The selenoprotein phospholipid hydroperoxide glutathione peroxidase (PHGPx) changes its physical characteristics and biological functions during sperm maturation. PHGPx exists as a soluble peroxidase in spermatids but persists in mature spermatozoa as an enzymatically inactive, oxidatively cross-linked, insoluble protein. In the midpiece of mature spermatozoa, PHGPx protein represents at least 50 percent of the capsule material that embeds the helix of mitochondria. The role of PHGPx as a structural protein may explain the mechanical instability of the mitochondrial midpiece that is observed in selenium deficiency.
Macrophages are typically stimulated by components of microbial cell walls. Surprisingly, cell wall–less mycoplasmas can also very efficiently stimulate macrophages. We showed recently that mycoplasma-derived lipopeptides constitute the active principle. We have now isolated a clone of Mycoplasma fermentans expressing mainly one macrophage-stimulating lipopeptide. This lipopeptide was detergent-extracted and isolated by reversed-phase high-performance liquid chromotography, using nitric oxide release from C3H/HeJ mouse macrophages as bioassay for detection. In contrast to “conventional” bacterial lipoproteins, this lipopeptide had a free NH2 terminus. Amino acid composition, sequence, and the molecular weight of 2,163.3 are consistent with the following structure: S-(2,3-bisacyloxypropyl)cysteine-GNNDESNISFKEK with one mole C16:0, and a further mole of a mixture of C18:0 and C18:1 fatty acid per lipopeptide molecule. The sequence could not be found in either the protein identification resource nor the Swiss Prot data bank. We named this 2-kD lipopeptide, macrophage-activating lipopeptide-2 (MALP-2). Synthetic dipalmitoyl MALP-2 and mycoplasma-derived MALP-2 were compared with the bioassay. Both lipopeptides showed an identical dose dependency with a half-maximal response at 10−11 M concentration. MALP-2 may be one of the most potent natural macrophage stimulators besides endotoxin.
Parasitic trypanosomatids comprise causative agents of debilitating or life-threatening tropical diseases. The limited capacity of these parasites to cope with oxidative stress has been discussed as a target area for therapeutic approaches but success has been hampered by a lack of comprehension of their peculiar oxidant defense system depending on the unique redox metabolite trypanothione. Here we report that trypanothione-dependent hydroperoxide metabolism in Crithidia fasciculata is catalysed by two distinct proteins working in concert. One is Cf16, a unique protein which, apart from a WCPPC sequence that resembles the thioredoxin-type WCG(A)PC motif, only shows low similarity to thioredoxin-like proteins of bacteria and invertebrates. The second component is Cf21, which can be classified as a member of the peroxiredoxin family of proteins. The two proteins have been purified to homogeneity and shown to be essential for the trypanothione-dependent removal of hydroperoxides. By means of selective derivatisation of the substrate-reduced proteins the flux of reduction equivalents from trypanothione to Cf16, Cf21 and finally to the hydroperoxide was elucidated. Cf21 proved to be a moderately efficient peroxidase with broad specificity. The rate constants for the reaction of the reduced protein with H2O2, t-butyl hydroperoxide, linoleic acid hydroperoxide and phosphatidylcholine hydroperoxide were 1.0 x 10(5), 1.2 x 10(5), 1.0 x 10(5) and 0.4 x 10(5) M-1S-1, respectively. The apparent rate constant for the regeneration of reduced Cf21 by Cf16 was in the range of 1.5-3.5 x 10(6) M-1S-1. This newly discovered metabolic pathway adds two further candidates to the list of potential targets for trypanocidal drugs.
Genetic evidence from retinoblastoma patients and experiments describing the mechanism of cellular transformation by the DNA tumor viruses have defined a central role for the retinoblastoma protein (pRB) family of tumor suppressors in the normal regulation of the eukaryotic cell cycle. These proteins, pRB, p107, and p130, act in a cell cycle-dependent manner to regulate the activity of a number of important cellular transcription factors, such as the E2F-family, which in turn regulate expression of genes whose products are important for cell cycle progression. In addition, inhibition of E2F activity by the pRB family proteins is required for cell cycle exit after terminal differentiation or nutrient depletion. The loss of functional pRB, due to mutation of both RB1 alleles, results in deregulated E2F activity and a predisposition to specific malignancies. Similarly, inactivation of the pRB family by the transforming proteins of the DNA tumor viruses overcomes cellular quiescence and prevents terminal differentiation by blocking the interaction of pRB, p107, and p130 with the E2F proteins, leading to cell cycle progression and, ultimately, cellular transformation. Together these two lines of evidence implicate the pRB family of negative cell cycle regulators and the E2F family of transcription factors as central components in the cell cycle machinery.
The complete amino acid sequence of glucose oxidase from Penicillium amagasakiense was determined by Edman degradation and mass spectrometry of peptide fragments derived from three different specific proteolytic digests and a cyanogen bromide cleavage. The complete sequence of each monomer comprises 587 amino acid residues, contains three cysteine residues, and seven potential N-glycosylation sites, of which at least five were confirmed to be glycosylated. Glucose oxidase from P. amagasakiense shows a high degree of identity (66%) and 79% similarity to glucose oxidase from Aspergillus niger, and is a member of the glucose-methanol-choline (GMC) oxidoreductase family. The tertiary structures of glucose oxidase from A. niger and cholesterol oxidase from Brevibacterium sterolicum were superimposed to provide a template for the sequence comparison of members of the GMC family. Keywords : glucose oxidase; Penicillium amagasakiense ; amino acid sequence; glucose-methanol-choline oxidoreductase ; consensus pattern.The glycoprotein glucose oxidase catalyses the oxidation of stable but has a sixfold higher affinity for β-D-glucose and a β-D-glucose to D-glucono-1,5-lactone with the concomitant re-tenfold higher specificity constant than glucose oxidase from duction of molecular oxygen to hydrogen peroxide. The enzyme Aspergillus niger (Kalisz et al., 1997). Despite the commercial has been purified from Aspergillus (Pazur and Kleppe, 1964; importance and extensive industrial application of glucose oxiSwoboda and Massey, 1965) and Penicillium species (Kusai et dase (Röhr et al., 1983;Crueger and Crueger, 1984; Wilson and al., 1960). Fungal glucose oxidase is a homodimer of approxi-Turner, 1992), and the availability of the preliminary X-ray difmately 160 kDa containing two tightly, but non-covalently, fraction data , the three-dimensional strucbound FAD cofactors (Yoshimura and Isemura, 1971a,b; Hay-ture of P. amagasakiense glucose oxidase has only recently been ashi and Nakamura, 1976) and 13% carbohydrate of the high elucidated (Wohlfahrt, G., Witt, S., Herdle, J., Kalisz, H. M., mannose type (Hayashi and Nakamura, 1976; Kalisz et al., Schomburg, D. and Hecht, H. J., unpublished results). The main 1997). Glucose oxidase from Penicillium amagasakiense is less stumbling block was the unavailability of its primary structure.In contrast, both the amino acid sequence (Kriechbaum et al., Correspondence to H. M. Kalisz, Gesellschaft für Biotechnologische 1989; Frederick et al., 1990) and X-ray structure (Hecht et al.,
Tryparedoxin, a thioredoxin-related protein from Crirhidiu jusciculutu with a molecular mass of 16 kDa catalyses the reduction of a peroxiredoxin-type peroxidase, Cf21, at the expense of trypanothione [Nogoceke, E., Gommel, D. U., KieR, M., Kalisz, H. M. & FlohC, L. E. (1997) Biol. , The kinetic analysis of tryparedoxin revealed an enzyme substitution mechanism. The corresponding molecular event was elucidated to be a reversible oxidoreduction of the disulfide bridge in the thioredoxin-related motif WCPPC. The amino-proximal cysteine residue of this active site was more reactive in S-alkylation experiments than the distal residue. The natural substrates of tryparedoxin, trypanothione and Cf21, could only be substituted by glutathione and glutathione disulfide with considerable loss in activity. The pronounced specificity of tryparedoxin is further accentuated by low limiting K,, values for Cf21 and trypanothione (2.2 pM and 130 pM, respectively, as compared to 990 pM for gluthathione disulfide and an infinite value for glutathione). Tryparedoxin can therefore be classified as a trypanothione: peroxiredoxin oxidoreductase. The reduction of tryparedoxin by trypanothione appears to be the rate-limiting step in the trypanothione-dependent hydroperoxide reduction because(a) the regeneration of reduced tryparedoxin from the tryparedoxin-trypanothione complex is rate limiting (k,,l, 392 min-'), (b) the physiological trypanothione concentrations may not always saturate tryparedoxin, and (c) the rate constants for the net forward reaction of Cf21 are faster than those of the tryparedoxin reaction. The functional characteristics of tryparedoxin explain the limited capacity of trypanosomatids in coping with oxidative stress and qualify the enzyme as a potential target for the design of specific trypanocidal compounds.
Mycoplasmas are potent macrophage stimulators. We describe the isolation of macrophage-stimulatory lipopeptidesS-[2,3-bisacyl(C16:0/C18:0)oxypropyl]cysteinyl-GQTDNNSSQSQQPGSGTTNT andS-[2,3-bisacyl(C16:0/C18:0)oxypropyl]cysteinyl-GQTN derived from the Mycoplasma hyorhinis variable lipoproteins VlpA and VlpC, respectively. These lipopeptides were characterized by amino acid sequence and composition analysis and by mass spectrometry. The lipopeptidesS-[2,3-bis(palmitoyloxy)propyl]cysteinyl-GQTNT andS-[2,3-bis(palmitoyloxy)propyl]cysteinyl-SKKKK and the N-palmitoylated derivative of the latter were synthesized, and their macrophage-stimulatory activities were compared in a nitric oxide release assay with peritoneal macrophages from C3H/HeJ mice. The lipopeptides with the free amino terminus showed half-maximal activity at 3 pM regardless of their amino acid sequence; i.e., they were as active as the previously isolated M. fermentans-derived lipopeptide MALP-2. The macrophage-stimulatory activity of the additionally N-palmitoylated lipopeptide or of the murein lipoprotein from Escherichia coli, however, was lower by orders of magnitude. It is concluded that the lack of N-acyl groups in mycoplasmal lipoproteins explains their exceptionally high in vitro macrophage-stimulatory capacity. Certain features that lipopolysaccharide endotoxin and mycoplasmal lipopeptides have in common are discussed. Lipoproteins and lipopeptides are likely to be the main causative agents of inflammatory reactions to mycoplasmas. This may be relevant in the context of mycoplasmas as arthritogenic pathogens and their association with AIDS.
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