Abstract
Known for its ability to enhance the performance of the immune system, preclude microbial infections, and reduce susceptibility to influenza, Vitamin D (or 1,25-dihydroxyvitamin D (1,25(OH)2D) as the active form) has garnered a positive reputation in the management of COVID-19 for some time. Its deficiency is statistically correlated with infection of the disease, as well as disease severity and fatalities. There have been suggestions that Vitamin D supplements could either prevent the contraction of SARS-CoV-2, the coronavirus which causes the disease or alleviate the symptoms of the disease. Indeed, data have established a relationship between Vitamin D supplementation and the severity of respiratory illnesses, with some assays indicating optimistic results in COVID-19 patients who were supplemented with the vitamin. Accordingly, a great deal of research and efforts have been put into investigating the physiological mechanisms in the human body attributable to the vitamin’s reputation against the coronavirus. Combined with what was already discovered before the advent of SARS-CoV-2, a great amount of knowledge has consequently now been unveiled. Via regulation of various pathways, 1,25(OH)2D promotes the production of antimicrobial peptides, autophagy, as well as integrity and impermeability of cellular junctions against pathogens. Moreover, it mitigates the consequences of SARS-CoV-2 infection, such as cytokine storm (through immunomodulation of T cell differentiation pathways) and lung injury (through stimulation of the Angiotensin-Converting Enzyme 2 (ACE2) and manipulation of the Renin-Angiotensin System (RAS)). Nevertheless, Vitamin D deficiency still plagues the global population across all age groups, possibly contributing to the heightened global exposure to the coronavirus. With the COVID-19 pandemic inexorably raging on with no prospect of termination observable in the foreseeable future, this review article provides a concise yet thorough insight into the vast knowledge which could illuminate the significance of Vitamin D amidst the current predicament experienced by mankind, as well as instigate further curiosity and ignite further investigations into the role of vitamins, such as Vitamin D, as a safeguard against SARS-CoV-2.
Background
The outbreak of the Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2), which causes the Coronavirus Disease 2019 (COVID-19), has engendered a global pandemic placing a great toll upon humanity1. Consequently, there has been an astronomical amount of interest in any available means to alleviate such a toll on science and medical communities. One of those means happens to be the use of Vitamin D.
Known otherwise as Calcitriol or 1,25-dihydroxycholecalciferol, Vitamin D is a steroid hormone derived from dietary intake or endogenous synthesis, conditional upon exposure to sunlight ultraviolet radiation2. Past studies have established it as an integral agent in the functioning of the human immune system with the roles of immunomodulation and promotion of antimicrobial peptide expression3, 4, 5, 6, 7, 8. Data have also indicated a link between its insufficiency or deficiency and vulnerability to infections, especially in the respiratory tract9, 10, 11. For this reason, intense research has been undertaken to shed light on the relevance of Vitamin D amidst the ongoing COVID-19 pandemic and to investigate the possible benefits of its supplementation. The results were promising; both statistical and clinical studies discovered a correlation between low vitamin D levels and increased COVID-19 risk, as well as infection severity and mortality12, 13, 14, 15, 16, 17. In conjunction with knowledge from past research, a notion has been developed that the correlation is due to the vitamin’s promotive role in the secretion of such antimicrobial peptides as β-defensin 2 (BD2) and cathelicidins, which not only act to eradicate microbes themselves but also help in the recruitment of cells in the human innate immune system, the autophagy of virus-borne cells, and the maintenance of cellular junctions, all of which are believed to help eradicate SARS-CoV-2 from the bodies of the afflicted2. The vitamin’s anti-inflammatory property is also accredited to suppressing the adaptive immune system’s overaction that could entail a cytokine storm, which is accountable for symptoms, deterioration, and eventual fatality in multifarious cases15.
Throughout this review article, the roles and mechanisms of Vitamin D are assiduously examined, using available data from apposite studies conducted hitherto that converged to provide a basis for the article's summarization. With vitamin D deficiency remaining a pre-eminent medical condition extensively affecting a sizeable portion of the global population18, the ultimate purpose is to highlight the significance of the steroidal vitamin. The use of vitamin D has heightened in the wake of the Coronavirus outbreak and reminds the science and medical communities, as well as the general populace, of its potential efficacy in this grueling pandemic.
Vitamin D and the Immune System
Apart from its functions in calcium homeostasis and the maintenance of the skeletal system, vitamin D has played a critical role in the human immune system. Receptors for its active form, 1,25-dihydroxyvitamin D (1,25(OH)2D), have been found in cells of the immune system, including B cells, T cells, and such antigen-presenting cells (APCs) as macrophages and dendritic cells, which have the 1α-hydroxylase enzyme (CYP27B1) that synthesizes Vitamin D from its precursor, 25-hydroxyvitamin D (25-OHD)3, 1. Strikingly, such a synthesis is entirely independent of regulation by the Parathyroid Hormone (PTH), inducible by cytokines, and ultimately regulated by the abundance of 25-OHD, which makes the CYP27B1 of immune cells exclusively dissimilar to its renal counterpart. The availability of the receptors (Vitamin D Receptors; VDR) and CYP27B1 in cells of the immune system allows them to generate active Vitamin D autonomously and to utilize it instantaneously. Such a provision suggests an autocrine activity of Vitamin D in the immunological sphere and its overall role in the body’s defense mechanisms. Moreover, CYP27B1 has also been found in epithelial cells, which constitutes the first line of defense and plays a crucial role in mediating local immune responses, including instigating inflammation and recruiting immune cells via cytokine and chemokine molecules19. Accordingly, a conceptualization about the immunological functions of the steroidal hormones has taken root, which has helped to explicate the correlation between low serum 25-OHD levels and proneness to infections, as demonstrated by multiple studies in the past20, 21, 22, 23, 24, 25.
Role of Vitamin D in Antiviral Mechanisms
As mentioned previously, the coexistence of CYP27B1 and VDRs in cells of the immune system is part of an autocrine mechanism for defense against pathogens. One way such a mechanism acts is by promoting the secretion of antimicrobial peptides like β-defensin 2 (BD2) and cathelicidins26. For instance, the complex between 1,25(OH)2D and VDR can bind with the promoter of the cathelicidin gene, expediting the transcription process and expanding the number of cathelicidins available for antimicrobial activities27, 28. This capability of the vitamin was proven in a previous study which found a superior level of cathelicidin expression in individuals with high serum 25-OHD levels29 and found to be emulated in lung epithelial cells30.
When released, cathelicidins can either directly extinguish pathogens of sundry sorts or neutralize the toxins, thus performing an immeasurably vital task in innate immunity31. In viral infections, the antimicrobial peptide is efficacious at combating viruses and curtailing their replications32, 33, 34, 35. This particular ability is also seen with BD-2, which could also stimulate the secretion and action of cytokines and chemokines responsible for the recruitment of immune cells to the site of infection36, 37, 38, 39. Together, BD-2 and cathelicidins are potent tools of the body to thwart pathogens and preclude the dilapidation of illness.
Interestingly, the expression of both the CYP27B1 enzyme and VDRs, or more obliquely the amount of 1,25(OH)2D endogenously synthesized by immune cells, is influenced by the availability of pathogens, or more accurately, the abundance of Pattern Recognition Receptors (PRRs) that bind with them40, 41. Such an arrangement enables the immune cells to ratchet up their secretion of antimicrobial peptides upon detection of the pathogens they are meant to eliminate. However, it is not the only Vitamin D-related innate defense mechanism the human body employs when menaced by viruses.
One of the most rudimentary apparatuses in the body’s defense against any pathogen is barriers, which are principally upheld by cellular junctions—especially those of the epithelia—where Vitamin D wields excellent relevance. The 1,25(OH)2D/VDR complex is capable of activating multiple signaling pathways responsible for the regulation of junction proteins and conferring structural integrity and functionality (such as in transport) to tissues42. To elaborate, VDRs have been shown to bind with the promoter sequence for the genes of proteins in the Claudin family which are essential to tight junctions and regulate their production43, 44, 45. There have also been indications that they are involved in regulating Occludin and ZO-1 proteins, which are integral to the junctions46, 47. For SARS-CoV-2, a virus that targets the respiratory system, it could be positively impacted by the modus operandi of Vitamin D, which has been shown to minimize lung permeability, strengthen pulmonary epithelial barriers against pathogenic invaders, and reduce the vulnerability to respiratory diseases48, 49.
Additionally, Vitamin D can also induce the procedures of autophagy, which is undertaken in cells infected with the pathogen and in cancerous cells50. This could be done through the upregulation of Beclin1, which can account for autophagy upon binding with class III phosphatidylinositol 3-kinase, or the downregulation of mammalian target of rapamycin (mTOR), which acts at various steps of the autophagy pathway to inhibit the process of cellular self-devouring51. As autophagy proceeds in a virus-borne cell, viral particles are bound for lysosomal degradation and antigen presentation, which would kickstart the type I Interferon (INF) antiviral pathway, thereby repressing viral replication and pathogenesis52, 53. The entirety of these factors above contributes to achieving the purpose of subjugating viral invaders in the human body.
Vitamin D’s Immunomodulatory Role Against Cytokine Storm
While the SARS-CoV-2 virus itself can adversely affect the afflicted body in various ways, perhaps more concerning and threatening are the body’s own mechanisms in tackling it. Importantly, an extravagance in inflammatory responses embodied by the “cytokine storm” has been associated with the severity of COVID-19 and its associated mortality54, 55, 56, 57. It has also been reported as a chief cause of fatality for the Middle East Respiratory Syndrome (MERS), the early 2000s Severe Acute Respiratory Syndrome (SARS), and influenza, in general58.
Conventionally, a cytokine storm, or even a proportionate release of cytokines, starts with antigen presentation, which leads to the activation of cells in both the immunological domain and the surrounding tissues. This triggers the secretion of such pro-inflammatory signal molecules as Interleukin 1 (IL-1), Interleukin 6 (IL-6), Interleukin 8 (IL-8), Interleukin 10 (IL-10), Interferon Gamma (IFNγ), and Tumor Necrosis Factor Alpha (TNF-α)59. The secretions of these molecules proceed in a positive feedback loop60, and the higher their serum levels are, the more lung inflammation and damage they are accountable for61, 62. This can be explicated as the cytokines attract and activate immune cells like macrophages and neutrophils, which are then prompted to release leukotrienes and reactive oxygen species (ROS) in an attempt to destroy pathogens that unfortunately entail collateral damage upon surrounding tissues63. In the case of SARS-CoV-2 in the respiratory tract, such tissues are those of the alveoli and the encompassing capillaries, the destruction of which could result in acute lung injury (ALI) or, worse, the deadly acute respiratory distress syndrome (ARDS)64, 65. Moreover, activated neutrophils can also deploy their intracellular genetic material to set up neutrophil extracellular traps (NETs) designed to ensnare pathogenic intruders in an exorbitant amount in the occurrence of a cytokine storm, leading to the occlusion of blood vessels called “immunothrombosis”66.
The entirety of this constitutes the pathogenesis of COVID-19 and presents a distinct case as to the disease’s lethal quality. Intriguingly, it is also subject to the influence of Vitamin D, whose manifold functions include being an immunomodulator, among other functions7.
Understanding the immunomodulatory role of steroidal vitamin, one can experience insight into adaptive immunity and the inflammatory pathway. Typically, adaptive immunological processes pertaining to this context begin with antigen presentation by APCs to naïve helper T cells, a process that activates them via the interaction between a T-cell receptor (TCR), a CD4 glycoprotein, and an antigen-MHC II complex (Class II Major Histocompatibility Complex)67. Activated helpers T cells can then differentiate into either type I helper T cells (Th1), majorly involving Interleukin 12 (IL-12)68, or type II helper T cells (Th2), notedly with the signaling of Interleukin 4 (IL-4)69, which promote cellular and humoral immune responses, respectively. For the former, IFNγ is secreted to promote inflammatory responses that incorporate the release of pro-inflammatory cytokines, whereas, for the latter, IL-4 and Interleukin 5 (IL-5) are secreted to activate antibody production by B lymphocytes70, 71, 72, 73. A homeostatic mechanism has been found to exist between the two; a comparative increase in the Th1 pathway can suppress the Th2 pathway, and vice versa74, 75.
As previously mentioned, the cytokine storm, an excessive release of pro-inflammatory cytokines, is harmful and often contributes to deterioration and death. Therefore, one would surmise that a disproportionate Th1 inflammatory response and an accompanying skewness in the Th1/Th2 ratio could potentially entail a lethal or, at least, devastating cytokine storm54, 76; this is where Vitamin D’s immunomodulatory role becomes highly relevant.
According to research data, 1,25(OH)2D promotes the differentiation of naïve T cells into Th1 cells via increases in the amounts of GATA-3 and STAT6, which are transcription factors integral to the differentiation pathway77. Furthermore, the active steroid also inhibits IFNγ release while increasing IL-4 secretion78. Both of these effects contribute to the shift in the direction of T cells differentiation towards Th2, decreasing the amount of both Th1 cells and the potentially problematic pro-inflammatory cytokines they produce79. Moreover, 1,25(OH)2D can also induce the differentiation of naïve T cells into regulatory T cells (Treg) responsible for the restraint of Th1 cells either by upregulating Foxp3, a crucial protein in the differentiation process or by manipulating with a cluster of differentiation (CD) molecules on the surface of dendritic cells, one of whose functions is to foster the development of Tregs80, 81. The totality of this helps to modulate the inflammatory pathway and safeguard the body against disease pathologies82.
Vitamin D and the Renin-Angiotensin Axis
One of the most critical reasons why the Renin-Angiotensin System (RAS) bears so much relevance in the topic of vitamin D is that COVID-19 pivots around the SARS-CoV-2’s infection mechanism.
Typically, the RAS acts to maintain the homeostasis of blood pressure, as well as blood electrolytes83. Its ultimate and most bioactive effector, the octapeptide Angiotensin II (Ang-II), usually binds with type I angiotensin receptors (AT1Rs) to attain the goal of increasing BP through vasoconstriction and the secretion of Aldosterone (which stimulates renal Na+ absorption and thus more water retention). However, the binding can also have adverse effects as it promotes inflammation, platelet aggregation, production of mitotic agents, and ROS synthesis (which diminishes the availability of nitric oxide, upon which the functionality of endothelial cells is dependent)84. These effects can morph into deleterious conditions, such as thrombosis, fibrosis, oxidative stress, and endothelial dysfunction84, 85.
Alternatively, Ang-II can also interact with Angiotensin-converting Enzyme 2 (ACE2), which cleaves away the phenylalanine at its carboxy terminus, turning it into Angiotensin–(1-7), which can also be produced from the sequential cleavages of Ang-II’s precursor, the decapeptide Angiotensin I (Ang-I), by Angiotensin-converting Enzyme (ACE) and ACE2, respectively83. Angiotensin-(1-7) then binds with the G protein-coupled receptor (GPCR) Mas, leading to effects opposite to those stemming from the interaction between Ang-II and AT1R—vasodilation, anti-fibrosis, anti-inflammation, and vascular protection, just to name a few86.
Unfortunately, SARS-CoV-2’s mechanism of entry into human cells happens to hinge upon ACE2. After the human serine-protease TMPRSS2 enzyme primes its spike proteins, they bind with ACE2 on the human cell membrane, beginning entry by receptor-mediated endocytosis87. As the virus proliferates, the binding of ACE2 becomes more extensive, and the availability of ACE2 plunges in the short term, ensured by the enzyme’s downregulation in the long term, decreasing Ang-II's conversion into Angiotensin-(1-7)88. This shifts the balance of the RAS greatly in that less binding between Angiotensin-(1-7) and Mas would be incurred, whereas the binding between Ang-II and AT1R would be elevated89. These interactions prove to be of great detriment for COVID-19 patients. The former has been described to protect the body against pulmonary fibrosis, acute lung injury, and fibrosis90, 91. The latter is where Vitamin D has profound effects upon alleviating the consequences of SARS-CoV-2 infection.
The steroidal hormone has been indicated to increase the expression of ACE2 and ergo, the activity of the ACE2/Angiotensin-(1-7)/Mas axis92, 93. This consequently suppresses the potentially pernicious ACE/Ang-II/AT1R axis and moderates the body’s inflammatory response, palliating acute lung injury and precluding multiple organ damage that could be precipitated by COVID-1994, 95.
Vitamin D Supplementation Against COVID-19?
While the aforementioned association between Vitamin D deficiency and either risk of COVID-19 contraction or severe outcomes, corroborated by all the germane mechanisms detailed above, might tantalize one to believe that Vitamin D supplementation can translate into protection against SARS-CoV-2, the reality is yet too complex for such a straightforward notion.
However, data from some research studies seem to substantiate the notion. For example, a meta-analysis96 found lower intensive care unit (ICU) admissions in COVID-19 patients supplemented with Vitamin D. One study97 also observed a decrease in disease severity, mortality rate, and serum level of markers of inflammation in Vitamin D-supplemented patients. Moreover, another study98 reported that high-dose Vitamin D supplementation aided the body’s clearance of SARS-CoV-2 and helped mildly symptomatic and asymptomatic individuals infected with COVID-19 to become COVID-19-negative. These findings are in line with that of a preceding study99 which reported that Vitamin D supplementation helped protect against acute respiratory infections.
Nevertheless, the current evidence is insufficient to conclude that Vitamin D supplements are substantively helpful against COVID-19 or for suggesting Vitamin D supplementation as a hedge against the disease. Furthermore, some studies would digress from such a conclusion. One100, for instance, found no significant difference in the length of hospitalization between patients given Vitamin D supplements and those given placebo. Another study101, albeit not precisely concerning COVID-19, also reported no reduction in pneumonia risk and an even elevated risk of pneumonia recurrence from taking oral Vitamin D supplements. Due to this reason, there remains more investigations to be executed and queries to be answered.
Conclusions
Multiple clinical studies and circumstantial observations have correlated Vitamin D levels and COVID-19 infection, severity, and mortality. This correlation could be rationalized by an insight into the multi-faceted roles of Vitamin D in the physiology of the human immune and endocrine systems.
On the immunological side, the steroidal hormone’s active form, 1,25(OH)2D, can promote the secretion of antimicrobial peptides like Cathelicidins and BD-2, responsible for thwarting viral replication and achieving viral clearance. Vitamin D can also stimulate autophagy by upregulating Beclin1 and downregulating mTOR, leading to antigen presentation and subsequent activation of the type I INF antiviral pathway. It can also maintain cellular junctions, especially those in the respiratory epithelia, via regulation of Claudins, Occludin, and ZO-1, among a host of junction proteins, thus preserving the integrity of the body’s barriers and reducing their permeability against pathogens. Moreover, it is responsible for fostering naïve T cells into Th2 cells functioning in humoral immunity and inhibiting the inflammatory Th1 pathway, an immunomodulatory role that helps avert the calamitous cytokine storm. Meanwhile, on the endocrinological side, the vitamin can promote the activity of ACE2 and, thus, the binding between Angiotensin-(1-7) and Mas receptors, repressing that between Ang-II and AT1R could result in fibrosis and acute lung injury.
This whole prospective may appear promising and generate an incentive for Vitamin D supplementation as a protective measure against COVID-19. Yet, the current information pool is inadequate for one to suggest such a supplementation regimen. There remains a great deal of unclarity, and hence, a considerable necessity for even more thorough research in the future.
Abbreviations
1,25(OH)2D: 1,25-dihydroxyvitamin D
25-OHD: 25-hydroxyvitamin D
ACE2: Angiotensin-converting Enzyme 2
ACE: Angiotensin-converting Enzyme
ALI: Acute Lung Injury
Ang-II: Angiotensin II
APC: Antigen-presenting Cell
ARDS: Acute Respiratory Distress Syndrome
AT1R: Type I Angiotensin Receptor
BD-2: β-defensin 2
CD: Cluster of Differentiation
COVID-19: Coronavirus Disease 2019
CYP27B1: 1α-hydroxylase
GPCR: G protein-coupled receptor
IL-1: Interleukin 1
IL-4: Interleukin 4
IL-5: Interleukin 5
IL-6: Interleukin 6
IL-8: Interleukin 8
IL-10: Interleukin 10
IL-12: Interleukin 12
INF: Interferon
INF-γ: Interferon Gamma
MERS: Middle East Respiratory Syndrome
MHC II: Class II Major Histocompatibility Complex
mTOR: mammalian target of Rapamycin
NET: Neutrophil Extracellular Trap
PRR: Pattern Recognition Receptor
PTH: Parathyroid Hormone
RAS: Renin-Angiotensin System
ROS: Reactive Oxygen Species
SARS: Severe Acute Respiratory Syndrome
SARS-CoV-2: Severe Acute Respiratory Syndrome Coronavirus 2
TCR: T-cell Receptor
Th1: Type I Helper T cells
Th2: Type II Helper T cells
TNF-α: Tumor Necrosis Factor Alpha
Treg: Regulatory T cells
VDR: Vitamin D Receptor
Acknowledgments
None
Author’s contributions
Not applicable.
Funding
None
Availability of data and materials
Not applicable
Ethics approval and consent to participate
Not applicable
Consent for publication
Not applicable
Competing interests
The author declares that he/she has no competing interests.
References
-
Hu
B.,
Guo
H.,
Zhou
P.,
Shi
Z.L.,
Characteristics of SARS-CoV-2 and COVID-19. Nat Rev Microbiol.
2021;
19
(3)
:
141-54
.
View Article PubMed Google Scholar -
Ali
N.,
Role of vitamin D in preventing of COVID-19 infection, progression and severity. J Infect Public Health.
2020;
13
(10)
:
1373-80
.
View Article PubMed Google Scholar -
Aranow
C.,
Vitamin D and the immune system. J Investig Med.
2011;
59
(6)
:
881-6
.
View Article PubMed Google Scholar -
Prietl
B.,
Treiber
G.,
Pieber
T.R.,
Amrein
K.,
Vitamin D and immune function. Nutrients.
2013;
5
(7)
:
2502-21
.
View Article PubMed Google Scholar -
Bivona
G.,
Agnello
L.,
Ciaccio
M.,
The immunological implication of the new vitamin D metabolism. Cent Eur J Immunol.
2018;
43
(3)
:
331-4
.
View Article PubMed Google Scholar -
Martens
P.J.,
Gysemans
C.,
Verstuyf
A.,
Mathieu
A.C.,
Vitamin D's Effect on Immune Function. Nutrients.
2020;
12
(5)
:
1248
.
View Article PubMed Google Scholar -
Goldsmith
J.R.,
Vitamin D as an Immunomodulator: Risks with Deficiencies and Benefits of Supplementation. Healthcare (Basel).
2015;
3
(2)
:
219-32
.
View Article PubMed Google Scholar -
Youssef
D.A.,
Miller
C.W.,
El-Abbassi
A.M.,
Cutchins
D.C.,
Cutchins
C.,
Grant
W.B.,
Antimicrobial implications of vitamin D. Dermatoendocrinol.
2011;
3
(4)
:
220-9
.
View Article PubMed Google Scholar -
Gunville
C.F.,
Mourani
P.M.,
Ginde
A.A.,
The role of vitamin D in prevention and treatment of infection. Inflamm Allergy Drug Targets.
2013;
12
(4)
:
239-45
.
View Article PubMed Google Scholar -
Dankers
W.,
Colin
E.M.,
van Hamburg
J.P.,
Lubberts
E.,
Vitamin D in Autoimmunity: Molecular Mechanisms and Therapeutic Potential. Front Immunol.
2017;
7
:
697
.
View Article PubMed Google Scholar -
Infante
M.,
Ricordi
C.,
Sanchez
J.,
Clare-Salzler
M.J.,
Padilla
N.,
Fuenmayor
V.,
Influence of Vitamin D on Islet Autoimmunity and Beta-Cell Function in Type 1 Diabetes. Nutrients.
2019;
11
(9)
:
2185
.
View Article PubMed Google Scholar -
Meltzer
D.O.,
Best
T.J.,
Zhang
H.,
Vokes
T.,
Arora
V.,
Solway
J.,
Association of Vitamin D Deficiency and Treatment with COVID-19 Incidence. MedRxiv.
2020
.
View Article Google Scholar -
McCall
B.,
Vitamin D Deficiency in COVID-19 Quadrupled Death Rate [Internet]. Medscape. Medscape; 2020 [cited 2021Apr29]. Available from: https://www.medscape.com/viewarticle/942497.
.
-
Ahmad
A.,
Heumann
C.,
Ali
R.,
Oliver
T.,
Vitamin D levels in 19 European Countries & COVID-19 Mortality over 10 months. 2021.
.
-
Daneshkhah
A.,
Agrawal
V.,
Eshein
A.,
Subramanian
H.,
Roy
H.K.,
Backman
V.,
The Possible Role of Vitamin D in Suppressing Cytokine Storm and Associated Mortality in COVID-19 Patients. 2020.
.
-
Smet
D. De,
Smet
K. De,
Herroelen
P.,
Gryspeerdt
S.,
Martens
G.A.,
Vitamin D deficiency as risk factor for severe COVID-19: a convergence of two pandemics. MedRxiv.
2020
.
View Article Google Scholar -
Ilie
P.C.,
Stefanescu
S.,
Smith
L.,
The role of vitamin D in the prevention of coronavirus disease 2019 infection and mortality. Aging Clin Exp Res.
2020;
32
(7)
:
1195-8
.
View Article PubMed Google Scholar -
Hovsepian
S.,
Amini
M.,
Aminorroaya
A.,
Amini
P.,
Iraj
B.,
Prevalence of vitamin D deficiency among adult population of Isfahan City, Iran. J Health Popul Nutr.
2011;
29
(2)
:
149-55
.
View Article PubMed Google Scholar -
Hansdottir
S.,
Monick
M.M.,
Lovan
N.,
Powers
L.,
Gerke
A.,
Hunninghake
G.W.,
Vitamin D decreases respiratory syncytial virus induction of NF-kappaB-linked chemokines and cytokines in airway epithelium while maintaining the antiviral state. J Immunol.
2010;
184
(2)
:
965-74
.
View Article PubMed Google Scholar -
Ginde
A.A.,
Mansbach
J.M.,
Camargo
C.A.,
Association between serum 25-hydroxyvitamin D level and upper respiratory tract infection in the Third National Health and Nutrition Examination Survey. Arch Intern Med.
2009;
169
(4)
:
384-90
.
View Article PubMed Google Scholar -
Sabetta
J.R.,
DePetrillo
P.,
Cipriani
R.J.,
Smardin
J.,
Burns
L.A.,
Landry
M.L.,
Serum 25-hydroxyvitamin d and the incidence of acute viral respiratory tract infections in healthy adults. PLoS One.
2010;
5
(6)
:
e11088
.
View Article PubMed Google Scholar -
Laaksi
I.,
Ruohola
J.P.,
Tuohimaa
P.,
Auvinen
A.,
Haataja
R.,
Pihlajamäki
H.,
An association of serum vitamin D concentrations < 40 nmol/L with acute respiratory tract infection in young Finnish men. Am J Clin Nutr.
2007;
86
(3)
:
714-7
.
View Article PubMed Google Scholar -
Cannell
J.J.,
Vieth
R.,
Umhau
J.C.,
Holick
M.F.,
Grant
W.B.,
Madronich
S.,
Epidemic influenza and vitamin D. Epidemiol Infect.
2006;
134
(6)
:
1129-40
.
View Article PubMed Google Scholar -
Bodnar
L.M.,
Krohn
M.A.,
Simhan
H.N.,
Maternal vitamin D deficiency is associated with bacterial vaginosis in the first trimester of pregnancy. J Nutr.
2009;
139
(6)
:
1157-61
.
View Article PubMed Google Scholar -
Rodríguez
M.,
Daniels
B.,
Gunawardene
S.,
Robbins
G.K.,
High frequency of vitamin D deficiency in ambulatory HIV-Positive patients. AIDS Res Hum Retroviruses.
2009;
25
(1)
:
9-14
.
View Article PubMed Google Scholar -
Wang
T.T.,
Nestel
F.P.,
Bourdeau
V.,
Nagai
Y.,
Wang
Q.,
Liao
J.,
Cutting edge: 1,25-dihydroxyvitamin D3 is a direct inducer of antimicrobial peptide gene expression. J Immunol.
2004;
173
(5)
:
2909-12
.
View Article PubMed Google Scholar -
Yim
S.,
Dhawan
P.,
Ragunath
C.,
Christakos
S.,
Diamond
G.,
Induction of cathelicidin in normal and CF bronchial epithelial cells by 1,25-dihydroxyvitamin D(3). J Cyst Fibros.
2007;
6
(6)
:
403-10
.
View Article PubMed Google Scholar -
Bilezikian
J.P.,
Bikle
D.,
Hewison
M.,
Lazaretti-Castro
M.,
Formenti
A.M.,
Gupta
A.,
Mechanism in endocrinology: vitamin D and COVID-19. Eur J Endocrinol.
2020;
183
(5)
:
133-47
.
View Article PubMed Google Scholar -
Armas
L.A.,
Vitamin D, infections and immune-mediated diseases. Int J Clin Rheumatol.
2009;
4
(1)
:
89-103
.
View Article Google Scholar -
Hansdottir
S.,
Monick
M.M.,
Hinde
S.L.,
Lovan
N.,
Look
D.C.,
Hunninghake
G.W.,
Respiratory epithelial cells convert inactive vitamin D to its active form: potential effects on host defense. J Immunol.
2008;
181
(10)
:
7090-9
.
View Article PubMed Google Scholar -
Ramanathan
B.,
Davis
E.G.,
Ross
C.R.,
Blecha
F.,
Cathelicidins: microbicidal activity, mechanisms of action, and roles in innate immunity. Microbes Infect.
2002;
4
(3)
:
361-72
.
View Article PubMed Google Scholar -
Tripathi
S.,
Tecle
T.,
Verma
A.,
Crouch
E.,
White
M.,
Hartshorn
K.L.,
The human cathelicidin LL-37 inhibits influenza A viruses through a mechanism distinct from that of surfactant protein D or defensins. J Gen Virol.
2013;
94
(Pt 1)
:
40-9
.
View Article PubMed Google Scholar -
Sousa
F.H.,
Casanova
V.,
Findlay
F.,
Stevens
C.,
Svoboda
P.,
Pohl
J.,
Cathelicidins display conserved direct antiviral activity towards rhinovirus. Peptides.
2017;
95
:
76-83
.
View Article PubMed Google Scholar -
Barlow
P.G.,
Svoboda
P.,
Mackellar
A.,
Nash
A.A.,
York
I.A.,
Pohl
J.,
Antiviral activity and increased host defense against influenza infection elicited by the human cathelicidin LL-37. PLoS One.
2011;
6
(10)
:
e25333
.
View Article PubMed Google Scholar -
Barlow
P.G.,
Findlay
E.G.,
Currie
S.M.,
Davidson
D.J.,
Antiviral potential of cathelicidins. Future Microbiol.
2014;
9
(1)
:
55-73
.
View Article PubMed Google Scholar -
Selsted
M.E.,
Ouellette
A.J.,
Mammalian defensins in the antimicrobial immune response. Nat Immunol.
2005;
6
(6)
:
551-7
.
View Article PubMed Google Scholar -
Ganz
T.,
Defensins: antimicrobial peptides of innate immunity. Nat Rev Immunol.
2003;
3
(9)
:
710-20
.
View Article PubMed Google Scholar -
Hazlett
L.,
Wu
M.,
Defensins in innate immunity. Cell Tissue Res.
2011;
343
(1)
:
175-88
.
View Article PubMed Google Scholar -
Kim
J.,
Yang
Y.L.,
Jang
S.H.,
Jang
Y.S.,
Human β-defensin 2 plays a regulatory role in innate antiviral immunity and is capable of potentiating the induction of antigen-specific immunity. Virol J.
2018;
15
(1)
:
124
.
View Article PubMed Google Scholar -
Liu
P.T.,
Stenger
S.,
Li
H.,
Wenzel
L.,
Tan
B.H.,
Krutzik
S.R.,
Toll-like receptor triggering of a vitamin D-mediated human antimicrobial response. Science.
2006;
311
(5768)
:
1770-3
.
View Article PubMed Google Scholar -
Adams
J.S.,
Rafison
B.,
Witzel
S.,
Reyes
R.E.,
Shieh
A.,
Chun
R.,
Regulation of the extrarenal CYP27B1-hydroxylase. J Steroid Biochem Mol Biol.
2014;
144
:
22-7
.
View Article PubMed Google Scholar -
Zhang Y-guo
Wu S, Sun J. Vitamin D, vitamin D receptor and tissue barriers. Tissue Barriers.
2013;
1
(1)
.
-
Zhang
Y.G.,
Wu
S.,
Lu
R.,
Zhou
D.,
Zhou
J.,
Carmeliet
G.,
Tight junction CLDN2 gene is a direct target of the vitamin D receptor. Sci Rep.
2015;
5
(1)
:
10642
.
View Article PubMed Google Scholar -
Stio
M.,
Retico
L.,
Annese
V.,
Bonanomi
A.G.,
Vitamin D regulates the tight-junction protein expression in active ulcerative colitis. Scand J Gastroenterol.
2016;
51
(10)
:
1193-9
.
View Article PubMed Google Scholar -
Fujita
H.,
Sugimoto
K.,
Inatomi
S.,
Maeda
T.,
Osanai
M.,
Uchiyama
Y.,
Tight junction proteins claudin-2 and -12 are critical for vitamin D-dependent Ca2+ absorption between enterocytes. Mol Biol Cell.
2008;
19
(5)
:
1912-21
.
View Article PubMed Google Scholar -
Elizondo
R.A.,
Yin
Z.,
Lu
X.,
Watsky
M.A.,
Effect of vitamin D receptor knockout on cornea epithelium wound healing and tight junctions. Invest Ophthalmol Vis Sci.
2014;
55
(8)
:
5245-51
.
View Article PubMed Google Scholar -
Kong
J.,
Zhang
Z.,
Musch
M.W.,
Ning
G.,
Sun
J.,
Hart
J.,
Novel role of the vitamin D receptor in maintaining the integrity of the intestinal mucosal barrier. Am J Physiol Gastrointest Liver Physiol.
2008;
294
(1)
:
208-16
.
View Article PubMed Google Scholar -
Chen
H.,
Lu
R.,
Zhang
Y.G.,
Sun
J.,
Vitamin D Receptor Deletion Leads to the Destruction of Tight and Adherens Junctions in Lungs. Tissue Barriers.
2018;
6
(4)
:
1-13
.
View Article PubMed Google Scholar -
Shi
Y.Y.,
Liu
T.J.,
Fu
J.H.,
Xu
W.,
Wu
L.L.,
Hou
A.N.,
Vitamin D/VDR signaling attenuates lipopolysaccharide induced acute lung injury by maintaining the integrity of the pulmonary epithelial barrier. Mol Med Rep.
2016;
13
(2)
:
1186-94
.
View Article PubMed Google Scholar -
Abdel-Mohsen
M.A.,
El-Braky
A.A.,
Ghazal
A.A.,
Shamseya
M.M.,
Autophagy, apoptosis, vitamin D, and vitamin D receptor in hepatocellular carcinoma associated with hepatitis C virus. Medicine (Baltimore).
2018;
97
(12)
:
e0172
.
View Article PubMed Google Scholar -
Wang
J.,
Lian
H.,
Zhao
Y.,
Kauss
M.A.,
Spindel
S.,
Vitamin D3 induces autophagy of human myeloid leukemia cells. J Biol Chem.
2008;
283
(37)
:
25596-605
.
View Article PubMed Google Scholar -
Choi
Y.,
Bowman
J.W.,
Jung
J.U.,
Autophagy during viral infection - a double-edged sword. Nat Rev Microbiol.
2018;
16
(6)
:
341-54
.
View Article PubMed Google Scholar -
Mao
J.,
Lin
E.,
He
L.,
Yu
J.,
Tan
P.,
Zhou
Y.,
Autophagy and viral infection. Adv Exp Med Biol.
2019;
1209
:
55-78
.
View Article PubMed Google Scholar -
Fajgenbaum
D.C.,
June
C.H.,
Cytokine Storm. N Engl J Med.
2020;
383
(23)
:
2255-73
.
View Article PubMed Google Scholar -
Hojyo
S.,
Uchida
M.,
Tanaka
K.,
Hasebe
R.,
Tanaka
Y.,
Murakami
M.,
How COVID-19 induces cytokine storm with high mortality. Inflamm Regen.
2020;
40
(1)
:
37
.
View Article PubMed Google Scholar -
Moore
J.B.,
June
C.H.,
Cytokine release syndrome in severe COVID-19. Science.
2020;
368
(6490)
:
473-4
.
View Article PubMed Google Scholar -
Cron
R.Q.,
COVID-19 cytokine storm: targeting the appropriate cytokine. Lancet Rheumatol.
2021;
3
(4)
:
e236-7
.
View Article PubMed Google Scholar -
Channappanavar
R.,
Perlman
S.,
Pathogenic human coronavirus infections: causes and consequences of cytokine storm and immunopathology. Semin Immunopathol.
2017;
39
(5)
:
529-39
.
View Article PubMed Google Scholar -
Tang
L.,
Yin
Z.,
Hu
Y.,
Mei
H.,
Controlling Cytokine Storm Is Vital in COVID-19. Front Immunol.
2020;
11
:
570993
.
View Article PubMed Google Scholar -
Shimabukuro-Vornhagen
A.,
Gödel
P.,
Subklewe
M.,
Stemmler
H.J.,
Schlö\sser
H.A.,
Schlaak
M.,
Cytokine release syndrome. J Immunother Cancer.
2018;
6
(1)
:
56
.
View Article PubMed Google Scholar -
Wong
C.K.,
Lam
C.W.,
Wu
A.K.,
Ip
W.K.,
Lee
N.L.,
Chan
I.H.,
Plasma inflammatory cytokines and chemokines in severe acute respiratory syndrome. Clin Exp Immunol.
2004;
136
(1)
:
95-103
.
View Article PubMed Google Scholar -
Zhang
Y.,
Li
J.,
Zhan
Y.,
Wu
L.,
Yu
X.,
Zhang
W.,
Analysis of serum cytokines in patients with severe acute respiratory syndrome. Infect Immun.
2004;
72
(8)
:
4410-5
.
View Article PubMed Google Scholar -
Zhang
J.M.,
An
J.,
Cytokines, inflammation, and pain. Int Anesthesiol Clin.
2007;
45
(2)
:
27-37
.
View Article PubMed Google Scholar -
Vardhana
S.A.,
Wolchok
J.D.,
The many faces of the anti-COVID immune response. J Exp Med.
2020;
217
(6)
:
e20200678
.
View Article PubMed Google Scholar -
Meftahi
G.H.,
Jangravi
Z.,
Sahraei
H.,
Bahari
Z.,
The possible pathophysiology mechanism of cytokine storm in elderly adults with COVID-19 infection: the contribution of inflame-aging. Inflamm Res.
2020;
69
(9)
:
825-39
.
View Article PubMed Google Scholar -
Bonaventura
A.,
Vecchié
A.,
Dagna
L.,
Martinod
K.,
Dixon
D.L.,
Van Tassell
B.W.,
Endothelial dysfunction and immunothrombosis as key pathogenic mechanisms in COVID-19. Nat Rev Immunol.
2021;
21
(5)
:
319-29
.
View Article PubMed Google Scholar -
Luckheeram
R.V.,
Zhou
R.,
Verma
A.D.,
Xia
B.,
CD4+ T cells: differentiation and functions. Clin Dev Immunol.
2012;
2012
:
925135
.
View Article PubMed Google Scholar -
Trinchieri
G.,
Pflanz
S.,
Kastelein
R.A.,
The IL-12 family of heterodimeric cytokines: new players in the regulation of T cell responses. Immunity.
2003;
19
(5)
:
641-4
.
View Article PubMed Google Scholar -
Chen
L.,
Grabowski
K.A.,
Xin
J.P.,
Coleman
J.,
Huang
Z.,
Espiritu
B.,
IL-4 induces differentiation and expansion of Th2 cytokine-producing eosinophils. J Immunol.
2004;
172
(4)
:
2059-66
.
View Article PubMed Google Scholar -
Paul
W.E.,
Seder
R.A.,
Lymphocyte responses and cytokines. Cell.
1994;
76
(2)
:
241-51
.
View Article PubMed Google Scholar -
Berger
A.,
Th1 and Th2 responses: what are they?. BMJ.
2000;
321
(7258)
:
424
.
View Article PubMed Google Scholar -
Mosmann
T.R.,
Coffman
R.L.,
TH1 and TH2 cells: different patterns of lymphokine secretion lead to different functional properties. Annu Rev Immunol.
1989;
7
(1)
:
145-73
.
View Article PubMed Google Scholar -
Abbas
A.K.,
Murphy
K.M.,
Sher
A.,
Functional diversity of helper T lymphocytes. Nature.
1996;
383
(6603)
:
787-93
.
View Article PubMed Google Scholar -
Kidd
Parris,
Th1/Th2 balance: the hypothesis, its limitations, and implications for health and disease. Alternative medicine review : a journal of clinical therapeutic.
2003;
8
(3)
:
223-46
.
-
Eden
W. van,
Zee
R. van der,
Kooten
P. van,
Berlo
S.E.,
Cobelens
P.M.,
Kavelaars
A.,
Balancing the immune system: Th1 and Th2. Annals of the Rheumatic Diseases.
2002;
61
(Supplement 2)
:
25-28
.
-
Silva
R.,
Morgado
J.M.,
Freitas
A.,
Couceiro
A.,
Orfao
A.,
Regateiro
F.,
Influence of pro- and anti-inflammatory cytokines in Th1 polarization after allogeneic stimulation. Int J Biomed Sci.
2005;
1
(1)
:
46-52
.
PubMed Google Scholar -
Cantorna
M.T.,
Snyder
L.,
Lin
Y.D.,
Yang
L.,
Vitamin D and 1,25(OH)2D regulation of T cells. Nutrients.
2015;
7
(4)
:
3011-21
.
View Article PubMed Google Scholar -
Bivona
G.,
Agnello
L.,
Ciaccio
M.,
Vitamin D and Immunomodulation: Is It Time to Change the Reference Values?. Ann Clin Lab Sci.
2017;
47
(4)
:
508-10
.
PubMed Google Scholar -
Kang
S.W.,
Kim
S.H.,
Lee
N.,
Lee
W.W.,
Hwang
K.A.,
Shin
M.S.,
1,25-Dihyroxyvitamin D3 promotes FOXP3 expression via binding to vitamin D response elements in its conserved noncoding sequence region. J Immunol.
2012;
188
(11)
:
5276-82
.
View Article PubMed Google Scholar -
Adorini
L.,
Tolerogenic dendritic cells induced by vitamin D receptor ligands enhance regulatory T cells inhibiting autoimmune diabetes. Ann N Y Acad Sci.
2003;
987
(1)
:
258-61
.
View Article PubMed Google Scholar -
Cantorna
M.T.,
Munsick
C.,
Bemiss
C.,
Mahon
B.D.,
1,25-Dihydroxycholecalciferol prevents and ameliorates symptoms of experimental murine inflammatory bowel disease. J Nutr.
2000;
130
(11)
:
2648-52
.
View Article PubMed Google Scholar -
Fountain
J.H.,
Lappin
S.L.,
StatPearls Publishing: Treasure Island (FL); 2021.
Google Scholar -
Dandona
P.,
Dhindsa
S.,
Ghanim
H.,
Chaudhuri
A.,
Angiotensin II and inflammation: the effect of angiotensin-converting enzyme inhibition and angiotensin II receptor blockade. J Hum Hypertens.
2007;
21
(1)
:
20-7
.
View Article PubMed Google Scholar -
Murphy
A.M.,
Wong
A.L.,
Bezuhly
M.,
Modulation of angiotensin II signaling in the prevention of fibrosis. Fibrogenesis & Tissue Repair.
2015;
8
:
7
.
View Article Google Scholar -
Santos
R.A.,
Simoes e Silva
A.C.,
Maric
C.,
Silva
D.M.,
Machado
R.P.,
de Buhr
I.,
Angiotensin-(1-7) is an endogenous ligand for the G protein-coupled receptor Mas. Proc Natl Acad Sci USA.
2003;
100
(14)
:
8258-63
.
View Article PubMed Google Scholar -
Hoffmann
M.,
Kleine-Weber
H.,
Schroeder
S.,
Krüger
N.,
Herrler
T.,
Erichsen
S.,
SARS-CoV-2 Cell Entry Depends on ACE2 and TMPRSS2 and Is Blocked by a Clinically Proven Protease Inhibitor. Cell.
2020;
181
(2)
.
View Article PubMed Google Scholar -
Silhol
F.,
Sarlon
G.,
Deharo
J.C.,
Vaisse
B.,
Downregulation of ACE2 induces overstimulation of the renin-angiotensin system in COVID-19: should we block the renin-angiotensin system?. Hypertens Res.
2020;
43
(8)
:
854-6
.
View Article PubMed Google Scholar -
Gheblawi
M.,
Wang
K.,
Viveiros
A.,
Nguyen
Q.,
Zhong
J.C.,
Turner
A.J.,
Angiotensin-Converting Enzyme 2: SARS-CoV-2 Receptor and Regulator of the Renin-Angiotensin System: Celebrating the 20th Anniversary of the Discovery of ACE2. Circ Res.
2020;
126
(10)
:
1456-74
.
View Article PubMed Google Scholar -
Bhalla
V.,
Blish
C.A.,
South
A.M.,
A historical perspective on ACE2 in the COVID-19 era. J Hum Hypertens.
2020
.
View Article Google Scholar -
Zhang
B.N.,
Xu
H.,
Gao
X.M.,
Zhang
G.Z.,
Zhang
X.,
Yang
F.,
Protective Effect of Angiotensin (1-7) on Silicotic Fibrosis in Rats. Biomed Environ Sci.
2019;
32
(6)
:
419-26
.
PubMed Google Scholar -
Malek Mahdavi
A.,
A brief review of interplay between vitamin D and angiotensin-converting enzyme 2: implications for a potential treatment for COVID-19. Rev Med Virol.
2020;
30
(5)
:
e2119
.
View Article PubMed Google Scholar -
McLachlan
C.S.,
The angiotensin-converting enzyme 2 (ACE2) receptor in the prevention and treatment of COVID-19 are distinctly different paradigms. Clin Hypertens.
2020;
26
(1)
:
14
.
View Article PubMed Google Scholar -
Xu
J.,
Yang
J.,
Chen
J.,
Luo
Q.,
Zhang
Q.,
Zhang
H.,
Vitamin D alleviates lipopolysaccharide‑induced acute lung injury via regulation of the renin‑angiotensin system. Mol Med Rep.
2017;
16
(5)
:
7432-8
.
View Article PubMed Google Scholar -
Aygun
H.,
Vitamin D can prevent COVID-19 infection-induced multiple organ damage. Naunyn Schmiedebergs Arch Pharmacol.
2020;
393
(7)
:
1157-60
.
View Article PubMed Google Scholar -
Shah
K.,
Saxena
D.,
Mavalankar
D.,
Vitamin D supplementation, COVID-19 and disease severity: a meta-analysis. QJM: An International Journal of Medicine.
2021;
114
(3)
:
175-181
.
View Article Google Scholar -
Nikniaz
L.,
Akbarzadeh
M.A.,
Hosseinifard
H.,
Hosseini
M.-S.,
The impact of vitamin D supplementation on mortality rate and clinical outcomes of COVID-19 patients: A systematic review and meta-analysis. MedRxiv.
2021
.
View Article Google Scholar -
Rastogi
A.,
Bhansali
A.,
Khare
N.,
Suri
V.,
Yaddanapudi
N.,
Sachdeva
N.,
Short term, high-dose vitamin D supplementation for COVID-19 disease: a randomised, placebo-controlled, study (SHADE study). Postgrad Med J.
2020
.
View Article Google Scholar -
Martineau
A.R.,
Jolliffe
D.A.,
Hooper
R.L.,
Greenberg
L.,
Aloia
J.F.,
Bergman
P.,
Vitamin D supplementation to prevent acute respiratory tract infections: systematic review and meta-analysis of individual participant data. BMJ.
2017;
356
:
i6583
.
View Article PubMed Google Scholar -
Murai
I.H.,
Fernandes
A.L.,
Sales
L.P.,
Pinto
A.J.,
Goessler
K.F.,
Duran
C.S.,
Effect of a Single High Dose of Vitamin D3 on Hospital Length of Stay in Patients With Moderate to Severe COVID-19: A Randomized Clinical Trial. JAMA.
2021;
325
(11)
:
1053-60
.
View Article PubMed Google Scholar -
Sloka
S.,
Silva
C.,
Wang
J.,
Yong
V.W.,
Predominance of Th2 polarization by vitamin D through a STAT6-dependent mechanism. J Neuroinflammation.
2011;
8
(1)
:
56
.
View Article PubMed Google Scholar -
Manaseki-Holland
S.,
Maroof
Z.,
Bruce
J.,
Mughal
M.Z.,
Masher
M.I.,
Bhutta
Z.A.,
Effect on the incidence of pneumonia of vitamin D supplementation by quarterly bolus dose to infants in Kabul: a randomised controlled superiority trial. Lancet.
2012;
379
(9824)
:
1419-27
.
View Article PubMed Google Scholar
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Volume & Issue : Vol 8 No 5 (2021)
Page No.: 4358-4366
Published on: 2021-05-31
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