Metabolic response Metabolism of glucose Cortisol plays a crucial role in regulating glucose metabolism and promotes
gluconeogenesis (
glucose synthesis) in the liver, producing glucose to provide to other tissues. It also increases blood glucose levels by reducing glucose uptake in muscle and
adipose tissue, decreasing protein synthesis, and increasing the breakdown of fats into fatty acids (lipolysis). All of these metabolic steps have the net effect of increasing blood glucose levels, which fuel the brain and other tissues during the fight-or-flight response. Cortisol is also responsible for releasing amino acids from muscle, providing a substrate for
gluconeogenesis. In general, cortisol stimulates gluconeogenesis (the synthesis of 'new' glucose from non-carbohydrate sources, which occurs mainly in the
liver, but also in the
kidneys and
small intestine under certain circumstances). The net effect is an increase in the concentration of glucose in the blood, further complemented by a decrease in the sensitivity of peripheral tissue to
insulin, thus preventing this tissue from taking the glucose from the blood. Cortisol has a permissive effect on the actions of hormones that increase glucose production, such as
glucagon and
adrenaline. Cortisol also plays an important, but indirect, role in liver and muscle
glycogenolysis (the breaking down of
glycogen to
glucose-1-phosphate and glucose) which occurs as a result of the action of glucagon and adrenaline. Additionally, cortisol facilitates the activation of
glycogen phosphorylase, which is necessary for adrenaline to have an effect on glycogenolysis. It is paradoxical that cortisol promotes not only
gluconeogenesis (biosynthesis of glucose molecules) in the liver, but also
glycogenesis (
polymerization of glucose molecules into glycogen); cortisol is thus better thought of as stimulating glucose/glycogen turnover in the liver. This is in contrast to cortisol's effect in the skeletal muscle where glycogenolysis is promoted indirectly through
catecholamines. In this way, cortisol and catecholamines work synergistically to promote the breakdown of muscle glycogen into glucose for use in the muscle tissue.
Metabolism of proteins and lipids Elevated levels of cortisol, if prolonged, can lead to
proteolysis (breakdown of proteins) and muscle wasting. The reason for proteolysis is to provide the relevant tissue with a feedstock for gluconeogenesis; see
glucogenic amino acids. The usual explanation to account for this apparent discrepancy is that the raised blood glucose concentration (through the action of cortisol) will stimulate
insulin release. Insulin stimulates lipogenesis, so this is an indirect consequence of the raised cortisol concentration in the blood but it will only occur over a longer time scale.
Immune response Cortisol prevents the release of substances in the body that cause
inflammation. It is used to treat conditions resulting from overactivity of the B-cell-mediated antibody response. Examples include inflammatory and
rheumatoid diseases, as well as
allergies. Low-dose
topical hydrocortisone, available as a nonprescription medicine in some countries, is used to treat skin problems such as
rashes and
eczema. Cortisol inhibits production of
interleukin 12 (IL-12),
interferon gamma (IFN-gamma),
IFN-alpha, and
tumor necrosis factor alpha (TNF-alpha) by
antigen-presenting cells (APCs) and
T helper cells (Th1 cells), but upregulates
interleukin 4,
interleukin 10, and
interleukin 13 by Th2 cells. This results in a shift toward a Th2 immune response rather than general immunosuppression. The activation of the stress system (and resulting increase in cortisol and Th2 shift) seen during an infection is believed to be a protective mechanism which prevents an over-activation of the inflammatory response. Cortisol can weaken the activity of the
immune system. It prevents proliferation of T-cells by rendering the
interleukin-2 producer
T-cells unresponsive to
interleukin-1, and unable to produce the T-cell growth factor IL-2. Cortisol downregulates the expression of the IL2 receptor IL-2R on the surface of the helper T-cell which is necessary to induce a Th1 'cellular' immune response. This thus favors a shift towards Th2 dominance and the release of the cytokines listed above which results in Th2 dominance and favors the 'humoral' B-cell mediated antibody immune response. Cortisol also has a negative-feedback effect on IL-1. The way this negative feedback works is that an immune stressor causes peripheral immune cells to release IL-1 and other
cytokines such as IL-6 and TNF-alpha. These cytokines stimulate the hypothalamus, causing it to release
corticotropin-releasing hormone (CRH). CRH in turn stimulates the production of
adrenocorticotropic hormone (ACTH) among other things in the adrenal gland, which (among other things) increases production of cortisol. Cortisol then closes the loop as it inhibits TNF-alpha production in immune cells and makes them less responsive to IL-1. Through this system, as long as an immune stressor is small, the response will be regulated to the correct level. In general, on the immune system. But in a severe infection or in a situation where the immune system is overly sensitized to an antigen (such as in
allergic reactions) or there is a massive flood of antigens (as can happen with
endotoxic bacteria) Also because of downregulation of Th1 immunity by cortisol and other
signaling molecules, certain types of infection (notably
Mycobacterium tuberculosis) can trick the body into getting locked in the wrong mode of attack, using an antibody-mediated humoral response when a cellular response is needed.
Lymphocytes include the B-cell lymphocytes that are the antibody-producing cells of the body, and are thus the main agents of
humoral immunity. A larger number of lymphocytes in the lymph nodes, bone marrow, and skin means the body is increasing its humoral immune response. B-cell lymphocytes release antibodies into the bloodstream. These antibodies lower infection through three main pathways: neutralization,
opsonization, and
complement activation. Antibodies neutralize pathogens by binding to surface adhering proteins, keeping pathogens from binding to host cells. In opsonization, antibodies bind to the pathogen and create a target for phagocytic immune cells to find and latch onto, allowing them to destroy the pathogen more easily. Finally antibodies can also activate complement molecules which can combine in various ways to promote opsonization or even act directly to lyse a bacteria. There are many different kinds of antibody and their production is highly complex, involving several types of lymphocyte, but in general lymphocytes and other antibody regulating and producing cells will migrate to the lymph nodes to aid in the release of these antibodies into the bloodstream. On the other side of things, there are
natural killer cells; these cells have the ability to take down larger in size threats like bacteria, parasites, and tumor cells. A separate study found that cortisol effectively disarmed natural killer cells, downregulating the expression of their natural cytotoxicity receptors.
Prolactin has the opposite effect. It increases the expression of cytotoxicity receptors on natural killer cells, increasing their firepower. Cortisol stimulates many copper enzymes (often to 50% of their total potential), including
lysyl oxidase, an enzyme that cross-links
collagen and
elastin. Especially valuable for immune response is cortisol's stimulation of the
superoxide dismutase, since this copper enzyme is almost certainly used by the body to permit superoxides to poison bacteria. Some viruses, such as
influenza and
SARS-CoV-1 and
SARS-CoV-2, are known to suppress the secretion of stress hormones to avoid the organism's immune response. These viruses suppress cortisol by producing a protein that mimics the human ACTH hormone but is incomplete and does not have hormonal activity. ACTH is a hormone that stimulates the adrenal gland to produce cortisol and other steroid hormones. However, the organism makes antibodies against this viral protein, and those antibodies also kill the human ACTH hormone, which leads to the suppression of adrenal gland function. Such adrenal suppression is a way for a virus to evade immune detection and elimination. This viral strategy can have severe consequences for the host (human that is infected by the virus), as cortisol is essential for regulating various physiological processes, such as metabolism, blood pressure, inflammation, and immune response. A lack of cortisol can result in a condition called adrenal insufficiency, which can cause symptoms such as fatigue, weight loss, low blood pressure, nausea, vomiting, and abdominal pain. Adrenal insufficiency can also impair the ability of the host to cope with stress and infections, as cortisol helps to mobilize energy sources, increase heart rate, and downregulate non-essential metabolic processes during stress. Therefore, by suppressing cortisol production, some viruses can escape the immune system and weaken the host's overall health and resilience. ==Other effects==