The effect of thiamine deficiency on inflammation, oxidative stress and cellular migration in an experimental model of sepsis.

BACKGROUND: Sepsis is a prevalent condition in critically ill patients and may be associated with thiamine deficiency (TD). The aim of this study was to evaluate the effect of TD on inflammation, oxidative stress and cellular recruitment in a sepsis model. METHODS: The experimental sepsis model, cecal ligation and puncture (CLP), was utilized on mice in comparison with a sham procedure. The following four groups were compared against each other: SHAM with AIN93G complete chow, SHAM with thiamine deficient (TD) chow, CLP with AIN93G complete chow, and CLP with TD chow. Thiamine pyrophosphate (TPP) blood concentrations were determined, and blood and peritoneal fluid were evaluated for differences in TNF-alpha, IL-1, IL-6, KC and MCP-1/CCL2 levels. In addition, the levels of 4-HNE adducts in liver proteins were evaluated by Western Blot. RESULTS: The mean TPP blood concentration from the mice fed with the complete chow was 303.3 ± 42.6 nmol/L, and TD occurred within 10 days. TNF-α and MCP-1 concentrations in the peritoneal fluid were significantly greater in the CLP with TD chow group when compared with the other groups. The blood IL-1ß level, however, was lower in the CLP with TD chow group. Liver 4-HNE levels were highest in the TD chow groups. Blood mononuclear cell numbers, as well as peritoneal total leukocyte, mononuclear cell and neutrophil numbers were greater in the CLP with TD chow group. Peritoneal bacterial colony forming units (CFU) were significantly lower in the CLP with TD chow group. CONCLUSION: TD was associated with greater bacterial clearance, oxidative stress and inflammatory response changes.

A influência do metabolismo redox na transmissão da doença de Chagas / The influence of the redox metabolism upon the transmission of Chagas disease

As formas epimastigotas de Trypanosoma cruzi proliferam e se diferenciam no interior de diferentes compartimentos do trato digestivo dos triatomíneos. Esses ambientes antagônicos, no que diz respeito à concentração de nutrientes, pH e status redox, constituem um desafio para o protozoário por conterem moléculas e fatores capazes de deflagrar diferentes sinalizações e respostas no parasito. Por isso, testamos a influência de produtos abundantes do metabolismo do vetor e de status redox distintos, frente aos processos de proliferação e diferenciação in vivo e in vitro. Como exemplo temos o heme e a hemozoína, subprodutos da digestão da hemoglobina, e o urato, rico na urina dos insetos. O heme é uma importante molécula em todos os seres vivos. Nosso grupo mostrou seu papel na proliferação in vitro de T. cruzi e que esse sinal é governado pela enzima redox-sensível CaMKII (Lara et al., 2007; Souza et al., 2009). Esse efeito parece depender de uma sinalização redox, onde o heme e não seus análigos induz a formação de EROs, modulando a atividade da CaMKII (Nogueira et al, 2011). Apesar de gerar espécies reativas de oxigênio (EROs) em formas epimastigotas, o heme não alterou a ultraestrutura desses parasitos mostrando uma adaptação a ambientes oxidantes. Além disso, a adição de FCCP inibiu a formação de EROs mitocondrial, diminuindo a proliferação dos parasitos. Em contrapartida, a AA aumentou drasticamente a produção de EROs mitocondrial levando à morte dos epimastigotas. Estes resultados confirmam a hipótese de regulação redox do crescimento de epimastigotas...

Trypanosoma cruzi epimastigotes proliferate and differentiate inside different compartments of the triatomines gut. These environments are antagonic in terms of nutrient content, pH and redox status. All these factors represent a challenge to the protozoan due to the presence of molecules and factors which are able to induce different signals to the parasite. Thus, we tested the influence of abundant metabolism products of the vector, with distinct redox status, in the proliferation and metacyclogenesis in vitro and in vivo. These molecules are heme and hemozoin, both byproducts of hemoglobin digestion, and urate, present in the urine of insects. Heme is a ubiquitous molecule present in all living organisms. Our group studied its role in T. cruzi growth in vitro, showing that this signal is governed by the redox-sensitive enzyme CaMKII (Lara et al., 2007; Souza et al., 2009). Indeed, it seems to rely on a redox signaling pathway in which heme, but not its analogs, induces ROS formation, thus modulating CaMKII activity (Nogueira et al., 2011). Although it induces ROS in epimastigotes, the heme molecule had no deleterious effect upon the parasites ultrastructure, suggesting an adaptation to oxidative environments. In addition, FCCP inhibited mitochondrial ROS formation, then decreasing the parasite proliferation. On the other hand, AA drastically increased mitochondrial ROS production leading to cell death. These results corroborate the hypothesis of redox regulation of epimastigotes proliferation. Hemozoin (β- hematin) formation is an elegant strategy to minimize the toxic effect of heme in hematophagous insects. However, β-hematin had no influence upon the proliferation or metacyclogenesis in vitro. Also, urate, GSH and NAC impaired epimastigote proliferation. These effects were partially reversed when the antioxidants were incubated along with heme...

The Role of Heme and Reactive Oxygen Species in Proliferation and Survival of Trypanosoma cruzi.

Trypanosoma cruzi, the protozoan responsible for Chagas disease, has a complex life cycle comprehending two distinct hosts and a series of morphological and functional transformations. Hemoglobin degradation inside the insect vector releases high amounts of heme, and this molecule is known to exert a number of physiological functions. Moreover, the absence of its complete biosynthetic pathway in T. cruzi indicates heme as an essential molecule for this trypanosomatid survival. Within the hosts, T. cruzi has to cope with sudden environmental changes especially in the redox status and heme is able to increase the basal production of reactive oxygen species (ROS) which can be also produced as byproducts of the parasite aerobic metabolism. In this regard, ROS sensing is likely to be an important mechanism for the adaptation and interaction of these organisms with their hosts. In this paper we discuss the main features of heme and ROS susceptibility in T. cruzi biology.

Heme-induced ROS in Trypanosoma cruzi activates CaMKII-like that triggers epimastigote proliferation. One helpful effect of ROS.

Heme is a ubiquitous molecule that has a number of physiological roles. The toxic effects of this molecule have been demonstrated in various models, based on both its pro-oxidant nature and through a detergent mechanism. It is estimated that about 10 mM of heme is released during blood digestion in the blood-sucking bug's midgut. The parasite Trypanosoma cruzi, the agent of Chagas' disease, proliferates in the midgut of the insect vector; however, heme metabolism in trypanosomatids remains to be elucidated. Here we provide a mechanistic explanation for the proliferative effects of heme on trypanosomatids. Heme, but not other porphyrins, induced T. cruzi proliferation, and this phenomenon was accompanied by a marked increase in reactive oxygen species (ROS) formation in epimastigotes when monitored by ROS-sensitive fluorescent probes. Heme-induced ROS production was time- and concentration-dependent. In addition, lipid peroxidation and the formation of 4-hydroxy-2-nonenal (4-HNE) adducts with parasite proteins were increased in epimastigotes in the presence of heme. Conversely, the antioxidants urate and GSH reversed the heme-induced ROS. Urate also decreased parasite proliferation. Among several protein kinase inhibitors tested only specific inhibitors of CaMKII, KN93 and Myr-AIP, were able to abolish heme-induced ROS formation in epimastigotes leading to parasite growth impairment. Taken together, these data provide new insight into T. cruzi- insect vector interactions: heme, a molecule from the blood digestion, triggers epimastigote proliferation through a redox-sensitive signalling mechanism.