Functional assessment of microbial superoxide dismutase isozymes suggests a differential role for each isozyme.

Microbes can have multiple enzymes that are able to catalyse the same enzymatic reactions but may differ in structure. These are known as isozymes. It is assumed that isozymes have the same functional role for cells. Contrary to this assumption, we hypothesised that isozymes can confer different functions for microbial cells despite catalysing the same reactions. To test this hypothesis, we studied the role of superoxide dismutases (SOD) in Klebsiella pneumoniae, the causative agent of several nosocomial and community-acquired infections, in infection relevant assays. SODs are responsible for detoxification of toxic superoxide radicals. K. pneumoniae genome contains three superoxide dismutase genes, sodA, sodB, and sodC coding for Mn-, Fe- and CuZn- co-factored SODs, respectively. By creating and testing single, double, and triple SOD mutants, we investigated the regulatory interactions among SOD and determined the role of each isozyme in oxidative stress resistance, biofilm formation, cell morphology, metabolism, and in vivo colonization and persistence. Our results demonstrate that SOD isozymes in K. pneumoniae have unique roles beyond oxidative stress resistance, and there is a regulatory interplay among SODs.

Adaptation of Staphylococcus aureus to Airway Environments in Patients With Cystic Fibrosis by Upregulation of Superoxide Dismutase M and Iron-Scavenging Proteins.

Adaptation of S. aureus to the hostile environment of CF airways resulted in changed abundance of proteins involved in energy metabolism, cellular processes, transport and binding, but most importantly in an iron-scavenging phenotype and increased activity of superoxide dismutase M.

Eukaryotic copper-only superoxide dismutases (SODs): A new class of SOD enzymes and SOD-like protein domains.

The copper-containing superoxide dismutases (SODs) represent a large family of enzymes that participate in the metabolism of reactive oxygen species by disproportionating superoxide anion radical to oxygen and hydrogen peroxide. Catalysis is driven by the redox-active copper ion, and in most cases, SODs also harbor a zinc at the active site that enhances copper catalysis and stabilizes the protein. Such bimetallic Cu,Zn-SODs are widespread, from the periplasm of bacteria to virtually every organelle in the human cell. However, a new class of copper-containing SODs has recently emerged that function without zinc. These copper-only enzymes serve as extracellular SODs in specific bacteria (i.e. Mycobacteria), throughout the fungal kingdom, and in the fungus-like oomycetes. The eukaryotic copper-only SODs are particularly unique in that they lack an electrostatic loop for substrate guidance and have an unusual open-access copper site, yet they can still react with superoxide at rates limited only by diffusion. Copper-only SOD sequences similar to those seen in fungi and oomycetes are also found in the animal kingdom, but rather than single-domain enzymes, they appear as tandem repeats in large polypeptides we refer to as CSRPs (copper-only SOD-repeat proteins). Here, we compare and contrast the Cu,Zn versus copper-only SODs and discuss the evolution of copper-only SOD protein domains in animals and fungi.

Efecto del estrés oxidativo sobre la calcificación vascular a través del microARN-377 / The effect of oxidative stress on vascular calcification through microRNA-377

Introducción: El estrés oxidativo ha sido implicado en el desarrollo y la progresión de la calcificación vascular (CV); sin embargo, aún existen interrogantes sobre esta asociación causal. Objetivo: Analizar en un modelo experimental de insuficiencia renal crónica (IRC) el efecto del estrés oxidativo sobre el desarrollo y la progresión de la CV, evaluando la implicación del microARN-377 (miR-377). Material y métodos: Se estudiaron 2 grupos de ratas Wistar con IRC. El grupo 1 recibió dieta normal en fósforo (IRC+PN). El grupo 2 recibió dieta con alto fósforo (IRC+PA). Se incluyó un grupo de ratas Sham. Trascurridas 20 semanas, las ratas fueron sacrificadas. Resultados: El fósforo y la parathormona séricos no aumentaron en el grupo IRC+PA respecto al IRC+PN, pero sí los niveles de factor de crecimiento fibrobástico 23 (FGF23). En el grupo IRC+PN aumentó tres veces el contenido aórtico de calcio respecto al grupo Sham, un aumento 17 veces superior en el grupo IRC+PA, donde la densidad mineral ósea en tibia proximal descendió significativamente. En el grupo IRC+PN la expresión del miR-377 disminuyó un 65%, sin efecto adicional de la dieta con alto contenido en fósforo. En el grupo IRC+PN aumentó 3 veces la expresión proteica de superóxido dismutasa 2 mitocondrial (SOD-2), y en el grupo IRC+PA lo hizo hasta 6 veces. Conclusiones: La IRC con o sin alto contenido en fósforo en la dieta desencadenó el descenso del miR-377. El exceso de fósforo incrementó la SOD-2 como mecanismo compensador para frenar el estrés oxidativo y el daño vascular. Controlar el contenido en fósforo en la dieta cuando la función renal se ve comprometida permitirá aminorar el daño vascular producido como consecuencia, entre otros factores, del estrés oxidativo (AU)

Introduction: Oxidative stress has been implicated in the development and progression of vascular calcification (VC). However, this causal association remains a matter of controversy. Objective: To analyze in an experimental model of chronic renal failure (CRF), the effect of oxidative stress on the development and progression of the VC, assessing the implication of microRNA-377 (miR-377). Material and methods: Two groups of Wistar rats with CRF were studied. Group 1 received normal diet in phosphorus (CRF+NP). Group 2 received a high phosphorus (CRF+HP) diet. A group of sham rats was included. After 20 weeks, the rats were sacrificed. Results: Serum phosphorus and parathormone did not increase in the CRF+HP group compared to CRF+NP, but fibroblast growth factor 23 (FGF23) levels significantly increased. In the CRF+NP group, aortic calcium content increased three-fold over the sham group, a 17-fold increase in the CRF+HP group, where the bone mineral density in the proximal tibia decreased significantly. In the IRC+NP group, the expression of miR-377 decreased by 65%, with no additional effect detected of the diet with high phosphorus content. In the IRC+NP group, the protein expression of mitochondrial superoxide dismutase 2 (SOD-2) increased 3-fold, and in the IRC+HP group it increased up to 6-fold. Conclusions: CRF, with or without high phosphorus dietary content, triggered the descent of miR-377. Excess phosphorus increased SOD-2 as a compensatory mechanism to curb oxidative stress and vascular damage. Controlling phosphorus content in the diet when the renal impairment function is compromised will reduce the vascular damage produced due oxidative stress, among other factors (AU)

Bypassing miRNA-mediated gene regulation under drought stress: alternative splicing affects CSD1 gene expression.

KEY MESSAGE: The binding site for miR398 in an isoform of Cu/Zn superoxide dismutase (CSD1) is eliminated by alternative splicing to bypass miR398-mediated gene down-regulation under drought stress. MicroRNA (miRNA) binding sites (MBSs) are frequently interrupted by introns and therefore require proper splicing to generate functional MBSs in target transcripts. MBSs can also be excluded during splicing of pre-messenger RNA, leading to different regulation among isoforms. Previous studies have shown that levels of Cu/Zn superoxide dismutase (CSD) are down-regulated by miR398. In this study, sequences and transcript levels of peanut CSD1 isoforms (AhCSD1-1, AhCSD1-2.1, and AhCSD1-2.2) were analyzed under the drought stress. Results demonstrated that a miR398 binding site is eliminated in AhCSD1-2.2 as a consequence of alternative splicing, which bypasses miRNA-mediated down-regulation under drought stress. This alternative isoform was not only identified in peanut but also in soybean and Arabidopsis. In addition, transgenic Arabidopsis plants expressing AhCSD1 were more tolerant to osmotic stress. We hypothesize that the level of AhCSD1 is increased to allow diverse plant responses to overcome environmental challenges even in the presence of increased miR398 levels. These findings suggest that studies on the role of alternatively spliced MBSs affecting transcript levels are important for understanding plant stress responses.

Zymographic Method for Distinguishing Different Classes of Superoxide Dismutases in Plants.

In plants, especially in chloroplasts, superoxide radical is generated when an electron is transferred to dimolecular O2 due to decreased activity of Photosystem I. The superoxide (O2-) radical accumulation is more rampant in plants exposed to abiotic stresses due to oxidation of photosystem components. Excessive superoxide radical accumulation will lead to oxidative damage to the cellular macromolecules. The ubiquitous superoxide dismutases (SODs) represent critical enzymatic antioxidant system present in cells, which can catalyze the disproportion of superoxide (O2-) radical rapidly into hydrogen peroxide (H2O2) and molecular oxygen. Depending on the metal cofactor present, the plant SODs are classified into Cu/ZnSOD, MnSOD, and FeSOD. The activity of SODs can be quantified zymographically. Additionally, using this method, different classes of SODs can be distinguished by using H2O2, KCN, and NaN3.

Functional analysis of iron superoxide dismutase-A in wild-type and antimony-resistant Leishmania braziliensis and Leishmania infantum lines.

In this work, we characterized the gene encoding iron superoxide dismutase-A (FeSOD-A) in wild-type (WTS) and antimony-resistant (SbR) L. (Viannia) braziliensis and L. (Leishmania) infantum lines, which were selected in vitro. FeSOD-A transcript and protein expression were similar in all tested lines; however, specific enzyme activity analysis revealed higher superoxide dismutase activity in SbIII-resistant LbSbR and LiSbR lines than in the corresponding WTS lines. These parasites were also more tolerant to oxidative stress generated by the herbicide paraquat. Functional analysis showed that in comparison to non-transfected lines, wild-type LbWTS and LiWTS clones overexpressing the FeSOD-A enzyme are 1.6- and 1.7-fold more resistant to SbIII, respectively. Our results suggest that FeSOD-A is involved in the antimony resistance phenotype in L. (V.) braziliensis and L. (L.) infantum.

Isolation and in silico analysis of Fe-superoxide dismutase in the cyanobacterium Nostoc commune.

Cyanobacteria are known to endure various stress conditions due to the inbuilt potential for oxidative stress alleviation owing to the presence of an array of antioxidants. The present study shows that Antarctic cyanobacterium Nostoc commune possesses two antioxidative enzymes viz., superoxide dismutase (SOD) and catalase that jointly cope with environmental stresses prevailing at its natural habitat. Native-PAGE analysis illustrates the presence of a single prominent isoform recognized as Fe-SOD and three distinct isoforms of catalase. The protein sequence of Fe-SOD in N. commune retrieved from NCBI protein sequence database was used for in silico analysis. 3D structure of N. commune was predicted by comparative modeling using MODELLER 9v11. Further, this model was validated for its quality by Ramachandran plot, ERRAT, Verify 3D and ProSA-web which revealed good structure quality of the model. Multiple sequence alignment showed high conservation in N and C-terminal domain regions along with all metal binding positions in Fe-SOD which were also found to be highly conserved in all 28 cyanobacterial species under study, including N. commune. In silico prediction of isoelectric point and molecular weight of Fe-SOD was found to be 5.48 and 22,342.98Da respectively. The phylogenetic tree revealed that among 28 cyanobacterial species, Fe-SOD in N. commune was the closest evolutionary homolog of Fe-SOD in Nostoc punctiforme as evident by strong bootstrap value. Thus, N. commune may serve as a good biological model for studies related to survival of life under extreme conditions prevailing at the Antarctic region. Moreover cyanobacteria may be exploited for biochemical and biotechnological applications of enzymatic antioxidants.

Rapid evolution of a few members of nasuta-albomicans complex of Drosophila: study on two candidate genes, Sod1 and Rpd3.

Drosophila nasuta nasuta (2n = 8) and D. n. albomicans (2n = 6) are morphologically identical, cross fertile and karyotypically dissimilar pair of chromosomal races belonging to nasuta subgroup of immigrans group of Drosophila. Interracial hybridization between these two races yielded karyotypically stabilized newly evolved Cytoraces with new combinations of chromosomes and DNA content, and are called nasuta-albomicans complex of Drosophila. Along with many other features, striking plasticity in the lifespan has been observed in the karyotypically stabilized members of nasuta-albomicans complex of Drosophila. These findings provide a strong background to understand any changes at the molecular levels. In view of this, we cloned and characterized Sod1 and Rpd3 in the members of nasuta-albomicans complex of Drosophila. The evolution of Sod1 and Rpd3 in D. n. nasuta and D. n. albomicans is contrasting with the other species of Drosophila, at the level of synonymous mutations, intron variation, InDels and secondary structure changes in protein. In the members of NAC of Drosophila there were synonymous changes, variations in intron sequences of Sod1, whereas, in Rpd3, synonymous, nonsynonymous, intron variation, and secondary structure changes in protein were observed. The contrasting differences in the levels of Rpd3 (and Sir2) proteins were also noticed among short-lived and long-lived Cytoraces. The Cytoraces have exhibited not only specific changes in Sod1 and Rpd3, but also show pronounced changes in the levels of synthesis of these proteins, which indicates rapid evolution of these Cytoraces in laboratory. Further these Cytoraces have become a model system to understand the process of anagenesis.

In silico comparative analysis and expression profile of antioxidant proteins in plants.

The antioxidant system in plants is a very important defensive mechanism to overcome stress conditions. We examined the expression profile of antioxidant enzymes superoxide dismutase (SOD), catalase (CAT) and ascorbate peroxidase (APX) using a bioinformatics approach. We explored secondary structure prediction and made detailed studies of signature pattern of antioxidant proteins in four plant species (Triticum aestivum, Arabidopsis thaliana, Oryza sativa, and Brassica juncea). Fingerprinting analysis was done with ScanProsite, which includes a large collection of biologically meaningful signatures. Multiple sequence alignment of antioxidant proteins of the different plant species revealed a conserved secondary structure region, indicating homology at the sequence and structural levels. The secondary structure prediction showed that these proteins have maximum tendency for α helical structure. The sequence level similarities were also analyzed with a phylogenetic tree using neighbor-joining method. In the antioxidant enzymes SOD, CAT and APX, three major families of signature were predominant and common; these were PKC_PHOSPHO_SITE, CK2_PHOSPHO_SITE and N-myristoylation site, which are functionally related to various plant signaling pathways. This study provides new strategies for screening of biomodulators involved in plant stress metabolism that will be useful for designing degenerate primers or probes specific for antioxidant. These enzymes could be the first line of defence in the cellular antioxidant defence pathway, activated due to exposure to abiotic stresses.

Two Fe-superoxide dismutase families respond differently to stress and senescence in legumes.

Three main families of SODs in plants may be distinguished according to the metal in the active center: CuZnSODs, MnSOD, and FeSOD. CuZnSODs have two sub-families localized either in plant cell cytosol or in plastids, the MnSOD family is essentially restricted to mitochondria, and the FeSOD enzyme family has been typically localized into the plastid. Here, we describe, based on a phylogenetic tree and experimental data, the existence of two FeSOD sub-families: a plastidial localized sub-family that is universal to plants, and a cytosolic localized FeSOD sub-family observed in determinate-forming nodule legumes. Anti-cytosolic FeSOD (cyt_FeSOD) antibodies were employed, together with a novel antibody raised against plastidial FeSOD (p_FeSOD). Stress conditions, such as nitrate excess or drought, markedly increased cyt_FeSOD contents in soybean tissues. Also, cyt_FeSOD content and activity increased with age in both soybean and cowpea plants, while the cyt_CuZnSOD isozyme was predominant during early stages. p_FeSOD in leaves decreased with most of the stresses applied, but this isozyme markedly increased with abscisic acid in roots. The great differences observed for p_FeSOD and cyt_FeSOD contents in response to stress and aging in plant tissues reveal distinct functionality and confirm the existence of two immunologically differentiated FeSOD sub-families. The in-gel FeSOD activity patterns showed a good correlation to cyt_FeSOD contents but not to those of p_FeSOD. This indicates that cyt_FeSOD is the main active FeSOD in soybean and cowpea tissues. The diversity of functions associated with the complexity of FeSOD isoenzymes depending of the location is discussed.

Reactive oxygen species-mediated immunity against Leishmania mexicana and Serratia marcescens in the sand phlebotomine fly Lutzomyia longipalpis.

Phlebotomine sand flies are the vectors of medically important Leishmania. The Leishmania protozoa reside in the sand fly gut, but the nature of the immune response to the presence of Leishmania is unknown. Reactive oxygen species (ROS) are a major component of insect innate immune pathways regulating gut-microbe homeostasis. Here we show that the concentration of ROS increased in sand fly midguts after they fed on the insect pathogen Serratia marcescens but not after feeding on the Leishmania that uses the sand fly as a vector. Moreover, the Leishmania is sensitive to ROS either by oral administration of ROS to the infected fly or by silencing a gene that expresses a sand fly ROS-scavenging enzyme. Finally, the treatment of sand flies with an exogenous ROS scavenger (uric acid) altered the gut microbial homeostasis, led to an increased commensal gut microbiota, and reduced insect survival after oral infection with S. marcescens. Our study demonstrates a differential response of the sand fly ROS system to gut microbiota, an insect pathogen, and the Leishmania that utilize the sand fly as a vehicle for transmission between mammalian hosts.

Molecular cloning and characterization of cDNAs of the superoxide dismutase gene family in the resurrection plant Haberlea rhodopensis.

Resurrection plants can tolerate almost complete water loss in their vegetative parts. The superoxide dismutases (SODs) are essential enzymes of defense against the oxidative damage caused by water stress. Here, we cloned and characterized cDNAs of the SOD gene family in the resurrection plant Haberlea rhodopensis. Seven full-length cDNAs, and their partial genomic clones, were obtained by combination of degenerate PCR, RT-PCR and RACE. The derived amino acid sequences exhibited a very high degree of similarity to cytosolic Cu,Zn-SODs (HrCSD2, HrCSD3), chloroplastic Cu,Zn-SODs (HrCSD5), other Cu,Zn-SODs (HrCSD4), Mn-SODs (HrMSD) and Fe-SODs (HrFSD). One cDNA turned out to be a pseudogene (HrCSD1). All identified SOD genes were found expressed at transcriptional level--the HrCSD2, HrCSD5, HrMSD and HrFSD were constitutively expressed in all organs, while the HrCSD3 and HrCSD4 were organ-specific. The transcripts of the housekeeping SOD genes were detected at significant levels even in air-dry leaves. The multigene SOD family of H. rhodopensis is the first studied SOD family amongst resurrection plant species. Our finding of well expressed SOD transcripts in fully dehydrated leaves correlates with retention of SOD activity, and with the ability of H. rhodopensis to revive upon rehydration. Because of the endemic relict nature of that species, our findings may help to further elucidate the evolutionary relationships among different SOD isoforms from distinct plant species.

Molecular cloning, characterization and predicted structure of a putative copper-zinc SOD from the camel, Camelus dromedarius.

Superoxide dismutase (SOD) is the first line of defense against oxidative stress induced by endogenous and/or exogenous factors and thus helps in maintaining the cellular integrity. Its activity is related to many diseases; so, it is of importance to study the structure and expression of SOD gene in an animal naturally exposed most of its life to the direct sunlight as a cause of oxidative stress. Arabian camel (one humped camel, Camelus dromedarius) is adapted to the widely varying desert climatic conditions that extremely changes during daily life in the Arabian Gulf. Studying the cSOD1 in C. dromedarius could help understand the impact of exposure to direct sunlight and desert life on the health status of such mammal. The full coding region of a putative CuZnSOD gene of C. dromedarius (cSOD1) was amplified by reverse transcription PCR and cloned for the first time (gene bank accession number for nucleotides and amino acids are JF758876 and AEF32527, respectively). The cDNA sequencing revealed an open reading frame of 459 nucleotides encoding a protein of 153 amino acids which is equal to the coding region of SOD1 gene and protein from many organisms. The calculated molecular weight and isoelectric point of cSOD1 was 15.7 kDa and 6.2, respectively. The level of expression of cSOD1 in different camel tissues (liver, kidney, spleen, lung and testis) was examined using Real Time-PCR. The highest level of cSOD1 transcript was found in the camel liver (represented as 100%) followed by testis (45%), kidney (13%), lung (11%) and spleen (10%), using 18S ribosomal subunit as endogenous control. The deduced amino acid sequence exhibited high similarity with Cebus apella (90%), Sus scrofa (88%), Cavia porcellus (88%), Mus musculus (88%), Macaca mulatta (87%), Pan troglodytes (87%), Homo sapiens (87%), Canis familiaris (86%), Bos taurus (86%), Pongo abelii (85%) and Equus caballus (82%). Phylogenetic analysis revealed that cSOD1 is grouped together with S. scrofa. The predicted 3D structure of cSOD1 showed high similarity with the human and bovine CuZnSOD homologues. The Root-mean-square deviation (rmsd) between cSOD1/hSOD1 and cSOD1/bSOD1 superimposed structure pairs were 0.557 and 0.425 A. The Q-score of cSOD1-hSOD1 and cSOD1-bSOD1 were 0.948 and 0.961, respectively.

Molecular cloning, characterization of copper/zinc superoxide dismutase and expression analysis of stress-responsive genes from Eisenia fetida against dietary zinc oxide.

The full length cDNA of copper/zinc superoxide dismutase (Cu/Zn-SOD) from Eisenia fetida (E. fetida) was cloned (GenBank accession no. JN579648). Sequence characterization revealed that the cDNA contained characteristic Cu/Zn-SOD family signatures ((45)GFHVHEFGDNT(55) and (138)GNAGGRLACGVI(149)), cysteines (Cys-58 and-146) predicted to form one disulphide bond, Cu-binding (His-47, -49, -64 and -120) and Zn-binding (His-64, -72, -81 and Asp-84). They were essential for the structure and function of Cu/Zn-SOD. Differential expression of stress-responsive genes like Cu/Zn-SOD, catalase (CAT), heat shock protein 70 (Hsp70) and metallothionein (MT) was applied as potential biomarkers to assess their efficacy for the ecotoxicological effects of dietary zinc oxide (ZnO) on E. fetida. The results showed that the expression of Cu/Zn-SOD and MT increased to reach the highest levels of 6.22 and 7.68 fold in a dose-dependent manner at day 10 respectively. The highest expression of 3.03 fold of CAT was registered at day 10. The transient expression of Hsp70 without consistent time- or/and dose-dependent was observed. It implied that the transcriptional patterns of Cu/Zn-SOD, CAT and MT could serve as early warning signals in ecotoxicological assessment of dietary ZnO on earthworms while the expression of Hsp70 was not well done, which is helpful to monitoring and regulation of ZnO in veterinary application.

Superoxide dismutases: ancient enzymes and new insights.

Superoxide dismutases (SODs) catalyze the de toxification of superoxide. SODs therefore acquired great importance as O(2) became prevalent following the evolution of oxygenic photosynthesis. Thus the three forms of SOD provide intriguing insights into the evolution of the organisms and organelles that carry them today. Although ancient organisms employed Fe-dependent SODs, oxidation of the environment made Fe less bio-available, and more dangerous. Indeed, modern lineages make greater use of homologous Mn-dependent SODs. Our studies on the Fe-substituted MnSOD of Escherichia coli, as well as redox tuning in the FeSOD of E. coli shed light on how evolution accommodated differences between Fe and Mn that would affect SOD performance, in SOD proteins whose activity is specific to one or other metal ion.

Pasteurella multocida involved in respiratory disease of wild chimpanzees.

Pasteurella multocida can cause a variety of diseases in various species of mammals and birds throughout the world but nothing is known about its importance for wild great apes. In this study we isolated P. multocida from wild living, habituated chimpanzees from Taï National Park, Côte d'Ivoire. Isolates originated from two chimpanzees that died during a respiratory disease outbreak in 2004 as well as from one individual that developed chronic air-sacculitis following this outbreak. Four isolates were subjected to a full phenotypic and molecular characterisation. Two different clones were identified using pulsed field gel electrophoresis. Multi Locus Sequence Typing (MLST) enabled the identification of previous unknown alleles and two new sequence types, ST68 and ST69, were assigned. Phylogenetic analysis of the superoxide dismutase (sodA) gene and concatenated sequences from seven MLST-housekeeping genes showed close clustering within known P. multocida isolated from various hosts and geographic locations. Due to the clinical relevance of the strains described here, these results make an important contribution to our knowledge of pathogens involved in lethal disease outbreaks among endangered great apes.

Molecular mass spectrometric identification of superoxide dismutase in the liver of mice Mus musculus and Mus spretus using a metallomics analytical approach.

This paper reports the identification and quantification of superoxide dismutase in the liver of Mus musculus and Mus spretus mice using a metallomics analytical approach. The approach consisted of using orthogonal chromatographic systems coupled to ICP-MS and UV detectors. Size-exclusion fractionation of the cytosolic extracts was followed by anion-exchange chromatographic separation of Cu- and Zn-containing species. After purification then tryptic digestion, Cu- and Zn-containing superoxide dismutase was identified by nESI-QqTOF. The MS-MS spectra of doubly charged peptides, with the Mascot searching engine, were used to obtain the sequence of the protein.

Molecular cloning and expression of two cytosolic copper-zinc superoxide dismutases genes from Nelumbo nucifera.

Two cytosolic copper-zinc superoxide dismutase (cytCuZnSOD) complementary deoxyribonucleic acid were achieved in Nelumbo nucifera (Elian). The active sites and common characteristics of cytCuZnSOD family were showed by homology modeling. The two recombinant proteins expressed by PET-32a vector showed the similar SOD activity (89.94 ± 0.54 U/mg) and could maintain more than 90% activity after incubation at 65°C. The subcellular location by green fluorescent protein revealed that these two isoforms were all located in cytosol and nucleus. The cytCuZnSODs were expressed in various parts of N. nucifera, which were expressed highest in the leafstalks and young leaves and lowest in the roots. The cytCuZnSOD messenger ribonucleic acids isolated from wounded leaves significantly increased at 1.5 h after treatment (HAT) with the highest expression at 3 HAT, after which the level decreased.

Neuronal response of peroxisomal and peroxisome-related proteins to chronic and acute Abeta injury.

The central role of peroxisomes in ROS and lipid metabolism and their importance in brain functioning are well established. The aim of this work was to study the modulation of peroxisomal and peroxisome-related proteins in cortical neurons in vitro challenged with chronic or acute Abeta treatment, in order to investigate whether peroxisomes represent one of the cellular target of Abeta in these cells. The expression of peroxisomal (PMP70, catalase, acyl-CoA oxidase and thiolase), peroxisome-related (PPARalpha, insulin-degrading enzyme) and anti-oxidant (SOD1, SOD2, GSTP1) proteins was studied. The results obtained, demonstrating an early upregulation of the peroxisomal proteins during the chronic challenge, followed by their dramatic impairment after acute challenge, suggest that peroxisomes represent one of the first line of defence against Abeta-mediated oxidative injury. Our results support the notion that substances able to activate PPARalpha and/or to induce peroxisomal proliferation may constitute a novel preventive and/or therapeutic tool against neurodegenerative diseases.