Intracellular localization of GDP-l-fucose: Glycoprotein and CMP-sialic acid: Apolipoprotein glycosyltransferases in rat and pork livers

A GDP-l-fucose:glycoprotein fucosyltransferase which transfers l-fucose to terminal β-N-acetyl-d-glucosaminyl residues of sialidase-, β-galactosidase-treated α₁-acid glycoprotein and a CMP-sialic acid:glycoprotein sialyltransferase acting on sialidase-treated apolipoprotein-Ala₁ from human very low density lipoprotein have been shown to be concentrated in rat liver Golgi apparatus preparations at enrichments of 40- and 45-fold, respectively, and in pork liver Golgi-rich fractions at enrichments of 35- and 20-fold, respectively. A second fucosyltransferase acting on sialidase-treated α₁-acid glycopretein was absent from rat liver and was enriched only 13-fold in a pork liver Golgi-rich fraction. The smooth-surfaced microsome fraction was the only other rat liver subcellular fraction with appreciable levels of the GDP-l-fucose: β-N-acetyl-d-glucosaminide fucosyltransferase and the lipoprotein sialyltransferase (enrichments of 2.6- and 5.2-fold, respectivley). This enrichment could not be attributed to the plasma membrane content of the smooth microsome fraction since plasma membrane fractions from rat liver were shown to have relatively low concentrations of these two transferases (enrichments of 0.3 or less). Rat liver plasma membrane was also shown to have similarly low relative specific activities for three other glycosyltransferases (sialyl-, galactosyl-, and N-acetylglucosaminyl-). The accurate determination of the glycosyltransferase activities of the plasma membrane fraction required the use of relatively low concentrations of plasma membrane and relatively high concentrations of nucleotide-sugars in order to avoid interference by the high nucleotide-sugar pyrophosphatase and hydrolase activities of this fraction.     

The presence of two GDP-L-fucose: glycoproteine fucosyltransferases in human serum

Two soluble fucosyltransferases have been demonstrated in human serum. One enzyme transfers l-fucose from GDP-l-fucose to the terminal galactose residues of lactose, N-acetyllactosamine, and sialidase-treated α₁-acid glycoprotein, to form the blood group H determinant, α-l-fucosyl-(1 → 2)-β-d-galactosyl-R. The second enzyme transfers fucose to the terminal N-acetylglucosamine residue of sialidase-, β-galactosidase-treated α₁-acid glycoprotein. Serum from a donor with the rare “Bombay” O_h blood group (genotype hh) cannot transfer fucose to terminal galactose residues but has normal levels of the enzyme acting on sialidase-, β-galactosidase-treated α₁-acid glycoprotein. This observation, as well as mixed substrate experiments, demonstrate that the two fucosyltransferase activities are due to two separate enzymes. The GDP-l-fucose:galactoside fucosyltransferase has a pH optimum of 5.5 and the following K_m values: lactose, 31 mm; N-acetyllactosamine, 7.5 mm; sialidase-treated α₁-acid glycoprotein, 6.4 mm. The GDP-l-fucose: N-acetylglucosaminide fucosyltransferase has a pH optimum of 5.0 and a K_m for sialidase-, β-galactosidase-treated α₁-acid glycoprotein of 1.2 mm. The serum GDP-l-fucose: N-acetylglucosaminide fucosyltransferase is distinct from the blood group Lewis-dependent enzyme in milk since the serum enzyme is present in serum from Le (a-b-)donors and since the Le-dependent fucosyltransferase could not be demonstrated in serum from donors carrying the Le gene.     

Modulation of plasma membrane lipid profile and microdomains by H2O2 in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, the rate of hydrogen peroxide (H₂O₂) diffusion through the plasma membrane decreases during adaptation to H₂O₂ by a still unknown mechanism. Here, adaptation to H₂O₂ was observed to modulate rapidly the expression of genes coding for enzymes involved in ergosterol and lipid metabolism. Adaptation to H₂O₂ also alters plasma membrane lipid composition. The main changes were the following: (a) there was a decrease in oleic acid (30%) and in the ratio between unsaturated and saturated long-chain fatty acids; (b) the phosphatidylcholine:phosphatidylethanolamine ratio increased threefold; (c) sterol levels were unaltered but there was an increased heterogeneity of sterol-rich microdomains and increased ordered domains; (d) the levels of the sterol precursor squalene increased twofold, in agreement with ERG1 gene down-regulation; and (e) C26:0 became the major very long chain fatty acid owing to an 80% decrease in 2-hydroxy-C26:0 levels and a 50% decrease in C20:0 levels, probably related to the down-regulation of fatty acid elongation (FAS1, FEN1, SUR4) and ceramide synthase (LIP1, LAC1) genes. Therefore, H₂O₂ leads to a reorganization of the plasma membrane microdomains, which may explain the lower permeability to H₂O₂, and emerges as an important regulator of lipid metabolism and plasma membrane lipid composition.     

Subcellular localization of glycosidases and glycosyltransferases involved in the processing of N-linked oligosaccharides

Using isopycnic sucrose gradients, we have ascertained the subcellular location of several enzymes involved in the processing of the N-linked oligosaccharides of glycoproteins in developing cotyledons of the common bean, Phaseolus vulgaris. All are localized in the endoplasmic reticulum (ER) or Golgi complex as determined by co-sedimentation with the ER marker, NADH-cytochrome c reductase, or the Golgi marker, glucan synthase I. Glucosidase activity, which removes glucose residues from Glc₃Man₉(GlcNAc)₂, was found exclusively in the ER. All other processing enzymes, which act subsequent to the glucose trimming steps, are associated with the Golgi. These include mannosidase I (removes 1-2 mannose residues from Man_6-9[GlcNAc]₂), mannosidase II (removes mannose residues from GlcNAcMan₅[GlcNAc]₂), and fucosyltransferase (transfers a fucose residue to the Asn-linked GlcNAc of appropriate glycans). We have previously reported the localization of two other glycan modifying enzymes (GlcNAc-transferase and xylosyltransferase activities) in the Golgi complex. Attempts at subfractionation of the Golgi fraction on shallow sucrose gradients yielded similar patterns of distribution for all the Golgi processing enzymes. Subfractionation on Percoll gradients resulted in two peaks of the Golgi marker enzyme inosine diphosphatase, whereas the glycan processing enzymes were all enriched in the peak of lower density. These results do not lend support to the hypothesis that N-linked oligosaccharide processing enzymes are associated with Golgi cisternae of different densities.     

Functional expression of Escherichia coli enzymes synthesizing GDP-L-fucose from inherent GDP-D-mannose in Saccharomyces cerevisiae

Fucosylation of glycans on glycoproteins and -lipids requires the enzymatic activity of relevant fucosyltransferases and GDP-L-fucose as the donor. Due to the biological importance of fucosylated glycans, a readily accessible source of GDP-L-fucose would be required. Here we describe the construction of a stable recombinant S.cerevisiae strain expressing the E.coli genes gmd and wcaG encoding the two enzymes, GDP-mannose-4,6-dehydratase (GMD) and GDP-4-keto-6-deoxy-D-mannose-3,5-epimerase/4-reductase (GMER(FX)) respectively, needed to convert GDP-mannose to GDP-fucose via the de novo pathway. Taking advantage of the rich inherent cytosolic GDP-mannose pool in S.cerevisiae cells we could easily produce 0.2 mg/l of GDP-L-fucose with this recombinant yeast strain without addition of any external GDP-mannose. The GDP-L-fucose product could be used as the fucose donor for alpha1,3fucosyltransferase to synthesize sialyl Lewis x (sLex), a glycan crucial for the selectin-dependent leukocyte traffic.     

Function of reduced pyridine nucleotide-ferredoxin oxidoreductases in saccharolytic Clostridia

The physiological function of the clostridial NADH- and NADPH-ferredoxin oxidoreductases was investigated with Clostridium pasteurianum and Clostridium butyricum.The NADH-ferredoxin oxidoreductases are concluded to be catabolic enzymes required for the reduction of ferredoxin by NADH. The conclusion is based on the finding that during the entire growth phase the fermentation of glucose can be formally represented by the weighted sum of Eqns 1 and 2, Glucose + 2 H₂O → 1 butyrate^? + 2 HCO₃^? + 3 H⁺ + 2 H₂ (1) Glucose + 4 H₂O → 2 acetate^? + 2 HCO₃^? + 4 H⁺ + 4 H₂ (2) and that in these redox processes NADH rather than NADPH is specifically formed during glyceraldehyde phosphate dehydrogenation. This NADH can be consumed by substrate reduction in Process 1 only, while it must be reoxidized in Process 2 by the ferredoxin-dependent proton reduction to hydrogen which involves the NADH-ferredoxin oxidoreductases.The kinetic and regulatory properties of these enzymes are in line with their catabolic role: they are found with high specific activities typical for other catabolic enzymes; essentially they catalyze electron flow from NADH to ferredoxin only because the back reaction is very effectively inhibited by low concentrations of NADH. These enzymes have a key role in the coupling of the two partial processes and in regulating the overall thermodynamic efficiency of the fermentations.The NADPH-ferredoxin oxidoreductases are concluded to participate in anabolism; they are required for the regeneration of NADPH. The conclusion is based on the finding that in the two clostridia all catabolic oxidations-reductions are specific for NAD(H) and that the usual NADPH-producing processes such as the glucose 6-phosphate dehydrogenase or malate enzyme reactions are absent. The kinetic properties of the enzymes are in agreement with their anabolic function: the NADPH-ferredoxin oxidoreductases are found with sufficient specific activities; they preferentially catalyze electron transfer from reduced ferredoxin to NADP⁺.     

The Ataxia telangiectasia-mutated and Rad3-related protein kinase regulates cellular hydrogen sulfide concentrations

The ataxia telangiectasia-mutated and Rad3-related (ATR) serine/threonine kinase plays a central role in the repair of replication-associated DNA damage, the maintenance of S and G2/M-phase genomic stability, and the promotion of faithful mitotic chromosomal segregation. A number of stimuli activate ATR, including persistent single-stranded DNA at stalled replication folks, R loop formation, hypoxia, ultraviolet light, and oxidative stress, leading to ATR-mediated protein phosphorylation. Recently, hydrogen sulfide (H₂S), an endogenous gasotransmitter, has been found to regulate multiple cellular processes through complex redox reactions under similar cell stress environments. Three enzymes synthesize H₂S: cystathionine-β-synthase, cystathionine γ-lyase, and 3-mercaptopyruvate sulfurtransferase. Since H₂S can under some conditions cause DNA damage, we hypothesized that ATR activity may regulate cellular H₂S concentrations and H₂S-syntheszing enzymes. Here we show that human colorectal cancer cells carrying biallelic knock-in hypomorphic ATR mutations have lower cellular H₂S concentrations than do syngeneic ATR wild-type cells, and all three H₂S-synthesizing enzymes show lower protein expression in the ATR hypomorphic mutant cells. Additionally, ATR serine 428 phosphorylation is altered by H₂S donor and H₂S synthesis enzyme inhibition, while the oxidative-stress induced phosphorylation of the ATR-regulated protein CHK1 on serine 345 is increased by H₂S synthesis enzyme inhibition. Lastly, inhibition of H₂S production potentiated oxidative stress-induced double-stranded DNA breaks in the ATR hypomorphic mutant compared to ATR wild-type cells. Our findings demonstrate that the ATR kinase regulates and is regulated by H₂S.     

Lactosaminoglycans synthesized by mouse male germ cells are fucosylated by an epididymal fucosyltransferase

We have studied the synthesis of protein-bound carbohydrates in differentiating male germ cells in the mouse. Spermatocytes and spermatids synthesize asparagine-linked and high-molecular-weight glycopeptides as the major classes of protein bound carbohydrates. Asparagine-linked glycopeptides were found to be mainly composed of the complex bi-antennary type as shown by affinity chromatography on concanavalin-A Sepharose; high-molecular-weight glycopeptides were represented by nonfucosylated lactosaminoglycans since they were metabolically labeled with [¹⁴C]glucosamine but not with [³H]fucose, did not bind to DEAE-cellulose, and were susceptible to endo-β-galactosidase. Labeling with galactose oxidase/Na B³H₄ technique demonstrated that lactosaminoglycans were present on the surface of differentiating germ cells and of testicular and epididymal spermatozoa. Since lactosaminoglycans from germ cells and testicular spermatozoa were not retained on a column of fucose-binding lectin, it was concluded that these molecules do not contain fucose. On the other hand, epididymal spermatozoa lactosaminoglycans bound to the lectin and therefore contained fucose. A soluble fucosyltransferase, capable of transferring fucose to germ cell lactosaminoglycans, was found to be present in the epididymis but not in the testis. These data show that developing germ cells synthesize nonfucosylated lactosaminoglycans which are probably preserved throughout spermiogenesis. We suggest that these molecules are fucosylated in vivo by a fucosyltransferase secreted by the epididymal epithelium.     

The pyruvate: Ferredoxin oxidoreductase in heterocysts of the cyanobacteriuim Anabaena cylindrica

Heterocyst preparations have been obtained which actively perform nitrogen fixation (C₂H₂ reduction) and contain the enzymes of glycolysis and some of the tricarboxylic acid cycle. Pyruvate: ferredoxin oxidereductase has been unambiguously demonstrated in extracts from heterocysts by the formation of acetylcoenzyme A, CO₂ and reduced methyl viologen (ferredoxi) from pyruvate, coenzyme A and oxidized methyl viologen (ferredoxin) as well as by the synthesis of pyruvate from CO₂, acetylcoenzyme A and reduced methyl viologen. Pyruvate supports C₂H₂ reduction by isolated heterocysts, however, with lower activity than Na₂S₂O₄ and H₂. α-Ketoglutarate: ferredoxin oxidoreductase is absent in Anabaena cylindrica, confirming that the organism has an incomplete tricarboxylic acid cycle.     

Differentiative changes in fucosyltransferase activity in newborn rat epidermal cells.

An enzymatic activity catalyzing the transfer of L-fucose from GDP-L-fucose to a glycoprotein that is associated with the surfaces of the basal cells has been found in the membranous fraction of the cutaneous epidermis from the newborn rat. This fucosyltransferase which is located in the differentiated cells alters the acceptor glycoprotein's lectin-binding specificity from the Isolectin I-B4 of Griffonia simplicifolia (GS I-B4) to the Agglutinin I of Ulex europeus (UEA) and could be responsible for the same change in lectin-binding specificity that occurs as the epidermal basal cell differentiates. Another membraneous fucosyltransferase that can use asialofetuin--but not the GS I-B4-binding glycoprotein--as an acceptor, is also present in the membraneous fraction.     

1,3,4-Oxadiazole-2(3H)-thione and its analogues: A new class of non-competitive nucleotide pyrophosphatases/phosphodiesterases 1 inhibitors

A series of 1,3,4-oxadiazole-2 (3H)-thiones and 1,3,4-thiadiazole-2 (3H)-thiones were synthesized and evaluated for their inhibitory activities against the two nucleotide pyrophosphatase phosphodiesterase 1 enzymes. Dixon, as well as Lineweaver–Burk plots, and their secondary replots have indicated that the inhibition was of pure non-competitive type, against both snake venom and pure human recombinant enzymes as the V_max values decreases without affecting the K_m values. 5-[4-(t-Butyldimethylsilyloxy)-phenyl]-1,3,4-thiadiazole-2 (3H)-thione (17) and [4-(t-butyldimethylsilyloxy)-phenyl]-1,3,4-oxadiazole-2 (3H)-thione (1) were found to be the most active compounds with IC₅₀ values 66.47 and 368 μM, respectively. The K_i values were 100 μM and 360 μM against the snake venom and human recombinant NPP1 enzyme, respectively. Most active compounds were found to be non-toxic in neutrophil viability assay.     

Glyoxal oxidases: their nature and properties

H₂O₂ has been found to be required for the activity of the main microbial enzymes responsible for lignin oxidative cleavage, peroxidases. Along with other small radicals, it is implicated in the early attack of plant biomass by fungi. Among the few extracellular H₂O₂-generating enzymes known are the glyoxal oxidases (GLOX). GLOX is a copper-containing enzyme, sharing high similarity at the level of active site structure and chemistry with galactose oxidase. Genes encoding GLOX enzymes are widely distributed among wood-degrading fungi especially white-rot degraders, plant pathogenic and symbiotic fungi. GLOX has also been identified in plants. Although widely distributed, only few examples of characterized GLOX exist. The first characterized fungal GLOX was isolated from Phanerochaete chrysosporium. The GLOX from Utilago maydis has a role in filamentous growth and pathogenicity. More recently, two other glyoxal oxidases from the fungus Pycnoporus cinnabarinus were also characterized. In plants, GLOX from Vitis pseudoreticulata was found to be implicated in grapevine defence mechanisms. Fungal GLOX were found to be activated by peroxidases in vitro suggesting a synergistic and regulatory relationship between these enzymes. The substrates oxidized by GLOX are mainly aldehydes generated during lignin and carbohydrates degradation. The reactions catalysed by this enzyme such as the oxidation of toxic molecules and the production of valuable compounds (organic acids) makes GLOX a promising target for biotechnological applications. This aspect on GLOX remains new and needs to be investigated.     

Role of catalase,H2O2 and phenolics in resistance of pigeonpea towards Helicoverpa armigera (Hubner)

Rapid generation of superoxide radicals and accumulation of H₂O₂ is a characteristic early response of plants following perception of insect herbivory signals. Induction of oxidative burst on account of herbivory triggers various defense mechanisms in plants. Response of superoxide and H₂O₂-metabolizing enzymes and secondary metabolites in nine pigeonpea genotypes to Helicoverpa armigera feeding was investigated. Out of nine, four genotypes were found to be moderately resistant, three were intermediate and two were moderately susceptible. In general, H. armigera infestation resulted in increase in superoxide dismutase activity, H₂O₂ and phenolics content and decrease in catalase (CAT) activity in leaves, developing seeds and pod wall of pigeonpea genotypes. Peroxidase activity was found only in leaves. Among genotypes, the increase in phenolic constituents was found greater in moderately resistant genotypes than in moderately susceptible genotypes; this might determine their contribution in providing resistance to genotypes against H. armigera infestation. The capability of moderately resistant genotypes to maintain relatively lower H₂O₂ content and higher CAT activity in pod wall and developing seeds also appeared to determine resistance of genotypes towards H. armigera. Expression of resistance to H. armigera was found to be associated with a negative correlation of H₂O₂-metabolizing enzymes and phenolics with pod damage as well as with negative association between CAT activity and H₂O₂ content. A positive correlation found between H₂O₂ content and pod damage suggested the accumulation of H₂O₂ in response to pod borer attack. In addition, correlation analysis also revealed a positive association between CAT, phenolic compounds and DPPH radical scavenging activity following pod borer attack; this indicated their contribution in resistance mechanisms against H. armigera herbivory.     

Reduced nicotinamide adenine dinucleotide phosphate oxidase in adipocyte plasma membrane and its activation by insulin. Possible role in the hormone's effects on adenylate cyclase and the hexose monophosphate shunt.

An oxidase activity utilizing reduced nicotinamide adenine dinucleotide phosphate (NADPH) and producing H₂O₂ was observed in intact adipocytes of rat, as well as in the isolated plasma membranes of these cells. A stoichiometry of 1 mol of H₂O₂ production per mole of NADPH disappearance was found with isolated plasma membranes. Activation of this enzyme (R) was produced by pretreatment of cells with insulin, dithiothreitol, or sulfhydryl inhibitors, e.g., p-chloromercuribenzoate or tosyl-l-lysine chloromethyl ketone. All of these agents also stimulated glucose oxidation via the hexose monophosphate shunt. Activation of R was also observed with biologically active derivatives of insulin, e.g., proinsulin or desalanine insulin, but not with an inactive derivative, desoctapeptide insulin. The enzyme could not be activated by exposing the cells to membrane perturbants, e.g., hypotonic conditions or Triton X-100 (0.01–0.1%). The enzyme activity in the plasma membrane had a pH optimum at 6.0 and, from the Lineweaver-Burke plot, V was determined at 230 nmol and K_m for NADPH was at 5.8 × 10^?5, m. The activity remained unaltered in the presence of sodium azide or cyanide. Preincubation of adipocytes with insulin or SH reagents or direct addition of oxidants, e.g., H₂O₂, potassium ferricyanide, or phenazine methosulfate, to the membranes also caused inhibition of adenylate cyclase (AC). This enzyme activity could be restored in these preparations by adding thiols. It is suggested that inhibition of AC in whole cells in response to insulin may be caused by oxidation of its SH groups by the H₂O₂ generated from the activated NADPH oxidase. Reversal of this inhibition may involve cellular reducing equivalents. The evidence suggests that the plasma membrane enzymes, i.e., NADPH oxidase and adenylate cyclase, are controlled, in part, by the intracellular redox potential.     

Role of LytF and AtlS in eDNA Release by Streptococcus gordonii

Extracellular DNA (eDNA) is an important component of the biofilm matrix produced by many bacteria. In general, the release of eDNA is associated with the activity of muralytic enzymes leading to obvious cell lysis. In the Gram-positive oral commensal Streptococcus gordonii, eDNA release is dependent on pyruvate oxidase generated hydrogen peroxide (H₂O₂). Addition of H₂O₂ to cells grown under conditions non-permissive for H₂O₂ production causes eDNA release. Furthermore, eDNA release is maximal under aerobic growth conditions known to induce pyruvate oxidase gene expression and H₂O₂ production. Obvious cell lysis, however, does not occur. Two enzymes have been recently associated with eDNA release in S. gordonii. The autolysin AtlS and the competence regulated murein hydrolase LytF. In the present report, we investigated the role of both proteins in the H₂O₂ dependent eDNA release process. Single and double mutants in the respective genes for LytF and AtlS released less eDNA under normal growth conditions, but the AtlS mutant was still inducible for eDNA release by external H₂O₂. Moreover, we showed that the AtlS mutation interfered with the ability of S. gordonii to produce eDNA release inducing amounts of H₂O₂. Our data support a role of LytF in the H₂O₂ eDNA dependent release of S. gordonii as part of the competence stress pathway responding to oxidative stress.     

Current status of the metabolic engineering of microorganisms for biohydrogen production

The improvement of H₂ production capabilities of hydrogen (H₂)-producing microorganisms is a challenging issue. Microorganisms have evolved for fast growth and substrate utilization rather than H₂ production. To develop good H₂-producing biocatalysts, many studies have focused on the redirection and/or reconstruction of cellular metabolisms. These studies included the elimination of enzymes and carbon pathways interfering or competing with H₂ production, the incorporation of non-native metabolic pathways leading to H₂ production, the utilization of various carbon substrates, the rectification of H₂-producting enzymes (nitrogenase and hydrogenase) and photophosphorylation systems, and in silico pathway flux analysis, among others. Owing to these studies, significant improvements in the yield and rate of H₂ production, and in the stability of H₂ production activity, were reached. This review presents and discusses the recent developments in biohydrogen production, with a focus on metabolic pathway engineering.     

Ferric and manganic superoxide dismutases in Euglena gracilis.

Iron-containing superoxide dismutase was found in the soluble fraction from Euglena gracilis and Mn-superoxide dismutase was found in the thylakoid-bound form. Two major Fe-superoxide dismutases were isolated from the soluble fraction in the homogeneous state. Their absorption spectra, molecular weights, subunit structures, and metal contents resemble those of the Fe-enzymes from procaryotes. However,the Euglena enzymes are more sensitive to heating, to denaturants, and to H₂O₂ and less sensitive to azide than are the procaryote enzymes. The amino acid composition of the Euglena enzyme differs substantially from the compositions of the enzymes from procaryotes.     

Recent advances in studies of the mechanisms of microbial degradation of lignins

Major advances in our understanding of the biochemical and enzymological mechanisms of lignin biodegradation have been made in the past three years. Research has principally involved two ligninolytic microorganisms, the white rot fungus Phanerochaete chrysosporium and the actinomycete Streptomyces viridosporus. Research has been centred on attempts to identify the microbial catalysts that mediate lignin decay in these two microbes. Emphasis has been on studies concerned with isolating specific lignin catabolic enzymes and/or reduced forms of oxygen involved in attacking the lignin polymer. The possibility that lignin degradation might be non-enzymatic and mediated by extracellular reduced oxygen species such as hydrogen peroxide (H₂O₂), superoxide (O₂∪c-|_.), hydroxyl radical (·OH) or singlet oxygen (¹O₂) has been investigated with both microorganisms. Using methods which have not always been unequivocal, the question of involvement of reduced oxygen species in lignin degradation by P. chrysosporium has been examined exhaustively. Evidence for the involvement of H₂O₂ is conclusive. However, there is little evidence to support the involvement of other extracellular reduced oxygen species, including ·OH, directly in the process of lignin degradation. Scavenger studies have been inconclusive because of questions of their specificity. If activated oxygen species are involved, the activated oxygen is probably held within the active site of an enzyme molecule. With S. viridosporus, scavenger studies also strongly indicate that extracellular reduced oxygen species are not involved in lignin degradation since scavengers generally do not significantly affect the ligninolytic system. The involvement of specific enzymes in lignin degradation by both P. chrysosporium and S. viridosporus has now been confirmed. With P. chrysosporium, ligninolytic enzymes recently discovered include extracellular non-specific peroxidases and oxygenases. They show numerous activities including dehydrogenative, peroxidatic, oxygenative and C_α?C_β cleavages of lignin side chains. At least one P. chrysosporium enzyme, a unique H₂O₂-requiring oxygenase, has been purified to homogeneity. Evidence has been presented to show that S. viridosporus also produces a ligninolytic enzyme complex involved in demethylation of lignin's aromatic rings and in the oxidation of lignin side chains and cleavage of β-tether linkages within the polymer. The combined activites of these enzymes generate water-soluble polymeric modified lignin fragments, which are then slowly degraded further by S. viridosporus. The β-ether cleaving enzyme complex is probably membrane associated, but it is not extracellular. These first isolations of ligninolytic enzymes have changed the course of basic research on lignin biodegradation. New research priorities are already emerging and include enzyme purifications, kinetic studies, enzyme reaction mechanism studies and screenings for more enzymes. In addition, genetic studies are being carried out with both P. chrysosporium and S. viridosporus. Genetic manipulations include not only classical mutagenesis techniques, but also recombinant DNA techniques such as protoplast fusion. This latter technique has already been used to generate overproducers of the ligninolytic enzyme complex in S. viridosporus and it has been successfully used to recombine mutant strains of P. chrysosporium.     

Relationship between H2O2 and jasmonic acid in pea leaf wounding response

The relationship of H₂O₂ and jasmonic acid (JA) in wound-induced defense response was investigated in the leaves of pea (Pisum sativum L.) plants. The results showed that both wounding and JA treatment led to a significant increase in activities of plasma membrane NADPH oxidase and phenylalanine ammonialyase. However, such an increase was blocked by the pretreatment with plasma membrane NADPH oxidase inhibitors, O ₂ ^? scavengers, or H₂O₂ scavenger, implying that H₂O₂ functions downstream of JA. Furthermore, wounding treatment activated two key enzymes of JA biosynthesis, lipoxygenase and allene oxide synthase, while JA biosynthetic inhibitors impaired the wounding-induced H₂O₂ burst. Thus, it is suggested that H₂O₂ burst depends on JA production in plant wounding response.     

Cj1386, an Atypical Hemin-Binding Protein,Mediates Hemin Trafficking to KatA in Campylobacter jejuni

Catalase enzymes detoxify H₂O₂ by the dismutation of H₂O₂ into O₂ and H₂O through the use of hemin cofactors. While the structure and biochemical properties of catalase enzymes have been well characterized over many decades of research, it remained unclear how catalases acquire hemin. We have previously reported that Cj1386 is essential for ensuring proper hemin content in Campylobacter jejuni catalase (KatA) (A. Flint, Y. Q. Sun, and A. Stintzi, J Bacteriol 194:334–345, 2012). In this report, an in-depth molecular characterization of Cj1386 was performed to elucidate the mechanistic details of this association. Coimmunoprecipitation assays revealed that KatA-Cj1386 transiently interact in vivo, and UV-visible spectroscopy demonstrated that purified Cj1386 protein binds hemin. Furthermore, hemin titration experiments determined that hemin binds to Cj1386 in a 1:1 ratio with hexacoordinate hemin binding. Mutagenesis of potential hemin-coordinating residues in Cj1386 showed that tyrosine 57 was essential for hemin coordination when Cj1386 was overexpressed in Escherichia coli. The importance of tyrosine 57 in hemin trafficking in vivo was confirmed by introducing the cj1386^Y57A allele into a C. jejuni Δcj1386 mutant background. The cj1386^Y57A mutation resulted in increased sensitivity toward H₂O₂ relative to the wild type, suggesting that KatA was not functional in this strain. In support of this finding, KatA immunoprecipitated from the Δcj1386+cj1386^Y57A mutant had significantly reduced hemin content compared to that of the cj1386^WT background. Overall, these findings indicate that Cj1386 is involved in directly trafficking hemin to KatA and that tyrosine 57 plays a key role in this function.