Purification and characterization of homogeneous sunflower seed acid phosphatase

Acid phosphatase (EC 3.1.3.2) from sunflower seed was purified 1800-fold to homogeneity using both conventional and affinity chromatographic methods. The purified enzyme was a mixture of two enzyme forms distinguishable by polyacrylamide gel electrophoresis (PAGE). Gel exclusion chromatography, which did not distinguish between the two forms, gave an apparent M, of 103 000. Preparative PAGE permitted the separation of the two forms, and SDS-PAGE showed that they contained equivalent peptide subunits of apparent M, 56 000 and 52 000. Amino acid analysis indicated that both enzyme forms have similar amino acid compositions. Data on substrate specificity and pH dependence is presented. The kinetic constants for hydrolysis of p-nitrophenyl phosphate as catalysed by sunflower seed acid phosphatase were independent of pH in the range 3-5. The enzyme was competitively inhibited by inorganic phosphate and non-competitively inhibited by phosphomycin.     

Molecular properties of extracellular Botrytis cinerea laccase

Two molecular forms of extracellular laccase induced by different phenolics were studied in Botrytis cinerea. The enzyme induced by grapejuice had a MW of 38 000 and contained 80 % sugar while that induced by gallic acid had a MW of 36 000 and contained 70 % sugar. Both forms contained arabinose, xylose, mannose, galactose and glucose but differed markedly in the relative content of these sugars. Tunicamycin, which inhibits glycosylation of peptide chains, considerably reduced the level of laccase in both hyphae and medium. The two enzyme forms differed also in their isoelectric focusing pattern and amino acid composition, the grape juice enzyme being richer in basic amino acids and poorer in acidic ones. A third form, induced by p-coumaric acid, resembled the laccase induced by gallic acid in many of its properties but was apparently not identical to it. The possible significance of the various forms in relation to the infection process by the fungus is discussed.     

Biochemical and genetic evidence for a macromolecular -glucuronidase complex in microsomal membranes

In the mouse β-glucuronidase is present in both microsomes and lysosomes and the enzyme at both sites is coded by the same structural gene. Electrophoresis on polyacrylamide gels showed that liver, kidney and lung from normal strains contained five enzyme forms designated L, M1, M2, M3 and M4 in order of decreasing mobility toward the anode. Band L is found primarily in lysosomes and is a tetramer of 260,000 molecular weight. Bands M1 to M4 are found exclusively in microsomes and range in molecular weight from 310,000 to 470,000. The increase in molecular weight is due to sequential addition of an accessory protein chain. When glucuronidase is highly induced in kidneys of female mice by injection of dihydrotestosterone, a sixth electrophoretic form of glucuronidase, designated X, appears. Form X appears early in induction, is localized in microsomes, and has a molecular weight (260,000) equal to that of the tetramer form L.Mice homozygous for the eg ° mutation, and thus deficient in microsomal glucuronidase, completely lack the microsomal forms M1 to M4. They do contain form X, and this increases after testosterone induction in kidney. The form X present in eg ° mice is indistinguishable from the form X seen in normal induced kidney.It appears that mice synthesize two different tetrameric forms of glucuronidase from the same structural gene. One, form L, is lysosomal; the other, form X, gives rise to microsomal enzyme forms M1 to M4 by the successive addition of up to four accessory protein chains. The eg ° mutant is blocked in the conversion of X to M1.     

Maize microsomal benzoxazinone N-monooxygenase

The benzoxazinones occur in hydroxamic acid and lactam forms in maize (Zea mays L.) tissue. The hydroxamic acid forms which possess a N-hydroxyl group are found in the highest concentration while the lactam members which lack the N-hydroxyl group occur in lower concentrations. The hydroxamic acid 2,4-dihydroxy-1,4-benzoxazin-3-one (DIBOA) has as its lactam counterpart 2-hydroxy-1,4-benzoxazin-3-one (HBOA). An enzyme has been identified in maize microsomal preparations which catalyzes the N-hydroxylation of HBOA to form DIBOA. The enzyme is initially observed in seedlings 2 days after imbibition which coincides with the onset of hydroxamic acid accumulation. The enzyme requires NADPH and is inhibited by sulfhydryl reagents, NADP, cytochrome c, cations, carbon monoxide, and nitrogen gas. The effect of nitrogen can be reversed by exposing the enzyme to air, while the effect of carbon monoxide can be reversed by exposing the enzyme to 450 nanometer light during the incubation period. The apparent K_m values for HBOA and NADPH are 13 and 5 micromolar, respectively. The pH optimum is 7.5 and the temperature optimum for the enzyme is 35°C. A 450 nanometer absorbance peak is observed when reduced microsomal preparations are exposed to carbon monoxide which in combination with other data presented supports the hypothesis that the enzyme is a cytochrome P-450 dependent N-monooxygenase.     

Mga2p processing by hypoxia and unsaturated fatty acids in Saccharomyces cerevisiae: impact on LORE-dependent gene expression

In Saccharomyces cerevisiae, OLE1 encodes a Δ9 fatty acid desaturase, an enzyme that plays a critical role in maintaining the correct ratio of saturated to monounsaturated fatty acids in the cell membrane. Previous studies have demonstrated that (i) OLE1 expression is repressed by unsaturated fatty acids (UFAs) and induced by low oxygen tension, (ii) a component of this regulation is mediated through the same low oxygen response element (LORE) in the OLE1 promoter, and (iii) Mga2p is involved in LORE-dependent hypoxic induction of OLE1. We now report that LORE-CYC1 basal promoter-lacZ fusion reporter assays demonstrate that UFAs repress the reporter expression under hypoxic conditions in a dose-dependent manner via LORE. Electrophoretic mobility shift assays show that UFAs repress the hypoxia-induced complex formation with LORE. Studies with a construct encoding a truncated form of Mga2p support the hypothesis that both hypoxia and UFA signals affect the processing of Mga2p and the UFA repression of OLE1 hypoxic induction is mediated through Mga2p. Data from Western blot assays provide evidence that under normoxic conditions, Mga2p processing produces approximately equimolar levels of the membrane-bound and processed forms and is unaffected by UFAs. Hypoxic induction of OLE1, however, is associated with increased processing of the protein, resulting in an approximately fivefold increase in the soluble active form that is counteracted by exposure of the cells to unsaturated fatty acids. Data from this study suggest that the Mga2p-LORE interaction plays an important role in OLE1 expression under both normoxic and hypoxic conditions.     

A chloroplast-associated fatty acid synthetase system in Euglena

Fatty acid synthetase activity in etiolated Euglena gracilis strain Z is independent of added ACP and associated with a high-molecular-weight complex of the type found in yeast. Cells grown in the dark and then greened by illumination in a resting medium develop a second enzyme system which is dependent on added ACP and generally resembles the corresponding E. coli and plant enzymes. Cycloheximide has no effect on the appearance of the ACP-dependent fatty acid synthetase in greening cells whereas chloramphenicol causes complete inhibition at concentrations which decrease chlorophyll synthesis by 66%. An induction of the ACP-dependent fatty acid synthetase in the absence of chloroplast development occurs on exposure of dark-grown cells to doses of ultraviolet light which selectively affect proplastid nucleoprotein. This enzyme induction by ultraviolet light is inhibited by chloramphenicol. The protein synthesis machinery of the chloroplast appears to be responsible, either directly or indirectly, for the appearance of the ACP-dependent fatty acid synthetase of Euglena.     

Multiple forms of acid phosphatase in rat liver parenchymal,endothelial, and kupffer cells

Purified suspensions of highly viable parenchymal, endothelial, and Kupffer cells were prepared from rat liver. In the liver cell classes, total activities of acid phosphatase were determined with 4-methylumbelliferylphosphate, 1-naphthylphosphate, and p-nitrophenylphosphate. The specific enzyme activities were different for each type of cell and, even within one cell class, the enzymes showed different conversion rates for the three substrates. These results indicate the presence of multiple forms of acid phosphatase enzymes in each cell class. The inhibiting effects of tartrate, fluoride, and alloxan on the acid phosphatase activities were investigated. Depending on the substrate used, the inhibitors inactivated the enzymes at different rates, which also indicates the presence of multiple forms of acid phosphatase enzymes in the liver cell classes. By means of an isoelectric focusing technique, acid phosphatase enzymes could be separated on the basis of their differences in isoelectric points. One form with an isoelectric point around 4 is found in Kupffer cells, whereas another form with an isoelectric point of about 7 is found in parenchymal cells. Endothelial cells possess both forms. These findings suggest a specificity in the function of this lysosomal enzyme in each cell class.     

Flavour biogenesis. Partial purification and properties of a fatty acid hydroperoxide cleaving enzyme from fruits of cucumber

A membrane-bound enzyme, which catalyses the cleavage of fatty acid hydroperoxides to carbonyl fragments, has been partially purified from cucumber fruit. The isomeric 9- and 13-hydroperoxydienes (but not the hydroxydienes) derived from both linoleic and linolenic acids are cleaved by the enzyme but a mixture of 9- and 10-hydroperoxymonoenoic derivatives of oleic acid was not attacked. No evidence was obtained for free intermediates between fatty acid hydroperoxides and the cleavage products. Major volatile products were: cis-3-nonenal and hexanal (from 9- and 13-hydroperoxides of linoleic acid respectively) or cis-3,cis-6-nonadienal and cis-3-hexenal (from 9- and 13-hydroperoxides of linolenic acid). The increase in the ratio of cis-3- to trans-2-enal products with enzyme purification indicated that cis-3-enals are the immediate cleavage products and that the trans-2- forms are produced by subsequent isomerization.     

Acid phosphatase of HeLa cells: properties and regulation of lysosomal activity by serum.

Although the subcellular distribution profile of acid phosphatase in HeLa cells is typical of a lysosomal enzyme, different lysosomal (70–80%) and supernatant forms (20–30%) have been demonstrated by their differences in pH activity curves, substrate specificities, thermal stability, sensitivity to inhibitors, and kinetics. Enzymes of the lysosomal fraction displayed anomalous kinetics in the hydrolysis of p-nitrophenyl phosphate. The major lysosomal acid phosphatase activity appears to be associated with the membrane.The total acid phosphatase activity in the cell is controlled by the concentration of serum in the medium. The specific activity in the homogenates of cells grown in high serum concentration (30%) is about twice that of cells grown in low serum concentration (1%). This doubling of specific activity holds for the lysosomal enzyme (or enzymes), but little change occurs in the supernatant form (or forms). Two other lysosomal enzymes, β-glucuronidase and N-acetyl-β-d-hexosaminidase, do not increase in specific activity. The serum-dependent formation of acid phosphatase is sensitive to cycloheximide, actinomycin D, and cordycepin. Cycloheximide blocks the increase in enzymatic activity immediately, whereas cordycepin and actinomycin D have no effect for at least 8 h. These findings suggest that de novo protein synthesis is involved in the induction of lysosomal acid phosphatase by serum and that the mRNA for this enzyme is relatively stable.     

Comparison of phospho- and dephospho-ATP citrate lyase

The dephospho- form of rat liver citrate lyase has been prepared by treating purified [³²P]-ATP citrate lyase with a partially purified phosphatase. A comparison of the properties of the phospho- and dephosphoenzyme has been performed. The pH optima were the same for both forms of the enzyme in four different buffer systems although the optimum values varied identically for both enzyme forms with the buffer. Both the phospho- and dephosphoenzymes show the same kinetic properties except for the K_m observed for ATP in 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid buffer system where it was 54 μm for the phosphoenzyme and 292 μm for the dephosphoenzyme. The present study also indicates that both enzymes are cleaved by trypsin and lysosomal proteases in a similar manner. Both forms of the enzyme tend to associate with mitochondria to the same extent and both enzymes have identical temperature stability curves.     

Nature of Ribosome-Bound β-Galactosidase

Properties of the ribosome-bound β-galactosidase were examined in Escherichia coli cells after prolonged induction. This fraction of enzyme was not chased from ribosomes by removal of inducer, or by treatments with hydroxylamine, puromycin, chloramphenicol, and azide. However, the metabolic turnover of this fraction could be demonstrated by means of a pulsed exposure to the phenylalanine analogue β-2-thienylalanine, and this fraction was enriched in heavy forms relative to the soluble enzyme. These observations indicated a tight coupling of the release of ribosome-bound enzyme to nascent enzyme synthesis, and it is suggested that the ribosome-bound enzyme is related to an intermediate stage in the assembly of quarternary enzyme structures.     

Penicillinamidohydrolase inEscherichia coli

The differential rate of synthesis of penicillinamidohydrolase (penicillin acylase — EC 3.5.1.11) was studied inEscherichia coli growing in some chemically defined media and in a complex medium. The enzyme is synthesized at a constant rate only during the exponential phase of growth of cells. Its synthesis is induced most effectively (with respect to quantity) by phenylacetic acid. The induction lag of the enzyme synthesis in a medium with acetate corresponds to two generation times. The highest rate of the enzyme synthesis is reached in a medium containing phenylacetic acid as the only source of carbon and energy. The enzyme synthesis is fully repressed by an increased concentration of dissolved oxygen in the medium, even whenEscherichia coli is cultivated in the medium with phenylacetic acid as the only carbon and energy source.     

Photoreactivating enzyme from Euglena and the control of its intracellular level

Photoreactivating (PR) enzyme activity has already been demonstrated by us in cell-free extracts of Euglena gracilis var. bacillaris Pringsheim using the Hemophilus transformation assay. This activity can also be detected in extracts using a direct non-biological assay for the photorepair of thymine dimers in DNA. PR enzyme is found in extracts of both wild-type cells and cells of an aplastidic mutant, W₃BUL, lacking detectable chloroplast DNA, indicating that the PR enzyme is neither coded nor translated exclusively in the chloroplast, but is probably coded in the nucleus and translated in the cytoplasm. Growing cultures of wild-type cells manifest a large increase in PR enzyme activity in vitro upon entering stationary phase. This correlates with the increased photoreactivability of chloroplast inheritance in vivo in stationary phase cells, previously found for Euglena, and suggests that a substantial part of the newly synthesized PR enzyme is available to repair plastid DNA. When dark-grown nondividing wild-type cells are exposed to light, there is a large increase in the specific activity of PR enzyme measured in vitro. This increase is prevented by cycloheximide but not by chloramphenicol or streptomycin, indicating that the enzyme is synthesized on 87s cytoplasmic ribosomes rather than 68s chloroplast ribosomes. Wavelengths of light effective for PR of chloroplast DNA in vivo are also effective for the light induction of PR enzyme. A brief illumination (45 min) of dark-grown nondividing wild-type cells triggers the synthesis of PR enzyme which continues in the absence of light. Growing cultures of W₃BUL also exhibit a preferential synthesis of PR enzyme in the staionary phase of growth, but the specific activity in vitro is consistently ten times higher than that of wild-type. Dark-grown non-dividing cultures of W₃BUL also show a cycloheximide-sensitive light induction of PR enzyme synthesis which, however, is dependent on the continued presence of light. The light induction of PR enzyme synthesis can be regarded as the induction of an enzyme by one of its substrates.     

Wax ester formation catalysed by isoenzymes of lipolytic acyl hydrolase

Wax ester formation by esterification of a long chain fatty acid (palmitic acid) with a long chain fatty alcohol (octadecanol) was enzymically catalysed by acetone dried powder preparations of potato tubers. The enzyme responsible for wax ester formation had multiple isoenzymic forms and was identical with lipolytic acyl hydrolase, a lipid deacylating enzyme. Tubers from different varietiees of potato (Solanum tuberosum) demonstrated markedly different levels of activity and electrophoretic patterns for both wax ester formation and lipid deacylation.     

Sporulation in Bacillus subtilis 168. Comparison of alkaline phosphatase from sporulating and vegetative cells

1. The purification of the `vegetative' alkaline phosphatase of Bacillus subtilis 168 was simplified by ionic elution of the enzyme from intact cells. 2. The enzyme has a molecular weight of about 70000 and treatment of the enzyme with 10mm-hydrochloric acid or 6.0m-guanidine hydrochloride, β-mercaptoethanol (0.1m) gives rise to enzymically inactive subunits. 3. The amino acid composition of the enzyme was determined. The N-terminal residue determined by the DNS chloride method is glycine. 4. The properties of this enzyme were compared with the `sporulation' alkaline phosphatase of the same strain. 5. Although the `sporulation' enzyme differs from the `vegetative' enzyme in its physiology of appearance and apparent mRNA stability, an examination of properties of the enzymes revealed no differences. 6. The enzyme from both cell forms is bound to the particulate fraction of cell extracts, but can be solubilized by high concentrations of magnesium chloride; removal of the magnesium chloride, by dialysis, results in precipitation of both enzymes. Both enzymes can be removed from intact cells by ionic elution. 7. The `vegetative' and `sporulation' enzymes have identical pH optima, K_m and K_i values and electrophoretic mobilities in cellulose acetate. 8. Their half-life is 28min at 65°C and their Q₁₀ is 1.25. 9. The molecular size determined by gel filtration on Sephadex G-100 is about 69000. 10. `Vegetative' and `sporulation' forms gave precipitin lines that were continuous and non-spurred when tested against antiserum prepared against the `vegetative' enzyme. 11. The `sporulation' alkaline phosphatase appears to be associated with stage II of sporulation and appears to be induced by something specifically concerned in sporulation and not by phosphate starvation.     

Increase in cell-surface N-acetylglucosaminide β(1→4)galactosyltransferase activity with retinoic acid-induced differentiation of F9 embryonal carcinoma cells

Exposure of F₉ cells to all-trans-retinoic acid over a period of 6 days resulted in 4-fold induction of cell surface N-acetylglucosaminide β(1→4)galactosyltransferase (GT) activity. The retinoic acid-induced GT activity was further enhanced by treatment of the cells with 8-bromo cyclic AMP. The ability of retinoic acid alone, or retinoic acid in combination with 8-bromo cyclic AMP, to induce GT activity was inhibited by both actinomycin D and cycloheximide. These findings indicate that the induction of galactosyltransferase activity noted with differentiation of F₉ cells involves de novo synthesis of new enzyme protein.     

Induction of hepatic heme oxygenase activity by bromobenzene

Hepatic heme oxygenase, an enzyme which converts heme to carbon monoxide and bile pigment in vitro, is inducible by heme but also by large “toxic” doses of such nonheme substances as hormones, endotoxin, and heavy metal ions. When we gave rats a single hepatotoxic dose of allyl alcohol, ethionine, acetaminophen, furosemide, or endotoxin, hepatic heme oxygenase activity rose modestly (two- to fivefold) after 20 h. In contrast, administration of bromobenzene (5 mmol/kg) induced heme oxygenase in the liver an average of 15-fold after 20 h but was without effect on the enzyme in the kidney or spleen. The change in heme oxygenase was accompanied by a loss in cytochrome P-450 concentration and, in rats labeled with 5-δ-amino[¹⁴C]levulinic acid, an increased rate of degradation of hepatic [¹⁴C]heme to ¹⁴CO. Induction of heme oxygenase by bromobenzene was blocked by cycloheximide, an inhibitor of protein synthesis, but not by actinomycin D, an inhibitor of RNA synthesis. This suggests that bromobenzene stimulates de novo enzyme synthesis at the step of translation. Subtoxic doses of bromobenzene (less than 1 mmol/kg) gave proportionately greater induction of heme oxygenase. Furthermore, induction of the enzyme remained unaffected when bromobenzene hepatotoxicity was blocked by pretreatment of rats with SKF-525A, 3-methylcholanthrene, or cysteine (which supplements liver sulfhydryl content), or when hepatotoxicity was enhanced by pretreatment with phenobarbital or with diethylmaleate (which depletes hepatic glutathione). These data suggest that with induction of heme oxygenase by bromobenzene, neither liver cell necrosis nor alteration in hepatic sulfhydryl metabolism is indispensible. The latter characteristic differs from induction of the enzyme by metal ions in which depletion of sulfhydryl-containing constituents has been thought to be essential. We conclude that bromobenzene is a novel inducer of heme oxygenase activity in the liver, differing from other nonheme substances in potency and specificity for the liver, and in utilizing mechanism(s) which require neither production of hepatotoxicity, depletion of hepatic glutathione, nor sensitivity to actinomycin D.