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it is clear that E2 can stimulate antibody production by B cells, probably by inhibiting T cell suppression of B cells

In cycling women, the largest quantities of Ig were detected before ovulation

In contrast, E2 at high concentrations leads to a suppression of B-lymphocyte lineage precursors

E2 at periovulatory to pregnancy serum levels is able to stimulate antibody secretion under healthy conditions but also in autoimmune diseases, whereas similar serum levels of E2 lead to a suppression of bone marrow B cell lineage precursors

In chronic inflammatory disorders, where B cells play a decisive role, E2 would promote the disease when autoaggressive B cells are already present, whereas chronically elevated E2 would inhibit initiation of an autoimmune disease when no such B cells are available. This might be a good reason why particularly B cell-dependent diseases such as SLE, mixed connective tissue disease (Sharp syndrome), IgA nephropathy, dermatitis herpetiformis, gluten sensitive enteropathy, myasthenia gravis, and thyroiditis appear in women in the reproductive years, predominantly, in the third or fourth decades of life

Th17 cells are thought to be the main responsible cells for chronic inflammatory tissue destruction in autoimmune diseases

IFN-γ, IL-12, and TNF were allocated to Th1 reactions

IL-4, IL-5, and IL-10 to Th2 responses

antiinflammatory T regulatory cells producing TGF-β and proinflammatory T helper type 17 cells (Th17) producing IL-17

no direct effects of estrogens on Th17 cells or IL-17 secretion have been described until now.

So-called Th17 cells producing IL-17 are the main T cells responsible for chronic inflammation.

Because IFN-γ has been allocated a Th17-inhibiting role (Fig. 1⇑), its increase by E2 at pregnancy doses and the E2-mediated inhibition of TNF must be viewed as a favorable effect in chronic inflammation

in humans and mice, E2 at periovulatory to pregnancy levels stimulates IL-4, IL-10, and IFN-γ but inhibits TNF from CD4+ T cells

In humans and mice, E3 and E2, respectively, at pregnancy levels inhibit T cell-dependent delayed type hypersensitivity

increased IL-4, IL-10, and IFN-γ in the presence of low TNF support an antiaggressive immune response

secretion of IL-1β is increased at periovulatory/proestrus to early pregnancy levels, whereas IL-1 secretion is inhibited at high pregnancy levels

The dichotomous effect of E2 on IL-1β and TNF at high and low concentrations is most probably due to inhibition of NF-κB at high concentrations

experiments with mouse and rat macroglial and microglial cells demonstrate that E2 at proestrus to pregnancy levels exerts neuroprotective effects by increasing TGF-β and by inhibiting iNOS and NO release, and reducing expression of proinflammatory cytokines and prostaglandin E2 production.

E2 at periovulatory to pregnancy levels inhibits NF-κB activation, which must be viewed as an antiinflammatory signal

It was shown that E2 concentrations equal to or above 10−10 m are necessary to inhibit NF-κB activation

important proinflammatory cytokines are typically inhibited at periovulatory (proestrus) to pregnancy levels of E2, which is evident for IL-6, IL-8, and TNF

low E2 concentrations were demonstrated to have no or even stimulatory effects

This renders a woman in the postmenopausal phase to a more proinflammatory situation

most in vitro studies demonstrated a stimulatory effect of E2 on secretion of IL-4, IL-10, and TGF-β typically at periovulatory to pregnancy levels

E2 at periovulatory to pregnancy levels has an ameliorating effect on chronic inflammatory diseases as long as B cell-dependent immunity or an overshooting fibrotic tissue repair process do not play a crucial pathogenic role. However, when the B cell plays an important role, E2 might even stimulate the disease process as substantiated by flare-ups in SLE during pregnancy

Short-term administration of E2 at pregnancy levels was shown to induce an inflammatory response specific to the lateral prostate of the castrated male rat

NO also is co linked to VEGF which in turn increases the antiapoptotic gene bcl-2

The other important influence of NO is in its inhibition of the proapoptoic caspases cascade. This in turn protects the cells from intracellular preprogrammed death.

nitric oxide in immune suppression in relation to oxygen radicals is its inhibitory effect on the binding of leukocytes (PMN) at the endothelial surface

Inhibition of inducible Nitric Oxide Synthase (iNOS)

NO from the tumor cells actually suppresses the iNOS, and in addition it reduces oxygen radicals to stop the formation of peroxynitrite in these cells. But NO is not the only inhibitor of iNOS in cancer.

Spermine and spermidine, from the rate limiting enzyme for DNA synthases, ODC, also inhibit iNOS

tolerance in the immune system that decreases the immune response to antigens on the tumors

Freund’s adjuvant

increase in kinases in these cells which phosphorylate serine, and tyrosine

responsible for activation of many growth factors and enzymes

phosphorylated amino acids suppress iNOS activity

Hexokinase II

Prostaglandin E2, released from tumor cells is also an inhibitor of iNOS, as well as suppressing the immune system

Th-1 subset of T-cells. These cells are responsible for anti-viral and anti-cancer activities, via their cytokine production including Interleukin-2, (IL-2), and Interleukin-12 which stimulates T-killer cell replication and further activation and release of tumor fighting cytokines.

Th-2 subset of lymphocytes, on the other hand are activated in allergies and parasitic infections to release Interleukin-4 and Interleukin-10

These have respectively inhibitory effects on iNOS and lymphocyte Th-1 activation

Mast cells contain histamine which when released increases the T suppressor cells, to lower the immune system and also acts directly on many tumor Histamine receptors to stimulate tumor growth

Tumor cells release IL-10, and this is thought to be one of the important areas of Th-1 suppression in cancer patients

IL-10 is also increased in cancer causing viral diseases such as HIV, HBV, HCV, and EBV

IL-10 is also a central regulator of cyclooxygenase-2 expression and prostaglandin production in tumor cells stimulating their angiogenesis and NO production

nitric oxide in tumor cells even prevents the activation of caspases responsible for apoptosis

early stages of carcinogenesis, which we call tumor promotion, one needs a strong immune system, and fewer oxygen radicals to prevent mutations but still enough to destroy the tumor cells should they develop

later stages of cancer development, the oxygen radicals are decreased around the tumors and in the tumor cells themselves, and the entire cancer fighting Th-1 cell replication and movement are suppressed. The results are a decrease in direct toxicity and apoptosis, which is prevented by NO, a suppression of the macrophage and leukocyte toxicity and finally, a suppression of the T-cell induced tumor toxicity

cGMP is increased by NO

NO in cancer is its ability to increase platelet-tumor cell aggregates, which enhances metastases

the greater the malignancies and the greater the metastatic potential of these tumors

The greater the NO production in many types of tumors,

gynecological

elevated lactic acid which neutralizes the toxicity and activity of Lymphocyte immune response and mobility

The lactic acid is also feeding fungi around tumors and that leads to elevated histamine which increases T-suppressor cells.  Histamine alone stimulates many tumor cells.

T-regulatory cells (formerly,T suppressor cells) down regulate the activity of Natural killer cells

last but not least, the Lactic acid from tumor cells and acidic diets shifts the lymphocyte activity to reduce its efficacy against cancer cells and pathogens in addition to altering the bacteria of the intestinal tract.

intestinal tract bacteria in cancer cells release sterols that suppress the immune system and down regulate anticancer activity from lymphocytes.

In addition to the lactic acid, adenosine is also released from tumors. Through IL-10, adenosine and other molecules secreted by regulatory T cells, the CD8+ cells can be inactivated to an anergic state

Adenosine up regulates the PD1 receptor in T-1 Lymphocytes and inhibits their activity

Adenosine is a purine nucleoside found within the interstitial fluid of solid tumors at concentrations that are able to inhibit cell-mediated immune responses to tumor cells

Adenosine appears to up-regulate the PD1 receptor in T-1 Lymphocytes and inhibits the immune system further

Mast cells with their release of histamine lower the immune system and also stimulate tumor growth and activate the metalloproteinases involved in angiogenesis and metastases

COX 2 inhibitors or all trans-retinoic acid

Cimetidine, an antihistamine has been actually shown to increase in apoptosis in MDSC via a separate mechanism than the antihistamine effect

interleukin-8 (IL-8), a chemokine related to invasion and angiogenesis

In vitro analyses revealed a striking induction of IL-8 expression in CAFs and LFs by tumor necrosis factor-alpha (TNF-alpha)

these data raise the possibility that the majority of CAFs in CLM originate from resident LFs. TNF-alpha-induced up-regulation of IL-8 via nuclear factor-kappaB in CAFs is an inflammatory pathway, potentially permissive for cancer invasion that may represent a novel therapeutic target