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Pathway Description
Bacterial Sepsis
Homo sapiens
Disease Pathway
Bacterial sepsis begins when bacteria activate the Toll-like receptor TLR4 on the membranes of macrophages, T-cells and dendritic cells. TLR4 activates the production of interferon regulatory factor 3 (IRF3), TIR-domain-containing adapter-inducing interferon-β (TRIF), signal transducer and activator of transcription 1 (STAT1) and nuclear factor kappa B (NF-kB) in the cytoplasm [1]. The NF-kB protein then goes to nucleus and activates expression of nitric oxide synthase (iNOS) which generates nitric oxide (NO). It also activates aconitate decarboxylase (Irg1), tumor necrosis factor (TNF), interleukin 6 (IL-6) and interleukin 1 beta (IL-1β). These are the pro-inflammatory proteins while nitric oxide (NO) is also a pro-inflammatory molecule that can lead to the production of oxidized tyrosines (i.e., nitrotyrosine). Similarly, the newly expressed IRF3 goes to the nucleus and activates the production of interferon beta (IFN- β), which is another pro-inflammatory cytokine. The whole collection of cytokines, TNF, IL-6, IL-1β and IFN-β move into the bloodstream and head to the brain and into the hypothalamus, leading to release of the hypothalamic corticotropin releasing hormone (CRH) [2]. CRH, in turn, activates the release of pituitary adrenocorticotropic hormone (ACTH), which then moves down through the blood stream towards the adrenal glands (located at the top of the kidneys) to produce cortisol and epinephrine. Cortisol and epinephrine stimulate the ”flight or fight” response, leading to the increased production of glucose from the liver (via glycogen breakdown) and the release of short-chain acylcarnitines (also from the liver) to help support beta-oxidation of fatty acids. These compounds support cell synthesis and growth of the macrophages and neutrophils used in the innate immune response. The liver also produces more IL-6, more TNF and more NO to further stimulate the innate immune response.
Higher nitric oxide (NO) levels lead to blood vessel dilation and reduced blood pressure, which in its most extreme form, can be a major problem in sepsis. Higher iNOS expression in macrophages, neutrophils and dendritic cells consumes the amino acid arginine to produce more NO which disrupts the mitochondrial TCA cycle leading to the accumulation of citrate and the production of fatty acids and acylcarnitines (needed for lipid synthesis). Increased Irg1 (actonitate decarboxylase) expression leads to accumulation of succinate, which results in the succinylation of phosphofructokinase M2 (PKM2) [3]. Succinate also leads to the release of hypoxia inducible factor 1-alpha (HIF-1α) from its PHD-mediated inhibition. HIF-1α interacts with succinylated PKM2 and induces the expression of glycolytic genes such as Glut1 (the glucose transporter) and the pro-inflammatory cytokine IL-1β [3]. As a result of these metabolic changes and the deactivation of the oxidative phosphorylation pathway in their mitochondria, macrophages, neutrophils, T-cells and dendritic cells shift to aerobic glycolysis [4]. This leads to the production of more reactive oxygen species (ROS) which results in the oxidation of certain amino acids, such as methionine. This leads to the increased production of methionine sulfoxide (Met-SO). As the inflammatory response continues, more glucose and arginine in the bloodstream are consumed by dividing white blood cells to produce more lactate and more NO to further push the aerobic glycolytic pathway [4]. This aerobic glycolysis occurs primarily in white blood cells leading to active cell division and rapid white cell propagation (growing by a factor of three to four in a few hours). Hexokinase (HK) along with increased levels of lactate from aerobic glycolysis activate the inflammasome inside macrophages and dendritic cells, leading to the secretion of IL-1β. This cytokine further drives the aerobic glycolysis pathway for these white blood cells. All these signals and effects combine to lead to the rapid and sustained production of large numbers of macrophages, neutrophils, dendritic cells and T-cells to fight the bacterial infection. This often leads to a reduction in essential amino acids (threonine, lysine, tryptophan, leucine, isoleucine, valine, arginine) and a mild reduction in gluconeogenic acids (glycine, serine) in the bloodstram. The reduction in essential amino acids is intended to “starve” the invading bacteria (and other pathogens) of the amino acids they need to reproduce [4]. Some of the reduction in amino acid levels is moderated by the proteolysis of myosin in the muscle and the proteolysis of serum albumin in the blood (the most abundant protein in the blood, which is produced by the liver). These proteins act as amino acid reservoirs to help support rapid immune cell production. The loss of serum albumin in the blood to help support amino acid synthesis elsewhere can lead to hypoalbuminemia, a common feature of infections, inflammation, late-stage cancer and sepsis.
At some point during the innate immune response, the kynurenine pathway becomes dysregulated, potentially through over-stimulation by interferon gamma (IFNG). This hyperstimulation leads to large reductions in tryptophan levels as the indole dioxygenase (IDO) enzyme becomes more active. IDO activation results in the generation (from tryptophan) of large amounts of kynurenine (and its other metabolites) through a self-stimulating autocrine process. Kynurenine binds to the arylhydrocarbon receptor (AhR) found in most immune cells [5-7]. In addition to increased kynurenine production via IDO mediated synthesis, hyopalbuminemia can also lead to the release of bound kynurenine (and other immunosuppressive LysoPCs) into the bloodstream to fuel this kynurenine-mediated process. Regardless of the source of kynurenine, the kynurenine-bound AhR will migrate to the nucleus to bind to NF-kB which leads to more production of the IDO enzyme, which leads to more production of kynureneine and more loss of tryptophan. High kynurenine levels and low tryptophan levels leads to a shift in T-cell differentiation from a TH1 response (pro-inflammatory) to the production of Treg cells and an anti-inflammatory response [5-7]. High kynurenine levels also lead to the production of more IL10R (the interluekin-10 receptor) via binding of kynurenine to the arylhydrocarbon receptor (AhR). Activated AhR effectively increases the anti-inflammatory response from interleukin 10 (an anti-inflammatory cytokine). Low tryptophan levels also lead to the activation of the general control non-depressible 2 kinase (GCN2K) pathway, which inhibits the mammalian target of rapamycin (mTOR), and protein kinase C signaling. This leads to T cell autophagy and anergy. High levels of kynurenine also lead to the inhibition of T cell proliferation through induction of T cell apoptosis [5-7].
In other words, kynurenine leads to a blunted immune response as neither sufficient B-cells, macrophages nor T-cells (which are needed for B-cell production) are produced, leading to further immune suppression. This allows for uncontrolled viral propagation. As a result, the invading viruses are NOT successfully cleared. This leads to a “vicious” or futile cycle where the growing virus population pushes the body to produce more B-cells and T-cells and various organs (muscles, heart, liver) exhaust themselves to produce a more metabolites to fuel the pro-inflammatory response, while the kynurenine/tryptophan cycle keeps on killing off T-cells and blunting the immune response [5-7]. This “futile” cycle of producing ineffective B and T cells, leads to heightened lactate production resulting in lactic acidosis. Likewise, as more NO is produced, this leads to a further loss of blood pressure – both lactic acidosis and hypotension can lead to organ failure. The continuous release of proinflammatory cytokines through the failed fight to eliminate the virus can also damage the alveolar-capillary barrier in the lungs. Loss of integrity of this lung barrier leads to influx of pulmonary edema fluid and lung injury or fluid in the lungs. Excessive, long-term release of glucose, short-chain acylcarnitines and fatty acids from the liver along with higher amino acid production from the blood and liver via proteolysis of albumin (leading to more extreme hypoalbuminemia), results in reduced uremic toxin clearance and increased levels of uremic solutes in the blood. High levels of uremic toxins lead to liver, heart, brain and kidney injury [8]. Likewise excessive release of acylcarnitines from the heart and liver leads to heart and liver injury. Organ failure often develops in end-stage sepsis, leading to death.
References
Bacterial Sepsis References
Chen F, Zou L, Williams B, Chao W. Targeting Toll-Like Receptors in Sepsis: From Bench to Clinical Trials. Antioxid Redox Signal 2021; 35(15): 1324-1339.
Silverman MN, Pearce BD, Biron CA, Miller AH. Immune modulation of the hypothalamic-pituitary-adrenal (HPA) axis during viral infection. Viral Immunol 2005; 18(1): 41-78.
Zheng S, Liu Q, Liu T, Lu X. Posttranslational modification of pyruvate kinase type M2 (PKM2): novel regulation of its biological roles to be further discovered. J Physiol Biochem 2021; 77(3): 355-363.
O'Neill LAJ, Kishton RJ, Rathmell J. A guide to immunometabolism for immunologists. Nat Rev Immunol 2016; 16(9): 553-65.
Bello C, Heinisch PP, Mihalj M, Carrel T, Luedi MM. Indoleamine-2,3-Dioxygenase as a Perioperative Marker of the Immune System. Front Physiol 2021; 12:766511.
Herrera-Van Oostdam AS, Castañeda-Delgado JE, Oropeza-Valdez JJ, et al. Immunometabolic signatures predict risk of progression to sepsis in COVID-19. PLoS One 2021; 16(8): e0256784.
Guarnieri T. Hypothesis: Emerging Roles for Aryl Hydrocarbon Receptor in Orchestrating CoV-2-Related Inflammation. Cells 2022; 11(4): 648.
Okusa MD. The changing pattern of acute kidney injury: from one to multiple organ failure. Contrib Nephrol 2010; 65: 153-158.
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