After having a significant impact on rickets followed by a period of silence, vitamin D deficiency in humans is again being paid increasing attention and is currently considered a worldwide pandemic.1–3 According to a recent report from the National Center for Health Statistics of the United States covering the 2001–2006 period, from 32% to 46% of the US population had serum 25 (OH) D3 levels less than 20ng/mL, and 8% values lower than 12ng/mL.4

Vitamin D is known to play a role in bone metabolism, being important for maintaining calcium homeostasis, ensuring its physiological absorption from the bowel.1 The discovery of the vitamin D nuclear receptor (VDR), ubiquitously expressed in almost all body cells, including immune, vascular and myocardial cells, suggested an implication of effects mediated by vitamin D in several systems other than musculoskeletal tissues2 (Fig. 1).

Figure 1.

Action sites of vitamin D. Note extraosseous effects. ©Modified from Hossein-Nezhad and Holick.99

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This led to comprehensive research into vitamin D as a factor with an influence on the pathogenesis of various non-skeletal acute and chronic diseases such as infection, cancer, psychiatric disorders, and autoimmune diseases, as well as cardiovascular risk factors such as high blood pressure, dyslipidemia, diabetes mellitus, obesity, and atherosclerosis.4–6

Cardiovascular (CV) risk factors, and cardiovascular diseases, including myocardial infarction, coronary artery disease and stroke, are recognized as the most common diseases and represent the leading causes of death worldwide, particularly in Western countries.7 In Mexico, there has been a clear increase in cardiovascular risk factors in the past two decades, and the same pandemic has occurred elsewhere in Latin America. This emphasizes the importance of clarifying the role of vitamin D in the context of cardiovascular diseases and their most common risk factors.

It has recently been reported that coronary artery disease, especially myocardial infarction and heart failure, affects 7.9 and 5.7 million adults in the United States respectively.8,9 Left ventricular abnormalities related to remodeling (progressive dilation of the predominant chamber, fibrosis, and systolic/diastolic dysfunction) and heart failure often complicate an acute myocardial infarction.10,11 Recent data suggest that the prevalence of ventricular dysfunction related to myocardial infarction and heart failure is associated with decreased vitamin D levels.11 Thus, increasing attention is being paid to the role of vitamin D deficiency as a risk marker in the development of heart failure.

As early as in 1981, a study had reported seasonal variations in CV mortality and the potential positive effects of protection from UVB (ultraviolet B) radiation on CV risk.8 The association of vitamin D with CV risk factors and their associated diseases has been widely investigated in recent years. Multiple observational studies, prospective meta-analyses, and some interventional studies have addressed the potential link with vitamin D deficiency.9–12

Patients with advanced heart failure are known to have significantly lower serum 25 (OH) D levels, an independent risk factor associated with poor clinical outcomes and prolonged decompensation of heart failure.7,13–15 VDR agonists such as calcitriol and its analogs, including doxercalciferol, have been developed to treat secondary hyperparathyroidism in chronic kidney disease,8 osteoporosis,11 and psoriasis.13

Researchers are currently developing another candidate as a selective and effective VDR agonist for treating vitamin D deficiency in heart failure and the phenotypes associated with dysfunction in the renin–angiotensin–aldosterone system (RAAS).15

One of our central objectives is to lend scientific support to the urgent need to understand the prevalence of vitamin D deficiency in countries such as Mexico and elsewhere in Latin America, where the pandemic of non-communicable chronic diseases is the main factor responsible for overall morbidity and mortality.16

Basic vitamin D metabolism

Vitamin D3 is a steroid prohormone mainly derived from the synthesis induced by UVB radiation on dehydrocholesterol in the skin (Fig. 2).

Figure 2.

Schematic representation of vitamin D synthesis and metabolism for skeletal and non-skeletal functions. 1-OHase: 25 (OH) D 1α-hydroxylase; 24-OHasa: 24 hydroxylase; 25(OH)D: 25-hydroxyvitamin D; 1,25(OH)2D: 1,25-dihydroxyvitamin D; CaBP: calcium binding protein; DBP: vitamin D binding protein; ECaC: epithelial calcium channel; FGF-23: fibroblast growth factor-23; PTH: parathyroid hormone; RANK: receptor activator of nuclear factor kB (NFkB); RANKL: receptor activator of NFkB ligand; RXR: retinoic acid receptor; TLR2/1: toll-like receptor 2/1; VDR: vitamin D receptor; vitamin D: vitamin D2 or D3. ©Copyright Holick MF, 2013, coauthor of this study.99

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Endogenous synthesis is the main source of vitamin D in the body and accounts for approximately 80% of the vitamin. After synthesis in the skin or absorption from diet, vitamin D is transported by a specific binding protein to the liver, where it is hydroxylated to 25-hydroxyvitamin D. This inactive form is the main metabolite circulating in blood, and is also used to determine vitamin D status.1–3

25-Hydroxyvitamin D is hydroxylated by the enzyme 1α-hydroxylase (1α-OHase) to its most active metabolite, 1α-25 (OH)2 D3, mainly in the kidneys. From this 1α-hydroxylation it is known that it can also be activated by extrarenal 1α-hydroxylation throughout the body13,14 (Fig. 2). This has led to the assumption that vitamin D plays a wider role in overall health, including tissues beyond the musculoskeletal system such as the heart and blood vessels.15–17

Prevalence of vitamin D deficiency

Vitamin D deficiency and insufficiency are highly prevalent, as is shown by the fact that more than half of the population worldwide has levels lower than 30ng/mL13,16 (Fig. 3). However, the prevalence of the deficiency in countries such as Mexico is not known, which should alert the medical community. There are various risk factors for vitamin D deficiency that should always be taken into account, including age, female sex, pigmentation in darker skin, decreased sun exposure, seasonal variation and distance from the Equator. Special mention should be made of air pollution.17,18 Studies on the impact of pollution on vitamin D should be conducted in cities with high pollution levels because of their unique population and geodemographic conditions.11,19–21

Figure 3.

Reported prevalence of vitamin D deficiency, defined as 25-hydroxyvitamin D levels less than 20ng/mL in the worldwide population of pregnant women and the general population. Note the lack of information for Latin America. To convert 25 (OH) D levels to nmol/L, multiply by 2496. ©Copyright Holick 2013, reproduced with permission.99

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Apart from its traditional role as a modulator of calcium metabolism and bone homeostasis, vitamin D has been shown to have potent anti-inflammatory effects. Because of this, it has been considered as adjuvant therapy for many chronic diseases such as asthma, arthritis, prostate cancer and psoriasis, amongst others.4,22,23 A variety of both pro-inflammatory and anti-inflammatory effects of vitamin D had previously been reported.24,25 It has also been shown that vitamin D may directly induce the production of important antimicrobial peptides such as cathelicidins and defensin β4 in monocytes/macrophages and in human epithelial cells13,26 (Fig. 4).

Figure 4.

Vitamin D stimulates the production of cathelicidins and defensin B.

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1,25-(OH)2 D3 has been shown to have antiproliferative and proapoptotic activity in tumor cells due to the induction of the cyclin-dependent kinase inhibitors p27Kip1 and p21Waf/Cip1 and the inhibition of c-Myc and antiapoptotics such as Bcl-2.23 Moreover, vitamin D was shown to suppress the action pathways of prostaglandins in tumor cell lines through the inhibition of cyclooxygenase-2 production and the stimulation of 15-hydroxyprostaglandin production by the cells.23

Vitamin D has also been shown to interfere with the activation and signaling of nuclear factor (NF) kB by increasing the expression of IκBα in activated cells, and to interfere with the nuclear translocation of subunits of NF-κB.4

It has also been reported that vitamin D may influence dendritic cell maturation and function.27 Several studies have shown the ability of vitamin D to modulate the population and role of FOXP3-positive regulatory T cells and the production of IL-1027 (Fig. 5).

Figure 5.

Effects of vitamin D on immune response.

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The interaction of peroxisome proliferator-activated receptors (PPARs) and the VDR has been widely studied, because they both form heterodimers with LXR. The potential modulation of PPARy activity has been implicated in many metabolic processes, especially in lipids and in mechanisms for insulin release from β cells in the islets of Langerhans. Additional results of this transcriptome have shown that vitamin D regulates proadipogenic PPARy in activated macrophages. PPARy agonists reverse the antiadipogenic and antimicrobial effects attributed to the vitamin D receptor, which suggests a link between the VDR and signaling in the regulation of processes of two-directional functions between vitamin D and PPARy.28

As previously noted, decreased vitamin D levels have been associated with a greater incidence of cardiovascular events.10,55,75–77 Even asymptomatic coronary artery disease is associated with lower vitamin D levels in high-risk patients such as patients with T2DM (adjusted OR 2.9 [95% CI 2.0–7.0]), as reported in a recent observational study.78 Thus, vitamin D deficiency has been associated with an increased risk of myocardial infarction and a significant inverse relationship between 25 (OH) D and matrix metalloproteinase-9, a marker of myocardial infarction after myocardial remodeling.79,80

Vitamin D levels also appear to predict the risk of adverse events after acute infarction and cardiac surgery, thus suggesting a greater risk for subjects with very low vitamin D levels, as reported in recent publications.81,82

Data from prospective observational studies suggest that low vitamin D levels are a risk factor for stroke83–85. In a meta-analysis of seven studies comprising 47,809 subjects and 926 strokes, the risk of cerebrovascular disease was significantly lower in subjects with higher 25 (OH) D levels as compared to those with inadequate vitamin D levels.84

Other authors investigated 19 studies comprising 65,994 patients and 6123 strokes and found that the lower the 25 (OH) D levels, the greater the risk (12). It should be noted, however, that not all individual studies showed a significant association between low 25 (OH) D levels and a greater risk of cardiovascular disease.86

When all the above-mentioned studies are reviewed, confounding factors such as decreased mobility in patients with chronic diseases should be carefully weighted. Other confounding factors such as age or obesity rate, as well as PTH, renin, calcium, and phosphorus, cannot be completely ruled out as long as they are included as potential confounding factors in most analyses.15,87

Some small, controlled clinical trials reported mixed vitamin D results in cardiovascular events,34,88 while mention should be made of some meta-analyses of these controlled clinical trials that found no significant trends in CV event reduction in patients who received vitamin D supplements as compared to placebo.89,90

It should be noted that vitamin D supplementation was combined with calcium supplementation, and interpretation of the results of controlled clinical trials is therefore difficult, especially when we know that calcium intake may be associated with greater cardiovascular risk, as suggested by a previous meta-analysis.90–93

Based on the evidence currently available in the literature, it may be concluded that vitamin D deficiency is an independent cardiovascular risk factor that is associated with a greater risk of cardiovascular events. It is not clear, however, if these associations are causal in nature. Vitamin D should not be used to treat chronic diseases. It may be of help, but that is all. However, it appears plausible to take vitamin D deficiency as a very relevant marker of poor health, especially in patients with chronic diseases, including cardiovascular diseases and subjects with greater cardiovascular risk, so that, in this way, vitamin D may have a direct impact on cardiovascular results.94

Despite these conflicting results, it is quite clear that vitamin D supplements have significant benefits in healthy populations, and also in patients with various comorbidities, particularly as regards prevention. It should be noted that most clinical studies have shown that the most beneficial effects of vitamin D supplementation occur in patients with very low 25 (OH) D levels. Such patients appear to have a greater risk of suffering cardiovascular diseases.11,12,22,23,62,95

Large scale studies are ongoing, including a study of 1000 patients with heart failure in Germany, another study assessing vitamin D in more than 5000 subjects in New Zealand, and a final study (the VITAL trial) using vitamin D and omega-3 to assess cardiovascular mortality and cancer in more than 20,000 US adults with no cancer or cardiovascular diseases at study start.96–98

Vitamin D deficiency has multiple causes, and affects not only the inhabitants of countries at latitudes above 35°–40°, where there are no ultraviolet B rays for a good part of the year, but also the inhabitants of tropical countries, people with darker skin, obese subjects, and the elderly. Other causes include pollution in big cities, as in Mexico and elsewhere, which decreases ultraviolet radiation on the skin, and clothes and sun protectors, which reduce the capacity of the skin to synthesize vitamin D.

It may thus be concluded that vitamin D deficiency is a potential independent cardiovascular risk factor and is involved in immunomodulation events which are extremely significant for inflammation and in the processes that accelerate cell proliferation (cancer). It also participates actively in the stimulation of the release of substances with antibacterial properties, cathelicidins, and defensin B4.

Crossed communication between vitamin D receptors and other LXR heterodimers such as PPARy appears to determine significant functions in lipid metabolism and insulin release, and also an indirect protective effect of β cells of the islets of Langerhans. The cumulative evidence suggests a potential role of vitamin D in heart failure.

Mexico and other countries in Latin America urgently need adequate assessment of the prevalence of vitamin D deficiency and its association with the risk of chronic diseases and cardiovascular risk, but especially of the role of vitamin D in the prevention of such conditions. 25 (OH) D levels are already a potential risk marker of great value in cardiology, but specific randomized clinical trials, some of which are ongoing, are required to ascertain if vitamin D supplementation may significantly increase cardiovascular outcomes. However, vitamin D should not be considered as a mainstay treatment for chronic diseases.

The authors state that they have no conflicts of interest.