High concentrations of carbon monoxide (CO) are generated during incomplete combustion of carbon-containing compounds such as wood, coal, gas, oil, or tobacco. CO is a colorless and odorless gas that causes acute and chronic toxicity in humans and animals. CO mediates its toxic effects primarily by strongly binding to hemoglobin and forming carboxyhemoglobin (COHb), thereby reducing the oxygen-carrying capacity of the blood. The affinity of hemoglobin for CO is approximately 210 to 250 times that for oxygen 1. Both decreased arterial oxygen content (impaired O₂ binding to hemoglobin) and decreased tissue oxygen pressure (PO₂; increased affinity of COHb for O₂) lead to tissue hypoxia 23. There is a linear correlation between the inspired level of CO and arterial COHb levels 4. Although the percentage of COHb in blood represents the best predictive marker for extrapolating the total amount of CO, COHb levels do not always correlate with the degree of injury and outcome 5. COHb levels between 15 and 20% seem to be well tolerated in humans and are considered the 'biological threshold' above which severe CO-mediated injury is likely to occur 6. In addition to hemoglobin, CO binding to other heme-containing proteins, such as cytochrome c oxidase (thus interfering with cellular respiration), catalase, or myoglobin, may partly contribute to the toxic effects.

The most vulnerable organs to CO-induced hypoxia are the heart and the brain because of their high metabolic rate 7. The mild symptoms of acute CO poisoning are often non-specific and include headache, nausea, vomiting, dizziness, and fatigue, which may progress to confusion, tachypnea, tachycardia, impaired vision and hearing, convulsions, loss of consciousness, finally leading to death when immediate and adequate treatment is not available. The amount of CO inhaled and/or the exposure time are the most critical factors that determine the severity of CO poisoning. In addition, children and older adults are more susceptible and may have more severe symptoms 8. Predisposing conditions for CO toxicity have been described, such as cardiovascular disorders (for example, coronary heart disease), chronic obstructive pulmonary disease (COPD), or anemia 9. Heavy smokers may have more severe symptoms since their COHb levels are already elevated.

Carbon monoxide appears to be the leading cause of injury and death due to poisoning worldwide 10. Since tissue hypoxia is the underlying mechanism of CO-induced injury, increasing the inspired oxygen concentration represents the treatment for CO poisoning. In severe poisoning, hyperbaric oxygen therapy is regarded as the therapy of choice 11. Both normobaric and hyperbaric oxygen improve oxygen delivery by increasing the amount of oxygen dissolved in plasma and by reducing the half-life of COHb. However, the results from existing randomized, controlled trials of hyperbaric versus normobaric oxygen in the treatment of acute CO poisoning provide conflicting results regarding the effectiveness of hyperbaric oxygen for the prevention of neurological symptoms 12. An ongoing phase IV randomized clinical trial investigates important clinical outcomes (for example, 6-week cognitive sequelae) of patients with acute CO poisoning randomized to receive either one or three hyperbaric oxygen treatments 13. The estimated study completion date is May 2009. If treatment of CO poisoning is timely, most patients are able to recover, but even with adequate treatment CO poisoning may result in permanent memory loss or brain damage. For the long-term sequelae of acute CO poisoning, only symptomatic therapy is available. Chronic exposure to CO may lead to myocardial hypertrophy 14.

Coburn and colleagues 15 demonstrated that CO is endogenously produced in animals and humans. The vast majority of endogenous CO is derived from the oxidative breakdown of heme by microsomal heme oxygenases (HOs). HO catalyzes the first and rate-limiting step in heme degradation, yielding equimolar amounts of CO, iron, and biliverdin-IXα (Figure 1), which is further converted to bilirubin by biliverdin reductase 16. Two isoforms of HO have been described, namely HO-1 1718 and HO-2 1920. Furthermore, a third isoform has been found in rats 21, which represents a processed pseudogene derived from the gene for HO-2 22. HO-2 is constitutively expressed in many tissues, with high activity in testes, central nervous system, liver, kidney, and intestine. A basal expression of HO-1 is found in tissues that degrade senescent red blood cells, predominantly spleen, reticuloendothelial cells of the liver and bone marrow 23. HO-1 is the inducible isoform, and induction of HO-1 gene expression occurs in response to a wide variety of endogenous and exogenous stimuli, such as chemical or physical stimuli, xenobiotics, hyperoxia, hypoxia, ischemia/reperfusion, inflammation, surgical procedures, or anesthetics 242526272829.

The critical role of HO-1 under physiological conditions was demonstrated in the first described case of human HO-1 deficiency. The boy in this case presented with severe growth retardation, persistent hemolytic anemia, and severe, persistent endothelial damage 30 and died at the age of 6 years 31. Over the past decade the function of HO-1 has expanded from a heme-degrading enzyme to a key mediator of tissue protection and host defense, and its cytoprotective effects have been described in vivo and in vitro 2425283233343536373839404142.

The products of the HO pathway – CO, iron, and biliverdin/bilirubin – have long been regarded solely as waste products. Recently, the unique biological functions of the products and their contribution to the protective effects of the HO system have attracted great interest. Thus, the HO system has different functions: besides the breakdown of heme, a pro-oxidant 43, it produces cytoprotective substances, and the inducibility of HO-1 renders it a powerful endogenous cytoprotective system.

Bilirubin has been described as a potent endogenous anti-oxidant 44 with potential clinical implications 45. Free iron exhibits oxidizing capacities, although the iron released during heme degradation stimulates the synthesis of ferritin 46, which sequesters unbound iron, thereby serving as an additional anti-oxidant 47. The observation that CO can weakly activate soluble guanylate cyclase (sGC), thereby stimulating the production of cGMP, suggested an important role of CO as an intracellular messenger molecule, thus acting in a similar way to nitric oxide 4849. The functions of CO as a neural messenger have since been described 50. Vasoactive effects of CO have been reported in the pulmonary vasculature 51 and in the liver 3752, where CO acts to maintain portal venous vascular tone in a relaxed state 37. In addition to the biological functions of CO under physiological conditions, the substantial contribution of CO to the protective effects of induced HO activity has recently been recognized and includes vasoactive, anti-oxidative, anti-inflammatory, anti-apoptotic, and anti-proliferative properties. Thus, CO has advanced from a toxic waste product to a physiological regulator and the importance of endogenously derived CO to control homeostasis under both physiological and pathophysiological conditions is increasingly recognized in every organ system and cell type.

Although different mechanisms explaining the effects of CO have been described, the exact underlying signaling mechanisms and precise molecular targets of CO are only partially elucidated. Effects mediated by CO-induced activation of sGC/cGMP include inhibition of platelet activation and aggregation, smooth muscle relaxation, vasoactive effects, inhibition of cellular proliferation, and effects on neurotransmission 374950515253545556. cGMP-independent mechanisms of vasoregulation have also been suggested. CO may directly activate calcium-dependent potassium channels, thus mediating dilation of blood vessels 57. Recent evidence suggests an important role of CO as a signaling molecule in modulating mitogen-activated protein kinases (MAPKs), especially p38 MAPK in response to oxidative stress and inflammation (reviewed in 5859). CO-mediated activation of p38 MAPK has been shown to exert anti-inflammatory 60, anti-apoptotic, and anti-proliferative effects 6162. Downstream target molecules of CO-dependent p38 MAPK activation have been identified, namely heat shock protein 70 and caveolin-1 6162. Zhang and colleagues 63 demonstrated that the anti-apoptotic effects of CO involve both phosphatidylinositol 3-kinase/Akt and p38 MAPK signaling pathways in endothelial cells in a model of anoxia-reoxygenation injury. In hepatocytes, CO activated nuclear factor-κB (NF-κB) through a mechanism that involves reactive oxygen species-induced Akt phosphorylation and protected against cell death 64. Figure 2 provides a simplified overview of the described CO-mediated signal transduction pathways.

The observation that induction of HO-1 gene expression under pathological conditions plays an important role in organ preservation strongly suggests that CO might be substantially involved in mediating these effects. This is supported by the observation in models of HO-1 deficiency or after blockade of HO activity that the protective effects of induction of HO-1 are mimicked by low amounts of exogenous CO 545965. However, pre-induction of the HO-1 system by exogenous stimuli to induce local CO release or exogenous application of CO to potentiate the endogenous protective effects may be challenging. To increase the availability of CO, different approaches have been developed, including induction of HO-1 gene expression with pharmacological and genetic strategies, inhalation of low doses of CO, and application of CO-releasing molecules. Figure 3 briefly summarizes the protective effects and the potential therapeutic applications of CO in a variety of disorders and diseases of different organ systems.

CO has long been regarded solely as a toxic environmental or endogenous waste product. In addition to cytoprotective properties of endogenous CO, recent evidence strongly suggests protective effects of low concentrations of exogenous CO under pathophysiological conditions such as organ transplantation, ischemia/reperfusion, inflammation, sepsis, or shock states. Studies in humans are scarce and so far do not support the promising results observed in pre-clinical experimental studies. A potential beneficial effect of exogenous CO may highly depend on the pathological condition, the mode, time point and duration of application, the administered concentration, and on the target tissue. Further randomized, controlled clinical trials are needed to clarify whether exogenous application of CO, either by inhalation or intravenous application of CO-RMs, may become a safe and effective preventive and therapeutic tool to treat pathophysiological conditions associated with inflammatory or oxidative stress.

CO: carbon monoxide; COHb: carboxyhemoglobin; COPD: chronic obstructive pulmonary disease; CO-RM: carbon monoxide-releasing molecule; HO: heme oxygenase; IL: interleukin; LPS: lipopolysaccharide; MAPK: mitogen-activated protein kinase; NF-κB: nuclear factor-κB; sGC: soluble guanylate cyclase; TNF: tumor necrosis factor.

The authors declare that they have no competing interests.

This article is part of a review series on Gaseous mediators, edited by Peter Radermacher.

Other articles in the series can be found online at http://ccforum.com/series/gaseous_mediators