Clinical implications of a possible role of vitamin D in multiple sclerosis

Vitamin D is a steroidal hormone metabolised successively in the skin (by sunlight or ultraviolet B rays), the liver and the kidneys to the active metabolite 1.25-dihydroxyvitamin D3 (calcitriol), which has a half life of several hours. This metabolite is recognised by tissues containing specific vitamin D receptors which are present in many parts of the body: skin, bone, muscles, gonads, intestine, central nervous system (CNS), microglia, activated monocytes and B and T lymphocytes [23, 49‐51, 69]. In addition to its well known action on calcium and phosphorus metabolism, vitamin D seems to have other important general effects, in particular anti-inflammatory and antiproliferative, and also modulatory effects on neurotrophins, growth factors and neurotransmitters in the CNS of mammals. Daily vitamin D requirements have recently been re-evaluated and are at least 2,000 IU/d, which is far higher than was thought necessary up until a few years ago [47, 52, 126, 127]. Vitamin D intake via (non-enriched) food is marginal in western diets, generally providing less than 100 IU/d, which is far below the daily requirement, and even Scandinavian diets (rich in oily fish) scarcely exceed a few hundred IU/d [76]. Sunshine therefore remains the principal natural source of vitamin D, providing approximately 90% of requirements. Although sunbathing can provide 10,000–20,000 IU in 15–30 min, this supply disappears within a few weeks and cannot readily be replenished throughout the year except in tropical countries [52, 127]. Moreover, the elderly, regardless of origin, and dark-skinned subjects, regardless of age, are less able to synthesise vitamin D than young, light-skinned subjects, who, if they protect themselves too much from the sun (by clothing or a sun block) may also rapidly find themselves in a state of vitamin D insufficiency. Lastly, women generally have lower serum levels than men [132, 133] and when pregnant or breast-feeding their vitamin D requirement is higher, which is, at the current time, rarely compensated for [23, 130].

The serum component of vitamin D usually measured is 25-hydroxyvitamin D (with a half life of several weeks), which is representative of an individual’s overall vitamin D status [107, 134, 135]. The official international standard for serum 25-hydroxyvitamin D levels has been established on a physiological basis, mainly from calcium metabolism, since it is difficult to use control groups in the general population of temperate countries where most people could in fact be in a state of vitamin D insufficiency in the absolute, in particular in winter (see below). The internationally accepted norms fall between 75 and 200 nmol/l, with insufficiency existing below 75 nmol/l and deficiency below 25 nmol/l [10, 25, 38, 52, 69, 96, 107, 125, 135]. The 75 nmol/l lower limit has not been arbitrarily established: it corresponds to the serum level below which the parathyroid hormone is stimulated by the lack of vitamin D and below which osteoporosis and pathological fractures become frequent. In fact, the current usual recommendations [38, 48, 52, 88, 107, 128, 135] suggest that a blood level of at least 90 or 100 nmol/l is needed first to optimise calcium and phosphorus metabolism (to reduce osteoporosis and to protect against pathological fractures), but also to improve the prevention of several major autoimmune diseases (diabetes, MS, lupus, rheumatoid arthritis etc.), three major cancers (colon, breast, prostate) and other common syndromes (asthenia, depression, hypertension) and infections in general, all of which are pathologies in which there has recently been an upsurge of studies implicating vitamin D. On these physiological grounds it can be deduced that vitamin D is most likely involved in a number of general regulatory activities, over and above calcium and phosphorus metabolism, and could have a notable immunological role to play, in particular within the CNS. One might also suspect that a vitamin D insufficiency or deficiency could exist whenever there is a shortage of sunlight, whether for an entire population—deprived of sunshine for reasons of climate—or for a given individual spending little or no time in the sun.

There is a long-standing body of experimental evidence—constantly being added to and now quite extensive—in favour of vitamin D having a marked role in experimental autoimmune encephalitis (EAE). Furthermore, many recent immunological studies suggest that this role could be anti-inflammatory and immunomodulatory. Vitamin D clearly prevents the induction of EAE if administered before the triggering of the disease and noticeably improves clinical signs in affected mice if it is administered afterwards, thus having a significant effect that is both protective and curative[9, 11, 14, 15, 17, 19, 32, 67, 78, 79, 82, 84‐86, 90, 102, 108, 110, 121]. This action is reported to be more marked in female mice than in male mice, due to the potentialisation of vitamin D by oestrogen [108]. It should be noted that a potentialisation of this type has also been reported in non-menopausal women [113, 123]. In EAE, vitamin D could have an anti-inflammatory effect [109] by reducing macrophages [84] and/or by regulating certain cytokines [18, 90, 110], and/or a protective effect on myelin by activating oligodendrocytes [23] and/or an immunomodulatory effect on T lymphocytes by inhibiting Th1 development and increasing Th 2 and Tr (regulatory T) lymphocyte restoration [14, 16, 77, 82, 102]. The latter effect (while not ruling out the others) currently seems the most well-founded, with vitamin D consequently having a mode of action that might be close to that of interferon β, the beneficial effect of which in EAE is indeed potentiated by vitamin D [122]. Lastly, in patients with MS, it has recently been suggested that vitamin D also has a beneficial effect on Tr lymphocytes [24, 97]. Even if EAE is not exactly the same as MS, all these results, taken together, constitute a solid experimental basis that supports the existence of a marked immunological effect of vitamin D in this pathological field.

Latitude has an undisputed effect on the prevalence of MS, which increases with distance from the equator, in both the northern and southern hemispheres, at a world level [31], at a continental level, as in Europe [65, 91], as well as in very large countries, such as the USA [66] and Australia [117], and even in smaller countries, such as New Zealand [112] or France [30, 129]. In contrast, very low prevalences of MS are observed in tropical regions, for example in Ecuador [1], even though the protective effect of such regions appears to be nowadays slightly attenuated, likely due to changes in life style [3]. One can also see—at comparable latitudes—that the degree of sunlight in a given region or type of habitat (e.g., in Switzerland, in the mountains compared to lowland areas) is correlated with the prevalence of MS [64, 116, 119, 120]. It should also be noted that emigration after the age of 15–20 years has varying effects on immigrants depending on the direction of emigration: if it is from a region with a high prevalence of MS to a region of low prevalence, immigrants tend to acquire the low prevalence of the region to which they have emigrated (thereby losing the high risk of their region of origin), whereas in the opposite direction, when they move from a region with a low prevalence of MS to a region of high prevalence, they retain the low risk of their region of origin, at least for themselves, but not for their children, in whom one observes the same prevalence as that of the inhabitants of their host region [27‐29, 31, 41, 66]. Only environmental (non-genetic) risk factors can explain these differences in prevalence between the new immigrants and their children. As for the difference in effect on the prevalence of MS according to the direction of emigration, this could be due to protective environmental factors of countries with a low prevalence of MS, which also happen to be those with (a) the most sun but also (b) the least ‘hygiene’ in its broadest sense, due to (1a) the sustained protective action of past exposure to sunlight (see below) received in these countries during childhood, which could persist after emigration to a country with less sun, and/or (1b) a subsequent, relatively protective effect of diverse infections contracted during childhood in countries with a low prevalence of MS (the so-called ‘hygiene hypothesis’), and (2) the permanent and immediate protective effect of a country with a sunny climate if one has moved there before the normal age of onset of MS (i.e. in young adults) [5‐7]. In sum, even if the effects of migration make it a little more difficult to interpret the role of latitude in MS risk, they do make it possible to suspect the involvement of several environmental risk factors—possibly including infectious factors—to explain these effects.

At this point in the discussion, it is appropriate to analyse the effects of latitude on vitamin D status in the general population. Numerous studies have shown that on average vitamin D levels are too low—in other words below the normal range, which has been established on a metabolic basis (see above)—in the adult population of all temperate countries where they have been studied: for example, in the USA, 74 nmol/l in a cohort from 1988 to 1994 (n = 15,000) [133] declining to 60 nmol/l in a cohort from 2000 to 2004 (n = 18,558) [33, 71]; between 75 and 51 nmol/l in Australia, depending on the region (n = 1,398) [119]; 51 nmol/l in the United Kingdom (n = 7,437), with a north-south gradient [55]; 49 nmol/l in New Zealand (n = 2,900) [95]; 61 nmol/l in southern Canada (n = 188) [98]; and 61 nmol/l in France (n = 1,579) [22]. It should be noted that the serum levels were determined in different seasons of the year in four of these studies and that on each occasion the levels in winter were 20–30 nmol/l lower than those in summer (Australia, United Kingdom, New Zealand and Canada). In France, the study related to nine different regions during the winter of 1994–1995. The lowest serum levels were observed in the north (43 nmol/l) and north-east (53 nmol/l) and the highest in the south (81 nmol/l) and south-west (94 nmol/l), with significant correlations existing between these levels and both latitude (P < 0.01) and amount of sunshine (P = 0.003) [22]. In all these temperate countries, it was emphasised that such very low average levels of vitamin D raise serious public health issues and that there is an urgent need for national heath authorities to take preventive measures [38, 39], leading for example to vitamin D supplementation for all subjects in a state of insufficiency [20]. It should also be noted that rickets in very young children and osteomalacia in the elderly are nowadays generally well prevented in developed countries by paediatricians and geriatricians, who preventively treat their patients quasi systematically with vitamin D, whereas, between these two extremities of life, little interest is shown in the vitamin D status of older children, adolescents and adults, probably on the assumption that in the great majority of cases it is normal; in fact, all recent epidemiological studies performed in medium or high latitude countries have shown that this is not at all the case (see above), which is potentially prejudicial for all people in these age-groups, not protected from hypovitaminosis D and its consequences in terms of increased risk of multiple, serious general affections, possibly including MS.

Looking now at a worldwide level, a correlation was found between latitude and the serum vitamin D level in Caucasian adult subjects in a recent meta-analysis covering 394 studies [40]. Generally speaking, Nordic countries have even lower vitamin D levels than those in temperate countries—e.g. 44 nmol/l in summer and 24 nmol/l in winter in Finland (n = 220 young men) [115], and 29 nmol/l in winter in several countries of northern Europe (n = 199 adolescent girls) [4]—whereas tropical countries have far higher levels, e.g. 105 nmol/l in women and 168 nmol/l in men in Thailand (n = 158 adults) [21], and more than 100 nmol/l in several groups of children and adolescents in Brazil, including poorly nourished groups (n = 638) [68]. In another meta-analysis relating to Europe and Asia, it was stated that the factors affecting the serum vitamin D level in adults are age, sex, skin colour, type of clothing (wearing a veil leads almost systematically to insufficiency or deficiency), food (whether or not supplemented with vitamin D) and the degree of urbanisation [70]. Overall, the mean serum vitamin D level in the general population is therefore correlated with latitude and the amount of sunlight, whether one considers the world as a whole or one considers a relatively small country such as France. We can therefore see that there are links between latitude and the prevalence of MS on the one hand and between latitude, amount of sunlight and the serum vitamin D level in the general population on the other hand (Fig. 3). To complete this chain of cause and effect, we need to establish a link between the level of sunlight and the risk of MS, and then between the serum vitamin D level and the risk of MS. These will be dealt with in the following two paragraphs.

Based on a study of 136 MS patients and 272 control subjects in Tasmania, the risk of MS was found to be lower in those who in their childhood had been exposed to sunlight during their holidays and weekends than in those who had not benefited from such exposure (P < 0.01), a finding that was also correlated with the degree of actinic damage to their skin (an indicator of cumulative sun exposure, measured on the back of the hand) (P < 0.01) [118]. A similar result was found for the risk of CIS in Australia, which was correlated with past exposure to sun, actinic damage and latitude [72]. Inverse correlations between the risk of MS and past exposure to sunlight have also been reported in the USA [2], Norway [59] Canada [101] and Australia [26], with, furthermore, probable genetic regulation in the latter case. Lastly, in the USA, based on 79 monozygotic pairs of twins, one in each pair having MS and the other not and both twins being different in terms of exposure to the sun during their childhood (assessed on the basis of nine different activities implying sun exposure), it was shown that the twins who did not have MS were also those who had had significantly higher past exposure to the sun [57]. This result is particularly important because each pair of twins had the same genetic material and, apart from exposure to the sun, identical environmental constants (residence, food, etc.). In sum, the level of past exposure to the sun does indeed seem to play a role in the risk of MS.

To date, only one study has directly analysed the risk of MS based on the serum level of 25-hydroxyvitamin D in normal subjects before MS occurred in some of them. The study, which appears methodologically sound, is therefore extremely important since it now indicates a direct link between the level of vitamin D circulating in the blood and the disease, without having to rely on the effect of latitude or sun exposure [81]. The study included 257 cases of MS that occurred in young American soldiers (148 white and 77 black), and 514 control subjects, who had given at least one serum sample before the onset of any neurological symptoms during their military service. For the white subjects, 5 subgroups were defined according to the serum level of vitamin D: the subgroup with the highest—in fact normal—levels of vitamin D (between 99 and 152 nmol/l) had a significantly lower risk of MS than the subgroup with the lowest levels (between 15 and 63 nmol/l) (P < 0.01); for the less numerous black subjects, the results were not significant between the three defined subgroups, but the serum levels were much lower (not exceeding 99 nmol/l) with, therefore, a much smaller range of serum levels between the different subgroups than for the white subjects. It was concluded in this study that a relatively high serum vitamin D level (though still within the normal range) is associated with a lower risk of MS in white subjects. On the basis of this study, Ascherio and Munger [6] have estimated that almost three-quarters of MS cases might be avoided if the serum levels of vitamin D were maintained above 100 nmol/l during childhood and adolescence in the general population. Furthermore, the fact that there is a correlation between the mean levels of vitamin D in the general population in regions of France and the prevalence of MS in these regions (Fig. 3) establishes an additional link between serum vitamin D level and the risk of MS. Lastly, we must also cite studies where the supposed high oral intake of vitamin D, in the form of oily fish [58, 59] or vitamin supplements [80], decreased the risk of MS. The overall conclusion of these epidemiological studies is that it seems at least possible and already likely (see above) that there are links of causality between latitude, exposure to sun, serum vitamin D level and the risk of MS, in other words that the last link in this chain of influences, i.e. the one that is essential since it directly relates the organism to variations in the external environment, is vitamin D. This point of view, already proposed more than 35 years ago [35], now appears to be supported by numerous convergent experimental and epidemiological findings.

In a relatively old American study, it was shown that the mean level of 25-hydroxyvitamin D was very low (42 nmol/l) in 80 hospitalised female MS patients (mean EDSS: 7.2) [87], but the very lack of mobility of these patients (virtually no longer going outdoors) could in large part explain this result. Of far greater interest is a recent Finnish study on a group of 40 patients at the onset of MS (mean EDSS: 1.5) in whom serum levels were significantly reduced in summer (55 nmol/l) compared to a control group (80 nmol/l) [105]. Both patients and control subjects had low levels in winter (between 40 and 50 nmol/l), without any marked difference, but we may consider that such low levels in winter are abnormal and prejudicial to all. Furthermore, in three different studies, patients had significantly lower levels during relapses than at other times [24, 105, 106]. In an Irish study, no differences were observed between the serum levels of patients with MS and control subjects, but the two groups were recruited in winter, with serum levels that were slightly low (67 and 69 nmol/l) compared to the normal range [8]. In several other studies, serum vitamin D levels in MS patients were significantly reduced when compared to control subjects [24, 42, 73, 120] or to internationally accepted norms [74], or an inverse correlation was found between vitamin D level and either the EDSS [63, 103] or the relapse rate [114]. Other studies raised the question of a genetic regulation of vitamin D metabolism in patients with MS [89, 104], in particular in the HLA system [94], and of an influence of a vitamin D receptor gene polymorphism on disability [75, 111]. Lastly, as an illustration of vitamin D level in MS, out of 167 consecutive outpatients with a relapsing-remitting form of MS referred to a Parisian hospital between June 2008 and February 2009, 83% were found to have a vitamin D insufficiency (with levels of 25-hydroxyvitamin D below 75 nmol/l), with 17% in a state of deficiency (<25 nmol/l), and 95% did not reach the currently recommended level of 100 nmol/l, with a general mean of 52 nmol/l (Fig. 4, unpublished personal data). These different studies, which of course need to be confirmed, nevertheless already strongly suggest that most patients with MS have serum vitamin D levels that are too low when compared to the current norms. It should also be added that a good proportion of MS patients with vitamin D insufficiency have little or no disability and that one can (1) neither attribute the vitamin D insufficiency to a reduced mobility in these patients, (2) nor roughly predict the vitamin D status of individuals on the basis of their disability. It is nevertheless true that disability, by reducing the opportunities for going outdoors, as well as systematically avoiding heat—and therefore the sun—in a good many symptomatic MS patients (able or disabled) [100] are factors that can exacerbate an initial hypovitaminosis D. Accordingly, although it may be still difficult to accept that a major and previously unsuspected problem of hypovitaminosis D exists in MS patients, it should nevertheless be realised that these patients are at least as lacking in vitamin D as the general population, and maybe even a little more, although this latter point requires further studies.

Studies on the use of vitamin D in MS are still rare and limited in scope. After a two-year course of treatment with vitamin D (5,000 IU/d in the form of cod liver oil), 10 patients with MS had a 60% reduction in the predicted number of relapses, but there was no control group [36]. In another uncontrolled study, 15 patients who received 100 IU/d for 48 weeks experienced a 50% reduction in relapses [131]. In a study on 39 patients with MS (17 treated with 1,000 IU/d of vitamin D3 (cholecalciferol) for 6 months and 22 control subjects), the treated patients had a significantly increased level of TGF-β1, an anti-inflammatory cytokine affected by vitamin D in EAE [73]. Lastly, a Canadian team recently demonstrated that the use of high doses of vitamin D3 (cholecalciferol, 14,000 IU/d) during a long period (6 months–1 year) did not induce hypercalcaemia or notable side-effects, despite serum vitamin D levels of nearly 400 nmol/l [61]. After 1 year of such treatment, a 41% reduction in the number of relapses and a significant improvement in EDSS was observed in the treated patients (n = 25 vs. 24 untreated patients) [13]. The results of these methodologically weak studies do not of course allow us to draw any definite conclusions. However, taking into account the full scientific context, they are encouraging and provide ample justification for much more extensive therapeutic trials (phase II or phase III). The appropriate vitamin D doses will, however, have to be determined, since the daily dosages in the aforementioned four studies were 100, 1000, 5,000 and 14,000 IU/d, a situation that raises the perplexing question of the useful therapeutic dosage.