**1. Introduction**

246 Sex Steroids

Zala, S.M., Chan, B.K., Bilbo, S.D., Potts, W.K., Nelson, R.J. & Penn, D.J. (2008). Genetic

0378.

0889-1591.

mediated immunity in rat embryos: role of LHRH in regulation of lymphocyte proliferation. *J. Reprod. Immunol.* Vol.47. No.1. (May 2000), pp. 17–32. ISSN: 0165-

resistance to infection influences a male's sexual attractiveness and modulation of testosterone*. Brain Behav. Immun*. Vol.22. No.3. (March 2008), pp. 381-387. ISSN:

> The immune system must overcome daily challenges from pathogens to protect the body from infection. The success of the immune response to infection relies on the ability to sense and evaluate microbial threats and coordinate their elimination - all the while limiting damage to host tissues. This delicate balance is achieved through coordinated action of innate and adaptive arms of the immune system. The main distinguishing characteristic of these two branches of the immune response is the way they recognize antigens. Whereas innate immunity relies on germline-encoded receptors to sense the presence of pathogens, adaptive immunity employs a highly diverse set of receptors generated through somatic mutation and recombination that are tailored to specific pathogens. The second major defining characteristic of the adaptive immune system is the development of immunological memory that manifests with increased functionality and frequency of responding cells upon re-exposure to the same antigen.

> Several immune cell subsets play a critical role in mediating innate immune responses. These include neutrophils, natural killer (NK) cells, dendritic cells (DC), and macrophages. These cells are alerted to the presence of pathogens via recognition of microbial non-self, missing self, or altered self (Medzhitov and Janeway 2002). Recognition of microbial entities relies on the detection of conserved molecular patterns referred to as pathogen-associated molecular patterns (PAMPs) by pattern recognition receptors (PRRs) of the innate immune system. The three best-characterized families of PRRs are the toll-like receptors (TLR), the NOD-Like Receptors (NLR) and the retinoic acid-inducible gene (RIG-I)-like RNA helicases (RLHs). Following PAMP encounter, these receptors initiate signaling cascades that drive production of several anti-microbial molecules that ultimately limit pathogen replication and spread. Furthermore innate immune cells activate the adaptive arm of the immune system through the action of soluble mediators and antigen processing and presentation (Kabelitz and Medzhitov 2007; Medzhitov 2007).

> DCs can be divided into myeloid (mDC) also known as conventional DCs and plasmacytoid DCs (pDCs) (Sallusto and Lanzavecchia 1994; Olweus, BitMansour et al.

Modulation of Immune Senescence by Menopause and Hormone Therapy 249

T cells are broadly divided into CD4 and CD8 T cells (90%) as well as T cells (10%). T cells recognize antigens in the form of small peptides bound to major histocompatibility (MHC) class I or class II molecules. CD8 T cells, commonly known as cytotoxic T cells, recognize foreign peptide bound to MHC-I molecules and have evolved to monitor for and eliminate tumor cells and cells harboring intracellular pathogens. CD4 T cells, or helper T cells, recognize foreign peptides bound to MHC-II and secrete a broad range of cytokines, which play a crucial role in the maturation of the B cell response as well as the development and establishment of the CD8 T cell response. Once activated, CD4 T cells can differentiate into four major lineages, Th1, Th2, Th17, and regulatory (Treg) cells. These subsets can be distinguished by their unique cytokine production profiles and their functions: Th1 cells predominantly produce IFNγ and mediate responses to intracellular viral and bacterial pathogens; Th2 cells produce IL-4, IL-5, IL-9, IL-13, and IL-25 and are critical for expelling extracellular parasites such as helminths; Th17 cells are responsible for controlling extracellular bacteria and fungi through their production of IL-17a, IL-17f, and IL-22; Treg cells are important in maintaining immune tolerance, as well as in regulating lymphocyte homeostasis, activation and function and produce regulatory cytokines TGF and IL-10

The maintenance of a structurally and functionally diverse T cell repertoire is a dynamic process governed by thymic output and the exposure to antigen and cytokines, which modulate T cell survival, proliferation and death. A rigorous analysis developed over several years has demonstrated that human CD4 and CD8 T cells can be subdivided into naïve, central memory (CM) and effector memory (EM) in addition to several transitional subsets (Lanzavecchia and Sallusto 2005). Studies have identified IL-7 and IL-15 as key players in T cell homeostasis (Surh and Sprent 2008). IL-7 and MHC contact are critical for the survival of naïve T cells (Jared F. Purton 2007). These signals do not induce differentiation but rather a low level of homeostatic proliferation and promote the survival of these cells. Memory T cells on the other hand, do not require MHC contact for survival (Boyman, Purton et al. 2007), but do require both IL-7 and IL-15 (Purton, Tan et al. 2007). Upon antigen encounter, naïve antigen-specific B cells quickly differentiate into short-lived plasma cells that can immediately produce antibodies while others travel to germinal centers to undergo the longer process of becoming memory cells and long-lived plasma cells (Tangye and Tarlinton 2009). B cells within the germinal centers undergo vigorous proliferation, isotype class switching (from IgM to IgG, IgA or IgE) and somatic hypermutation thereby differentiating into memory and plasma cells that produce high affinity antibodies (Tarlinton 1998). Naïve B cells express IgM and IgD and are induced to class switch by T cell produced cytokines (Chaplin 2010). For example, IL-10 and possibly IFN-γ induces switching to IgG, while IL-4 and IL-13 induce switching to IgE, and TGF-β to IgA (Chaplin 2010). Different antibody classes target different pathogens as a result of the activation of different TH types. IgA are produced in response to infection of mucosal surfaces (Tiwari, Agrawal et al. 2010), IgE are important for allergic responses (Johansson) and IgG are critical for the anti-viral immune response. Long lived plasma cells continue to secrete antibodies well after antigen clearance while memory B can rapidly proliferate and differentiate into plasma cells upon antigen re-exposure (Tangye and Tarlinton 2009). B cells are also capable of T cell independent activation by polymeric antigens with a repeating structure such as LPS. However somatic mutation does not usually occur in this process and

(Zhu and Paul 2010).

immune response tends to be weak (Chaplin 2010).

1997). Myeloid DCs detect pathogens via TLR-3, -4, -7, and -8 and respond to infection by upregulating surface expression of CD40 and CD86 and producing IL-12 (Ketloy, Engering et al. 2008). Their main function is to process and present pathogen-derived peptides to naïve T cells (Siegal, Kadowaki et al. 1999). On the other hand, pDCs recognize viral DNA and RNA via TLR-7 and TLR-9 and produce vast amounts of type I interferons, which are potent antiviral cytokines, such as interferon α (IFNα) in response to viral infection (Cella, Jarrossay et al. 1999; Teleshova, Kenney et al. 2004; Chung, Amrute et al. 2005; Ketloy, Engering et al. 2008).

NK cells mediate the recognition of missing and altered self through the expression of inhibitory and activation receptors (Christopher E. Andoniou 2008). These receptors are member of either the immunoglobulin-like superfamily (IgSF) or the C-type lectin-like receptor (CTLR) superfamily (Radaev and Sun 2003). Recognition of MHC class I molecules is mediated by killer inhibitory receptors (KIR) such as CD94/NKG2 heterodimers/complexes, which deliver an inhibitory signal to NK cells (Biron, Nguyen et al. 1999; Biassoni 2008). Some viruses down-regulate MHC class I molecules to evade detection by CD8 T cells (discussed later). However, NK cells that do not receive a signal through inhibitory receptors receive an activation signal and can eliminate the infected cells (Biassoni 2008). Cell damage and some additional viral infections can also result in the upregulation of stress-induced molecules such as MIC-A, MIC-B, and ULBPs (Radaev and Sun 2003). These altered self-molecules function as ligands for NK cell activating receptors such as NKG2D (Radaev and Sun 2003; Biassoni 2008). NK cells can be subdivided based on the expression of CD16 (Lanier 2008). The majority of blood and spleen resident NK cells are CD16pos (85-90%); they are highly cytotoxic and secrete moderate amounts of inflammatory cytokines (Werner Held 2008). The CD16neg NK cells cannot kill target cells but they secrete large amounts of inflammatory cytokines.

Neutrophils and macrophages play a critical role in the elimination of pathogens via phagocytosis. Neutrophils are short-lived cells that are recruited by a chemotactic gradient into infected/inflamed tissues where they then phagocytose bacteria (Svanborg, Godaly et al. 1999). Neutrophils can also kill bacteria by respiratory burst, the release of reactive oxygen species (Dahlgren and Karlsson 1999), or the release of antimicrobials (Medzhitov 2003). Neutrophils are required for the clearance of bacteria from mucosal sites (Svanborg, Godaly et al. 1999). Macrophages also play a critical role in elimination of pathogens via phagocytosis, pinocytosis, or receptor-mediated endocytosis (Aderem and Underhill 1999). As described for DCs, macrophages express several PRRs, notably TLR 4 (Aderem and Underhill 1999). Activation of PRRs on macrophages activates the release of intracellular antimicrobial molecules (Linehan, Martinez-Pomares et al. 2000) as well as inflammatory cytokines such as IL-6, IL-8, and TNF (Larsson, Larsson et al. 1999; Beutler 2000). Like DCs, macrophages can also stimulate lymphocytes and initiate the development of the adaptive immune response (Beutler 2000).

The adaptive immune branch is composed of B and T lymphocytes, which unlike cells of the innate immune system can generate a response tailored specifically to each pathogen. This specificity is acquired through the expression of diverse, clonally distributed antigen receptors on T and B cells. The initial diversity is produced in primary lymphoid organs (the thymus in the case of T cells and the bone marrow in the case of B cells) through a series of gene recombination events; further diversification occurs by somatic hypermutation of the B-cell receptor (BCR, antibody) and by functional diversification of effector T cells.

1997). Myeloid DCs detect pathogens via TLR-3, -4, -7, and -8 and respond to infection by upregulating surface expression of CD40 and CD86 and producing IL-12 (Ketloy, Engering et al. 2008). Their main function is to process and present pathogen-derived peptides to naïve T cells (Siegal, Kadowaki et al. 1999). On the other hand, pDCs recognize viral DNA and RNA via TLR-7 and TLR-9 and produce vast amounts of type I interferons, which are potent antiviral cytokines, such as interferon α (IFNα) in response to viral infection (Cella, Jarrossay et al. 1999; Teleshova, Kenney et al. 2004; Chung,

NK cells mediate the recognition of missing and altered self through the expression of inhibitory and activation receptors (Christopher E. Andoniou 2008). These receptors are member of either the immunoglobulin-like superfamily (IgSF) or the C-type lectin-like receptor (CTLR) superfamily (Radaev and Sun 2003). Recognition of MHC class I molecules is mediated by killer inhibitory receptors (KIR) such as CD94/NKG2 heterodimers/complexes, which deliver an inhibitory signal to NK cells (Biron, Nguyen et al. 1999; Biassoni 2008). Some viruses down-regulate MHC class I molecules to evade detection by CD8 T cells (discussed later). However, NK cells that do not receive a signal through inhibitory receptors receive an activation signal and can eliminate the infected cells (Biassoni 2008). Cell damage and some additional viral infections can also result in the upregulation of stress-induced molecules such as MIC-A, MIC-B, and ULBPs (Radaev and Sun 2003). These altered self-molecules function as ligands for NK cell activating receptors such as NKG2D (Radaev and Sun 2003; Biassoni 2008). NK cells can be subdivided based on the expression of CD16 (Lanier 2008). The majority of blood and spleen resident NK cells are CD16pos (85-90%); they are highly cytotoxic and secrete moderate amounts of inflammatory cytokines (Werner Held 2008). The CD16neg NK cells cannot kill target cells but they secrete

Neutrophils and macrophages play a critical role in the elimination of pathogens via phagocytosis. Neutrophils are short-lived cells that are recruited by a chemotactic gradient into infected/inflamed tissues where they then phagocytose bacteria (Svanborg, Godaly et al. 1999). Neutrophils can also kill bacteria by respiratory burst, the release of reactive oxygen species (Dahlgren and Karlsson 1999), or the release of antimicrobials (Medzhitov 2003). Neutrophils are required for the clearance of bacteria from mucosal sites (Svanborg, Godaly et al. 1999). Macrophages also play a critical role in elimination of pathogens via phagocytosis, pinocytosis, or receptor-mediated endocytosis (Aderem and Underhill 1999). As described for DCs, macrophages express several PRRs, notably TLR 4 (Aderem and Underhill 1999). Activation of PRRs on macrophages activates the release of intracellular antimicrobial molecules (Linehan, Martinez-Pomares et al. 2000) as well as inflammatory cytokines such as IL-6, IL-8, and TNF (Larsson, Larsson et al. 1999; Beutler 2000). Like DCs, macrophages can also stimulate lymphocytes and initiate the development of the adaptive

The adaptive immune branch is composed of B and T lymphocytes, which unlike cells of the innate immune system can generate a response tailored specifically to each pathogen. This specificity is acquired through the expression of diverse, clonally distributed antigen receptors on T and B cells. The initial diversity is produced in primary lymphoid organs (the thymus in the case of T cells and the bone marrow in the case of B cells) through a series of gene recombination events; further diversification occurs by somatic hypermutation of the

B-cell receptor (BCR, antibody) and by functional diversification of effector T cells.

Amrute et al. 2005; Ketloy, Engering et al. 2008).

large amounts of inflammatory cytokines.

immune response (Beutler 2000).

T cells are broadly divided into CD4 and CD8 T cells (90%) as well as T cells (10%). T cells recognize antigens in the form of small peptides bound to major histocompatibility (MHC) class I or class II molecules. CD8 T cells, commonly known as cytotoxic T cells, recognize foreign peptide bound to MHC-I molecules and have evolved to monitor for and eliminate tumor cells and cells harboring intracellular pathogens. CD4 T cells, or helper T cells, recognize foreign peptides bound to MHC-II and secrete a broad range of cytokines, which play a crucial role in the maturation of the B cell response as well as the development and establishment of the CD8 T cell response. Once activated, CD4 T cells can differentiate into four major lineages, Th1, Th2, Th17, and regulatory (Treg) cells. These subsets can be distinguished by their unique cytokine production profiles and their functions: Th1 cells predominantly produce IFNγ and mediate responses to intracellular viral and bacterial pathogens; Th2 cells produce IL-4, IL-5, IL-9, IL-13, and IL-25 and are critical for expelling extracellular parasites such as helminths; Th17 cells are responsible for controlling extracellular bacteria and fungi through their production of IL-17a, IL-17f, and IL-22; Treg cells are important in maintaining immune tolerance, as well as in regulating lymphocyte homeostasis, activation and function and produce regulatory cytokines TGF and IL-10 (Zhu and Paul 2010).

The maintenance of a structurally and functionally diverse T cell repertoire is a dynamic process governed by thymic output and the exposure to antigen and cytokines, which modulate T cell survival, proliferation and death. A rigorous analysis developed over several years has demonstrated that human CD4 and CD8 T cells can be subdivided into naïve, central memory (CM) and effector memory (EM) in addition to several transitional subsets (Lanzavecchia and Sallusto 2005). Studies have identified IL-7 and IL-15 as key players in T cell homeostasis (Surh and Sprent 2008). IL-7 and MHC contact are critical for the survival of naïve T cells (Jared F. Purton 2007). These signals do not induce differentiation but rather a low level of homeostatic proliferation and promote the survival of these cells. Memory T cells on the other hand, do not require MHC contact for survival (Boyman, Purton et al. 2007), but do require both IL-7 and IL-15 (Purton, Tan et al. 2007).

Upon antigen encounter, naïve antigen-specific B cells quickly differentiate into short-lived plasma cells that can immediately produce antibodies while others travel to germinal centers to undergo the longer process of becoming memory cells and long-lived plasma cells (Tangye and Tarlinton 2009). B cells within the germinal centers undergo vigorous proliferation, isotype class switching (from IgM to IgG, IgA or IgE) and somatic hypermutation thereby differentiating into memory and plasma cells that produce high affinity antibodies (Tarlinton 1998). Naïve B cells express IgM and IgD and are induced to class switch by T cell produced cytokines (Chaplin 2010). For example, IL-10 and possibly IFN-γ induces switching to IgG, while IL-4 and IL-13 induce switching to IgE, and TGF-β to IgA (Chaplin 2010). Different antibody classes target different pathogens as a result of the activation of different TH types. IgA are produced in response to infection of mucosal surfaces (Tiwari, Agrawal et al. 2010), IgE are important for allergic responses (Johansson) and IgG are critical for the anti-viral immune response. Long lived plasma cells continue to secrete antibodies well after antigen clearance while memory B can rapidly proliferate and differentiate into plasma cells upon antigen re-exposure (Tangye and Tarlinton 2009). B cells are also capable of T cell independent activation by polymeric antigens with a repeating structure such as LPS. However somatic mutation does not usually occur in this process and immune response tends to be weak (Chaplin 2010).

Modulation of Immune Senescence by Menopause and Hormone Therapy 251

female and male mice (Klein 2004). These data are consistent with the hypothesis that estrogen

As described for infections, women also generate a more robust response to most vaccines as evidenced by higher rates of seroconversion and lower rates of disease after vaccination than men (Cook 2008; Klein, Jedlicka et al. 2010) as well as higher plasma levels of immunoglobulins than men (Ansar Ahmed, Penhale et al. 1985). In an influenza vaccine trial, participants aged 18-49 were given either a full or half dose of vaccine. Women who received a half dose developed an equivalent antibody response as men who received the full dose of vaccine (Engler, Nelson et al. 2008). Similarly, vaccines against HSV-2 also show sex differences in immunogenicity and efficacy. Early vaccine formulations showed some protection in women (26%) and no protection in men (4%) (Corey, Langenberg et al. 1999). More recent subunit vaccines expressing glycoprotein D resulted in 73 to 74% protection in HSV negative women while protection in men remained negligible (11%) (Stanberry,

The mechanisms by which ovarian steroids modulate the immune response are beginning to emerge. Several lines of evidence suggest that E2 enhances the immune response whereas progesterone dampens it. For instance, prolonged exposure to progesterone in the form of the contraceptive Depo-Provera (Depo) increases susceptibility of female mice to HSV-2 genital infection (Gillgrass, Ashkar et al. 2003) and of female nonhuman primates to *Chlamydia trachomatis* (Kaushic, Murdin et al. 1998), SIV (Marx, Spira et al. 1996) and SHIV (Trunova, Tsai et al. 2006). Clinical studies also found associations between Depo use and increased chlamydia, HSV-2, HIV and HPV incidence in adult women (Marx, Spira et al. 1996; Baeten, Nyange et al. 2001; Brabin 2002; Morrison, Richardson et al. 2007). In contrast to Depo treatment, E2 administration to ovariectomized (OVX) female mice protected them from HSV-2 infection (Gillgrass, Fernandez et al. 2005). Similarly, female rhesus macaques treated with estrogen were protected from SIV transmission (Smith, Baskin et al. 2000). Interestingly, vaccination studies in humans indicate that vaginal immunizations might be more effective for induction of genital tract antibodies if performed during the mid-follicular phase of the

menstrual cycle when estrogen levels are highest (Kozlowski, Williams et al. 2002).

Estrogen and progesterone can directly modulate T and B cell function or indirectly impact their function by modifying the function of innate immune cells such as DCs, or a combination of both. There are two types of nuclear estrogen receptors (ER): and , which form homo and heterodimers (Kovats and Agrawal 2010). The expression of ER has been reported on lymphocytes, DCs, macrophages, monocytes, NK cells, and mast cells (Suenaga, Evans et al. 1998; Komi and Lassila 2000; Curran, Berghaus et al. 2001; Grimaldi, Cleary et al. 2002; Mor, Sapi et al. 2003; Paharkova-Vatchkova, Maldonado et al. 2004; Phiel, Henderson et al. 2005; Harkonen and Vaananen 2006). The level of expression differs between immune cell types. For instance, CD4 T cells express higher amounts of ER than ER while the inverse expression profile is observed in B cells (Phiel, Henderson et al. 2005). CD8 T cells and monocytes express only low amounts of both receptor types (Phiel, Henderson et al. 2005). This difference in ER expression levels is likely to result in differential modulation of

Progesterone receptors (PR) are not as ubiquitous as ERs and no nuclear PR have been detected in peripheral blood mononuclear cells (PBMC) (Kovats and Agrawal 2010). T cells

promotes a protective Th1 response following parasitic infections.

Spruance et al. 2002; Bernstein, Aoki et al. 2005).

the of these immune cells by estradiol.

**2.1 Mechanisms of action of female sex hormomes** 

## **2. Gender and the immune response to infection/vaccination**

The incidence and severity of several viral diseases is higher in men than women (Klein 2010). For instance, coxsackie virus associated myocarditis occurs more often in men than women (Woodruff 1980). These gender differences were recapitulated by a murine infection model, where pro-inflammatory cytokines TNF and IL-1 are induced more strongly in male mice, resulting in the increased recruitment and accumulation of macrophages in the heart and the subsequent development of myocarditis (Huber and Pfaeffle 1994; Huber, Kupperman et al. 1999; Huber 2005). Adult women also generate a more robust cell mediated response following cytomegalovirus (CMV) infection with higher IFN and IL-2 production (Villacres, Longmate et al. 2004), a stronger humoral response to Epstein Barr virus (EBV) (Wagner, Hornef et al. 1994), and a better immune response to herpes simplex virus (HSV)-1 and 2 than men (Han, Lundberg et al. 2001). During human immune deficiency virus (HIV) infection premenopausal women have higher CD4 lymphocyte counts throughout infection and lower viral loads early during infection than men (van Benthem, Vernazza et al. 2002). Moreover, HIV+ women have higher levels of CD8+ T cell activation than men with equivalent viral loads (Meier, Chang et al. 2009). Similarly, female mice generate more robust immune responses and are better protected following infection with vesicular stomatitis virus and picornavirus (Curiel, Miller et al. 1993; Barna, Komatsu et al. 1996)

It is now well recognized that men experience greater morbidity and mortality due to bacterial infection and sepsis after trauma than women (reviewed by Marriott et al. (Marriott and Huet-Hudson 2006)). Moreover, more men develop severe septic shock than women (Schroder, Kahlke et al. 1998; Schroder, Kahlke et al. 2000; Wichmann, Inthorn et al. 2000). Similarly, male gender is a risk factor for major infections after surgery (Offner, Moore et al. 1999). The notion that males are more vulnerable to bacterial infections than females is supported by animal studies. *Mycobacterium marinum* infection in male mice results in higher bacterial burden and worse disease outcome than females (Yamamoto, Saito et al. 1991). Male rats also experience higher mortality than females following intravenous injection of LPS (Merkel, Alexander et al. 2001). Similar findings were reported in mice models of sepsis (Zellweger, Wichmann et al. 1997; Diodato, Knoferl et al. 2001). This gender difference in survival is most likely mediated by a difference in cytokine production. Whereas male patients produced higher levels of the inflammatory cytokines TNF and IL-6 during sepsis, females produced higher levels of the regulatory cytokine IL-10 (Schroder, Kahlke et al. 1998; Offner, Moore et al. 1999).

Parasitic infections also show a strong sex bias with higher prevalence of infection and disease severity in men compared to women (Klein 2004). This increased resistance seems to be mediated by a gender difference in T cell polorization. Female mice generate a Th1 response following infection with *Plasmodium brasiliensis* whereas males produce a Th2 response (Pinzan, Ruas et al. 2010). Moreover, when castrated male mice are treated with 17ß estradiol (E2), their spleen cells produced higher levels of IFN and lower levels of IL-10 following stimulation with *P. brasiliensis* compared to control males (Pinzan, Ruas et al. 2010). Similarly, ovariectomized (OVX) mice treated with E2 produced higher levels of IFN and IL-10 (associated with a protective response) as well as higher antibody responses after *Plasmodium chabaudi* infection compared to OVX mice treated with placebo (Klein, Easterbrook et al. 2008). OVX mice receiving E2 also experienced less weight and hematocrit loss, as well as less hypothermia following malaria infection than OVX mice receiving placebo (Klein, Easterbrook et al. 2008). Finally, E2 treatment induces resistance to *Toxoplasma gondii* infection in both

The incidence and severity of several viral diseases is higher in men than women (Klein 2010). For instance, coxsackie virus associated myocarditis occurs more often in men than women (Woodruff 1980). These gender differences were recapitulated by a murine infection model, where pro-inflammatory cytokines TNF and IL-1 are induced more strongly in male mice, resulting in the increased recruitment and accumulation of macrophages in the heart and the subsequent development of myocarditis (Huber and Pfaeffle 1994; Huber, Kupperman et al. 1999; Huber 2005). Adult women also generate a more robust cell mediated response following cytomegalovirus (CMV) infection with higher IFN and IL-2 production (Villacres, Longmate et al. 2004), a stronger humoral response to Epstein Barr virus (EBV) (Wagner, Hornef et al. 1994), and a better immune response to herpes simplex virus (HSV)-1 and 2 than men (Han, Lundberg et al. 2001). During human immune deficiency virus (HIV) infection premenopausal women have higher CD4 lymphocyte counts throughout infection and lower viral loads early during infection than men (van Benthem, Vernazza et al. 2002). Moreover, HIV+ women have higher levels of CD8+ T cell activation than men with equivalent viral loads (Meier, Chang et al. 2009). Similarly, female mice generate more robust immune responses and are better protected following infection with vesicular stomatitis virus and picornavirus

It is now well recognized that men experience greater morbidity and mortality due to bacterial infection and sepsis after trauma than women (reviewed by Marriott et al. (Marriott and Huet-Hudson 2006)). Moreover, more men develop severe septic shock than women (Schroder, Kahlke et al. 1998; Schroder, Kahlke et al. 2000; Wichmann, Inthorn et al. 2000). Similarly, male gender is a risk factor for major infections after surgery (Offner, Moore et al. 1999). The notion that males are more vulnerable to bacterial infections than females is supported by animal studies. *Mycobacterium marinum* infection in male mice results in higher bacterial burden and worse disease outcome than females (Yamamoto, Saito et al. 1991). Male rats also experience higher mortality than females following intravenous injection of LPS (Merkel, Alexander et al. 2001). Similar findings were reported in mice models of sepsis (Zellweger, Wichmann et al. 1997; Diodato, Knoferl et al. 2001). This gender difference in survival is most likely mediated by a difference in cytokine production. Whereas male patients produced higher levels of the inflammatory cytokines TNF and IL-6 during sepsis, females produced higher levels of the regulatory cytokine IL-

Parasitic infections also show a strong sex bias with higher prevalence of infection and disease severity in men compared to women (Klein 2004). This increased resistance seems to be mediated by a gender difference in T cell polorization. Female mice generate a Th1 response following infection with *Plasmodium brasiliensis* whereas males produce a Th2 response (Pinzan, Ruas et al. 2010). Moreover, when castrated male mice are treated with 17ß estradiol (E2), their spleen cells produced higher levels of IFN and lower levels of IL-10 following stimulation with *P. brasiliensis* compared to control males (Pinzan, Ruas et al. 2010). Similarly, ovariectomized (OVX) mice treated with E2 produced higher levels of IFN and IL-10 (associated with a protective response) as well as higher antibody responses after *Plasmodium chabaudi* infection compared to OVX mice treated with placebo (Klein, Easterbrook et al. 2008). OVX mice receiving E2 also experienced less weight and hematocrit loss, as well as less hypothermia following malaria infection than OVX mice receiving placebo (Klein, Easterbrook et al. 2008). Finally, E2 treatment induces resistance to *Toxoplasma gondii* infection in both

**2. Gender and the immune response to infection/vaccination** 

(Curiel, Miller et al. 1993; Barna, Komatsu et al. 1996)

10 (Schroder, Kahlke et al. 1998; Offner, Moore et al. 1999).

female and male mice (Klein 2004). These data are consistent with the hypothesis that estrogen promotes a protective Th1 response following parasitic infections.

As described for infections, women also generate a more robust response to most vaccines as evidenced by higher rates of seroconversion and lower rates of disease after vaccination than men (Cook 2008; Klein, Jedlicka et al. 2010) as well as higher plasma levels of immunoglobulins than men (Ansar Ahmed, Penhale et al. 1985). In an influenza vaccine trial, participants aged 18-49 were given either a full or half dose of vaccine. Women who received a half dose developed an equivalent antibody response as men who received the full dose of vaccine (Engler, Nelson et al. 2008). Similarly, vaccines against HSV-2 also show sex differences in immunogenicity and efficacy. Early vaccine formulations showed some protection in women (26%) and no protection in men (4%) (Corey, Langenberg et al. 1999). More recent subunit vaccines expressing glycoprotein D resulted in 73 to 74% protection in HSV negative women while protection in men remained negligible (11%) (Stanberry, Spruance et al. 2002; Bernstein, Aoki et al. 2005).

#### **2.1 Mechanisms of action of female sex hormomes**

The mechanisms by which ovarian steroids modulate the immune response are beginning to emerge. Several lines of evidence suggest that E2 enhances the immune response whereas progesterone dampens it. For instance, prolonged exposure to progesterone in the form of the contraceptive Depo-Provera (Depo) increases susceptibility of female mice to HSV-2 genital infection (Gillgrass, Ashkar et al. 2003) and of female nonhuman primates to *Chlamydia trachomatis* (Kaushic, Murdin et al. 1998), SIV (Marx, Spira et al. 1996) and SHIV (Trunova, Tsai et al. 2006). Clinical studies also found associations between Depo use and increased chlamydia, HSV-2, HIV and HPV incidence in adult women (Marx, Spira et al. 1996; Baeten, Nyange et al. 2001; Brabin 2002; Morrison, Richardson et al. 2007). In contrast to Depo treatment, E2 administration to ovariectomized (OVX) female mice protected them from HSV-2 infection (Gillgrass, Fernandez et al. 2005). Similarly, female rhesus macaques treated with estrogen were protected from SIV transmission (Smith, Baskin et al. 2000). Interestingly, vaccination studies in humans indicate that vaginal immunizations might be more effective for induction of genital tract antibodies if performed during the mid-follicular phase of the menstrual cycle when estrogen levels are highest (Kozlowski, Williams et al. 2002).

Estrogen and progesterone can directly modulate T and B cell function or indirectly impact their function by modifying the function of innate immune cells such as DCs, or a combination of both. There are two types of nuclear estrogen receptors (ER): and , which form homo and heterodimers (Kovats and Agrawal 2010). The expression of ER has been reported on lymphocytes, DCs, macrophages, monocytes, NK cells, and mast cells (Suenaga, Evans et al. 1998; Komi and Lassila 2000; Curran, Berghaus et al. 2001; Grimaldi, Cleary et al. 2002; Mor, Sapi et al. 2003; Paharkova-Vatchkova, Maldonado et al. 2004; Phiel, Henderson et al. 2005; Harkonen and Vaananen 2006). The level of expression differs between immune cell types. For instance, CD4 T cells express higher amounts of ER than ER while the inverse expression profile is observed in B cells (Phiel, Henderson et al. 2005). CD8 T cells and monocytes express only low amounts of both receptor types (Phiel, Henderson et al. 2005). This difference in ER expression levels is likely to result in differential modulation of the of these immune cells by estradiol.

Progesterone receptors (PR) are not as ubiquitous as ERs and no nuclear PR have been detected in peripheral blood mononuclear cells (PBMC) (Kovats and Agrawal 2010). T cells

Modulation of Immune Senescence by Menopause and Hormone Therapy 253

Immuno-senescent changes have been described for both innate and adaptive immunity. Specifically, circulating monocyte numbers are increased in the elderly, although circulating neutrophil numbers remain unaltered (Chatta, Andrews et al. 1993; Born, Uthgenannt et al. 1995; Lord, Butcher et al. 2001; Della Bella, Bierti et al. 2007). This may reflect the skewing of bone marrow hematopoietic stem cell (HSC) progenitors in the elderly towards the myeloid lineage (Beerman, Bhattacharya et al. 2010). Nonetheless, age-related decreases in circulating mDC numbers have been reported (Della Bella, Bierti et al. 2007). In addition, aged myeloid cells exhibit hyporesponsiveness to several innate stimuli, which may reflect reduced expression of PRR and their downstream signaling mediators, or increased negative regulation of these pathways (Dunston and Griffiths 2010; Shaw, Joshi et al. 2010). Furthermore, innate immune function may be compromised by diminished phagocytic activity in the elderly (Wenisch, Patruta et al. 2000; Lloberas and Celada 2002), compounded by reduced superoxide production and intracellular killing ability in the case of Grampositive bacteria (Lord, Butcher et al. 2001). Some reports have suggested that although NK cell numbers are conserved with age (Tarazona 2009), there is a decrease in proliferation and cytokine production (Mocchegiani and Malavolta 2004; Murasko and Jiang 2005; Zhang, Wallace et al. 2007). Changes in NK cytotoxicity with age are somewhat controversial with some studies showing a decrease while others show no change (Tarazona 2009). Preserved NK cytotoxicity is associated with lower infection and mortality rates and better vaccine response in the elderly (Ogata, Yokose et al. 1997; Mysliwska, Trzonkowski et al. 2004). Moreover, aging is associated with an increase in CD56dim NK cells which are cytotoxic and a decrease in CD56bright cells which are immuno-regulatory (Borrego, Alonso et al. 1999). Age-related changes in frequency and function of innate immune cells impact the protective immune response by decreasing anti-bacterial function as well as by impacting antigen

presentation and the generation of adaptive immunity in the elderly.

and increased inflammation (Vallejo, Weyand et al. 2004).

Although, it is clear that aging affects innate immune function, accumulating evidence indicate that the adaptive arm of the immune system, and more specifically in the T cell compartment, exhibits more profound and consistent changes than the innate arm (Pawelec, Larbi et al. 2009). The hallmarks of T cell senescence include: 1) loss of naïve T cells and accumulation of memory T cells; 2) reduced CD4:CD8 T cell ratio; 3) increased T cell production of inflammatory cytokines; and 4) reduced T cell proliferative ability. Several phenomena are believed to contribute to these changes. Decreased production of hematopoietic stem cells in the bone marrow leads to decreased migration of early T cell progenitors to the thymus, which in turn leads to thymic atrophy and a decline in naïve T cell production (Chen 2004). Other factors that contribute to naïve T cell loss include accelerated conversion of naïve T cells into memory T cells due to increased turnover (Naylor, Li et al. 2005), and a life-long exposure to chronic/persistent viruses, notably CMV (Pawelec, Derhovanessian et al. 2009). The loss of naïve T cells is accompanied by a concomitant increase in memory T cell number/frequency, especially terminally differentiated T cells. These cells preferentially accumulate within the CD8 T cell subset where they can reach significant proportions in the aged (Vallejo 2005; Sansoni, Vescovini et al. 2008) and can often be oligoclonal (expressing a single T cell receptor) (Schwab, Szabo et al. 1997). These T cell clonal expansions (TCE) are often CMV-specific and may play a role in controlling CMV viral burden (Derhovanessian, Larbi et al. 2009), but high frequencies of terminally differentiated T cells have also been associated with the poor responses to influenza vaccines (Saurwein-Teissl, Lung et al. 2002; Trzonkowski, Mysliwska et al. 2003)

do however express membrane bound progesterone receptors and (Dosiou, Hamilton et al. 2008). The expression of PR is also upregulated on CD8+ T cells during the luteal phase of the menstrual cycle (Dosiou, Hamilton et al. 2008). Adding to the complexity of the effects of sex steroids, PR are primarily induced by estrogen via ER, thus creating an intricate interaction between these two hormones (Kovats and Agrawal 2010). NK cells and monocytes are the only other immune cell types known to express PRs (Kovats and Agrawal 2010). Both ER and PR function as transcription factors by binding to estrogen and progesterone responsive elements upon ligation or by binding to other transcription factors (Kovats and Agrawal 2010).

Estrogen treatment of B cells increases the expression of the anti-apoptotic molecule Bcl-2 thereby potentially increasing the resistance of auto-reactive B cells to apoptosis (Evans, MacLaughlin et al. 1997; Verthelyi and Ahmed 1998; Rider, Jones et al. 2001). Estrogen also enhances B cell activation (Paavonen, Andersson et al. 1981), IgG production (Kanda and Tamaki 1999), and upregulates activation-induced deaminase (AID), thereby enhancing somatic hypermutation frequency and class-switch recombination, resulting in greater antibody affinity-maturation (Karpuzoglu and Zouali 2011). In vitro studies examining the effect of E2 on T cell proliferation and cytokine production have often yielded contradictory results when using PBMC (Bouman, Heineman et al. 2005) although some observations do suggest a potential bias towards Th2, Th17 (Polanczyk, Hopke et al. 2006) and Treg polarization in E2 treated T cell cultures (Khan, Dai et al. 2010).

Several studies have demonstrated the modulation of innate immunity by estrogen. E2 regulates TLR2 expression on lipopolysaccharide (LPS) stimulated microglial cells *in vivo* after both intracerebral and systemic LPS injection (Soucy, Boivin et al. 2005). A recent study showed that presence of estrogen related receptor ERR on macrophages was required for IFN production and efficient clearance of *Listeria monocytogenes* (Sonoda, Laganiere et al. 2007). Moreover, E2 administration significantly increases mRNA for the inflammatory cytokines IL-1, IL-6, and TNF as well as inducible NO synthase in thioglycate-elicited macrophages from OVX mice(Calippe, Douin-Echinard et al. 2010). This mechanism was ER dependant (Calippe, Douin-Echinard et al. 2010). Human dendritic cells matured in the presence of E2 and TNF, but not TNF alone, promote the differentiation of naïve CD4 T cells into Th2 cells (Uemura, Liu et al. 2008). However, E2 treatment may limit the capacity of mature DC to stimulate T cell proliferation (Segerer, Muller et al. 2009). Mouse pDCs stimulated with CpG in the presence of E2 have higher expression of the co-stimulatory molecules CD40 and CD86 as well as higher IFN- production (Li, Xu et al. 2009). When cocultured with B cells, these E2 treated pDCs increase B cell viability, but as described for T cells above, not proliferative capacity (Li, Xu et al. 2009). Similarly, in vitro stimulation of PBMC with HIV-1 antigens which stimulate pDC via binding to TLR-7 resulted in higher IFN production by women than by men (Meier, Chang et al. 2009). In contrast to these data, progesterone treatment reduces the ability of dendritic cells to take up antigenic peptides, stimulate T cell responses (Butts, Shukair et al. 2007), and secrete the potent antiviral cytokine IFN (Hughes, Thomas et al. 2008).

#### **3. Immune senescence**

Increasing age results in a gradual erosion of immune function that is commonly referred as "immune senescence" (Larbi, Franceschi et al. 2008). This age-related loss of immune fitness is believed to result in greater morbidity and mortality from infection in this age group.

do however express membrane bound progesterone receptors and (Dosiou, Hamilton et al. 2008). The expression of PR is also upregulated on CD8+ T cells during the luteal phase of the menstrual cycle (Dosiou, Hamilton et al. 2008). Adding to the complexity of the effects of sex steroids, PR are primarily induced by estrogen via ER, thus creating an intricate interaction between these two hormones (Kovats and Agrawal 2010). NK cells and monocytes are the only other immune cell types known to express PRs (Kovats and Agrawal 2010). Both ER and PR function as transcription factors by binding to estrogen and progesterone responsive elements upon ligation or by binding to other transcription factors

Estrogen treatment of B cells increases the expression of the anti-apoptotic molecule Bcl-2 thereby potentially increasing the resistance of auto-reactive B cells to apoptosis (Evans, MacLaughlin et al. 1997; Verthelyi and Ahmed 1998; Rider, Jones et al. 2001). Estrogen also enhances B cell activation (Paavonen, Andersson et al. 1981), IgG production (Kanda and Tamaki 1999), and upregulates activation-induced deaminase (AID), thereby enhancing somatic hypermutation frequency and class-switch recombination, resulting in greater antibody affinity-maturation (Karpuzoglu and Zouali 2011). In vitro studies examining the effect of E2 on T cell proliferation and cytokine production have often yielded contradictory results when using PBMC (Bouman, Heineman et al. 2005) although some observations do suggest a potential bias towards Th2, Th17 (Polanczyk, Hopke et al. 2006) and Treg

Several studies have demonstrated the modulation of innate immunity by estrogen. E2 regulates TLR2 expression on lipopolysaccharide (LPS) stimulated microglial cells *in vivo* after both intracerebral and systemic LPS injection (Soucy, Boivin et al. 2005). A recent study showed that presence of estrogen related receptor ERR on macrophages was required for IFN production and efficient clearance of *Listeria monocytogenes* (Sonoda, Laganiere et al. 2007). Moreover, E2 administration significantly increases mRNA for the inflammatory cytokines IL-1, IL-6, and TNF as well as inducible NO synthase in thioglycate-elicited macrophages from OVX mice(Calippe, Douin-Echinard et al. 2010). This mechanism was ER dependant (Calippe, Douin-Echinard et al. 2010). Human dendritic cells matured in the presence of E2 and TNF, but not TNF alone, promote the differentiation of naïve CD4 T cells into Th2 cells (Uemura, Liu et al. 2008). However, E2 treatment may limit the capacity of mature DC to stimulate T cell proliferation (Segerer, Muller et al. 2009). Mouse pDCs stimulated with CpG in the presence of E2 have higher expression of the co-stimulatory molecules CD40 and CD86 as well as higher IFN- production (Li, Xu et al. 2009). When cocultured with B cells, these E2 treated pDCs increase B cell viability, but as described for T cells above, not proliferative capacity (Li, Xu et al. 2009). Similarly, in vitro stimulation of PBMC with HIV-1 antigens which stimulate pDC via binding to TLR-7 resulted in higher IFN production by women than by men (Meier, Chang et al. 2009). In contrast to these data, progesterone treatment reduces the ability of dendritic cells to take up antigenic peptides, stimulate T cell responses (Butts, Shukair et al. 2007), and secrete the potent antiviral cytokine

Increasing age results in a gradual erosion of immune function that is commonly referred as "immune senescence" (Larbi, Franceschi et al. 2008). This age-related loss of immune fitness is believed to result in greater morbidity and mortality from infection in this age group.

polarization in E2 treated T cell cultures (Khan, Dai et al. 2010).

(Kovats and Agrawal 2010).

IFN (Hughes, Thomas et al. 2008).

**3. Immune senescence** 

Immuno-senescent changes have been described for both innate and adaptive immunity. Specifically, circulating monocyte numbers are increased in the elderly, although circulating neutrophil numbers remain unaltered (Chatta, Andrews et al. 1993; Born, Uthgenannt et al. 1995; Lord, Butcher et al. 2001; Della Bella, Bierti et al. 2007). This may reflect the skewing of bone marrow hematopoietic stem cell (HSC) progenitors in the elderly towards the myeloid lineage (Beerman, Bhattacharya et al. 2010). Nonetheless, age-related decreases in circulating mDC numbers have been reported (Della Bella, Bierti et al. 2007). In addition, aged myeloid cells exhibit hyporesponsiveness to several innate stimuli, which may reflect reduced expression of PRR and their downstream signaling mediators, or increased negative regulation of these pathways (Dunston and Griffiths 2010; Shaw, Joshi et al. 2010). Furthermore, innate immune function may be compromised by diminished phagocytic activity in the elderly (Wenisch, Patruta et al. 2000; Lloberas and Celada 2002), compounded by reduced superoxide production and intracellular killing ability in the case of Grampositive bacteria (Lord, Butcher et al. 2001). Some reports have suggested that although NK cell numbers are conserved with age (Tarazona 2009), there is a decrease in proliferation and cytokine production (Mocchegiani and Malavolta 2004; Murasko and Jiang 2005; Zhang, Wallace et al. 2007). Changes in NK cytotoxicity with age are somewhat controversial with some studies showing a decrease while others show no change (Tarazona 2009). Preserved NK cytotoxicity is associated with lower infection and mortality rates and better vaccine response in the elderly (Ogata, Yokose et al. 1997; Mysliwska, Trzonkowski et al. 2004). Moreover, aging is associated with an increase in CD56dim NK cells which are cytotoxic and a decrease in CD56bright cells which are immuno-regulatory (Borrego, Alonso et al. 1999). Age-related changes in frequency and function of innate immune cells impact the protective immune response by decreasing anti-bacterial function as well as by impacting antigen presentation and the generation of adaptive immunity in the elderly.

Although, it is clear that aging affects innate immune function, accumulating evidence indicate that the adaptive arm of the immune system, and more specifically in the T cell compartment, exhibits more profound and consistent changes than the innate arm (Pawelec, Larbi et al. 2009). The hallmarks of T cell senescence include: 1) loss of naïve T cells and accumulation of memory T cells; 2) reduced CD4:CD8 T cell ratio; 3) increased T cell production of inflammatory cytokines; and 4) reduced T cell proliferative ability. Several phenomena are believed to contribute to these changes. Decreased production of hematopoietic stem cells in the bone marrow leads to decreased migration of early T cell progenitors to the thymus, which in turn leads to thymic atrophy and a decline in naïve T cell production (Chen 2004). Other factors that contribute to naïve T cell loss include accelerated conversion of naïve T cells into memory T cells due to increased turnover (Naylor, Li et al. 2005), and a life-long exposure to chronic/persistent viruses, notably CMV (Pawelec, Derhovanessian et al. 2009). The loss of naïve T cells is accompanied by a concomitant increase in memory T cell number/frequency, especially terminally differentiated T cells. These cells preferentially accumulate within the CD8 T cell subset where they can reach significant proportions in the aged (Vallejo 2005; Sansoni, Vescovini et al. 2008) and can often be oligoclonal (expressing a single T cell receptor) (Schwab, Szabo et al. 1997). These T cell clonal expansions (TCE) are often CMV-specific and may play a role in controlling CMV viral burden (Derhovanessian, Larbi et al. 2009), but high frequencies of terminally differentiated T cells have also been associated with the poor responses to influenza vaccines (Saurwein-Teissl, Lung et al. 2002; Trzonkowski, Mysliwska et al. 2003) and increased inflammation (Vallejo, Weyand et al. 2004).

progestins.

cancer (Bluming and Tavris 2009).

**5. Impact of menopause on immune cell function** 

Modulation of Immune Senescence by Menopause and Hormone Therapy 255

There are three basic forms of hormone replacement therapy (HRT): 1) unopposed estrogen therapy; 2) sequentially combined HRT (scHRT) where estrogens are taken daily and; 3) progesterone or progestins are taken intermittently, and continuous combined HRT (ccHRT) where both hormones are taken daily. Estrogen administration can be accomplished orally via tablets, or transdermally through a variety of vehicles including patches, creams, and vaginal inserts. Estrogen is most commonly prescribed as conjugated equine estrogens (CEE) in the U.S. (Nelson HD 2007), but other forms such as synthetic conjugated estrogens, estradiol estropipate, esterified estrogen, and ethinylestradiol are gaining in popularity. The method of delivery is often determined by the target symptoms and patient preference. Progesterones can be prescribed as progesterone or as a wide array of synthetic congeners or

Treatment of postmenopausal symptoms with estrogen began in the 1940's (Nelson HD 2007). In the 1970's progesterone was added to regimens when a link was made between unopposed estrogen treatment and endometrial cancer (Smith, Prentice et al. 1975; Ziel and Finkle 1975). In the 1980's estrogen began to be prescribed as a prophylactic against osteoporosis when it was shown to reduce fractures (Weiss, Ure et al. 1980; Kiel, Felson et al. 1987) and was thought to be potentially beneficial against other chronic illnesses such as heart disease and dementia (Bluming and Tavris 2009). A sharp decline in prescription of HRT occurred after the termination of the combination estrogen-progestin therapy arm of the Women's Health Initiative (WHI) in 2002 (Hing and Brett 2006). Since 2002 the WHI has made a number of updated reports warning of the dangers of HRT, however careful review of the data reveals these dangers are largely unfounded in most women (Bluming and Tavris 2009). The only conclusive danger is that of an increased cardiac risk in women over the age 60 taking HRT for the first time, and only for the first year (Bluming and Tavris 2009). There is no conclusive evidence that exogenous estrogens increase the risk of breast

In contrast to the plethora of studies examining the effect of hormone therapy on cardiovascular disease, bone metabolism and breast cancer, very few studies have examined the effects of menopause and HRT on immunological parameters. Given that female sex hormones modulate immune response to infection in young women and animal models, it has been hypothesized that that the loss of ovarian steroids during menopause could exacerbate immune senescence (Gameiro and Romao 2010; Gameiro, Romao et al. 2010; Rehman and Masson 2005). This hypothesis is supported by the observation that rhinovirus infection induces a higher IFN and IL-13 response in women than men, however this sex difference is no longer detected after the age of 50 (Carroll, Yerkovich et al. 2010). Similarly, hepatitis vaccines induce higher antibody titers and seroconversion rates in adult women, but this gender difference is no longer evident in vaccinees over the age of 60 (Klein, Jedlicka et al. 2010). The incidence of herpes zoster is also higher in women 50 years of age and older compared to males (Chapman, Cross et al. 2003; Fleming, Cross et al. 2004). The mechanisms underlying these observations are being examined in rodent and nonhuman primate models where menopause was induced surgically via bilateral removal of the ovaries (ovariectomy). This approach allows the investigation of the impact of menopause without the confounding factor of age. In adult female rats, ovariectomy resulted in decreased chemotaxis (migration in response to chemokine gradients) and LPS-induced proliferation by leukocytes

Both quantitative and qualitative changes in the B cell compartment have been reported with age. The frequency of B cells decreases with age (Huppert, Solomou et al. 1998; Colonna-Romano, Bulati et al. 2003). More importantly, there is a consistent reduction in the antibody response to infection and vaccination. For instance, 25% of persons over the age of 65 fail to develop a neutralizing antibody response following influenza vaccination, whereas 90% of adults aged 25 to 45 successfully do so (Beyer, Palache et al. 1989). This decline was also reported in response to other vaccines such as hepatitis B (Cook, Gualde et al. 1987) and A (D'Acremont, Herzog et al. 2006; Genton, D'Acremont et al. 2006). It was initially proposed that reduced B cell function is due to diminished CD4 T cell help. However, accumulating evidence points to the fact that there are intrinsic defects within the B cell compartment independent of the CD4 helper function. One of the possible intrinsic B cell deficiencies is that isotype class switching and/affinity maturation is compromised in the elderly (Aydar, Balogh et al. 2004; Frasca, Riley et al. 2004; Cancro, Hao et al. 2009). Another contributing factor to the decreased B cell response in the elderly is the reduction in the B cell repertoire. As described for T cells, B cell clonal expansions are detected with greater frequency in the elderly and could potentially interfere in the development of a protective immune response by constricting the proliferative burst, establishment of new memory B cell population or reducing naïve B cell output (LeMaoult, Delassus et al. 1997; LeMaoult, Szabo et al. 1997; LeMaoult, Manavalan et al. 1999; Weksler and Szabo 2000; Szabo, Li et al. 2004).

Last but not least, immune senescence is associated with the upregulation of circulating proinflammatory cytokines, notably IL-6 and TNF and to a lesser extent IL-1 (De Martinis, Franceschi et al. 2005; Wikby, Nilsson et al. 2006). Increased production of chemokines such as RANTES, MIP-1a, IL-8 and MCP-1 was also reported (Gerli, Monti et al. 2000; Pulsatelli, Meliconi et al. 2000; Mariani, Pulsatelli et al. 2002). This chronic inflammatory state has been correlated with overall mortality rate and is believed to significantly contribute to the development of age-related diseases such as Alzheimer's, atherosclerosis, sarcopenia, diabetes, rheumatoid arthritis and certain types of cancer (Vasto, Candore et al. 2007).

#### **4. Menopause and hormone therapy regimens**

In women, aging is accompanied by a dramatic loss in ovarian function and subsequent menopause around the age of 51. Thus, with the average life span of ~80 years, women can expect to spend a significant portion of their lives in a post-menopausal state (Hall 2004). The endocrine changes associated with entry into menopause appear to be driven by the age-related depletion of follicular reserve, which leads to a failure to produce the hormonal support necessary to maintain levels of inhibin B. The decrease in inhibin B production results in deregulated production of follicular stimulating hormone (FSH), which in turn results in altered estrogen production and eventually a decrease in the levels of circulating estrogen (Wu, Zelinski et al. 2005; Burger, Hale et al. 2008). This diminished responsiveness results in a cycle that culminates in menopause.

Menopause not only affects women's fertility, but also exacerbates several age-related diseases such as osteoporosis, cardiovascular disease, loss of cognitive abilities and the incidence of some cancers (Prior 1998; Grady 2006). Interestingly, some of these diseases, notably osteoporosis and atherosclerosis correlate with increased inflammatory cytokine production (Ginaldi, Di Benedetto et al. 2005), thereby establishing a complex interaction between immune senescence and menopause. However, few studies have investigated the impact of menopause and hormone therapy on immune senescence.

Both quantitative and qualitative changes in the B cell compartment have been reported with age. The frequency of B cells decreases with age (Huppert, Solomou et al. 1998; Colonna-Romano, Bulati et al. 2003). More importantly, there is a consistent reduction in the antibody response to infection and vaccination. For instance, 25% of persons over the age of 65 fail to develop a neutralizing antibody response following influenza vaccination, whereas 90% of adults aged 25 to 45 successfully do so (Beyer, Palache et al. 1989). This decline was also reported in response to other vaccines such as hepatitis B (Cook, Gualde et al. 1987) and A (D'Acremont, Herzog et al. 2006; Genton, D'Acremont et al. 2006). It was initially proposed that reduced B cell function is due to diminished CD4 T cell help. However, accumulating evidence points to the fact that there are intrinsic defects within the B cell compartment independent of the CD4 helper function. One of the possible intrinsic B cell deficiencies is that isotype class switching and/affinity maturation is compromised in the elderly (Aydar, Balogh et al. 2004; Frasca, Riley et al. 2004; Cancro, Hao et al. 2009). Another contributing factor to the decreased B cell response in the elderly is the reduction in the B cell repertoire. As described for T cells, B cell clonal expansions are detected with greater frequency in the elderly and could potentially interfere in the development of a protective immune response by constricting the proliferative burst, establishment of new memory B cell population or reducing naïve B cell output (LeMaoult, Delassus et al. 1997; LeMaoult, Szabo et al. 1997; LeMaoult, Manavalan

Last but not least, immune senescence is associated with the upregulation of circulating proinflammatory cytokines, notably IL-6 and TNF and to a lesser extent IL-1 (De Martinis, Franceschi et al. 2005; Wikby, Nilsson et al. 2006). Increased production of chemokines such as RANTES, MIP-1a, IL-8 and MCP-1 was also reported (Gerli, Monti et al. 2000; Pulsatelli, Meliconi et al. 2000; Mariani, Pulsatelli et al. 2002). This chronic inflammatory state has been correlated with overall mortality rate and is believed to significantly contribute to the development of age-related diseases such as Alzheimer's, atherosclerosis, sarcopenia, diabetes, rheumatoid arthritis and certain types of cancer (Vasto, Candore et al. 2007).

In women, aging is accompanied by a dramatic loss in ovarian function and subsequent menopause around the age of 51. Thus, with the average life span of ~80 years, women can expect to spend a significant portion of their lives in a post-menopausal state (Hall 2004). The endocrine changes associated with entry into menopause appear to be driven by the age-related depletion of follicular reserve, which leads to a failure to produce the hormonal support necessary to maintain levels of inhibin B. The decrease in inhibin B production results in deregulated production of follicular stimulating hormone (FSH), which in turn results in altered estrogen production and eventually a decrease in the levels of circulating estrogen (Wu, Zelinski et al. 2005; Burger, Hale et al. 2008). This diminished responsiveness

Menopause not only affects women's fertility, but also exacerbates several age-related diseases such as osteoporosis, cardiovascular disease, loss of cognitive abilities and the incidence of some cancers (Prior 1998; Grady 2006). Interestingly, some of these diseases, notably osteoporosis and atherosclerosis correlate with increased inflammatory cytokine production (Ginaldi, Di Benedetto et al. 2005), thereby establishing a complex interaction between immune senescence and menopause. However, few studies have investigated the

et al. 1999; Weksler and Szabo 2000; Szabo, Li et al. 2004).

**4. Menopause and hormone therapy regimens** 

results in a cycle that culminates in menopause.

impact of menopause and hormone therapy on immune senescence.

There are three basic forms of hormone replacement therapy (HRT): 1) unopposed estrogen therapy; 2) sequentially combined HRT (scHRT) where estrogens are taken daily and; 3) progesterone or progestins are taken intermittently, and continuous combined HRT (ccHRT) where both hormones are taken daily. Estrogen administration can be accomplished orally via tablets, or transdermally through a variety of vehicles including patches, creams, and vaginal inserts. Estrogen is most commonly prescribed as conjugated equine estrogens (CEE) in the U.S. (Nelson HD 2007), but other forms such as synthetic conjugated estrogens, estradiol estropipate, esterified estrogen, and ethinylestradiol are gaining in popularity. The method of delivery is often determined by the target symptoms and patient preference. Progesterones can be prescribed as progesterone or as a wide array of synthetic congeners or progestins.

Treatment of postmenopausal symptoms with estrogen began in the 1940's (Nelson HD 2007). In the 1970's progesterone was added to regimens when a link was made between unopposed estrogen treatment and endometrial cancer (Smith, Prentice et al. 1975; Ziel and Finkle 1975). In the 1980's estrogen began to be prescribed as a prophylactic against osteoporosis when it was shown to reduce fractures (Weiss, Ure et al. 1980; Kiel, Felson et al. 1987) and was thought to be potentially beneficial against other chronic illnesses such as heart disease and dementia (Bluming and Tavris 2009). A sharp decline in prescription of HRT occurred after the termination of the combination estrogen-progestin therapy arm of the Women's Health Initiative (WHI) in 2002 (Hing and Brett 2006). Since 2002 the WHI has made a number of updated reports warning of the dangers of HRT, however careful review of the data reveals these dangers are largely unfounded in most women (Bluming and Tavris 2009). The only conclusive danger is that of an increased cardiac risk in women over the age 60 taking HRT for the first time, and only for the first year (Bluming and Tavris 2009). There is no conclusive evidence that exogenous estrogens increase the risk of breast cancer (Bluming and Tavris 2009).

#### **5. Impact of menopause on immune cell function**

In contrast to the plethora of studies examining the effect of hormone therapy on cardiovascular disease, bone metabolism and breast cancer, very few studies have examined the effects of menopause and HRT on immunological parameters. Given that female sex hormones modulate immune response to infection in young women and animal models, it has been hypothesized that that the loss of ovarian steroids during menopause could exacerbate immune senescence (Gameiro and Romao 2010; Gameiro, Romao et al. 2010; Rehman and Masson 2005). This hypothesis is supported by the observation that rhinovirus infection induces a higher IFN and IL-13 response in women than men, however this sex difference is no longer detected after the age of 50 (Carroll, Yerkovich et al. 2010). Similarly, hepatitis vaccines induce higher antibody titers and seroconversion rates in adult women, but this gender difference is no longer evident in vaccinees over the age of 60 (Klein, Jedlicka et al. 2010). The incidence of herpes zoster is also higher in women 50 years of age and older compared to males (Chapman, Cross et al. 2003; Fleming, Cross et al. 2004).

The mechanisms underlying these observations are being examined in rodent and nonhuman primate models where menopause was induced surgically via bilateral removal of the ovaries (ovariectomy). This approach allows the investigation of the impact of menopause without the confounding factor of age. In adult female rats, ovariectomy resulted in decreased chemotaxis (migration in response to chemokine gradients) and LPS-induced proliferation by leukocytes

senescence.

Modulation of Immune Senescence by Menopause and Hormone Therapy 257

impact on the loss of naïve T cells than menopause. Another hallmark of T cell senescence is a reduced CD4/CD8 ratio (Larbi, Franceschi et al. 2008). Data from a few studies suggest that menopause decreases the CD4/CD8 ratio by reducing the frequency of CD4 T cells (Gameiro and Romao 2010; Giglio, Imro et al. 1994). Since women of reproductive age have more CD4 T cells and respond more vigorously to infection/vaccination than men (Tollerud, Clark et al. 1989; Maini, Gilson et al. 1996), menopause-associated loss of CD4 T cells could be one of the mechanisms by which ovarian senescence contributes to immune

Total B cell numbers also decline with age and with menopause (Giglio, Imro et al. 1994). B cells can be broadly divided into B1 and B2 cells and their frequency is altered with increasing age (Weksler and Szabo 2000). B1 cells produce predominantly non-specific binding IgM whereas B2 cells, or conventional B cells are involved in the adaptive humoral immune response. The reduction in B cell numbers through menopause appears to be isolated to the B2 cells, which are significantly lower in late menopause compared to early and perimenopause (Kamada, Irahara et al. 2001). Furthermore, B2 cells are significantly higher in HT users than non-users (Kamada, Irahara et al. 2001). These studies suggest that menopause leads to a reduced humoral response and this change can potentially explain the disappearance of sex differences in antibody responses following infection and vaccination

(Carroll, Yerkovich et al. 2010; Engler, Nelson et al. 2008; Klein, Jedlicka et al. 2010).

menopausal women thereby increasing the CD4/CD8 ratio (Holl, Donat et al. 2001).

It is well accepted that aging is accompanied by the establishment of a chronic proinflammatory state, notably via increased levels of IL-6 and TNF (Krabbe, Pedersen et al. 2004; Vasto, Candore et al. 2007; Vasto, Carruba et al. 2009). This process is often referred to as inflamm-aging (Franceschi, Bonafe et al. 2000), and is associated with the development of several chronic diseases such as sarcopenia, Alzheimer's, osteoporosis and certain types of cancer (Kim, Chae et al. 2011; Giuliani, Sansoni et al. 2001; Yasui, Maegawa et al. 2007). The age related increase in IL-6 levels could in part be explained by the decline in sex hormones. Both IL-6 and soluble IL-6 receptor are significantly higher in postmenopausal than premenopausal women (Giuliani, Sansoni et al. 2001). Similarly, IL-6 production after *in vitro* stimulation also increases with age. More specifically, in vitro stimulation of PBMC with LPS results in higher production of IL-6 ,TNF and IL-1 in women aged 52 to 63 compared to young adult women (Kim, Chae et al. 2011). Interestingly, IL-6 production by LPS stimulated PBMC is higher in women taking combined hormone therapy compared to nonusers, but not in post-menopausal

**7. Inflammation and menopause** 

Similarly, oopherectomy results in a decrease in circulating B cells, CD4/CD8 ratio, and an increase in the percentage of NK cells in adult women (Kumru, Godekmerdan et al. 2004). Similarly, surgical menopause leads to increased NK cell frequencies (Giglio, Imro et al. 1994). All these changes are hallmarks of immune senescence and suggest that loss of ovarian steroids exacerbates aging of the immune system. Estrogen therapy reverses the decrease in CD4 and B cells and the increase in NK cells that is seen in patients who have undergone a hysterectomy (Giglio, Imro et al. 1994; Kumru, Godekmerdan et al. 2004). Similarly, combined hormone therapy reverses the age-related decrease in number of circulating B cells and T cell proliferative potential in post-menopausal women (Porter, Greendale et al. 2001) and leads to an increase in B2 B cells (Kamada, Irahara et al. 2001). Furthermore, estrogen has been shown to decrease the number of CD8 T cells in post-

as well as decreased NK cell lysis, suggestive of premature immunosenescence (Baeza, De Castro et al. 2011). More recently, studies from the same group showed that ovariectomy results in increased oxidative damage and inflammatory cytokine production by peritoneal macrophages (Baeza, De Castro et al. 2011).

Similarly, in a mouse model of HSV-2 challenge, ovariectomy resulted in a reduced response to HSV vaccine and ovariectomized female mice experienced the same rate of vaginal infection as unvaccinated controls following challenge (Pennock, Stegall et al. 2009). E2 treatment of control or OVX mice enhanced protection and decreased disease severity (Pennock, Stegall et al. 2009). Interestingly, antibody titers in E2 treated mice were not significantly higher than those observed in untreated mice, but the neutralization potential was significantly improved (Pennock, Stegall et al. 2009).

We have also recently shown that ovariectomy results in several changes in T cell homeostasis in the female rhesus macaque and that these changes were in part modulated by the age at which ovariectomy was perfomed (Engelmann, Barron et al. 2010). Young adult OVX rhesus macaques had a higher frequency of CD4 naïve T cells, whereas OVX aged female rhesus macaques had an increased frequency of terminally differentiated CD4 memory T cells. Moreover, in contrast to young adult females, OVX aged female rhesus macaques showed increased inflammatory cytokine production by T cells compared to intact aged animals. These data suggest that ovariectomy may accelerate some aspects of immune senescence in aged but not young female rhesus macaques. More importantly, both adult and aged OVX animals generated a reduced T and B cell response to vaccination compared to ovary-intact females. Specifically, T and B cell proliferative bursts were delayed and reduced in magnitude in OVX animals. Consequently IgG titers and frequency of IFN+ T cells were significantly reduced in OVX animals (Engelmann, Barron et al. 2010). Thus, as described in rodent models, loss of ovarian steroids results in diminished T cell responses to vaccination/infection in nonhuman primates but the mechanisms underlying this reduced immune response remain unclear. The exacerbation of immune senescence by menopause is likely mediated by changes in immune cell frequencies as well as functions discussed in the sections below.

### **6. Impact of menopause and hormone therapy on immune cell frequency**

As reviewed earlier, aging leads to several perturbations in the frequency of several immune cell subsets. However, the contribution of menopause to those changes is not entirely clear. Some studies have reported a significant decline in total lymphocyte numbers (Giglio, Imro et al. 1994), while others report no change (Kamada, Irahara et al. 2000). Women receiving HRT were reported to have higher lymphocyte numbers than post-menopausal women not using HRT within one to six months following treatment (Kamada, Irahara et al. 2000). Peripheral blood monocytes increase after menopause (Ben-Hur, Mor et al. 1995) but the number of tissue specific macrophages in the ovary diminish (Best, Pudney et al. 1996; Katabuchi, Suenaga et al. 1997). HRT can restore the levels of circulating monocytes to levels seen in cycling women (Ben-Hur, Mor et al. 1995).

One of the most conserved age-related changes is the decrease in the percentage of naïve T cells and the accumulation of memory T cells. There is a significant decrease in naïve T cells and an increase in memory and activated T cells between early and late menopause and the use of HRT has no effect on these changes (Fahlman, Boardley et al. 2000; Kamada, Irahara et al. 2000; Yang, Chen et al. 2000), suggesting that chronological age has a more significant

as well as decreased NK cell lysis, suggestive of premature immunosenescence (Baeza, De Castro et al. 2011). More recently, studies from the same group showed that ovariectomy results in increased oxidative damage and inflammatory cytokine production by peritoneal

Similarly, in a mouse model of HSV-2 challenge, ovariectomy resulted in a reduced response to HSV vaccine and ovariectomized female mice experienced the same rate of vaginal infection as unvaccinated controls following challenge (Pennock, Stegall et al. 2009). E2 treatment of control or OVX mice enhanced protection and decreased disease severity (Pennock, Stegall et al. 2009). Interestingly, antibody titers in E2 treated mice were not significantly higher than those observed in untreated mice, but the neutralization potential

We have also recently shown that ovariectomy results in several changes in T cell homeostasis in the female rhesus macaque and that these changes were in part modulated by the age at which ovariectomy was perfomed (Engelmann, Barron et al. 2010). Young adult OVX rhesus macaques had a higher frequency of CD4 naïve T cells, whereas OVX aged female rhesus macaques had an increased frequency of terminally differentiated CD4 memory T cells. Moreover, in contrast to young adult females, OVX aged female rhesus macaques showed increased inflammatory cytokine production by T cells compared to intact aged animals. These data suggest that ovariectomy may accelerate some aspects of immune senescence in aged but not young female rhesus macaques. More importantly, both adult and aged OVX animals generated a reduced T and B cell response to vaccination compared to ovary-intact females. Specifically, T and B cell proliferative bursts were delayed and reduced in magnitude in OVX animals. Consequently IgG titers and frequency of IFN+ T cells were significantly reduced in OVX animals (Engelmann, Barron et al. 2010). Thus, as described in rodent models, loss of ovarian steroids results in diminished T cell responses to vaccination/infection in nonhuman primates but the mechanisms underlying this reduced immune response remain unclear. The exacerbation of immune senescence by menopause is likely mediated by changes in immune cell frequencies as well as functions

**6. Impact of menopause and hormone therapy on immune cell frequency** 

As reviewed earlier, aging leads to several perturbations in the frequency of several immune cell subsets. However, the contribution of menopause to those changes is not entirely clear. Some studies have reported a significant decline in total lymphocyte numbers (Giglio, Imro et al. 1994), while others report no change (Kamada, Irahara et al. 2000). Women receiving HRT were reported to have higher lymphocyte numbers than post-menopausal women not using HRT within one to six months following treatment (Kamada, Irahara et al. 2000). Peripheral blood monocytes increase after menopause (Ben-Hur, Mor et al. 1995) but the number of tissue specific macrophages in the ovary diminish (Best, Pudney et al. 1996; Katabuchi, Suenaga et al. 1997). HRT can restore the levels of circulating monocytes to levels

One of the most conserved age-related changes is the decrease in the percentage of naïve T cells and the accumulation of memory T cells. There is a significant decrease in naïve T cells and an increase in memory and activated T cells between early and late menopause and the use of HRT has no effect on these changes (Fahlman, Boardley et al. 2000; Kamada, Irahara et al. 2000; Yang, Chen et al. 2000), suggesting that chronological age has a more significant

macrophages (Baeza, De Castro et al. 2011).

discussed in the sections below.

seen in cycling women (Ben-Hur, Mor et al. 1995).

was significantly improved (Pennock, Stegall et al. 2009).

impact on the loss of naïve T cells than menopause. Another hallmark of T cell senescence is a reduced CD4/CD8 ratio (Larbi, Franceschi et al. 2008). Data from a few studies suggest that menopause decreases the CD4/CD8 ratio by reducing the frequency of CD4 T cells (Gameiro and Romao 2010; Giglio, Imro et al. 1994). Since women of reproductive age have more CD4 T cells and respond more vigorously to infection/vaccination than men (Tollerud, Clark et al. 1989; Maini, Gilson et al. 1996), menopause-associated loss of CD4 T cells could be one of the mechanisms by which ovarian senescence contributes to immune senescence.

Total B cell numbers also decline with age and with menopause (Giglio, Imro et al. 1994). B cells can be broadly divided into B1 and B2 cells and their frequency is altered with increasing age (Weksler and Szabo 2000). B1 cells produce predominantly non-specific binding IgM whereas B2 cells, or conventional B cells are involved in the adaptive humoral immune response. The reduction in B cell numbers through menopause appears to be isolated to the B2 cells, which are significantly lower in late menopause compared to early and perimenopause (Kamada, Irahara et al. 2001). Furthermore, B2 cells are significantly higher in HT users than non-users (Kamada, Irahara et al. 2001). These studies suggest that menopause leads to a reduced humoral response and this change can potentially explain the disappearance of sex differences in antibody responses following infection and vaccination (Carroll, Yerkovich et al. 2010; Engler, Nelson et al. 2008; Klein, Jedlicka et al. 2010).

Similarly, oopherectomy results in a decrease in circulating B cells, CD4/CD8 ratio, and an increase in the percentage of NK cells in adult women (Kumru, Godekmerdan et al. 2004). Similarly, surgical menopause leads to increased NK cell frequencies (Giglio, Imro et al. 1994). All these changes are hallmarks of immune senescence and suggest that loss of ovarian steroids exacerbates aging of the immune system. Estrogen therapy reverses the decrease in CD4 and B cells and the increase in NK cells that is seen in patients who have undergone a hysterectomy (Giglio, Imro et al. 1994; Kumru, Godekmerdan et al. 2004). Similarly, combined hormone therapy reverses the age-related decrease in number of circulating B cells and T cell proliferative potential in post-menopausal women (Porter, Greendale et al. 2001) and leads to an increase in B2 B cells (Kamada, Irahara et al. 2001). Furthermore, estrogen has been shown to decrease the number of CD8 T cells in postmenopausal women thereby increasing the CD4/CD8 ratio (Holl, Donat et al. 2001).

### **7. Inflammation and menopause**

It is well accepted that aging is accompanied by the establishment of a chronic proinflammatory state, notably via increased levels of IL-6 and TNF (Krabbe, Pedersen et al. 2004; Vasto, Candore et al. 2007; Vasto, Carruba et al. 2009). This process is often referred to as inflamm-aging (Franceschi, Bonafe et al. 2000), and is associated with the development of several chronic diseases such as sarcopenia, Alzheimer's, osteoporosis and certain types of cancer (Kim, Chae et al. 2011; Giuliani, Sansoni et al. 2001; Yasui, Maegawa et al. 2007). The age related increase in IL-6 levels could in part be explained by the decline in sex hormones. Both IL-6 and soluble IL-6 receptor are significantly higher in postmenopausal than premenopausal women (Giuliani, Sansoni et al. 2001). Similarly, IL-6 production after *in vitro* stimulation also increases with age. More specifically, in vitro stimulation of PBMC with LPS results in higher production of IL-6 ,TNF and IL-1 in women aged 52 to 63 compared to young adult women (Kim, Chae et al. 2011). Interestingly, IL-6 production by LPS stimulated PBMC is higher in women taking combined hormone therapy compared to nonusers, but not in post-menopausal

**women** 

Rimoldi et al. 2006).

(Genazzani and Pluchino 2011).

Modulation of Immune Senescence by Menopause and Hormone Therapy 259

Alternative approaches for dealing with menopausal symptoms have gained significant interest in recent years. One of the most popular interventions is nutritional supplementation with estrogen-like substances that might not have the undesirable side effects of hormones. Dietary phyto-estrogens are organic compounds found in soy products, fruits and legumes (Huntley and Ernst 2004). It has been proposed that the beneficial effects of soybean compounds are mediated by isoflavones such as genistein since they show

Some rodent studies support a beneficial effect of isoflavones on immune function in postmenopausal animals. In mature ovariectomized female rats, nutritional supplementation with soybean or soybean and green tea improved chemotaxis, phagocytic index as well as the production of reactive oxygen species by peritoneal macrophages (Baeza, De Castro et al. 2010). This nutritional supplementation also improved T and B cell proliferative potential and NK cell killing (Baeza, De Castro et al. 2010). Similar results were reported for human (Zhang, Song et al. 1999) and murine (Guo, McCay et al. 2001) NK cells after exposure to another isoflavone, genistein. Genistein treatment of murine splenocytes in vitro increased IL-10 production thereby tilting the cytokine balance towards a Th2 response (Rachon,

Post-menopausal women receiving a daily dose of 70mg of isoflavones either in the form of soy milk (700ml) or oral supplements for 16 weeks experienced an increase in the frequency of circulating B cells as well as a reduction in plasma concentrations of 8-hydroxy-2-deoxyguanosine (8-OHdg), an oxidative damage marker (Ryan-Borchers, Park et al. 2006). No changes in the plasma levels of IL-2, IFN or TNF were observed in this and a second study where women consumed comparable amount of soymilk (Beavers, Serra et al. 2009). However in an earlier study where women consumed 1064 ml of soymilk for 16 weeks, a decrease in plasma levels of TNF and IL-1, but not IL-6, were detected (Huang, Cao et al. 2005). These data suggest that additional studies with a bigger range of doses in different populations of post-menopausal women need to be conducted in order to define dynamic ranges and individuals who stand to benefit the most from such nutritional interventions

Dehydroepiandrosterone (DHEA) is produced by the adrenal cortex and is the most abundant steroid in humans. Serum levels of DHEA and its sulfated conjugation product, DHEA sulfate (DHEAS), peak in men and women in the third decade and decrease progressively and profoundly with age. In the longitudinal Baltimore study, plasma levels of DHEAS emerged at the most consistent aging biomarker and correlated with longevity. In addition to its role as a precursor for androgens and estrogens, DHEA can exert a direct, physiologically relevant, agonistic effect on ERβ, a lesser antagonistic effect on androgen receptor, and a modest effect on ERα (Chen, Knecht et al. 2005). Therefore, DHEA supplementation has been explored as an alternative to classical hormone therapy. Early studies in aged mice, showed that age-related upregulation of IL-6 production could be effectively prevented and/or reversed by supplementing aging animals with DHEA (Daynes, Araneo et al. 1993). More importantly, either DHEA or DHEA sulfate supplementation promoted enhanced antibody responses against recombinant hepatitis B surface antigen by aged mice when incorporated directly into the vaccine (Araneo, Woods et al. 1993). In contrast to the rodent data, the effect of DHEA on the immune response to

**8. Alternative approaches and their effect on immunity in post menopausal** 

structural similarities to estradiol (Bingham, Atkinson et al. 1998).

women receiving unopposed estrogen (Brooks-Asplund, Tupper et al. 2002). Similarly, women receiving transdermal estrogen experienced a significant decrease in IL-6 serum levels three months after treatment compared to post-menopausal women who did not receive estradiol (Saucedo, Rico et al. 2002). Indeed, serum IL-6 levels show a negative correlation with serum estrogen levels in users (Saucedo, Rico et al. 2002) and in women spanning the transitional stages of menopause aged 40 to 65 years (Yasui, Maegawa et al. 2007).

A trend toward an increase in serum IFN levels is seen during early menopause (< 5 years post menopause) followed by a slight decrease in late menopause (Yasui, Maegawa et al. 2007). Similarly, IFN production in whole blood or PBMC in response to either PHA or LPS stimulation *in vitro*, begins to increase at around the age of 40 and peaks during early to mid menopause before again decreasing during late menopause (Deguchi, Kamada et al. 2001; Kamada, Irahara et al. 2001; Stopinska-Gluszak, Waligora et al. 2006). Previous *in vitro* studies have shown that estrogen has a biphasic effect on IFN production by LPS stimulated whole blood samples, with low estrogen levels stimulating and high levels inhibiting IFN production (Matalka 2003). Therefore, it is possible that the initial decrease in estrogen levels during early menopause stimulates an increase in IFN production, but during late menopause, estrogen levels become too low to have an effect (Goetzl, Huang et al. 2010). In support of this hypothesis, IFN serum levels decreased in women who have had a bilateral oopherectomy and increase once estrogen treatment is initiated (Kumru, Godekmerdan et al. 2004). On the other hand, combined hormone therapy is associated with lower IFN production possibly due to the opposing effect of progesterone (Deguchi, Kamada et al. 2001; Stopinska-Gluszak, Waligora et al. 2006)

A transient increase in serum IL-2 was described in women within the first five years of menopause and the data suggest a weak negative correlation with serum estrogen levels (Yasui, Maegawa et al. 2007). Similarly, IL-2 production following LPS stimulation of whole blood cultures increases with age, peaking during early menopause before declining (Deguchi, Kamada et al. 2001). HRT reduces plasma IL-2 levels as well as IL-2 production by T cells following stimulation of purified PBMC with PHA (Stopinska-Gluszak, Waligora et al. 2006). In contrast, transdermal administration of estrogen does not change IL-2 levels, probably because plasma levels achieved via this delivery route are too low to modulate T cell functions (Saucedo, Rico et al. 2002). IL-4 plasma levels were reported to increase after menopause and HT reverses this increase (Vural, Canbaz et al. 2006; Yasui, Maegawa et al. 2007). In PHA stimulated whole blood, IL-4 production increases in mid menopause and then becomes significantly lower in late menopause (Deguchi, Kamada et al. 2001). In contrast, oopherectomy decreases IL-4 levels and unopposed estrogen therapy does not affect this decrease (Kumru, Godekmerdan et al. 2004).

Menopause-induced changes in circulating levels of additional cytokines are controversial. Some studies reported an increase in TNF and IL-1 after menopause that is reversed by HRT (Kamada, Irahara et al. 2001; Vural, Canbaz et al. 2006), while other studies reported no changes (Yasui, Maegawa et al. 2007). The impact of menopause on IL-10 and IL-12 is equally controversial with some studies reporting an increase (Deguchi, Kamada et al. 2001; Vural, Canbaz et al. 2006), while others report no change (Yasui, Maegawa et al. 2007) or a decrease in these cytokines (Kamada, Irahara et al. 2001). HRT and transdermal estrogen do not seem to have an impact on IL-10 levels (Saucedo, Rico et al. 2002; Vural, Canbaz et al. 2006). A negative correlation of IL-8 with estrogen level was reported in both humans and mice (Yasui, Maegawa et al. 2007; Abu-Taha, Rius et al. 2009).

women receiving unopposed estrogen (Brooks-Asplund, Tupper et al. 2002). Similarly, women receiving transdermal estrogen experienced a significant decrease in IL-6 serum levels three months after treatment compared to post-menopausal women who did not receive estradiol (Saucedo, Rico et al. 2002). Indeed, serum IL-6 levels show a negative correlation with serum estrogen levels in users (Saucedo, Rico et al. 2002) and in women spanning the transitional

A trend toward an increase in serum IFN levels is seen during early menopause (< 5 years post menopause) followed by a slight decrease in late menopause (Yasui, Maegawa et al. 2007). Similarly, IFN production in whole blood or PBMC in response to either PHA or LPS stimulation *in vitro*, begins to increase at around the age of 40 and peaks during early to mid menopause before again decreasing during late menopause (Deguchi, Kamada et al. 2001; Kamada, Irahara et al. 2001; Stopinska-Gluszak, Waligora et al. 2006). Previous *in vitro* studies have shown that estrogen has a biphasic effect on IFN production by LPS stimulated whole blood samples, with low estrogen levels stimulating and high levels inhibiting IFN production (Matalka 2003). Therefore, it is possible that the initial decrease in estrogen levels during early menopause stimulates an increase in IFN production, but during late menopause, estrogen levels become too low to have an effect (Goetzl, Huang et al. 2010). In support of this hypothesis, IFN serum levels decreased in women who have had a bilateral oopherectomy and increase once estrogen treatment is initiated (Kumru, Godekmerdan et al. 2004). On the other hand, combined hormone therapy is associated with lower IFN production possibly due to the opposing effect of progesterone (Deguchi,

A transient increase in serum IL-2 was described in women within the first five years of menopause and the data suggest a weak negative correlation with serum estrogen levels (Yasui, Maegawa et al. 2007). Similarly, IL-2 production following LPS stimulation of whole blood cultures increases with age, peaking during early menopause before declining (Deguchi, Kamada et al. 2001). HRT reduces plasma IL-2 levels as well as IL-2 production by T cells following stimulation of purified PBMC with PHA (Stopinska-Gluszak, Waligora et al. 2006). In contrast, transdermal administration of estrogen does not change IL-2 levels, probably because plasma levels achieved via this delivery route are too low to modulate T cell functions (Saucedo, Rico et al. 2002). IL-4 plasma levels were reported to increase after menopause and HT reverses this increase (Vural, Canbaz et al. 2006; Yasui, Maegawa et al. 2007). In PHA stimulated whole blood, IL-4 production increases in mid menopause and then becomes significantly lower in late menopause (Deguchi, Kamada et al. 2001). In contrast, oopherectomy decreases IL-4 levels and unopposed estrogen therapy does not

Menopause-induced changes in circulating levels of additional cytokines are controversial. Some studies reported an increase in TNF and IL-1 after menopause that is reversed by HRT (Kamada, Irahara et al. 2001; Vural, Canbaz et al. 2006), while other studies reported no changes (Yasui, Maegawa et al. 2007). The impact of menopause on IL-10 and IL-12 is equally controversial with some studies reporting an increase (Deguchi, Kamada et al. 2001; Vural, Canbaz et al. 2006), while others report no change (Yasui, Maegawa et al. 2007) or a decrease in these cytokines (Kamada, Irahara et al. 2001). HRT and transdermal estrogen do not seem to have an impact on IL-10 levels (Saucedo, Rico et al. 2002; Vural, Canbaz et al. 2006). A negative correlation of IL-8 with estrogen level was reported in both humans and

stages of menopause aged 40 to 65 years (Yasui, Maegawa et al. 2007).

Kamada et al. 2001; Stopinska-Gluszak, Waligora et al. 2006)

affect this decrease (Kumru, Godekmerdan et al. 2004).

mice (Yasui, Maegawa et al. 2007; Abu-Taha, Rius et al. 2009).
