Nicholas Stoy

Tryptophan metabolism and oxidative stress in patients with Huntington's disease

Abnormalities in the kynurenine pathway may play a role in Huntingtons disease (HD). In this study, tryptophan depletion and loading were used to investigate changes in blood kynurenine pathway metabolites, as well as markers of inflammation and oxidative stress in HD patients and healthy controls. Results showed that the kynurenine : tryptophan ratio was greater in HD than controls in the baseline state and after tryptophan depletion, indicating increased indoleamine dioxygenase activity in HD. Evidence for persistent inflammation in HD was provided by elevated baseline levels of C‐reactive protein, neopterin and lipid peroxidation products compared with controls. The kynurenate : kynurenine ratio suggested lower kynurenine aminotransferase activity in patients and the higher levels of kynurenine in patients at baseline, after depletion and loading, do not result in any differences in kynurenic acid levels, providing no supportive evidence for a compensatory neuroprotective role for kynurenic acid. Quinolinic acid showed wide variations in blood levels. The lipid peroxidation data indicate a high level of oxidative stress in HD patients many years after disease onset. Levels of the free radical generators 3‐hydroxykynurenine and 3‐hydroxyanthranilic acid were decreased in HD patients, and hence did not appear to contribute to the oxidative stress. It is concluded that patients with HD exhibit abnormal handling of tryptophan metabolism and increased oxidative stress, and that these factors could contribute to ongoing brain dysfunction.

An expanding range of targets for kynurenine metabolites of tryptophan

The kynurenine pathway of tryptophan metabolism accounts for most of the tryptophan that is not committed to protein synthesis and includes compounds active in the nervous and immune systems. Kynurenine acts on the aryl hydrocarbon receptor, affecting the metabolism of xenobiotics and promoting carcinogenesis. Quinolinic acid is an agonist at N-methyl-D-aspartate receptors (NMDARs), but is also pro-oxidant, has immunomodulatory actions, and promotes the formation of hyperphosphorylated tau proteins. Kynurenic acid blocks NMDARs and α7-homomeric nicotinic cholinoceptors and is also an agonist at the orphan G-protein-coupled receptor GPR35. 3-Hydroxykynurenine and 3-hydroxyanthranilic acid have pronounced redox activity and regulate T cell function. Cinnabarinic acid can activate metabotropic glutamate receptors. This review highlights the increasing range of molecular targets for components of the kynurenine pathway in both the nervous and immune systems in relation to their relevance to disease and drug development.

Altered kynurenine metabolism correlates with infarct volume in stroke

Inflammation and oxidative stress are involved in brain damage following stroke, and tryptophan oxidation along the kynurenine pathway contributes to the modulation of oxidative stress partly via the glutamate receptor agonist quinolinic acid and antagonist kynurenic acid, and via redox‐active compounds such as 3‐hydroxyanthranilic acid. We have confirmed that following a stroke, patients show early elevations of plasma neopterin, S100B and peroxidation markers, the latter two correlating with infarct volume assessed from computed tomography (CT) scans, and being consistent with a rapid inflammatory response. We now report that the kynurenine pathway of tryptophan metabolism was also activated, with an increased kynurenine : tryptophan ratio, but with a highly significant decrease in the ratio of 3‐hydroxyanthranilic acid : anthranilic acid, which was strongly correlated with infarct volume. Levels of kynurenic acid were significantly raised in patients who died within 21 days compared with those who survived. The results suggest that increased tryptophan catabolism is initiated before or immediately after a stroke, and is related to the inflammatory response and oxidative stress, with a major change in 3‐hydroxyanthranilic acid levels. Together with previous evidence that inhibiting the kynurenine pathway reduces brain damage in animal models of stroke and cerebral inflammation, and that increased kynurenine metabolism directly promotes oxidative stress, it is proposed that oxidative tryptophan metabolism may contribute to the oxidative stress and brain damage following stroke. Some form of anti‐inflammatory intervention between the rise of S100B and the activation of microglia, including inhibition of the kynurenine pathway, may be valuable in modifying patient morbidity and mortality.

Tryptophan metabolism and oxidative stress in patients with chronic brain injury

The kynurenine pathway generates the excitotoxic N‐methyl‐d‐aspartate receptor agonist, quinolinic acid and the glutamate antagonist, kynurenic acid, as well as free‐radical generators. We investigated the status of the pathway following severe brain injury sustained at least 1 year previously in 15 patients compared with controls. At baseline, patients with brain injury showed increased levels of neopterin, erythrocyte sedimentation rate, C‐reactive protein and peroxidation products in the blood compared with controls, indicating persistent inflammation and oxidative stress. At baseline and following tryptophan depletion, more tryptophan was converted to kynurenine in patients than controls, but less kynurenine was converted into the neuroprotectant, kynurenic acid. This suggests that neuroprotection by kynurenic acid may be inadequate in brain‐damaged patients even many years after injury. On tryptophan loading, patients metabolized more kynurenine into kynurenic acid than controls, a process which may be neuroprotective. In addition, lower levels of 3‐hydroxykynurenine and 3‐hydroxyanthranilic acid in patients after tryptophan loading should be protective since these compounds generate free radicals. The results suggest that for brain‐damaged patients, increased activation of the kynurenine pathway, oxidative stress and raised levels of inflammation continue many years after the original insult, possibly contributing to the continuing cerebral dysfunction in these patients.

Tryptophan Loading Induces Oxidative Stress

In previous studies tryptophan loads have been administered to human subjects in order to raise central levels of 5-hydroxytryptamine (5HT) and assess the effects of 5HT on behaviour and mood. However, tryptophan is metabolised primarily along the oxidative kynurenine pathway. In this study a 6 g oral tryptophan load was administered to 15 healthy volunteers and the levels of kynurenines and lipid peroxidation products (indicative of oxidative stress) were measured. The results demonstrate that tryptophan loading produces a highly significant increase in lipid peroxidation products in parallel with increased kynurenines. The oxidative stress may result from the generation of quinolinic acid, 3-hydroxykynurenine, and 3-hydroxyanthranilic acid, all of which are known to have the ability to generate free radicals. The results may have implications for the use of tryptophan loading in psychiatric practice, and for the chronic use of diets high in tryptophan.

Blood levels of kynurenines, interleukin-23 and soluble human leucocyte antigen-G at different stages of Huntington's disease.

J. Neurochem. (2010) 112, 112–122.

KYNURENINE PATHWAY METABOLISM IN PATIENTS WITH OSTEOPOROSIS AFTER 2 YEARS OF DRUG TREATMENT

1 Metabolism of tryptophan along the oxidative pathway via kynurenine results in the production of quinolinic acid and kynurenic acid, which can act on glutamate receptors in peripheral tissues. We have now measured the concentrations of kynurenine pathway metabolites in the plasma of patients with osteoporosis before treatment with drugs, throughout and after 2 years of treatment with the drugs raloxifene or etidronate. Oxidative stress was assessed by measuring levels of the lipid peroxidation products malondialdehyde and 4‐hydroxynonenal. Kynurenines were analysed by HPLC. Bone density was measured using dual‐energy X‐ray absorptiometry scans. 2 Patients with osteoporosis showed significantly lower baseline levels of 3‐hydroxyanthranilic acid compared with healthy controls, but significantly higher levels of anthranilic acid and lipid peroxidation products. After 2 years treatment with etidronate and calcium, we observed significant therapeutic responses quantified by bone densitometric scanning. Significant improvements were not seen in patients treated with raloxifene. 3 In parallel, the levels of 3‐hydroxyanthranilic acid, anthranilic acid and lipid peroxidation products were restored to control values by both drug treatments studied and tryptophan levels were increased significantly compared with baseline values. 4 The results suggest that tryptophan metabolism is altered in osteoporosis in a manner that could contribute to the oxidative stress and, thus, to progress of the disease. The oxidative metabolism of tryptophan (the kynurenine pathway) could represent a novel target for the development of new drugs for the treatment of osteoporosis. In addition, we noted that etidronate is a more effective drug than raloxifene, but that the simultaneous use of non‐steroidal anti‐inflammatory drugs may reduce the efficacy of etidronate.

Involvement of kynurenines in Huntington’s disease and stroke-induced brain damage

Several components of the kynurenine pathway of tryptophan metabolism are now recognised to have actions of profound biological importance. These include the ability to modulate the activation of glutamate and nicotinic receptors, to modify the responsiveness of the immune system to inflammation and infection, and to modify the generation and removal of reactive oxygen species. As each of these factors is being recognised increasingly as contributing to major disorders of the central nervous system (CNS), so the potentially fundamental role of the kynurenine pathway in those disorders is presenting a valuable target both for understanding the progress of those disorders and for developing potential drug treatments. This review will summarise some of the evidence for an important contribution of the kynurenines to Huntington’s disease and to stroke damage in the CNS. Together with preliminary evidence from a study of kynurenine metabolites after major surgery, an important conclusion is that kynurenine pathway activation closely reflects cognitive function, and may play a significant role in cognitive ability.

On the Biological Importance of the 3-hydroxyanthranilic Acid: Anthranilic Acid Ratio

Of the major components of the kynurenine pathway for the oxidative metabolism of tryptophan, most attention has focussed on the N-methyl-D-aspartate (NMDA) receptor agonist quinolinic acid, and the glutamate receptor blocker kynurenic acid. However, there is increasing evidence that the redox-active compound 3-hydroxyanthranilic acid may also have potent actions on cell function in the nervous and immune systems, and recent clinical data show marked changes in the levels of this compound, associated with changes in anthranilic acid levels, in patients with a range of neurological and other disorders including osteoporosis, chronic brain injury, Huntingtons disease, coronary heart disease, thoracic disease, stroke and depression. In most cases, there is a decrease in 3-hydroxyanthranilic acid levels and an increase in anthranilic acid levels. In this paper, we summarise the range of data obtained to date, and hypothesise that the levels of 3-hydroxyanthranilic acid or the ratio of 3-hydroxyanthranilic acid to anthranilic acid levels, may contribute to disorders with an inflammatory component, and may represent a novel marker for the assessment of inflammation and its progression. Data are presented which suggest that the ratio between these two compounds is not a simple determinant of neuronal viability. Finally, a hypothesis is presented to account for the development of the observed changes in 3-hydroxyanthranilic acid and anthranilate levels in inflammation and it is suggested that the change of the 3HAA:AA ratio, particularly in the brain, could possibly be a protective response to limit primary and secondary damage.

Macrophage Biology and Pathobiology in the Evolution of Immune Responses: A Functional Analysis

A number of general principles of macrophage biology and pathobiology are formulated to define the contribution of macrophages to the kinetics and sequencing of innate and adaptive immune responses more precisely. The application of these principles to modelling immune responses and to macrophage-based treatments of immune disorders is discussed. The concept of innate peripheral tolerance is developed. It is suggested that macrophage activation could be a primary determinant of nearly every aspect of immune responsiveness, both normal and abnormal, as might be predicted from the innate immune response to ‘danger’ being evolutionarily more primitive than the adaptive.