S-Antigen Localization in the Erythrocytic Stages of Plasmodium falciparum

Localization of the S-antigen of Plasmodium falciparum isolate FCQ27/PNG, from Papua New Guinea, was studied by post-embedding immunoelectron microscopy using affinity-purified rabbit antibodies raised against the repeat region of the antigen. Labelling was found in the parasitophorous vacuole (PV) space of early to late schizonts and in PV-related vesicles within the erythrocyte cytoplasm of schizont-infected cells. Other subcellular structures within the erythrocyte cytoplasm were not labelled. After breakdown of the PV membrane, label was observed around the merozoites, consistent with mixing of the PV contents and erythrocyte cytoplasm. The antigen was not found in uninfected cells, ring stages, trophozoites or associated with free merozoites. Antibodies to FCQ27/PNG S-antigen did not react with other isolates tested, whereas rabbit antibodies to the Palo Alto/Wellcome S-antigen repeat region reacted with isolates FCR3 and ItG2F6 but not with FCQ27/PNG.     

Erythrocytic adenosine monophosphate as an alternative purine source in Plasmodium falciparum

Plasmodium falciparum is a purine auxotroph, salvaging purines from erythrocytes for synthesis of RNA and DNA. Hypoxanthine is the key precursor for purine metabolism in Plasmodium. Inhibition of hypoxanthine-forming reactions in both erythrocytes and parasites is lethal to cultured P. falciparum. We observed that high concentrations of adenosine can rescue cultured parasites from purine nucleoside phosphorylase and adenosine deaminase blockade but not when erythrocyte adenosine kinase is also inhibited. P. falciparum lacks adenosine kinase but can salvage AMP synthesized in the erythrocyte cytoplasm to provide purines when both human and Plasmodium purine nucleoside phosphorylases and adenosine deaminases are inhibited. Transport studies in Xenopus laevis oocytes expressing the P. falciparum nucleoside transporter PfNT1 established that this transporter does not transport AMP. These metabolic patterns establish the existence of a novel nucleoside monophosphate transport pathway in P. falciparum.     

Phosphoenolpyruvate Carboxylase Identified as a Key Enzyme in Erythrocytic Plasmodium falciparum Carbon Metabolism

Phospoenolpyruvate carboxylase (PEPC) is absent from humans but encoded in the Plasmodium falciparum genome, suggesting that PEPC has a parasite-specific function. To investigate its importance in P. falciparum, we generated a pepc null mutant (D10^Δpepc), which was only achievable when malate, a reduction product of oxaloacetate, was added to the growth medium. D10^Δpepc had a severe growth defect in vitro, which was partially reversed by addition of malate or fumarate, suggesting that pepc may be essential in vivo. Targeted metabolomics using ¹³C-U-D-glucose and ¹³C-bicarbonate showed that the conversion of glycolytically-derived PEP into malate, fumarate, aspartate and citrate was abolished in D10^Δpepc and that pentose phosphate pathway metabolites and glycerol 3-phosphate were present at increased levels. In contrast, metabolism of the carbon skeleton of ¹³C,¹⁵N-U-glutamine was similar in both parasite lines, although the flux was lower in D10^Δpepc; it also confirmed the operation of a complete forward TCA cycle in the wild type parasite. Overall, these data confirm the CO₂ fixing activity of PEPC and suggest that it provides metabolites essential for TCA cycle anaplerosis and the maintenance of cytosolic and mitochondrial redox balance. Moreover, these findings imply that PEPC may be an exploitable target for future drug discovery.     

Ultrastructure of the Erythrocytic Stages of Plasmodium malariae1

This report describes the fine structure of the erythrocytic stages of Plasmodium malariae. Erythrocytic parasites from a naturally acquired human infection and an experimentally infected chimpanzee were morphologically indistinguishable and structurally similar to other primate malarias. New findings included observations of highly structured arrays of merozoite surface coat proteins in the cytoplasm of early schizonts and on the surface of budding merozoites and the presence of knobs in the membranes of Maurer's clefts. Morphological evidence is presented suggesting that proteins are transported between the erythrocyte surface and intracellular parasites via two routes: one associated with Maurer's clefts for transport of membrane-associated knob material and a second associated with caveolae in the host cell membrane for the import or export of host- or parasite-derived substances through the erythrocyte cytoplasm.     

Superoxide Dismutase in Plants

Superoxide dismutases (SODs) are metal-containing enzymes that catalyze the dismutation of superoxide radicals to oxygen and hydrogen peroxide. The enzyme has been found in all aerobic organisms examined where it plays a major role in the defense against toxic-reduced oxygen species, which are generated as byproducts of many biological oxidations. The generation of oxygen radicals can be further exacerbated during environmental adversity and consequently SOD has been proposed to be important for plant stress tolerance. In plants, three forms of the enzyme exist, as classified by their active site metal ion: copper/zinc, manganese, and iron forms. The distribution of these enzymes has been studied both at the subcellular level and at the phylogenic level. It is only in plants that all three different types of SOD coexist. Their occurrence in the different subcellular compartments of plant cells allows a study of their molecular evolution and the possibility of understanding why three functionally equivalent but structurally different types of SOD have been maintained. Several cDNA sequences that encode the different SODs have recently become available, and the use of molecular techniques have greatly increased our knowledge about this enzyme system and about oxidative stress in plants in general, such that now is an appropriate time to review our current knowledge.     

Association between Gene Polymorphism of Manganese Superoxide Dismutase and Prostate Cancer Risk

Manganese superoxide dismutase (MnSOD) is the most effective antioxidant enzyme in mitochondria and protects cells from reactive oxygen species‐induced oxidative damage. The aim of this study was to investigate the association between MnSOD Ala‐9Val gene polymorphism and prostate cancer (PCa) risk in Turkish men with prostate cancer. 33 patients with PCa and 81 control individuals were included in the study. We observed an association between MnSOD Ala/Ala frequency and a higher PCa risk. In addition, we found that the increased risk of early‐onset PCa (under age of 65) in the men homozygous for Ala allele was higher than the men homozygous for Val allele. However, we determined that MnSOD Ala‐9Val genotype was not associated with the aggressiveness of the disease. The results of our study suggest that MnSOD Ala/Ala genotype may influence on early‐onset of PCa patients, but no effect on subsequent development of the disease in Turkish men. However, our study has a limitation that is small numbers of individuals for cases and controls. Therefore, the presented study limited our statistical power to fully investigate the gene polymorphism on cancer risk. © 2013 Wiley Periodicals, Inc. J BiochemMol Toxicol 27:213‐218, 2013; View this article online at wileyonlinelibrary.com . DOI 10.1002/jbt.21472     

Superoxide Dismutase in Bacillus popilliae

Vegetative cells of Bacillus popilliae were devoid of catalase but had high levels of superoxide dismutase. This provides further support of a theory that oxygen tolerance by an organism is more dependent on superoxide dismutase than on catalase.     

Treatment of Brain Trauma with Liposomal Superoxide Dismutase

Brain trauma was induced in rats by impact of a steel bar on the head with a force such that damage (as measured by neurological scoring) was reversible in fourteen days. Systemic treatment (intraperitoneal injections) with free bovine copper superoxide dismutase or a liposomal form of the enzyme considerably shortened recovery time to less than half Tests included cranial nerves - cornean and aural reflexes. and sensorial motricity functions — gripping reflexes. displacement reactions, recovery and flexion reflexes, equilibrium tests and spontaneous mobility. Normalisation of EEG recordings was also greatly accelerated in the case of treated animals. No changes of brain glutathione peroxidase, glutathione transferase or Mn superoxide dismutase in traumatized animals were observed. However a slight decrease in Cu-SOD occurs. Cerebral lipoperoxidation is increased in the traumatized animals compared with controls. This increase is reduced on treatment of the rats with liposomal SOD (or the free enzyme). Very small amounts of the exogenous SOD pass the brain barrier. the permeability of which is increased in traumatized animals. The enzyme is particularly concentrated in the cortex. Despite apparent total neurological recovery at 15 days for untreated traumatized animals. significant differences in EEG recordings, in percentage cerebral water content and in histological examination of brain tissue of these controls compared with treated animals were observed with a net improvement in the latter case. The results obtained with this model suggest that clinical treatment of coma states and brain traumas with liposomal superoxide dismutase may have certain advantages over orthodox treatments     

超氧化物歧化酶(SOD)的分子生物学

本文主要从分子生物学角度概述了超氧化物歧化酶基因的克隆,表达,分子调控,及转基因研究的情况。     

Treatment of Brain Trauma with Liposomal Superoxide Dismutase

Brain trauma was induced in rats by impact of a steel bar on the head with a force such that damage (as measured by neurological scoring) was reversible in fourteen days. Systemic treatment (intraperitoneal injections) with free bovine copper superoxide dismutase or a liposomal form of the enzyme considerably shortened recovery time to less than half Tests included cranial nerves - cornean and aural reflexes. and sensorial motricity functions — gripping reflexes. displacement reactions, recovery and flexion reflexes, equilibrium tests and spontaneous mobility. Normalisation of EEG recordings was also greatly accelerated in the case of treated animals. No changes of brain glutathione peroxidase, glutathione transferase or Mn superoxide dismutase in traumatized animals were observed. However a slight decrease in Cu-SOD occurs. Cerebral lipoperoxidation is increased in the traumatized animals compared with controls. This increase is reduced on treatment of the rats with liposomal SOD (or the free enzyme). Very small amounts of the exogenous SOD pass the brain barrier. the permeability of which is increased in traumatized animals. The enzyme is particularly concentrated in the cortex. Despite apparent total neurological recovery at 15 days for untreated traumatized animals. significant differences in EEG recordings, in percentage cerebral water content and in histological examination of brain tissue of these controls compared with treated animals were observed with a net improvement in the latter case. The results obtained with this model suggest that clinical treatment of coma states and brain traumas with liposomal superoxide dismutase may have certain advantages over orthodox treatments     

Association of molecular markers in Plasmodium falciparum crt and mdr1 with in vitro chloroquine resistance: A Philippine study

Specific mutations in the pfcrt and pfmdr1 genes have been reported to be associated with chloroquine-resistant falciparum malaria parasites worldwide. These genetic markers are considered to be useful tools for the elucidation of several aspects of the epidemiology of drug resistant malaria. In this study, Plasmodium falciparum isolates from three distinct areas of the Philippines were analyzed for drug-resistance-associated genetic mutations, and their association with the in vitro chloroquine (CQ) response. Two novel pfcrt 72–76 allelic types, CVMDT and SVMDT, were detected. The frequency of the pfcrt K76T mutation in the isolates that were successfully tested for in vitro CQ susceptibility was found to be 100% in Kalinga, 80% in Palawan, and 87% in Mindanao. The frequency of the pfmdr1 N86Y mutation was 39% in Kalinga, 35% in Palawan, and 93% in Mindanao isolates. No mutations were found at positions 1042 and 1246 of pfmdr1. However, there were no significant associations found between polymorphisms in these genes and in vitro CQ susceptibility. The results of this study indicate that mutations in pfcrt and pfmdr1 are not predictive of in vitro CQ resistance in Philippine isolates and may therefore not be suitable as molecular markers for surveillance.     

An Expanded Function for Superoxide Dismutase

α-Hydroxyalkylperoxyl radicals were generated from the primary and secondary alcohols methanol, ethanol and 2-propanol in N₂O/O₂-saturated aqueous solutions by pulse radiolysis. These radicals reduced a ferric iron porphyrin complex, tetrakis-(4-N-methylpyridyl)porphine, with diffusiontontrolled rate constants. The extreme sensitivity of the shift of the Soret absorption band in this reaction was used to determine, by competition kinetics, the reactivity of the peroxyl radicals with different proteins. Only native Cu, Zn-superoxide dismutase and metallothionein showed competitive behavior, with SOD exhibiting rate constants close to the dismutation rate for O₂-. Metallothionein was slower by a factor of 30 with hydroxymethylperoxyl radicals. We propose, that SOD has unique properties of the protein surface in addition to the prosthetic copper site, having possibly evolved as a 'general-purpose radical-scavenging protein'.     

Plasmodium falciparum merozoite surface protein 1.

In addition to the major carbohydrate moieties of the glycosylphosphatidylinositol (GPI) anchor, we report that Plasmodium falciparum merozoite surface protein 1 (MSP-1) bears O-GlcNAc modifications predominantly in beta-anomeric configuration, in both the C- and N-terminal portions of the protein. Subcellular fractionation of parasitized erythrocytes in the late trophozoite/schizont stage reveals that GPI-anchored C-terminal fragments of MSP-1 are recovered in Triton X-100 resistant, low-density membrane fractions. Our results suggest that O-GlcNAc-modified MSP-1 N-terminal fragments tend to localize within the parasitophorous vacuolar membrane while GPI-anchored MSP-1 C-terminal fragments associate with low-density, Triton X-100 resistant membrane domains (rafts), redistribute in the parasitized erythrocyte and are eventually shed as membrane vesicles that also contain the endogenous, GPI-linked CD59.     

牛血清白蛋白对超氧化物歧化酶的化学修饰

目的：通过化学修饰提高超氧化歧化酶（SOD）的稳定性,考察金属离子在不同浓度下对SOD活性的影响。方法：用戊二醛作为交联剂,用牛血清白蛋白（BSA）将牛红细胞超氧化物歧化酶进行化学修饰,得到SOD的修饰酶。对比研究三种SOD：修饰酶,混合酶及天然酶的理化性质。结果：修饰酶等电点降低,对温度、pH的稳定性较天然酶有很大提高,对胰蛋白酶和胃蛋白酶也表现出很强的耐水解性。二价离子Mg^2 、Mn^2 对天种SOD活力均有不同程度的抵制作用,Ca^2 、Zn^2 、Cu^2 对修饰酶活力有激活作用,一价离子K^ 对三种OSD活力均无明显影响.结论:修饰酶较天然酶的稳定性有很大的提高,加入Ca^2 、Zn^2 、Cu^2 可提高修饰酶的活力。     

Plasma Superoxide Dismutase Measurement in Children with Viral Hepatitis

Seventy-seven blood samples from normal controls aged 0–8 years and 93 blood samples from children of similar ages with various viral hepatitis were investigated by measuring plasma superoxide dismutase (EC 1.15.1.1) using chemiluminescence immunoassay (CLIA). Total and Cu,Zn-SOD activities of normal controls of group 2(1–8 years old) were significantly higher than that of normal controls of group 1 (0–1 year old) (P < 0.01. P < 0.01), while there were no differences of Mn-SOD activities between the two groups. Total. Cu,Zn-and Mn-SOD activities significantly increased in the acute phase (0–4 weeks after onset) and dropped to the normal levels in the restoration phase (4th week later) for 29 children with cytomegalovirus hepatitis (CMVH), in comparison with group 1. Only Mn-SOD activities were significantly increased in the acute phase (with increased ALT levels) and restoration phase (with normal ALT levels) for 18 children with hepatitis A (HA). Total and Cu,Zn-SOD activities significantly decreased and Mn-SOD activities significantly increased in both the active (with increased ALT levels) and the inactive phases (with normal ALT levels) for 36 children with chronic persistent hepatitis (CPH). Only Cu,Zn-SOD activities fell significantly in both active and inactive phases for 10 children with chronic active hepatitis (CAH).     

The Interaction of Mitochondrial Iron with Manganese Superoxide Dismutase

Superoxide dismutase 2 (SOD2) is one of the rare mitochondrial enzymes evolved to use manganese as a cofactor over the more abundant element iron. Although mitochondrial iron does not normally bind SOD2, iron will misincorporate into Saccharomyces cerevisiae Sod2p when cells are starved for manganese or when mitochondrial iron homeostasis is disrupted by mutations in yeast grx5, ssq1, and mtm1. We report here that such changes in mitochondrial manganese and iron similarly affect cofactor selection in a heterologously expressed Escherichia coli Mn-SOD, but not a highly homologous Fe-SOD. By x-ray absorption near edge structure and extended x-ray absorption fine structure analyses of isolated mitochondria, we find that misincorporation of iron into yeast Sod2p does not correlate with significant changes in the average oxidation state or coordination chemistry of bulk mitochondrial iron. Instead, small changes in mitochondrial iron are likely to promote iron-SOD2 interactions. Iron binds Sod2p in yeast mutants blocking late stages of iron-sulfur cluster biogenesis (grx5, ssq1, and atm1), but not in mutants defective in the upstream Isu proteins that serve as scaffolds for iron-sulfur biosynthesis. In fact, we observed a requirement for the Isu proteins in iron inactivation of yeast Sod2p. Sod2p activity was restored in mtm1 and grx5 mutants by depleting cells of Isu proteins or using a dominant negative Isu1p predicted to stabilize iron binding to Isu1p. In all cases where disruptions in iron homeostasis inactivated Sod2p, we observed an increase in mitochondrial Isu proteins. These studies indicate that the Isu proteins and the iron-sulfur pathway can donate iron to Sod2p.Metal-containing enzymes are generally quite specific for their cognate cofactor. Misincorporation of the wrong metal ion can be deleterious and tends to be a rare occurrence in biology. A prime example of metal ion selectivity is illustrated by the family of manganese- and iron-containing superoxide dismutases (SODs)³. This large family of enzymes utilizes either manganese or iron as cofactors to scavenge superoxide anion. The iron- and manganese-containing forms are highly homologous to one another at primary, secondary, and tertiary levels and have virtually identical metal binding and catalytic sites (1–3). Despite this extensive homology, Mn- and Fe-SODs are only active with their cognate metal. Misincorporation of iron into Mn-SOD or vice versa alters the redox potential of the enzyme''s active site and prohibits superoxide disproportionation (4, 5). Nevertheless, misincorporation of iron into Mn-SOD does occur in vivo (6, 7). The isolated Mn-SOD from Escherichia coli is found as a mixture of manganese- and iron-bound forms (7); binding of manganese is favored under oxidative stress, whereas iron binding is increased under anaerobic conditions (3, 8). It has been proposed that changes in bioavailability of manganese versus iron determine the metal selectivity of Mn-SOD in bacterial cells (3, 8). But is this also true for Fe-SOD? Currently, there is no documentation of manganese misincorporation into Fe-SOD in vivo.Unlike bacteria that co-express Mn- and Fe-SOD molecules in the same cell, eukaryotic mitochondria generally harbor only one member of the Fe/Mn-SOD family, a tetrameric Mn-SOD typically known as SOD2 (9). In some organisms, SOD2 is essential for survival (10–12), and mitochondria have therefore evolved to prevent iron-SOD2 interactions despite high levels of mitochondrial iron relative to manganese. Using a yeast model system, we have shown previously that metal ion mis-incorporation can occur with Saccharomyces cerevisiae Sod2p (7). Specifically, iron binds and inactivates yeast Sod2p when cells are either starved for manganese or have certain disruptions in mitochondrial iron homeostasis. These disruptions include mutations in MTM1, a mitochondrial carrier protein that functions in iron metabolism (7, 13), and mutations in GRX5 or SSQ1, involved in iron-sulfur biogenesis (14). We proposed that these disruptions lead to expansion of a mitochondrial pool of so-called SOD2-reactive iron (7). Currently, it is unknown whether SOD2-reactive iron represents a major shift in the chemistry of bulk mitochondrial iron or whether it is just a small pool of the metal emerging from one or more specific sites.The grx5 and ssq1 mutants that promote iron-SOD2 interactions encode just two of many components of a complex pathway for iron-sulfur biogenesis (15, 16). One of the key components is a well conserved iron-sulfur scaffold protein originally described for bacteria as IscU, also known as mammalian ISCU and S. cerevisiae Isu1p and Isu2p, referred collectively herein as “Isu proteins” (17–22). The iron-sulfur clusters on Isu proteins are labile and can be transferred to target iron-sulfur proteins through the aid of mitochondrial factors including Grx5p and Ssq1p (15, 16). It is not clear whether disruption of the iron-sulfur pathway per se is sufficient to promote iron interactions with yeast Sod2p or whether this effect is specific to grx5, ssq1, and mtm1 mutants.In the current study, we explore the nature of mitochondrial iron that can interact with Sod2p. We find that the changes in mitochondrial metal homeostasis that shift metal binding in yeast Sod2p likewise alter metal cofactor selection in a heterologously expressed Mn-SOD, but not in a Fe-SOD molecule. Through x-ray absorption near edge structure (XANES) and extended x-ray absorption fine structure (EXAFS) analyses of mitochondrial iron, we detected no major change in bulk mitochondrial iron under conditions that promote iron-SOD2 interactions. SOD2-reactive iron appears to represent a small pool of the metal, and we provide evidence that the iron-sulfur scaffold Isu1p can act as an important source of this reactive iron.     

Oxygen Toxicity and the Superoxide Dismutase

Oxygen caused an increase in the amount of superoxide dismutase in Escherichia coli B but not in Bacillus subtilis. E. coli B cells, induced by growth under 100% O(2), were much more resistant to the lethal effects of 20 atm of O(2) than were cells which contained the low uninduced level of this enzyme. In contrast, B. subtilis, which could not respond to O(2) by increasing its content of superoxide dismutase, remained equally sensitive to hyperbaric O(2) whether grown under 100% O(2) or areobically. The catalase in these organisms exhibited a reciprocal response to oxygen. Thus, the catalase of E. coli B was not induced by O(2), whereas that of B. subtilis was so induced. These results are consistent with the view that superoxide dismutase is an important component of the defenses of these organisms against the toxicity of oxygen, whereas their catalases are of secondary importance in this respect. The ability of streptonigrin to generate O(2) (-), by a cycle of reduction followed by spontaneous reoxidation, has been verified in vitro. It is further observed that E. coli B which contain the high induced level of superoxide dismutase were more resistant to the lethality of this antibiotic, in the presence of oxygen, than were E. coli B which contained the low uninduced level of this enzyme. This difference between induced and uninduced cells was eliminated by the removal of O(2). These results are consistent with the proposal that the enhanced lethality of streptonigrin under aerobic conditions may relate to its in vivo generation of O(2) (-) by a cycle of reduction and spontaneous reoxidation. In toto, these observations lend support to the hypothesis that O(2) (-) is an important agent of oxygen toxicity and that superoxide dismutase functions to blunt the threat posed by this reactive radical.     

Superoxide Dismutase Therapy for Myocardial Ischemia

Oxygen derived free radicals have been shown to be generated during reperfusion of ischemic myocardium by a variety of approaches including spin trap probes. Three levels of injury have been described for the reperfused heart. Periods of ischemia of only several minutes can trigger lethal arrhythmias on reperfusion. Anti-oxidants including SOD and or catalase, as well as iron chelators reduce the incidence of these arrhythmias in both dog and rat. Xanthine oxidase inhibitors arc equipotent with SOD in this model suggesting that xanthine oxidase is the source of the radicals. Periods of occlusion lasting 10–15 minutes produce a recoverable defect in contractility termed “stunning”. SOD plus catalase has been shown to reduce the incidence of stunning in a variety of models including the xanthine oxidase deficient rabbit. Neither agent on its own seemed to be effective against stunning in either the rabbit or the dog. Stunning is more difficult to demonstrate in the rabbit heart, presumably due to its lack of xanthine oxidase. Periods of ischemia in excess of 20 minutes will result in some irreversible cell death (infarction) with reperfusion. While studies using histochemical methods suggested that SOD plus Catalase given at the time of reper-fusion could limit necrosis in the dog model, histological studies reveal that infarct size was not modified but rather, SOD appears to interfere with the ability of tetrazoliurn to histochemically discriminate between living and dead cells. While PEG SOD with its extended plasma half life was reported to reduce infarct size in the dog. it was unable to protect the reprefused rabbit heart. To date. none of the scavengers have been proven to limit infarction suggesting that free radicals contribute to arrythmias and stunning, but do not. kill cells in the reperfused heart.     

Plasmodium falciparum: S-adenosyl-L-methionine decarboxylase

Putrescine-dependent S-adenosyl-L-methionine decarboxylase has been detected in the malaria parasite Plasmodium falciparum. Mg2+ did not affect the enzyme activity. The apparent Km value of the plasmodial enzyme for adenosyl-methionine was found to be 33 microM. Methylglyoxal bis(guanylhydrazone) competitively inhibited the enzyme activity with respect to adenosylmethionine. The inhibition constant for methylglyoxal bis(guanylhydrazone) was determined to be 0.46 microM. Spermidine was the main polyamine detected in the parasite. There was significant decrease in the S-adenosyl-L-methionine decarboxylase activity when the infected erythrocytes were incubated with chloroquine and mefloquine for 2 hr at 1 and 10 microM, respectively. Since at similar concentrations these drugs did not directly affect the plasmodial enzyme activity, the interaction of these drugs with the polyamine biosynthesis remains unclear.