Vitamin D and estrogen steroid hormones and their immunogenetic roles in Infectious respiratory (TB and COVID-19) diseases

Abstract The role of steroid hormones against infectious diseases has been extensively studied. From immunomodulatory action to direct inhibition of microorganism growth, hormones D3 (VD3) and 17β-estradiol (E2), and the genetic pathways modulated by them, are key targets for a better understanding pathogenesis of infectious respiratory diseases (IRD) such as tuberculosis (TB) and the coronavirus disease-19 (COVID-19). Currently, the world faces two major public health problems, the outbreak of COVID-19, accounting for more than 6 million so far, and TB, more than 1 million deaths per year. Both, although resulting from different pathogens, the Mtb and the SARS-CoV-2, respectively, are considered serious and epidemic. TB and COVID-19 present similar infection rates between men and women, however the number of complications and deaths resulting from the two infections is higher in men when compared to women in childbearing age, which may indicate a role of the sex hormone E2 in the context of these diseases. E2 and VD3 act upon key gene pathways as important immunomodulatory players and supporting molecules in IRDs. This review summarizes the main roles of these hormones (VD3 and E2) in modulating immune and inflammatory responses and their relationship with TB and COVID-19.


Introduction
Steroid hormones have been the target of recent studies due to their immunomodulatory role in inflammation, in cardiovascular, autoimmune and in infectious diseases (Chocano-Bedoya and Ronnenberg, 2009;Lopes Marques, 2010;Kovats, 2015;Trenti et al., 2018).The main female hormone, 17β-estradiol (E 2 ), present high circulating levels in women in childbearing age but its production declines considerably after menopause, usually when women become more susceptible to cardiovascular and infectious diseases.In fact, E 2, presents a wide and potent signalling among immune system cells towards a pro-inflammatory response, making women more prone in restraining infectious diseases during childbearing ages (Deguchi et al., 2001;Carr, 2003;Patel et al., 2018;Kadel and Kovats, 2018).
Cholecalciferol or vitamin D 3 (VD 3 ) plays a key role in bone metabolism and calcium homeostasis, however, this hormone is capable of exerting extra-skeletal activities such as in cellular physiology, antiproliferative effects on cancer cells (Trochoutsou et al., 2015), modulation of the immune response and control of inflammation, roles performed through the binding to the Vitamin D Receptor (VDR) (Sassi et al., 2018).The functions performed by VD 3 can be mediated by the transcriptional role of the VDR in the cell nucleus; and by a non-genomic mechanism, when the VDR induces rapid signalling by sensitising cell membrane and/or cytoplasmic proteins.Importantly, VD deficiency affects more than 1 billion people in the world and has been associated with a series of pathologies including infectious, autoimmune, and allergic diseases (Trochoutsou et al., 2015).
Lower respiratory infections are among the three leading causes of death and disability in children and adults, and remain as the world's most deadly communicable diseases, ranked as the 4th leading cause of death (World Health Organization, 2020).Over the last decades, epidemics of respiratory diseases caused by pathogens, whether viruses or bacteria, have been a major public health problem, especially tuberculosis (TB), which has one of the highest global mortality rates, and more recently the pandemic caused by the new coronavirus, Coronavirus , responsible for more than six million deaths worldwide (World Health Organization, 2022).
COVID-19 and TB are communicable diseases and epidemiological data on the profile of the infected population, including complication rates and deaths, have been collected worldwide.Although infection rates in these diseases are similar between men and women, it is observed that sex, Borborema et al. 2 age and genetic profile may influence the clinical outcome of these diseases, once women in childbearing age, compared to men in the same age group, have lower rates of infection complications and death in both diseases (Hertz and Schneider, 2019;Ahmed and Dumanski, 2020).
The steroid hormones VD 3 and E 2 share not only chemical similarities but also actions.They are able to act upon gene expression and mRNA stability in different tissues and defence cells from the innate and adaptive immune system allowing them to influence their response efficiency (Ing, 2005;Haussler et al., 2011).Emerging evidence supports the hypothesis that VD 3 improves immunity by maintaining a balanced immune response.This receptor is expressed by most cells of the defence system such as T and B lymphocytes and antigen-presenting cells (APCs) (Trochoutsou et al., 2015).The VD 3 /VDR complex triggers the differentiation of innate cells such as monocytes into macrophages and in the adaptive response by modulating T cell differentiation (Durrant et al., 2022).VD 3 produced locally by monocytes and macrophages can induce the expression of cathelicidins and β-defensin 2, which play a direct role in the response against pathogens as Mycobacterium tuberculosis (Mtb) (Ao et al., 2021).
E 2 through Estrogen Receptors (ERs) can regulate cells and pathways in the innate and adaptive immune responses, as well as immune cell differentiation.ERs are ligand-dependent transcription factors and play key roles in mediation of longrange chromatin interactions and the formation of complexes that regulates gene expression by binding to estrogen response elements (EREs).ERs also participate in membrane-initiated steroid signalling to generate rapid responses.E 2 /ER activity shows dose-and context-dependent effects on innate immune signalling pathways (Kovats, 2015).
In this way, understanding the main pathways of action of these hormones against infections caused by pathogens can be an important weapon in the investigation of possible molecules that help in the improvement of the host's immune response as well as in a containment of inflammation in these individuals in the response against these pathogens.

Respiratory diseases
Respiratory tract diseases (RTDs) are pathological conditions that affect organs and tissues responsible for breathing (Forum of International Respiratory Societies, 2017).The respiratory system turns out to be the internal set of organs most susceptible to infections and injuries from the environment due to its constant exposure to particles such as chemicals and pathogenic microorganisms (Lee, 2017).Respiratory diseases include acute respiratory infections as well as chronic respiratory diseases such as asthma, chronic obstructive pulmonary disease, and lung cancer (Forum of International Respiratory Societies, 2017).
RTDs can be classified in different ways, from the organ or tissue affected to the pattern of signs and symptoms associated with the disease.They can range from mild, such as a simple cold, to serious illnesses such as bacterial pneumonia, TB, pulmonary embolism, lung cancer, asthma, and severe acute respiratory syndromes (Nair et al., 2011;Herefordshire Council, 2022).
Lower respiratory tract infections are among the top three causes of disability and death in children and adults.
It is estimated that these infections cause nearly 4 million deaths per year.Moreover, acute infections in the lower respiratory tract in children increase the predisposition for chronic respiratory diseases development in adult life (Forum of International Respiratory Societies, 2017).
Infections can affect any part of the respiratory system, traditionally divided into upper respiratory tract infections (URTIs) and lower respiratory tract infections (LRTIs).The most common type of URTI is the cold, however, infections in specific organs such as sinusitis, tonsillitis, pharyngitis, and laryngitis are also frequent.In the lower respiratory tract, the most frequent disease is pneumonia, a pulmonary infection caused by different pathogens, from bacteria such as Streptococcus pneumoniae to Mtb that causes TB (Lozano et al., 2012;Wang et al., 2016;Lee, 2017).
TB has one of the highest global mortality rates, leading about 17% of infected individuals to death, which approximately a quarter are co-infected with the human immunodeficiency virus (HIV).This makes it the leading disease caused by a single infectious agent and one of the leading causes of death worldwide from infectious diseases (World Health Organization, 2021).
Lately, new pathogens that cause respiratory infections have emerged.In 2003, severe acute respiratory syndrome (SARS), caused by the Coronavirus (SARS-CoV), a previously unknown pathogen, spread rapidly around the world.In 2019, a new coronavirus (SARS-CoV-2) triggered a pandemic that by September 2022 reached the mark of more than 615 million infected and 6.5 million deaths worldwide (World Health Organization, 2022).

Tuberculosis
TB is a notifiable infectious disease caused by Mtb.Its transmission is almost exclusively by inhalation of aerosols, containing the bacillus, released during the cough of infected individuals.Usually affects the lungs (pulmonary TB), but can affect other organs such as bones, liver, intestines, and lymph nodes (extrapulmonary TB) (Dheda et al., 2016).
According to WHO, in 2020 a large global drop in the number of people newly diagnosed with TB was observed, from 7.1 million in 2019 to 5.8 million in 2020 (18% of reduction) (World Health Organization, 2021).This decrease may be a result of the likely underreporting of the number of TB cases due to the COVID-19 pandemic.Another consequence of the pandemic was the reduction in TB treatment access, which is reflected in the increase of TB deaths (1.3 million in 2020) (World Health Organization, 2021).
It is known that TB affects both males and females in all age groups, but a higher incidence is observed in men over 15 years of age.In 2020, men accounted for 56% of all TB cases, while women of the same age group accounted for 33% of cases (World Health Organization, 2021).Brazil is now the centre of WHO concern in Americas, where TB incidence appears to be increasing owing to an upward trend.In 2020, Brazil recorded 66,819 new TB cases with an incidence coefficient of 31.6 cases per 100,000 habitants.Following the global trend, between 2011 and 2020, 69.0% of new TB cases were male (Secretaria de Vigilância em Saúde, 2021).
A relatively small portion, 5-10% of the nearly 2 billion people infected with Mtb have developed or will develop VD3 and E2 in TB and COVID-19 3 active TB during their lifetime.However, the likelihood of developing the disease is much higher among patients coinfected with HIV or risk factors such as malnutrition, diabetes, smoking and excessive alcohol consumption (World Health Organization, 2019).
The development of the TB active form depends on several factors from lifestyle to immunological status, comorbidities like diabetes and acquired immunodeficiency syndrome (AIDS) as well as the genetic profile of the infected individual (Menon et al., 2016;Mathema et al., 2017).
TB transmission occurs when the individual inhales the infectious nuclei and the Mtb manages to cross the URTIs and the bronchi, to reach the pulmonary alveoli only then where it settles and is phagocytosed by cells of the immune system, especially alveolar macrophage (Ketata et al., 2015).
Immunocompetent individuals can control the development of TB through two specific lines of defence: the first one formed by phagocytic cells, such as polymorphonuclear cells, monocytes, and alveolar macrophages, thus constituting the innate immune response.And the second one, characterised by an acquired immune response (Gupta et al., 2018;Furin et al., 2019).
Once Mtb bacilli are phagocytosed by alveolar macrophages, occurs the internalisation into the phagosome, which fuses with the lysosome, forming the phagolysosome, where a series of granules and other toxic products produced by macrophages and stored in the lysosome are released.The lysosome contains numerous hydrolytic enzymes and has an acidic content.Phagolysosome formation is considered to be the primary infection control mechanism and occurs via interferon-γ (IFN-γ) (Fogel, 2015).
After phagocytosis, the inhaled bacilli remain in cytoplasmic vacuoles and are presented to CD4+ T lymphocytes by the major histocompatibility complex class II (MHC-II), present in macrophages, dendritic cells (DCs), and B lymphocytes.These cells are APCs and produce inflammatory cytokines such as tumor necrosis factor (TNF) and interleukin-1 (IL-1), capable of recruiting neutrophils and monocytes maintaining the innate response (Gupta et al., 2018;Furin et al., 2019).Macrophages also activate a specific immune response against TB, when infected, they release IL-12 and IL-18, which predominantly stimulate CD4+ T lymphocytes to release IFN-γ, which in turn stimulates Mtb phagocytosis (Cliff et al., 2015;Gupta et al., 2018).However, if the bacilli are not killed during this initial interaction, they can proliferate within DCs and alveolar macrophages at a high rate of growth (Fogel, 2015;Domingo-Gonzalez et al., 2016).
The acquired immune response is mediated by pathogenrecognition receptors (PRRs) that are expressed by these cells and recognize pathogen-associated molecular patterns (PAMPs) expressed by the Mtb (Hossain and Norazmi, 2013).Among these receptors several stand out in triggering the inflammatory response against Mtb, including nucleotide oligomerization NOD-like receptors (NLRs) and toll-like receptors (TLRs).The purpose of Mtb presentation to these receptors is the induction of various intracellular signalling cascades for cytokine production, whether pro-or anti-inflammatory, thus regulating the inflammatory process (Fogel, 2015).
Recognition of specific microbial ligands by TLRs activates inflammatory signalling pathways (Apt et al., 2017).Among the main TLRs that recognize Mtb are TLR2, TLR9 and TLR4 (Means et al., 1999).Activation of these receptors on the surface of macrophages initiates the recruitment of various adapter proteins such as the myeloid differentiation primary response gene 88 (MyD88).In sequence, the activation of a series of molecules of the signalling pathway occurs, culminating in the translocation of nuclear factor-κB (NF-κB) to the nucleus and in the activation of the transcription of immune response genes, such as cytokines, chemokines and enzyme induced nitric oxide synthase (iNOS) (Apt et al., 2017).
Mycobacterial recognition by TLRs activates the transcription of genes encoding the NF-κB and the iNOS by the secretion of TNF, responsible for high levels of nitric oxide (NO).NO production is strongly associated with Mtb resistance because reactive nitrogen intermediates (RNI) are toxic to Mtb, and infection is exacerbated by enzyme nitric oxide synthase 2 (NOS2) inhibition (Sia and Rengarajan, 2019).It is also known that NO production after IFN-γ signalling limits inflammation by inhibiting IL-1β processing by the inflammasome (Mishra et al., 2013).
The recognition of Mtb by TLRs, in fact, induces a predominantly pro-inflammatory response.However, signalling via TLR2 also increases the secretion of IL-10, an anti-inflammatory T helper-2 (Th2) cytokine, by DCs and macrophages, suggesting a pathogen defence mechanism in controlling the host's inflammatory response (Salgame, 2005).
The initial infection is dominated by a Th1 immune response, however, if the infection is not contained, a gradual shift to Th2 response occurs (Moutinho, 2011).Several studies try to clarify the immunological mechanisms in infections by intracellular bacteria, and the finding of cytokines produced by Th2 cells, such as IL-4 and IL-10, may reflect the inability to respond to these bacteria.These and other cytokines that suppress Th1 activity and markers of Th2 activity, such as immunoglobulins (Ig) E and IgG4, are frequently found in advanced TB (Ferraz et al., 2006).
The balance between Th1 cytokines to inhibit mycobacterial growth (IFN-γ and TNF), or Th2 to accelerate Mtb growth (IL-4 and IL-10), may be the key in the regulation of mycobactericidal activity in infected macrophages (Ferraz et al., 2006).Alveolar cells from patients with active pulmonary TB express Th1 cytokines (IL-2 and IFN-γ) in an environment also known as Th2 due to the presence of IL-10 and IL-4.It is not the increase in Th1 cytokines, but the increase in Th2 cytokines, which play an important role in the TB progression (Novikov et al., 2011).
However, the immune response against the Mtb should not be interpreted solely based on a Th1/Th2 regulatory balance.The successful elimination of Mtb depends on the correct interaction between the innate and the acquired response, in which numerous cells and a wide network of chemical mediators participate.Although TB is an infectious disease, the clinical outcome (latent TB or TB disease) varies by the influence of other factors such as immunity and the genetic background of the host (Malik and Schurr, 2002).
Many of the studies that address the genetics of the host in the face of Mtb infection are based on the association between the development of TB and the variation in the frequencies of polymorphisms in candidate genes.Several studies have been associating genetic factors with susceptibility or protection against Mtb infection (Chocano-Bedoya and Ronnenberg, 2009;Chen et al., 2013;Aravindan, 2019).In the immune response against the Mtb, allele and genotype frequencies from inflammatory gene polymorphisms (IFN-γ, IL-10, TNF, TLR4 and VDR) vary considerably across populations (Malik and Schurr, 2002;Chen et al., 2013;Simmons et al., 2018;Aravindan, 2019;de Albuquerque Borborema et al., 2020;Chen et al., 2021).Polymorphisms that cause alterations on cytokine serum levels  are in association with a worse prognosis and a higher mortality rate (Zhang et al., 2011;Simmons et al., 2018).
Variants in the TLR pathway genes are can deregulate the cellular immune response and may influence the susceptibility to the bacillus (Berrington and Hawn, 2007).Polymorphisms in the TLR2 signalling domain (G2258A (R753Q)) can alter the response to stimulation with Mtb lipoproteins, altering the response triggered by NF-κB (Schröder et al., 2005).Other polymorphisms such as the GT dinucleotide repeat in intron II of TLR2 are associated with increased susceptibility to TB, as well as altered activity of the TLR2 promoter (Yim et al., 2006).
DCs recognize Mtb through receptors such as TLR1, TLR2, TLR6, TLR9, NOD2, DC-SIGN and possibly TLR4 and Dectin-1.Several adaptive immune responses can be activated depending on the activated receptor (Arentz and Hawn, 2007).Host genetic variations can influence the adaptive immune response to Mtb triggered by DCs.Some alterations are described in the MHC gene and associated with Mtb susceptibility (Fernando and Britton, 2006).Changes in the DC-SIGN encoded by CD209 gene at the promoter region (-871G and -336A) are associated with TB susceptibility, although reports are still conflicting (Barreiro et al., 2006;Gómez et al., 2006).The homozygous mutation in the IL-12p40 subunit, which inhibits the production of IL-12, is associated with primary immunodeficiency and increased susceptibility to TB (Casanova and Abel, 2002).
The outcome of infection with Mtb depends on several factors, among them the effective acidification of the phagosome in the phagosome-lysosome fusion, the activation of the inflammasome complex by NLRs, that results in the release of IL-1β and IL-18 (Gröschel et al., 2016), and the upregulation of host genes that are required for activation of intracellular death mechanisms such as reactive oxygen species (ROS), NO, the production and release of the antimicrobial cathelicidin peptide (CAMP) and, finally, the activation of pathways of cell death by the host (pyroptosis, apoptosis and necrosis) (Behar et al., 2010;Verrall et al., 2014).
All these mechanisms are activated by genomic or non-genomic pathways.Both share their regulation through several mechanisms, including the modulation performed by steroid hormones such as VD 3 and E 2 .

COVID-19
In early December 2019, the outbreak of a new respiratory disease began, COVID-19, caused by Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2), in Wuhan City, Hubei Province, China, and spread around the world causing the biggest pandemic of the 21st century (Harapan et al., 2020).
Daily, since the beginning of the COVID-19 pandemic, the WHO updates the number of new cases and deaths resulting from COVID-19. As of September 26, 2022, 612.236.677cases have been reported worldwide.As for the number of deaths, 6.514.397have been recorded since December 2019 (World Health Organization, 2022).
According to WHO, there is a little difference in the reported numbers of cases in men and in women.Among over 700,000 confirmed cases reported by April 2020, the sex rate is almost equal Male: Female cases = 1.03:1.However, this sex ratio varies with age: the younger (20-29 years old) and older (80 years and older) age groups, present more cases in women than men.On the other hand, for age groups 0-9 years, 60-69 years and 70-79 years, there are more cases in men than women (Global Health 50/50, 2022).According to global data for every ten women, there are twelve hospitalisations, 17 intensive care unit (ICU) admissions and 13 male deaths by COVID-19 and its complications.These data show that although men and women have the same rate of infection, men generally complicate and die more compared to women.
SARS-CoV-2 is the seventh member of the family of coronaviruses that infect humans (Cheng and Shan, 2020) and is considered a new RNA virus, belonging to the order Nidovirales, to the genus Betacoronavirus, subgenus Sarbecovirus, of the family Coronaviridae and subfamily Orthocoronavirinae (Chen et al., 2020;Lu et al., 2020;Paraskevis et al., 2020).
SARS-CoV-2 infection is transmitted through large droplets generated during the coughing and sneezing of patients, but it can also occur in asymptomatic people or before the onset of symptoms by droplets expelled during speech (Rothe et al., 2020).Binding to a receptor expressed by host cells is the first step of viral infection, followed by fusion of the virus with the cell membrane (Rothan and Byrareddy, 2020).It is known that type II pneumocytes are the main target of the virus.The infection occurs initially by the binding of the receptor binding domain (RBD) of the S protein of the virus and the cellular receptor that has been identified as the angiotensin-converting enzyme 2 (ACE2) receptor (Jaimes et al., 2020;Wan Y et al., 2020).ACE2 is expressed in type I and II alveolar epithelial cells.Men have a higher level of ACE2 in pneumocytes compared to women.The expression of ACE2 is autoregulated by the binding of ACE2 to SARS-CoV-2, which can lead to alveolar cell damage by increasing the expression of this receptor.This damage triggers a series of systemic reactions and even death (Sun et al., 2020).
As the SARS-CoV-2 entry receptor into the host cell, ACE2, is highly expressed by the epithelial cells (pneumocytes) of the alveolar space on the apical side of the lungs, this virus can easily enter and destroy this tissue.Receptor recognition is not the only determinant for successful infection, immediately after binding to ACE2, SARS-CoV-2 enters the host cell and triggers the activation of an innate immune response.In order to stay alive and replicate in the host, the virus has the ability to inhibit or avoid the signalling of innate host response (Hamming et al., 2004;Jia et al., 2005;Yuki et al., 2020).
The host immune system response to viral infection by mediating inflammation and cellular antiviral activity are critical to inhibiting viral replication and spread.However, the exacerbated immune response in conjunction with the lytic effect of the virus on host cells results in pathogenesis (Harapan et al., 2020).As a first step, immune cells detect the viral infection by identifying PAMPs such as viral RNA.These PAMPs are able to bind and activate PRRs such as TLR3, TLR7, cytoplasmic RNA sensors (retinoic acid-inducible gene, RIG-I) and melanone differentiation-associated protein (MDA5) in immune cells, which results in the activation of these cells (Felsenstein et al., 2020).
Normally, activation of TLR3 and TLR7 results in nuclear translocation of transcription factors NF-κB and interferon regulatory factor 3 (IRF3), while activation by RIG-I and MDA5 results in activation of IRF3.This activation triggers the expression of IFN-I through IRF3 and other innate pro-inflammatory cytokines (IL-1, IL-6, TNF) through NF-κB (de Wit et al., 2016;Prompetchara et al., 2020).In this context, IFN-I and other innate pro-inflammatory cytokines promote their own expression through self-amplification, where IFN-I activates the IFN-α receptor complex (IFNAR) that results in phosphorylation/activation of transcription factors 1 and 2 of the signal transducers and activators of transcription (STAT) family, while the activation of IL-1, IL-6 and TNF receptors fuels the expression of pro-inflammatory cytokines through NF-κB (de Wit et al., 2016;Lazear et al., 2019).Activation of the innate response and initiation of the adaptive response should result in pathogen elimination and host recovery (Felsenstein et al., 2020).
Suppression of innate immune response mechanisms in infected epithelial cells and infected monocytes and macrophages, allows SARS-CoV-2 to proliferate without triggering the innate antiviral response machinery.However, at a later stage of infection, infected cells undergo cell death and release viral particles along with intracellular components that trigger inflammatory mechanisms of the innate immune response through their recognition by PRRs of immune system cells such as DCs and macrophages.As a result of the activation of the innate immune response and consequent expression of pro-inflammatory cytokines such as IL-1β, IL-6 and TNF, immune cells of the adaptive response, such as T and B lymphocytes, engage in host defence against the virus (Felsenstein et al., 2020).
SARS-CoV-2 can also escape, even partially, from the adaptive response by inducing T cell apoptosis (Yi et al., 2020).However, lymphocyte depletion can occur due to the over-expression of pro-inflammatory cytokines by innate (uninfected) immune cells that are recruited to the lungs where they trigger hyper-inflammation, known as a Cytokine Storm (Costela-Ruiz et al., 2020).
Circulating monocytes respond to granulocytemacrophage colony-stimulating factor (GM-CSF) released by activated T cells.Subsets of CD14+ CD16+ inflammatory monocytes, which rarely exist in healthy controls, were found in large amounts in COVID-19 patients.These cells express high amounts of IL-6, which likely can accelerate the progression of the systemic inflammatory response (Yuki et al., 2020).Uninfected monocytes/macrophages and neutrophils recruited to the site of infection exhibit strong and poorly controlled inflammatory responses, resulting in tissue damage and systemic inflammation, which contribute to host morbidity and mortality (Zhang et al., 2020).
Another factor that contributes to organ damage and insufficient results against infection is the early production of neutralising antibodies against SARS-CoV-2.The antibodydependent enhancement (ADE) phenomenon contributes to the accumulation of damage during viral infection, which promotes cellular uptake of viral particles bound to immune complexes through their binding to Fcγ receptors (FcγR).This can contribute to persistent viral replication in immune cells, including infected APCs, but also to immune complexmediated inflammatory responses, which contribute to tissue and organ damage (Takada and Kawaoka, 2003;Jin et al., 2020;Fu et al., 2020).

Steroid hormones
Steroid hormones are responsible for regulating several physiological and developmental mechanisms during life.They essentially orchestrate basal cell, tissue and organ functioning and when they are impaired or deficient several organs and tissue may collapse leading deleterious effects and disease establishment.Their action mechanism is mainly through cytosolic receptors that complexes with homo or hetero-dimers and follows to the nucleus whereas binds to response elements (RE) in DNA and activate or repress gene transcription (Schwartz et al., 2016).
Steroid hormones are lipid in nature, they have a basic core that is derived from the cholesterol molecule.Its synthesis occurs in some tissues such as the cortex of the adrenal glands and gonads, which express different forms of the P450 enzyme complex (Shahidi, 2001).They are classified as corticosteroids, androgens, estrogen and progestins being responsible for several functions in the body from metabolic, hydro-saline, and sexual control (Schwartz et al., 2016).
In this review we will address two of the main steroid hormones with immunoregulatory action and recently described with activity against pathogens: Vitamin D 3 and 17β-estradiol.

Vitamin D
Vitamin D (VD) represents the nomenclature for a group of fat-soluble secosteroid hormones responsible for increasing intestinal calcium absorption, in addition to several other biological effects (Holick, 2006).In humans, the most important compounds in this group are: 25-hydroxyvitamin D 2 or ergocalciferol (VD 2 ) and 1,25α-dihydroxyvitamin D 3 or cholecalciferol (VD 3 ) (Al-Zohily et al., 2020).
Ultraviolet B (UVB) radiation (280-315 nm), originated from the sun, activates a chemical reaction in the plasmatic membrane of epidermal keratinocytes and dermal fibroblasts in the skin leading to photolysis of B ring from 7-dehydrocholesterol, resulting as product pre-vitamin D 3 , which undergoes a spontaneous, but non-catalytic, thermosensitive process of isomerization (Bikle, 2014).The pre-vitamin D 3 undergoes a first hydroxylation process on carbon 25 by the enzyme 25-hydroxylase/cytochrome oxidase P450 (CYP2R1), expressed by hepatocytes and stored in the endoplasmic reticulum of these cells (Figure 1A).This first hydroxylation results in VD 2 , the blood stream circulating form with a half-life time of 2 to 3 weeks.VD 2 is released into the plasma, where binds to a carrier called VD-binding protein (VDBP) and is transported to various tissues in the body (Cheng et al., 2004).Another source of VD 2 is the diet rich in foods such as fatty fish, egg yolks, shiitake mushrooms and liver (Lehmann et al., 2015).
VD 2 deficiency is considered pandemic, with high prevalence in all population groups, not just risk groups (young children, pregnant women, elderly and negroid population).About one billion individuals have a deficiency in serum levels of this hormone (van Schoor and Lips, 2011; Palacios and Gonzalez, 2014).Ideal VD 2 serum levels are considered when greater than 32 ng/mL (80 nmol/L).Low serum concentration makes it impossible the functions performed by this hormone and increases the risk of developing several diseases such as hypertension, diabetes, atherosclerosis, TB, and cancer (Heaney, 2008).
VD 2 is converted into VD 3 by hydroxylation, an active state with a time of half-life of 4 to 6 hours.The second hydroxylation process, on carbon 1 from A ring, is performed by the enzyme 1α-hydroxylase, a product of the CYP27A1 gene that is expressed in greater amounts in the cells of the proximal tubules of the kidneys but can also be expressed by other cell types such as leukocytes, especially macrophages (Adams and Hewison, 2010) (Figure 1A).
VD 2 performs its functions in the body through two main mechanisms: an endocrine mechanism that allows the regulation of calcium absorption; and an autocrine, which promotes the expression of several genes (van Schoor and Lips, 2011) (Figure 1C).VD 3 plays many roles in the body, including modulating cell growth, neuromuscular and immune function and reducing inflammation (Norman, 2008;Kamen and Tangpricha, 2010;Boucher, 2012).Many genes that encode proteins that regulate cell proliferation, differentiation and apoptosis are modulated in part by VD 3 .The VDR is expressed in several cell types and the CYP271A enzyme is responsible for local conversion of VD 2 into VD 3 (National Institutes of Health, 2020) (Figure 1).
VDR is a member of the steroid hormone receptor superfamily, which includes receptors from retinoic acid, thyroid hormone, sex hormones and adrenal steroids (Margolis and Christakos, 2010;Wang et al., 2012).The mechanism of action of VD 3 is mediated by the VDR, which acts as a transcription factor in target cells after forming a heterodimer with the α and β retinoic acid receptors (RXRα and RXRβ).Once dimerized, the complex binds to the VD response element (VDRE), located in the promoter regions of target genes or at enhancers, to up-or down-regulate their expression (Gil et al., 2018) (Figure 1B,C).As the VDR has been found in virtually all cell types, it may explain its multiple actions in different tissues (Wang et al., 2012).
The VDR in humans is located on chromosome 12 (12q13.11)and is composed of eight coding exons (2-9) in addition to six non-coding exons (1a-1f), which have alternative splicing, in eight introns.The gene also has two promoter regions (Zella et al., 2006) and a tissue-specific promoter is suggested (Zella et al., 2010) (Figure 1).
The VDR protein in humans contains 427 amino acids (Pike and Meyer, 2010;Haussler et al., 2013).The two main VDR functional domains are the highly conserved NH2terminal DNA-binding domain (DBD) and the more variable COOH-terminal ligand-binding domain (LBD).DBD is a cysteine-rich zinc finger region.There are two zinc fingers, each of which contains a single zinc atom in a tetrahedral arrangement with four invariant cysteine residues (Haussler et al., 2013).The LBD is composed of at least 12 α helices [H1-H12; the ligand-dependent activation function (AF2) corresponds to H12] and 3 β sheets (S1-3).VD 3 binding induces a conformational change that facilitates interaction with the RXR and co-regulatory complexes necessary for transcription of target genes (Christakos et al., 2016).
Several genes can be directly upregulated such as CYP24A1 or downregulated such as parathyroid hormone (PTH) and CYP27B1, through VDR activation (Christakos et al., 2016).The VD 3 /VDR/RXR complex interacts with basal transcription factors such as transcription factor IIB (TFIIB) and several factors associated with TATAbox binding protein in DNA.VDR-mediated transcription is facilitated by the mediator, a multiprotein complex that functions through the recruitment of RNA polymerase II and promotes the formation of the transcriptional pre-initiation complex (Yin and Wang, 2014) (Figure 1C).
In addition to VD 3 , the VDR-RXR dimer can associate with other molecules such as the p160 family of steroid receptor coactivators 1, 2 and 3, which have histone acetylase (HAT) activity, and are primary coactivators that bind for the AF2 domain of the VDR complex (Christakos et al., 2016).Members of the p160 family recruit proteins as secondary coactivators, such as CBP/p300, that also have HAT activity, resulting in a complex of multiple subunits that modify chromatin and destabilise the histone/DNA interaction (Pike et al., 2016).In epidermal cells is found the molecule 7-dehydrocholesterol, which is broken down by UVB radiation from the sun, forming pre-VD 3 .This undergoes first hydroxylation process in liver through CYP2R1 enzyme, having as a product of the reaction to 25-hydroxyvitamin D 2 .This is converted into 1,25α-dihydroxyvitamin D 3 through the second hydroxylation process through CYP27B1 enzyme.B) Chromosomal localization of the VDR gene.VD 3 performs its functions by connecting to the VDR, forming VD 3 /VDR.C) Transcriptional complex of VD 3 /VDR.Gene regulation by genomic site (red arrow) occurs when VD 3 binds to VDBP transporter.The VD 3 /VDR interaction is recruited to nucleus that heterodimerizes with RXRα and RXRβ.These act as transcription factors and bind to the VDREs present in the promoter region of target genes.Gene regulation by means of the alternative site (blue arrow) is a rapid response that occurs when VDR interacts with caveolae and through signal transduction activates the PI3K enzyme that induces intracellular conduction through secondary messages in the promoter region of target genes.
The result of VDR genomic interactions is the regulation of transcription of multiple genes, in many cases far from the VDR cis binding site.However, in some cases, the VDR can still exert a regulatory action in the absence of the VD 3 (Gil et al., 2018).Genetic alterations in the VDR can lead to important defects in gene activation, affecting calcium metabolism, cell proliferation and immune function, which can be explained by changes in protein conformation (Jones et al., 1998;DeLuca, 2004;Vasilovici et al., 2018).The gene comprises more than 60 single nucleotide polymorphisms (SNPs) identified in the coding region.Despite this large number, few are considered functional, and the most studied VDR polymorphisms are: FokI, Cdx-2, TaqI, BsmI and ApaI (Table 1) (Ozaki et al., 2000;Huang et al., 2002;Halsall et al., 2004;Ralston and Rossant, 2008;Gapska et al. 2009;Savory et al., 2009;Luo et al., 2011;Luo et al., 2012;Carvalho et al., 2015;Salimi et al., 2019).

Vitamin D and inflammation
In the last years an immune response role has been described for VD 3 .Its immunomodulatory actions influence innate and adaptive immune responses either by regulating the expression/release of cytokines or by regulating cytokines and cell signalling pathways (Laird et al., 2020).The VD 3 / VDR complex can control more than 200 genes involved in cell proliferation, differentiation, apoptosis, and angiogenesis (DeLuca, 2004;Nagpal et al., 2005;Holick, 2007).
The involvement of VD 3 in the immune system becomes even more evident when several studies in vivo and in vitro showed that immune cells, such as DCs, macrophages, B and T cells express the VDR (Yin and Agrawal, 2014) (Figure 2).VD 3 has been closely associated with modulation of the immune response against different pathogens and acting in the regulation of the adaptive immune response in chronic inflammatory disorders and autoimmune diseases (White, 2008;Tiosano et al., 2013;de Albuquerque Borborema et al., 2021).It is known that in monocytes, VD 3 acts by inhibiting the production of IL-6 and TNF and reduces the expression of monocyte chemoattractant protein-1 (MCP-1) which inhibits the activation of NF-κB in macrophages (Sanchez-Niño et al., 2012;Zhang et al. 2012;Filgueiras et al., 2020) (Figure 2).In general, VD 3 works by enhancing the innate immune response and inhibiting the adaptive response (Topilski et al., 2004).
The immunosuppressive effect of VD 3 is correlated with a decrease in the expression and consequent release of inflammatory cytokines, including IL-2 and IFN-γ (Lemire et al., 1985).
The repressive effect of VD 3 on IFN-γ transcription is due to the direct binding of the VD 3 /VDR/RXR complex to a promoter silencer region of its gene (hIFN-γ) (Christakos et al., 2016).VD 3 also stimulates the production of antiinflammatory cytokine IL-4 by Th2 cells (Mahon et al., 2003).This hormone has also been reported to play a role in increasing Treg cells, a subset of CD4+ T cells important for inhibiting inflammation and for inducing forkhead box P3 (FOXP3), a transcription factor lineage-specific involved in Treg cell development and function (Jeffery et al., 2009;Unger et al., 2009;Van Belle et al., 2014) (Figure 2).
The stimulatory effects of VD 3 on the expression of IL-4 and IL-10 and perhaps other cytokines may be indirect, and the VD 3 immune response may be dependent on the interaction of various cell types and activation states (Christakos et al., 2016).
One of the main targets of VD 3 are DCs.Exposure of differentiated in vitro DCs to VD 3 interferes with their maturation, locking the cells into a semi-mature state.Altered DCs have a reduced expression of MHC class II, costimulatory molecules (CD40, CD80, CD86) and an altered IL12/IL10 ratio (Ferreira et al., 2011).
DCs are able to alter the behaviour of T lymphocytes, inducing T cell anergy and increasing levels of apoptosis, while shifting T cell cytokine responses from pro-inflammatory, Th1 and Th17, to a more tolerant profile with Th2 and Treg cells.VD 3 affects the phenotype and behaviour of DCs through their early and transcription-mediated reprogramming of metabolic pathways, i.e., increased glycolysis and oxidative phosphorylation at the same time (Ferreira et al., 2011).
Generates a non-synonymous polymorphism resulting in a change of threonine to methionine.The presence of the restriction site FokI C allele, generates a new start codon (ATG) 9 bp after the common starting site, which translates to a shorter truncated VDR protein of 424 amino acids with more transactivation capacity as a transcription factor than the wild type full-length VDR A isoform (VDRA) with 427 amino acids (Luo et al., 2011;Carvalho et al., 2015;Salimi et al., 2019).rs11568820 (Cdx2) Location: VDR promoter region; Change: A > G.
Potentiates the binding strength between VDR and its transcriptional complex (Ralston and Rossant, 2008;Savory et al., 2009).Could affect mRNA stability and VDR gene expression.Could generate an alteration in the splice sites for mRNA transcription or a change in the intron regulatory elements of VDR (Ozaki et al., 2000;Huang et al., 2002;Luo et al., 2012).
Generates a synonymous change of the isoleucine amino acid in the coding sequence, therefore it does not change the encoded protein, but it could influence the stability of the mRNA (Carvalho et al., 2015;Salimi et al., 2019).VD 3 increases the production of β2 defensin and CAMP by macrophages and monocyte-derived keratinocytes increasing their antimicrobial activity (Gombart et al., 2005;Dai et al., 2010).In addition, this hormone enhances chemotaxis, autophagy, and phagolysosome fusion of innate immune cells (White, 2010).
VD 3 /VDR inhibits the expression of cytokines by APCs such as IL-1, IL-6, IL-12 and TNF and decreases the expression of a set of cell surface proteins of the MHC in macrophages and development of Th1 and Th17 pro-inflammatory cells, while inducing Treg and Th2 cells, which in turn down-regulate Th1 activity.Thus, this hormone inhibits the production of IL-12 and stimulates the production of IL-10, while down-regulates the expression of some costimulatory molecules, e.g., CD40, CD80 and CD86 differentiation clusters, necessary for DCs activation and other APCs, leading to Th1 inhibition.Furthermore, VD 3 acts directly on T cells by inhibiting the secretion of IL-2, a cytokine essential for the clonal expansion of lymphocytes, and IFN-γ (Christakos et al., 2016;Gil et al., 2018).
VD 3 also inhibits B cell differentiation and antibody production.In addition, inhibits enterocyte apoptosis and promotes the synthesis of antimicrobial peptides and reduces the proliferation of keratinocytes in psoriasis, favouring cell differentiation in both cases (Christakos et al., 2016;Gil et al., 2018).The VD 3 /VDR complex activates the expression of antimicrobial peptides (AMPs), such as cathelicidins and beta defensins that attack pathogens (Wang et al., 2004;Lai and Gallo, 2009).
VD 3 suppresses adaptive immunity (Chun et al., 2014;Wei and Christakos, 2015).In experimental models, this hormone negatively regulates immune responses mediated by Th1 cells, thus inhibiting the production of pro-inflammatory cytokines, such as IFN-γ, IL-6, IL-2 and TNF (Carvalho et al., 2017;Xie et al., 2017).Although experimental studies in vitro and in animals have produced encouraging results on the immunomodulatory effect of VD 3 , the same cannot be said about studies in humans, since they are discrepant regarding the confirmation of the suppressive effect of this hormone on Th1 cells and on the production of inflammatory cytokines in different diseases (Bendix-Struve et al., 2010;Stubbs et al., 2010;Seibert et al., 2013;Drozdenko et al., 2014;Buondonno et al., 2017;Zhou et al., 2018).
The overall effect of VD 3 on Th cell differentiation may be mediated by its effect on DCs, which are responsible for T cell differentiation into an effector cell with pro-or antiinflammatory properties, therefore, modulation of APCs is crucial to initiate and maintain adaptive immune response and self-tolerance (Hu and Wan, 2011).In vitro differentiation of DCs in the presence of VD 3 induces a "tolerance state" characterised by low levels of inflammatory cytokines such as IL-12 and TNF, and increased levels of anti-inflammatory cytokines such as IL-10.These cells further induce Treg cell differentiation and autoreactive T cell apoptosis (Penna and Adorini, 2000;Piemonti et al., 2000;van Halteren et al., 2004;Unger et al., 2009).
More studies are needed to completely elucidate the mechanisms of VD 3 in inflammation and immune response.

Vitamin D and tuberculosis
Exposure to sunlight has been known for over centuries to help in the treatment of TB, although the first indicator of VD with antimicrobial activity against Mtb was from studies Figure 2 -Genetic effect of VDR on different cells of the immune system.In macrophages VDR inhibits activation of NF-kB.In monocytes, the production of IL-6, TNF-α and MCP-1 is inhibited.The VD 3 /VDR/RXR complex promotes IFN-γ gene silencing.Blockade of AP-1 and NFAT formation by VD 3 /VDR/RXR complex promotes suppressive effect on transcription of IL-2, IL-9 and IL-17.The immunomodulatory action of VD 3 inhibits the immune response of Th1 cells and modulates the activities of Th2 and Treg cells, through the production of IL-4, and IL-10 and TGF-β, respectively.VD 3 inhibits the production of antibodies.Borborema et al. 10 only in the 1980s, in which VD stimulation of monocytes and macrophages infected with the bacillus showed reduced mycobacterial burden (Crowle et al., 1987;Cohen et al., 1992;Liu et al., 2007;Holick and Chen, 2008).
People with active TB often have VD 2 deficiency (Desai et al., 2012).VD 3 can affect Mtb infection by several immunological defence mechanisms, among them is the production of the specific antimicrobial peptide for Mtb, LL-37, through the activation of the expression of hCAP-18 gene, precursor of this cathelecidin (Selvaraj, 2011;Dini and Bianchi, 2012).Antimicrobial peptides such as defensins and cathelicidins are involved as a first line of defence in preventing infections, including TB (Rivas-Santiago et al., 2008) (Figure 3).
Although cathelicidin are widely distributed in mammals, LL-37 is the only member of the cathelicidin family that has been identified in humans, being found in alveolar macrophages, lymphocytes, neutrophils, and epithelial cells (Martineau et al., 2007;Rivas-Santiago et al., 2008).In addition to direct bactericidal activity, LL-37 also modulates the immune response by attracting monocytes, T cells, and neutrophils to the site of infection (Martineau et al., 2007).The dose-dependently presence of VD 3 in neutrophils and macrophages upregulates the hCAP-18 by binding the VD 3 /VDR/RXR transcriptional complex to the VDRE present in the promoter region of this gene (Liu et al., 2007) (Figure 3).Increased activation of TLRs by the VD 3 also results in the production of defensin-2 and cathelecidins (Adams et al., 2009).
VD 3 reduces Mtb viability by increasing phagosome and lysosome fusion in infected macrophages (Chocano-Bedoya and Ronnenberg, 2009).The pathways used to promote VDinduced phagolysosome formation are independent of classical IFN-γ-dependent macrophage activation and involve products of phosphatidylinositol-3-kinases (PI3K), which helps to regulate the transport of endosomes into lysosomes (Liu et al., 2007) (Figure 3).Furthermore, the presence of the VD 3 is essential for the IFN-γ-mediated antimicrobial function of macrophages (Fabri et al., 2011).Another relevant role of VD 3 in TB control may be its modulating effect on the T cell phenotype, balancing Th1 and Th2 responses (Lin and Flynn, 2010).
Exposure of human monocytes to Mtb upregulates the expression of CYP27B1 and the VDR itself, thus increasing the cell's ability to produce VD 3 at the site of infection and to respond to this hormone more efficiently.However, monocytes differentiate into different macrophage profiles that play different roles in the immune response (Sassi et al., 2018).For example, macrophages formed after IL-15 stimulation respond to VD 3 stimulation by increasing their antimicrobial activity, while phagocytic macrophages obtained after IL-10 stimulation are weakly influenced by VD 3 levels, regardless of their high phagocytic activity (Kim et al., 2018).VD 3 increases the defence capacity of macrophages by inducing their differentiation, phagocytic capacity, and antimicrobial activity, also increasing the expression of cathelicidin.Furthermore, VD 3 inhibits monocyte proliferation and promotes the differentiation of monocytes into macrophages, these effects are mediated by cell surface Fc receptors upregulation and by increase of cellular respiration.VD 3 inhibits the proliferation and maturation of DCs, as well as its immune stimulating properties, leading to the induction of Treg cells.Consequently, VD 2 deficiency results in a state less tolerant to foreign antigens (Christakos et al. 2016).
Genetic alterations in VDR can lead to defects in gene activation or changes in VDR protein structure, both of which can affect VD 3 cell functions.Several polymorphisms in the VDR may also be linked to each other or to unidentified genes that are important determinants of the risk of developing active TB (Lee et al., 2016;de Albuquerque Borborema et al., 2020).
In view of its immunomodulatory action, VD 3 uses three different mechanisms to reduce the risk of several viral infection tract respiratory, such as Influenza A, respiratory syncytial virus (RSV) and rotavirus, which are: physical barrier -mucus secretion, in which presence of fatty acids and enzymes eliminate the pathogen -, innate cellular immunity and adaptive immunity (Greiller and Martineau, 2015).
In innate cellular immunity, there will be greater production of anti-inflammatory cytokines, due to the reduction of pro-inflammatory cytokines and consequent decrease in the activation of cytokine storm (Cantorna et al., 2015).A study realised in an animal model with bleomycininduced pulmonary fibrosis and human lung fibroblast cell line (HLFCLs) shows that VD 3 exerted activity in lung tissue and protective effects in interstitial pneumonia, because in HPFCs there was an increase in VDR mRNA levels and genes that metabolize VD 3 , and in addition, there was a suppression in the dosage of pro-inflammatory cytokines.In the animal model, there was a significant improvement in the symptoms of fibrosis, and the expression of genetic markers was reduced on a diet rich in VD 3 (Tsujino et al., 2019).
In vitro studies demonstrate that this hormone plays a significant role in local "respiratory homeostasis" in this case, the VD 3 /VDR/RXR complex, described in a previous topic, binds to the promoter region of antimicrobial peptides, cathelicidin and defensins, which has direct activity against a spectrum of pathogens, including gram-positive and gram-negative bacteria, enveloped and non-enveloped viruses, and fungi, with an increase in its expression and neutralization of endotoxins, and consequently the reduction of the viral replication rate, which promotes chemotaxis of immune cells to the inflamed organs and induces autophagy (Bikle, 2016;Zdrenghea et al., 2017).
Another study evaluated the effect of the treatment of human cathelicidin LL-37 in mice infected with the Influenza A virus.In this case, infected mice had decreased levels of pro-inflammatory cytokines in the lung compared to untreated mice, suggesting that cathelicidins may be key components of the immune system and in reducing infection and inflammation, as well as therapy derived from this peptide may provide protection (Barlow et al., 2011).
A recent in silico study reported the possible involvement of TLRs that respond to viral ligands, such as TLR3, TLR7 and TLR8, and specifically TLR4 that responds to bacterial ligand, in the recognition and induction of inflammatory response to SARS-CoV-2, in which a hydrophobic and hydrophilic interaction between TLRs with spike protein (TLR-spike) was observed (Choudhury and Mukherjee, 2020).In contrast, a preliminary study reveals that oral administration of cathelicidin improved the symptoms of 11 patients with mild COVID-19, suggesting that improvement in circulating levels of VD 3 may be a constituent in the initial host defence against SARS-CoV-2 infection through the production of antimicrobial peptides (Wan S et al., 2020).
In adaptive immunity, T and B cells present important activities in the immune response to a viral infection and VD 3 can act to contain the pathogen.Individuals with COVID-19 seem to present functional exhaustion of T and B cells, because the main manifestation of severe SARS-CoV-2 infection is lymphopenia (Qin et al., 2020;Bae et al., 2022).However, VD 3 may contain this process through immunomodulation on the adaptive immune response (Bikle, 2022).In severe COVID-19, DCs are activated when they find the SARS-CoV-2 and migrate to the lymph nodes, however, VD 3 inhibits DCs its differentiation and maturation, as well the expression of costimulatory molecules, such as CD40, CD80 and CD86, these aspects induce DCs to present a tolerogenic phenotype, reducing antigen presentation and T cells activation (Vanherwegen et al., 2017;Bikle, 2022).Still, to modulate the immune system, this hormone can induce the production of Treg cells, induce gene transcription of anti-inflammatory cytokines such as IL-10, and a phenotypic change from Th1 to Th2 (Kumar et al., 2021) (Figure 4).
To better understand how the action of the adaptive immune response occurs against SARS-CoV-2 and VD 3 performance in this context, it is interesting to mention about the immune checkpoint inhibitory molecules expressed on the surfaces of T cells, B cells, DCs and natural killers (NK), such as programmed death-1 (PD-1) and their programmed death-1 linker (PD-L1), which play a crucial role in severe inflammation (Wan S et al., 2020).
PD-1, when expressed, is a potent immune regulator because it indicates an activation threshold before an immune response is initiated, thus limiting the activity of T and B cells preventing the proliferation and differentiation of T cells (Schönrich and Raftery, 2019;Aygun, 2022).
In a clinical and experimental study, a positive regulation of PD-L1 mRNA levels in individuals with COVID-19 was reported when compared to controls.The results showed positive regulation of PD-L1 in epithelial cells infected with SARS-CoV-2 and negative regulation of this gene in immune cells such as monocytes, neutrophils and CD4+ T cells, suggesting that this gene may present a positive prognosis to individuals with COVID-19 (Sabbatino et al., 2021).
Interestingly, PD-1/PD-L1, is regulated through several signalling pathways activated by pro-inflammatory cytokines (Aygun, 2022).As already reported, VD 3 has a potential role to reduce inflammation and a recent study reported that this hormone can regulate PD-1/PD-L1 axis by increasing PD-L1 when they are too low or decreasing PD-L1 when are too high, i.e., through T-cell production.This suggests that sufficient levels of VD 3 decrease pro-inflammatory cytokine levels and consequently obtain a favourable immune response to the individual by regulating this pathway (Morita et al., 2021).
In addition to all the aspects mentioned above on VD 3 , it is also known that the deficiency of this hormone may promote dysregulation of the renal angiotensin-aldosterone system (RAAS), which may predispose the individual to a higher risk of cardiovascular diseases and lung diseases, risk features to severe COVID-19 (Bae et al., 2022).The RAAS system operates through two mechanisms: classic and alternative.The classical mechanism is composed of angiotensin converting enzyme (ACE), angiotensin-II (Ang-II) and AT1R, called Ang-II/ACE/AT1R axis, triggering vasoconstriction and production of reactive oxygen species (ROS).The alternative, or counter-regulation, consists of angiotensin-converting enzyme 2 (ACE2), angiotensin 1-7 (Ang1-7) and Mas receptor (MasR), called the Ang1-7/ACE2/MasR axis, which has a vasodilator role and inhibits ROS production.This system is a homeostatic regulation pathway, and the balance between ACE/ACE2 is essential for electrolyte and tissue balance (Patel et al., 2017;Paz Ocaranza et al., 2020).
Thus, when RAAS dysregulation occurs, the classical axis presents excessive activity when compared to the alternative axis.Generally, individuals with systemic arterial hypertension, heart failure or other comorbidity use medications such as ACE inhibitors (iACE) and angiotensin receptor blockers (ARBs), which promote higher ACE2 production (de Kloet et al., 2010;Babajani et al., 2021).ACE is the gateway to SARS-CoV-2 through its S protein, competing with Ang-II blocking ACE2 activity, promoting vasoconstriction and endothelial dysfunction.Therefore, pre-existing comorbidities are related to developing a higher risk of severe COVID-19 and higher mortality (de Lucena et al., 2020;Beyerstedt et al., 2021).
VD 3 acts inhibiting the expression of ACE and stimulating the alternative axis activity, while negatively regulating the classical axis (Babajani et al., 2021).Even if there is greater expression of ACE2, this hormone reduces the entry and replication of viruses, including SARS-CoV-2, through previously mentioned mechanisms.VD3 and E2 in TB and COVID-19 13 In fact, the specific action of VD against SARS-CoV-2 is not yet clearly understood and further genetic studies are still needed to prove the beneficial performance of this hormone in COVID-19 prognosis, but the literature cited so far demonstrate possible mechanisms that are similar to its antimicrobial and antiviral activities.

17β-estradiol (E 2 )
Estrogen refers to a group of female mono phenolic steroid hormones that performs numerous activities throughout the body.Its chemical structure consists of 17 carbon-carbon bonds arranged in four molten rings (Fuentes and Silveyra, 2019).The four estrogens are denominated C 18 steroids since it contains 18 carbons (Patel et al., 2018).They consist of a benzene ring, phenolic group, and a ketone group (estrone or E 1 ) or one group (17β-estradiol or E 2 ), two groups (Estriol or E 3 ) or three hydroxyl groups (Estretrol or E 4 ) (Fuentes and Silveyra, 2019).E 2 is the estrogen with the highest biological activity and consists in a phenolic ring, a hydroxyl (OH) at position 17 and a grouping in the β conformation (Jia et al., 2015).
In women at puberty and pre-menopausal periods, estrogen is mainly synthesized in the ovaries, but can also be produced in the liver and adipose tissue, using cholesterol as a precursor, and regulating various physiological processes such as growth, reproduction, development, and cellular differentiation (Fan et al., 2019;Fuentes and Silveyra, 2019).In post-menopausal women and men, the synthesis of E 2 occurs through the conversion of the male sex hormone, testosterone, and androstenedione, from the estrone under the action of the aromatase-converting enzyme of cytochrome P450 (Österlund and Hurd, 2001;Jia et al., 2015;Saczko et al., 2017).
The physiological functions of E 2 are regulated by binding at estrogen receptors (ERs), the subtypes ERα and ERβ, which perform long-term or rapid actions, i.e., acting through classical or non-classical receptors, genomics (nuclear) or non-genomic (extranuclear), respectively, in which it controls mechanisms of gene expression, protein modification and cell signalling (Moulton, 2018;Trenti et al., 2018) (Figure 5).ERα are found mainly in reproductive tissues (uterus, ovary), breast, adipose tissue, and liver, while Erβ is found in the ovary, cardiorespiratory system and immune system (Jia et al., 2015).
The classical or genomic mechanisms are mediated by ERα and ERβ isoforms with 56% homology and ensembles homo or heterodimers (α-α, β-β, α-β) before binding to estrogen response elements (EREs) to alter gene expression (Moulton, 2018).The genes encoding ERα and ERβ are ESR1 and ESR2, respectively.ESR1 is located on chromosome 6q25.1 and codes a protein with 595 amino acids while ESR2 is located at 14q23.2 and ERβ present 530 amino acids (Cohen et al., 1992;van Halteren et al., 2004).Both ERs have a DNA binding domain and six regions, denominated A to F and divided into four functional domains: amino-terminal domain (domains A and B or NTD) with ligand function domain 1 (AF-1); a DNA binding domain (C domain or DBD) (van Halteren et al., 2004), which contributes to the dimerization of the ER and to the binding to EREs specific sequences and an activation to ligand 2 (AF-2) domain; a D domain which is a region that contains the nuclear localization signal and when binding to estrogen allows the receptor-ligating complexes to perform translocation to the nucleus (Jia et al., 2015;Saczko et al., 2017); and the E/F domain with the carboxy terminal contains the estrogen connection area together with other co-activators (Fuentes and Silveyra, 2019) (Figure 5).
Thus, genomic signalling occurs as follows: the nuclear receptors of estrogen ERα and ERβ act as transcription factors activated by ligands.After E 2 /ERα or ERβ binding in the cytoplasm, a conformational alteration occurs inducing the receptor dimerization (Le Dily and Beato, 2018).This complex is translocated to the nucleus, where it binds to ERE (CAGGTCA) sequence (Trenti et al., 2018;Fuentes and Silveyra, 2019) (Figure 5).
The ERs non-genomic mechanism promotes faster responses (in minutes) through receptors in the plasma membrane that are often associated with the activation of protein-kinase cascades such as PI3K with protein kinase B (PKB or AKT), intracellular calcium mobilization, cyclic adenosine monophosphate (cAMP) generation, potassium current modulation, phospholipase C activation, and NO production (Trenti et al., 2018).
The non-classical mechanism, also known as membraneinitiated steroid signalling (MISS), is mediated by a subunit of ERα associated with a palmitoylation site (Cys447 in humans) with the plasma membrane cytosolic portion.In the membrane, the ERα is connected to the caveolae by direct connection to caveolin-1 (CAV-1) through Ser522, performing transcriptional activity once MISS leads to histone modification and chromatin structure (Björnström and Sjöberg, 2005;Pérez-Cremades et al., 2018).E 2 can also bind to G protein associated with receptors with coupled membrane (GPCRs) and trigger the signalling in many cell types such as immune cells.The E 2 / ER complex can to bind to the receptor of estrogen coupled to G receptor protein 1 (GPER1) and lead to several gene transcriptional activation (Fuentes and Silveyra, 2019).

E 2 and inflammation
ERs are located in several immune system cells able to influence gene regulation (Di Florio et al., 2020).Furthermore, E 2 exerts anti-and pro-inflammatory effects, depending on the cell target, serum levels, organ microenvironment and expression levels from the receptors (Trenti et al., 2018;Fan et al., 2019).
In the adaptive immune system, ERs are present in thymocytes and thymus epithelial cells, modulating T cells differentiation and function (Brown and Su, 2019) promoting production of IFN-γ by Th1 cells in humans and mice, via gene promoter direct interaction (Karpuzoglu-Sahin et al., 2001).E 2 also regulates the anti-inflammatory exchange from Th2 by Serine/threonine-protein kinase 1 (SGK1) activation and promotes Treg cells expansion by regulating FOXP3 expression (Polanczyk et al., 2005).
In the innate immune system, ERs functions control signalling pathways in DCs and macrophages.E 2 /ERα complex may promote pro-inflammatory cytokines in response to TLR stimulation in DCs and macrophages.Interestingly, E 2 inhibits neutrophil activation through metabolic oxidation reduction and adhesion to endothelial cells via positive regulation of the anti-inflammatory protein annexin A1.This mechanism attenuates the release of more potent pro-inflammatory cytokines such as TNF, IL-1β and IL-6 (Hughes et al., 2013).E 2 /ERα complex seems to fine coordinate a balanced pro-inflammatory response by promoting cell differentiation, MHC-II expression and induces IL-6, IL-23, IL-12 and IL-1β production (Douin-Echinard et al., 2008;Kadel and Kovats, 2018).Altogether, those mechanisms act upon tolerogenic phenotype and decreased pro-inflammatory cytokines and chemokines expression by upregulating anti-inflammatory cytokines such as IL-10 and TGF-β (Kadel and Kovats, 2018), i.e., decreasing Th1 and increasing Th2 cytokines.
Additionally, E 2 also reduces PI3K inhibitory signalling and AKT phosphorylation in macrophages, due to the activation of NF-κB impairment (Kovats, 2015).
By preventing the activation of the NF-κB transcription factor family, responsible for the activation of several inflammatory genes, E 2 assures its anti-inflammatory role.In the presence of inflammatory stimuli such as lipopolysaccharide (LPS) or TNF, E 2 activates a rapid response through a nongenomic mechanism, involving the interaction between hormone-activated E 2 /ERα and PI3K, which inhibits p65/RelA (member of NF-κB family) nuclear translocation, blocking inflammatory genes transcription without altering inhibitory-κB kinase (IKK)-Iκ-Bα pathway, that is targeted by several NF-κB inhibiting drugs (Ghisletti et al., 2005).
Iκ-Bα is responsible for binding to NF-κB reducing its access to DNA, while IKK, responsible for inflammatory stimuli, phosphorylates Iκ-Bα signalling it for degradation, which then releases NF-κB to nucleus translocation and regulates the expression of targeted gene.In a study using TNF treated rat aortic smooth muscle cells, E 2 inhibits p65 binding at promoters from inflammatory genes via E 2 /ERβ, while also enhances Iκ-Bα synthesis, therefore augmenting the NF-κB suppression (Xing et al., 2012).Also, by activating the intracellular ERα, E 2 shortens the pro-inflammatory stage in macrophages, leading to an IL-10-dependent "acquired deactivation" phenotype, which results in decreased inflammation and restoration of tissue homeostasis (Villa et al., 2015).In non-genomic signaling, plasma membrane receptors activate PI3K/AKT.The ERα subunit binds to Cys447 and also binds to caveolae through Ser522, inducing transcriptional activity due to histone modification.E 2 also has a link with GPCRs that interacts with E 2 /ER complex and induces transcriptional activation.With its broad activity, E 2 rapidly decreases TLR4 expression in murine macrophages, through G protein-coupled receptor 1 (GPR1) action (Rettew et al., 2010).With low TLR4 expression in alveolar macrophages less allergic airway inflammation is noted since inflammasome nucleotide-binding oligomerization domain leucine-rich repeat and pyrin domain containing 3 (NLRP3) is not recruited/activated.In fact, in female C57BL/6 mice with reduced NLRP3 mRNA levels and downstream products, caspase-1 and IL-1β, resulted in reduced airway inflammation (Cheng et al., 2019).

Women immunologic profile over the lifetime course
Susceptibility to infectious diseases between men and women varies not only according to gender but also according to age.In an intrauterine environment, adverse conditions can cause epigenetic adaptations, leading to altered gene activity that can remain throughout life, which includes immune programming (Gluckman et al., 2005).Many immunological response differences are observed throughout life, however, puberty and the reproductive senescence are remarkable especially in females, which reinforces the hormones role in immune response modulation (Klein and Flanagan, 2016).
Starting in the intrauterine phase, female fetuses have greater adaptability to intrauterine stress than males, which tend to be more chronically inflamed (Klein and Flanagan, 2016).Comparing female and male fetuses, the first ones present greater adaptability to intrauterine stress and lower placenta inflammation in premature when compared with those from male fetuses.This may provide female survival benefits, with better cardiovascular stability to lower levels of circulating cytokines (Goldenberg et al., 2006).Still in intrauterine life, male fetuses have an increased inflammatory response as a reflection of the exacerbated activation of the innate immune response by androgen hormones (Carr et al., 1983;Klein and Flanagan, 2016).
At birth, the transition from placental to the external environment and the bombarding with new antigens, present no difference between sex hormones.However, male new-borns have a higher monocytes count compared to females up to 13 months of age when in environments with high pathogenic load (Bellamy et al., 2000).Male individuals are believed to continue to develop a more active and efficient innate immunity, compared to females, early in life.This may explain the higher NK cell count in boys when compared to girls at the same age (Lee et al., 1996).In addition, a study performed in Nigerian children demonstrated that between 5 and 12 years, females present a lower IgA level, but equivalent levels of IgG and IgM compared to male (Obiandu et al., 2013) (Table 2).

Intrauterine life
Woman: -Increased adaptability to stress (Klein and Flanagan, 2016); -Less inflammation of the placenta; -Lower production of cytokines; -Greater cardiovascular stability.

Man:
-Increased inflammatory response due to exacerbated activation of the innate immune response by androgen hormones (Carr et al., 1983;Klein and Flanagan, 2016).

Man:
-Increased expression of IL-6R (Maggio et al., 2006); -Decreased activation of the immune system and inflammatory cytokines (Kumru et al., 2004).During puberty, sex steroid hormones play a central role in the immune system, with the female hormonal profile being more intense in the inflammatory aspect (Yang and Kozloski, 2011).Regarding sex, women have a higher CD4+ T cell count and a higher proportion of CD4+/CD8+ T cells, while men have a higher number of Treg cells (Afshan et al., 2012).Women at childbearing age have higher levels of inflammatory markers, but slower rates of increased inflammation with increasing age.This may suggest the interaction of sex hormones with inflammatory processes such as vascular disorders and autoimmunity (Tsujino et al., 2019).The E 2 modulating role has been investigated since its hypothetical anti-inflammatory effect that can improve the host's resistance to degenerative diseases to its pro-inflammatory role that can protect women from infectious diseases (Kovats, 2015;Trenti et al., 2018) (Table 2).
Female reproductive senescence due to depletion of ovarian oocytes and loss of ovarian steroids decreases the levels of sex hormones that can interact with these processes and contribute to age changes in inflammation (Giefing-Kröll et al., 2015).As age increases, hormone concentrations go the opposite direction and a faster process of hormone depletion in women is observed, while the immune system of both sexes decreases its efficiency it increases the risk of chronic diseases, especially for women (Castelo-Branco and Soveral, 2014) (Table 2).
Both innate and adaptive immune responses decrease with age and differ between women and men.After menopause, there is a significant increase in IL-1, IL-6, and TNF and a decrease of IFN-γ serum levels (Deguchi et al., 2001).In men, testosterone plays an immunosuppressive role in the production of inflammatory cytokines and its decline with ageing is associated with increased serum levels of IL-6 receptor (IL-6R) (Maggio et al., 2006).The humoral and cell-mediated immune responses to antigenic stimulation, vaccination and infection are greater among women than men (Fish, 2008).Women also have higher baseline levels of Ig and higher antibody responses to viruses at any age than men (Klein et al., 2010).On the other hand, menopausal women have a reduction in the number of B and T cells and a significant increase in the concentrations of IL-1β, IL-6 and TNF (Kumru et al., 2004) (Table 2).

E 2 and tuberculosis
TB is one of the most studied models of sexual dimorphism in respiratory tract infections.Although the prevalence of TB in men depends on geographic region, there is a general trend for the male/female ratio affecting more males with worse outcomes in developing countries, including a higher risk of mortality (Nhamoyebonde and Leslie, 2014;Nnadi et al., 2016;World Health Organization, 2021).This male gender prevalence is also observed when other risk factors such as HIV infection, diabetes mellitus and smoking are combined (Pimpin et al., 2011;Khan et al., 2015;Cabrera-Gaytán et al., 2016).
Men not vaccinated with Bacille Calmette-Guerin (BCG) have been reported to exhibit a stronger IFN-γ response in the purified protein derivative (PPD) skin test than women, which suggests that males exhibit a stronger immune response that may be associated with an uncontrolled inflammatory process and poor health prognosis during Mtb infection (Cabrera-Gaytán et al., 2016).During TB infection, there is also a differential immune response characterized by females having higher levels of CXC Motif Chemokine Ligand 9 (CXCL9) while males exhibiting higher levels of the growth factor derived from platelet subunit B (PDGFB), from serum C-reactive protein (CRP) and from specific antibodies against Mtb, highlighting a stronger innate and humoral immune response in men (Brown et al., 2016;Chavez et al., 2016).
In addition, plasma levels of anti-Mtb drugs such as isoniazid and pyrazinamide are lower in men than in women.This may be related to a worse outcome in treated men (Ramachandran et al., 2017).Interestingly, this higher proportion of affected males is not observed in children, suggesting the role of sex hormones in the pathogenesis of TB (Neyrolles and Quintana-Murci, 2009;Stival et al., 2014).
Older women with reduced E 2 levels (post-menopausal women) have been reported to have an increased risk of Mycobacterium-produced chronic lung infections (Chan and Iseman, 2010).Decreased levels of dehydroepiandrosterone (DHEA), an endogenous intermediate in the conversion of cholesterol to estrogens and androgens, have also been reported in elderly women to be associated with infection with Mycobacterium avium, a non-tuberculous mycobacterial lung infection (Danley et al., 2014).These studies suggest that non-tuberculous mycobacterial infections are also influenced by hormones, which in turn explains the sexual dimorphism in general mycobacterial infections in the respiratory tract (Vázquez-Martínez et al., 2018).
Miliary TB or disseminated TB is an uncommon and severe type of extrapulmonary Mtb infection.This disease can lead to catastrophic outcomes such as adrenal, hepatic, and pancreatic insufficiency, meningitis, and splenomegaly.With a high mortality rate (15%-20% in children and 25%-30% in adults), its incidence is difficult to record due to high underreporting (Rosenthal et al., 2019).On the other hand, patients with genetic susceptibility, immunodeficiency, malnutrition, T2DM, smoking and alcoholism are more susceptible to this clinical manifestation.Among the few case reports in immunocompetent patients, the highest frequency is in healthy adolescents (Hilal et al., 2014;Rosenthal et al., 2019).It is proposed that individuals at puberty have a higher risk of disseminated TB due to hormonal changes that would provide an environment of easy colonization and dissemination for Mtb (Wilcox and Laufer, 1994).
In vitro studies showed that E 2 is capable of inducing a Th1-mediated pro-inflammatory immune response (Ahmed et al., 1999), while testosterone would act by inhibiting the immune response.In an animal study, it was found that castrated mice, which have low levels of androgens and testosterone, had a less harmful clinical outcome than uncastrated mice (Bini et al., 2014) which corroborates the potential immunosuppressive effects of androgen hormones in TB.
It is well established in the literature that women have a more efficient immune system in fighting infections, and that androgen hormones such as E 2 play an important role in containing the disease.On the other hand, the mechanisms by which this hormone performs these activities and which gene pathways are activated have not yet been established, requiring further studies.

E 2 and COVID-19
E 2 acts as a potential key player in providing immunity against certain viral infections.It is associated with providing immunity against acute lung inflammation and the influenza virus, modulating the cytokine storm, and mediating adaptive immune changes (Shabbir et al., 2020).According to WHO, even though men and women have almost equal rates of infection by COVID-19, men tend to have more severe complications, higher rates of hospitalization and deaths (Global Health 50/50, 2022;World Health Organization, 2022).
For most infectious diseases, women are consistently observed to create a more effective immune response than men (Robinson et al., 2011).In general, the female immune system responds more efficiently to pathogens, producing greater amounts of IFN and antibodies.However, this protective effect, mediated mainly by E 2 , is attenuated in post-menopausal women (Straub, 2007).For coronaviruses in particular, women have demonstrated a consistent survival advantage over men both in the current COVID-19 pandemic, as well as the 2003 SARS-CoV and 2012 MERS-CoV epidemics, with substantially lower-case fatality rates (Karlberg, 2004).
Sex differences in inflammation have been well documented and attributed to several factors.Although most immune regulatory genes are encoded by the X chromosome, resulting in a generally stronger immune response in women, this sex difference in inflammatory response is postulated to be largely driven by sex hormones (Giefing-Kröll et al., 2015).Although E 2 plays a complex role in immune system modulation, often in a dose-dependent manner, it is reported to have an anti-inflammatory effect at normal physiological levels in pre-menopausal women (Straub, 2007;Gaskins et al., 2012).Most of the cytokines present in the "cytokine storm" such as IL-6, IL-8 and TNF are inhibited by periovulatory levels of E 2 , while low levels of this hormone can increase inflammatory mediators, which could explain the pro-inflammatory states (Straub, 2007).
In pre-menopausal women, E 2 has an anti-inflammatory effect, because high levels of this hormone, and consequently the action of E 2 /ERα complex inhibits the transcriptional activity of NF-κB and downregulates the gene expression of pro-inflammatory cytokines, such as IL-6, IL-8 and TNF (Gaskins et al., 2012).In postmenopausal women low levels of this hormone are reported that can be supplemented with the use of hormone replacement therapy, especially with E 2 (Giefing-Kröll et al., 2015), in this case, another study indicates that CD4+ monocytes and macrophages derived from monocytes deprived of E 2 express higher levels of CD16, with significant increases in the production of TNF, IL-1β and IL-6 due to the absence of estrogen (Kramer et al., 2004).
In reproductive phase women, E 2 in contraceptive methods was noted as a cellular immunity enhancer in HIVinfected patients (Hel et al., 2010) and in animal models, such as rats, when receiving high doses of E 2 survival rate increased and lung cytokine production after influenza infection decreased (Robinson et al., 2011).
In SARS-CoV-2 infection the activation of essential cellular proteins such as ACE2 and TMPRSS2 are key for cell recognition and virus entry, and both are highly expressed in lung tissue (Hoffmann et al., 2020).In an in vitro study conducted as a biological model for SARS-CoV-2 infection and treatment with E 2 , VERO E6 cell line of monkey kidney, assessing ACE2 and TMPRSS2 mRNA levels indicated a negative regulation of mRNA levels of TMPRSS2 when cells were pre-treated with this hormone.These data suggest that E 2 may reduce SARS-CoV-2 infection through TMPRSS2 inhibition, preventing viral dissemination and minimising ACE2 cleaving to increase the pathogen's entry into the host cell (Lemes et al., 2021).To corroborate these results, ACE2 and TMPRSS2 activation in lung cells were evaluated in another in vitro study investigating the culture of human lung epithelial cells (A549) treated with E 2 .The results showed a negative regulation in ACE2 and TMPRSS2 mRNA levels, suggesting that decreased gene expression may be involved with the lower incidence of morbidity and mortality (Baristaite and Gurwitz, 2022).An important factor affecting gender differences in COVID-19 include not only androgen-mediated transcription of TMPRSS2, but also X-linked effects such as ACE2, the androgen receptor, and TLR7 loci, all located on the X chromosome (Wambier and Goren, 2020).All these studies suggested E 2 as adjuvant therapy and pointed out the need for experimental studies in animal models.
E 2 is known to modulate the risk of cardiovascular diseases (CVDs) and still plays an important role in regulating RAAS expression and activity (Gallagher et al., 1999).The identification of ACE2 as a host cell receptor for SARS-CoV-2 has drawn attention to the functions of this enzyme outside the domain of its role in modulating Ang II metabolism as part of RAS (Zhou et al., 2020).Activation of angiotensin II (Ang II) from the NF-κB pathway increases cytokine synthesis after SARS infection, while E 2 can inhibit it, has great relevance for COVID-19 treatment strategies (Al-Lami et al., 2020).
Corroborating these findings, the E 2 /ERα complex inhibited NF-κB-mediated inflammatory response and cytokine production via lymphocytes, macrophages, and neutrophils (Biswas et al., 2005).CD14+ monocytes and macrophages derived from monocytes deprived of E 2 express higher levels of CD16, with significant increases in the production of TNF, IL-1β and IL-6 due to the absence of E 2 (Kramer et al., 2004).
In summary, the accumulating evidence of a somewhat lower rate of COVID-19 severity in women needs further investigation.Large databases are being generated in response to the pandemic and need to be analysed for sex-related differences in the clinical presentation of the disease, age and medical history, including records of contraceptive use and menopausal hormone therapy (Groban et al., 2020).

Search methodology
This study refers to a review of narrative literature, in which comprehensive bibliographic research was conducted in the scientific databases (PubMed and Scielo) until September 2022.
The requirements proposed for eligible articles in this review were: original data, reviews for conceptualization and English language.Studies with secondary data were not included.Therefore, our search results in the database were accessed, and relevant references were used for the proposed review.

Final considerations
VD 3 and E 2 can act in several immunogenetics routes in order to restrain pathogen infections in the upper respiratory tract.The immune response is under hormonal control and gender differences, indicating that gene regulation differs in men and women and according to age.Herein we summarized gene pathways involved in general immune response in TB and COVID-19, two of the deadliest diseases worldwide, as well as the differences in genetic profiles of individuals.Women in childbearing age present a genetic and hormonal regulation to afford more controlled inflammatory and innate responses resulting in increased survival rate seen in TB and COVID-19.A lot has to be described, but considering how genetic and hormonal profiles influence infection resolution shed light onto the complexity and integrated system of general (populational) and specific (individual) immune response.

Figure 1 -
Figure1-Metabolic and genetic aspects of VD 3 .A) Metabolism of VD 3 .In epidermal cells is found the molecule 7-dehydrocholesterol, which is broken down by UVB radiation from the sun, forming pre-VD 3 .This undergoes first hydroxylation process in liver through CYP2R1 enzyme, having as a product of the reaction to 25-hydroxyvitamin D 2 .This is converted into 1,25α-dihydroxyvitamin D 3 through the second hydroxylation process through CYP27B1 enzyme.B) Chromosomal localization of the VDR gene.VD 3 performs its functions by connecting to the VDR, forming VD 3 /VDR.C) Transcriptional complex of VD 3 /VDR.Gene regulation by genomic site (red arrow) occurs when VD 3 binds to VDBP transporter.The VD 3 /VDR interaction is recruited to nucleus that heterodimerizes with RXRα and RXRβ.These act as transcription factors and bind to the VDREs present in the promoter region of target genes.Gene regulation by means of the alternative site (blue arrow) is a rapid response that occurs when VDR interacts with caveolae and through signal transduction activates the PI3K enzyme that induces intracellular conduction through secondary messages in the promoter region of target genes.
Does not change the amino acid sequence of the VDR protein, therefore could affect mRNA stability and the gene expression of VDR(Salimi et al., 2019).rs1544410 (BsmI) Location: intron 8; Change: A > G.

Figure 3 -
Figure 3 -Mechanism of action of the Mtb in front of VD 3 .The Mtb is phagocytized by the alveolar macrophages, is internalized in phagosome, fuses with lysosome and forms the phagolysosome via IFN-γ.Bacilli remain in the cytoplasmic vacuole and recruit immune cells to maintain the innate response.Mtb can be recognized through TLRs and induces several cascades of intracellular signaling.The presence of VD 3 affects Mtb infection through two mechanisms: recruitment of the VD 3 /VDR/RXR complex to the VDRE present in promoter region of the hCAP-18 gene and consequent production of LL-37, antimicrobial peptide, and formation of IFN-γ independent phagolysosome with activation of PI3K signal transduction.

Figure 4 -
Figure 4 -Immunogenetic activity of VD 3 in COVID-19.VD 3 induces the production of Treg cells.The VD 3 /VDR complex induces expression of anti-inflammatory cytokines.VD 3 inhibits the differentiation and maturation of DCs, preventing migration to lymph nodes and activation of T cells of pro-inflammatory profile.VD 3 regulates expression of PD-L1.The increase in the activity of the alternative axis of RAS induces greater expression of ACE2, VD 3 may decrease viral replication.

Figure 5 -
Figure5-Genomic and non-genomic mechanisms of E 2 .In genomic signaling, E 2 binds to ERα and ERβ receptors in the cytoplasm, which undergo a conformational change, dimerize, and are translocated to nucleus.ERα e ERβ act as transcription factors, and E 2 /ER complex binds to ERE sequences near promoter region inducing transcription.In non-genomic signaling, plasma membrane receptors activate PI3K/AKT.The ERα subunit binds to Cys447 and also binds to caveolae through Ser522, inducing transcriptional activity due to histone modification.E 2 also has a link with GPCRs that interacts with E 2 /ER complex and induces transcriptional activation.