolism of guinea-pigs fed an atherogenic diet. Cor Vasa 11, 6573.Google ScholarPubMed
40Ginter, E, Babala, J & Cerven, J (1969) The effect of chronic hypovitaminosis C on the metabolism of cholesterol and atherogenisis in guinea pigs. J Atheroscler Res 10, 341352.CrossRefGoogle Scholar
41Ohara, Y, Peterson, TE & Harrison, DG (1993) Hypercholesterolemia increases endothelial superoxide anion production. J Clin Invest 91, 25462551.CrossRefGoogle ScholarPubMed
42Reilly, MP, Pratico, D, Delanty, N, et al. (1998) Increased formation of distinct F2 isoprostanes in hypercholesterolemia. Circulation 98, 28222828.Google Scholar
43Furukawa, S, Fujita, T, Shimabukuro, M, et al. (2004) Increased oxidative stress in obesity and its impact on metabolic syndrome. J Clin Invest 114, 17521761.Google Scholar
44Michels, AJ & Hagen, TM (2009) Hepatocyte nuclear factor 1 is essential for transcription of sodium-dependent vitamin C transporter protein 1. Am J Physiol Cell Physiol 297, C1220C1227.Google Scholar
45Fernandez, ML & Volek, JS (2006) Guinea pigs: A suitable animal model to study lipoprotein metabolism, atherosclerosis and inflammation. Nutr Metab (Lond) 3, 17.Google Scholar
46West, KL & Fernandez, ML (2004) Guinea pigs as models to study the hypocholesterolemic effects of drugs. Cardiovasc Drug Rev 22, 5570.Google Scholar
47Dietrich, M, Traber, MG, Jacques, PF, et al. (2006) Does gamma-tocopherol play a role in the primary prevention of heart disease and cancer? A review. J Am Coll Nutr 25, 292299.Google Scholar
48Mawatari, S, Ohnishi, Y, Kaji, Y, et al. (2003) High-cholesterol diets induce changes in lipid composition of rat erythrocyte membrane including decrease in cholesterol, increase in alpha-tocopherol and changes in fatty acids of phospholipids. Biosci Biotechnol Biochem 67, 14571464.Google Scholar
49Bezaire, V & Langin, D (2009) Regulation of adipose tissue lipolysis revisited. Proc Nutr Soc 68, 350360.CrossRefGoogle ScholarPubMed
50Martensson, J, Han, J, Griffith, OW, et al. (1993) Glutathione ester delays the onset of scurvy in ascorbate-deficient guinea pigs. Proc Natl Acad Sci U S A 90, 317321.Google Scholar
51Martensson, J & Meister, A (1991) Glutathione deficiency decreases tissue ascorbate levels in newborn rats: ascorbate spares glutathione and protects. Proc Natl Acad Sci U S A 88, 46564660.CrossRefGoogle ScholarPubMed
52Jiang, Q, Lykkesfeldt, J, Shigenaga, MK, et al. (2002) Gamma-tocopherol supplementation inhibits protein nitration and ascorbate oxidation in rats with inflammation. Free Radic Biol Med 33, 15341542.Google Scholar
53Hill, KE, Motley, AK, May, JM, et al. (2009) Combined selenium and vitamin C deficiency causes cell death in guinea pig skeletal muscle. Nutr Res 29, 213219.Google Scholar
54Bertinato, J, Hidiroglou, N, Peace, R, et al. (2007) Sparing effects of selenium and ascorbic acid on vitamin C and E in guinea pig tissues. Nutr J 6, 7.Google Scholar
55Barja, G, Lopez-Torres, M, Perez-Campo, R, et al. (1994) Dietary vitamin C decreases endogenous protein oxidative damage, malondialdehyde, and lipid peroxidation and maintains fatty acid unsaturation in the guinea pig liver. Free Radic Biol Med 17, 105115.CrossRefGoogle ScholarPubMed
56Chakraborty, S, Nandi, A, Mukhopadhyay, M, et al. (1994) Ascorbate protects guinea pig tissues against lipid peroxidation. Free Radic Biol Med 16, 417426.Google Scholar
57Lykkesfeldt, J (2002) Increased oxidative damage in vitamin C deficiency is accompanied by induction of ascorbic acid recycling capacity in young but not mature guinea pigs. Free Radic Res 36, 567574.CrossRefGoogle Scholar
58Burton, GW, Wronska, U, Stone, L, et al. (1990) Biokinetics of dietary RRR-alpha-tocopherol in the male guinea pig at three dietary levels of vitamin C and two levels of vitamin E. Evidence that vitamin C does not “spare” vitamin E in vivo. Lipids 25, 199210.Google Scholar
59Sato, K, Niki, E & Shimasaki, H (1990) Free radical-mediated chain oxidation of low density lipoprotein and its synergistic inhibition by vitamin E and vitamin C. Arch Biochem Biophys 279, 402405.Google Scholar
60Frei, B (1991) Ascorbic acid protects lipids in human plasma and low-density lipoprotein against oxidative damage. Am J Clin Nutr 54, 1113S1118S.Google Scholar
61Hughes, RE, Hurley, RJ & Jones, PR (1971) The retention of ascorbic acid by guinea-pig tissues. Br J Nutr 26, 433438.CrossRefGoogle ScholarPubMed
62Lykkesfeldt, J, Christen, S, Wallock, LM, et al. (2000) Ascorbate is depleted by smoking and repleted by moderate supplementation: a study in male smokers and nonsmokers with matched dietary antioxidant intakes. Am J Clin Nutr 71, 530536.Google Scholar
63Lykkesfeldt, J, Loft, S, Nielsen, JB, et al. (1997) Ascorbic acid and dehydroascorbic acid as biomarkers of oxidative stress caused by smoking. Am J Clin Nutr 65, 959963.Google Scholar
64Lykkesfeldt, J, Prieme, H, Loft, S, et al. (1996) Effect of smoking cessation on plasma ascorbic acid concentration. BMJ 313, 91.Google Scholar
65Lykkesfeldt, J, Viscovich, M & Poulsen, HE (2003) Ascorbic acid recycling in human erythrocytes is induced by smoking in vivo. Free Radic Biol Med 35, 14391447.Google Scholar
66Subar, AF, Harlan, LC & Mattson, ME (1990) Food and nutrient intake differences between smokers and non-smokers in the US. Am J Public Health 80, 13231329.Google Scholar
67Lykkesfeldt, J (2006) Smoking depletes vitamin C: should smokers be recommended to take supplements. In Cigarette Smoke and Oxidative Stress, pp. 237260 [Halliwell, BB and Poulsen, HE, editors]. Berlin/Heidelberg: Springer Verlag.Google Scholar
68Panel on Dietary Antioxidants and Related Compounds (2000) Dietary Reference Intakes for Vitamin C, Vitamin E, Selenium, and Carotenoids. A Report of the Institute of Medicine. Washington, DC: National Academy Press.Google Scholar
69Cundiff, DK (2002) Diet and tobacco use: analysis of data from the diabetic control and complications trial, a randomized study. MedGenMed 4, 2.Google ScholarPubMed
Figure 0

Table 1 Composition of experimental diets

Figure 1

Table 2 Biochemical measurements in plasma, brain and liver in guinea pigs subjected to four different 6-month dietary regimens(Mean values and standard deviations)

Figure 2

Fig. 1 Vitamin C status in the plasma of guinea pigs fed the four different diets. Plasma ascorbate (Asc) is expressed as a percentage of the initial Asc concentration in control animals with high C/low-fat diet (a). Asc oxidation ratio in plasma is expressed as % dehydroascorbic acid of total ascorbate (b). Value for each data point is n 7 or more. Values are represented as means with their standard errors; if error bars are not visible, it indicates that they are smaller than dot size. Dietary regimens: high C/low fat (○), high C/high fat (●), low C/low fat (△) and low C/high fat (▲). Three-way ANOVA using time, dietary fat and dietary Asc as factors revealed significant effects of all on both plasma Asc and plasma Asc oxidation ratio (P < 0·001 in all cases).

Figure 3

Fig. 2 Vitamin C status in the brains of guinea pigs fed the four different diets. Brain ascorbate (Asc) is expressed as a percentage of the initial Asc concentration in control animals with high C/low-fat diet (a). Asc oxidation ratio in brain is expressed as % dehydroascorbic acid (DHA) of total Asc (b). Value for each data point is given in parentheses in panel A. Values are represented as means with their standard errors; if error bars are not visible, it indicates that they are smaller than dot size. Dietary regimens: high C/low fat (○), high C/high fat (●), low C/low fat (△) and low C/high fat (▲). Three-way ANOVA with time, dietary content of Asc and fat revealed that brain Asc was significantly decreased by low C (P < 0·001) and high fat (P < 0·001), whereas brain Asc oxidation ratio was only significantly decreased by low C (P < 0·0001) and not high fat.