Ornithine carbamoyltransferase activity in plasma of mice with malaria as an index of liver damage

Exploring the Role of Antioxidants to Combat Oxidative Stress in Malaria Parasites

BACKGROUND

Malaria, a global challenge, is a parasitic disease caused by Plasmodium species. Approximately 229 million cases of malaria were reported in 2019. Major incidences occur in various continents, including African and Eastern Mediterranean Continents and South-East Asia.

INTRODUCTION

Despite the overall decline in global incidence from 2010 to 2018, the rate of decline has been almost constant since 2014. The morbidity and mortality have been accelerated due to reactive oxygen species (ROS) caused by oxidative stress generated by the parasite responsible for the destruction of host metabolism and cell nutrients.

METHODS

The excessive release of free radicals is associated with the infection in the animal or human body by the parasites. This may be related to a reduction in nutrients required for the generation of antioxidants and the destruction of cells by parasite activity. Therefore, an intensive literature search has been carried out to find the natural antioxidants used to neutralize the free radicals generated during malarial infection.

RESULTS

The natural antioxidants may be useful as an adjuvant treatment along with the antimalarial chemotherapeutics to reduce the death rate and enhance the success rate of malaria treatment.

CONCLUSION

In this manuscript, an attempt has been made to provide significant insight into the antioxidant activities of herbal extracts against malaria parasites.

Malarial infection develops mitochondrial pathology and mitochondrial oxidative stress to promote hepatocyte apoptosis

Activation of the mitochondrial apoptosis pathway by oxidative stress has been implicated in hepatocyte apoptosis during malaria. Because mitochondria are the source and target of reactive oxygen species (ROS), we have investigated whether hepatocyte apoptosis is linked to mitochondrial pathology and mitochondrial ROS generation during malaria. Malarial infection induces mitochondrial pathology by inhibiting mitochondrial respiration, dehydrogenases, and transmembrane potential and damaging the ultrastructure as evident from transmission electron microscopic studies. Mitochondrial GSH depletion and formation of protein carbonyl indicate that mitochondrial pathology is associated with mitochondrial oxidative stress. Fluorescence imaging of hepatocytes documents intramitochondrial superoxide anion (O(2)(-)) generation during malaria. O(2)(-) inactivates mitochondrial aconitase to release iron from iron-sulfur clusters, which forms the hydroxyl radical ((.)OH) interacting with H(2)O(2) produced concurrently. Malarial infection inactivates mitochondrial aconitase, and carbonylation of aconitase is evident from Western immunoblotting. The release of iron has been documented by fluorescence imaging of hepatocytes using Phen Green SK, and mitochondrial (.)OH generation has been confirmed. During malaria, the depletion of cardiolipin and formation of the mitochondrial permeability transition pore favor cytochrome c release to activate caspase-9. Interestingly, mitochondrial (.)OH generation correlates with the activation of both caspase-9 and caspase-3 with the progress of malarial infection, indicating the critical role of (.)OH.

Comparison of hepatotoxicity and metabolism of butyltin compounds in the liver of mice, rats and guinea pigs

The hepatotoxicity of tributyltin chloride (TBTC) and dibutyltin dichloride (DBTC) was compared among mice, rats and guinea pigs in vivo. Further, the metabolism of these butyltin compounds in the liver was also investigated in these species. The oral administration of TBTC and DBTC to mice induced obvious liver injury, as demonstrated by both serodiagnosis and histopathological diagnosis. The concentrations of TBTC and DBTC that induced hepatotoxicity in mice at 24 h after oral administration were 180 and 60 micro mol/kg, respectively. In the case of rats, the liver injury induced by TBTC and DBTC was detected at 24 h by the serodiagnosis, but not by histopathological diagnosis. On the other hand, in guinea pigs, TBTC and DBTC administration did not produce any clear liver injury at 24 h, as evaluated by these two diagnostic methods. Thus, the following ranking was obtained with regard to increasing order of sensitivity to liver injury caused by TBTC and DBTC: mice, rats and guinea pigs. The total butyltin contents in the liver of mice were equivalent at 3 h and 24 h after the administration of TBTC or DBTC; however, the contents in the liver of rats and guinea pigs were relatively lower at 3 h and higher at 24 h than those of mice, although there were no differences between rats and guinea pigs in the total liver butyltin content. Concerning the liver metabolism of these butyltin compounds, the main form of butyltin compounds in these animals treated with TBTC was DBTC within 3 h after oral administration, while the main metabolites at 24 h were different in each species, indicating that the liver metabolism of TBTC might vary by animal type. When the animals were treated with DBTC orally, DBTC was hardly metabolized in the livers of these animals even at 24 h, and the liver levels of DBTC were two times greater in mice and guinea pigs than in rats at 3 h and were lower in mice at 24 h than in rats and guinea pigs. The analysis of cellular distributions of DBTC in the liver at 3 h after the administration showed that the levels of DBTC in the nuclear, microsomal and mitochondrial fractions of mice hepatocytes were relatively higher than in those of rats, which were greater than in those of guinea pigs. These results suggest differences in the sensitivity of mice, rats and guinea pigs to hepatotoxicity caused by butyltin compounds and demonstrate that the difference in the sensitivity of these animals to the hepatotoxicity induced by TBTC and DBTC may be partly due to differences in hepatic metabolism of TBTC and in the distribution of DBTC within cell organelles, respectively.

Serum Ornithine Carbamoyl Transferase as a Surrogate Marker in Malaria

Ornithine carbamoyl transferase (OCT) activity and other liver function tests were studied in a total of 50 patients of clinical malaria and 15 controls. They were grouped as group I (positive for malarial parasite on peripheral blood smear, n=18), group II (negative for malarial parasite on peripheral blood smear (PBS) but responded to antimalarials, n=17) and group III (peripheral blood smear negative and did not respond to antimalarial therapy, n=15). The mean OCT levels were significantly raised in group I (6.79 ± 1.84 IU/L, p value = 0.006) and group II (5.0 ± 1.15 IU/L, p value = 0.014) as compared to controls (2.5 ± 1.13 IU/L) and returned to normal after treatment In contrast, group III had normal levels except in a case of kala azar and septicemia where OCT levels were high and increased further on treatment. Taking PBS positivity as a gold standard of diagnostic criteria, OCT had a sensitivity of 83% and specificity of 86% with a high positive predictive value of 88% as compared to ALT which had a lower sensitivity of 55% and specificity of 80%. The clinical response rate in PBS negative cases of fever having high OCT level was 83% as compared to 35% in cases with normal OCT level, making OCT a good surrogate marker of malaria. OCT levels could also be of prognostic significance as 2 cases of cerebral malaria had high OCT levels of 11.1 UAL and 10.7 IU/L, respectively.