Specific inhibition of alkane synthesis with accumulation of very long chain compounds by dithioerythritol, dithiothreitol, and mercaptoethanol in Pisum sativum

Sodium [1-¹⁴C]acetate and [1-¹⁴C]stearic acid were readily incorporated into hydrocarbons, secondary alcohols, wax esters, aldehydes, primary alcohols, and fatty acids in young pea leaves (Pisum sativum). Dithioerythritol, dithiothreitol, and mercaptoethanol (but not glutathione and cysteine) severely inhibited the incorporation of labeled acetate into alkanes and secondary alcohols with accumulation of label in wax ester and aldehyde fractions. Detailed radio gas-chromatographic analyses of the fatty acids of both the surface lipid components and internal lipids showed that dithioerythritol and mercaptoethanol specifically inhibited n-hentriacontane (C₃₁) synthesis and caused accumulation of C₃₂ aldehyde, suggesting that the inhibition was at or near the terminal step in alkane biosynthesis, presumably decarboxylation. Trichloroacetate, at a concentration that inhibited C₃₁ alkane synthesis but not the synthesis of alcohols (C₂₆ and C₂₈) specifically inhibited the formation of C₃₂ aldehyde but not that of the C₂₆ or C₂₈ aldehyde. From these results, it is concluded that the C₃₂ aldehyde is derived from the C₃₂ acyl derivative which is the precursor of C₃₁ alkane.     

Fate of naturally occurring epoxy acids: a soluble epoxide hydrase, which catalyzes cis hydration, from Fusarium solani pisi.

A cell-free extract prepared from Fusarium solani pisi grown on cutin, catalyzed the hydration of 18-hydroxy-9,10-epoxyoctadecanoic acid to 9,10,18-trihydroxyoctadecanoic acid while extracts from glucose-grown cells contained <6% of this activity. The product was identified by Chromatographic techniques and by radio gas-liquid chromatography of its periodate oxidation products. This epoxide hydrase activity had a pH optimum at 9.0 and it was located mainly in the 100,000g supernatant fraction. Rate of hydration of the epoxy acid was linear up to 15 min and up to a protein concentration of 30 μg/ml. This fungal epoxide hydrase has a molecular weight of 35,000, as determined by Sephadex G-100 gel filtration. It was partially purified by ammonium sulfate fractionation and gel filtration. The apparent K_m and V of the enzyme was 2 × 10^?4m and 222 nmoles/min/mg, respectively. Parachloromercuribenzoate strongly inhibited the enzyme, while N-ethylmaleimide was a less potent inhibitor. 1,1,1,-Trichloropropylene-2,3-oxide at 10^?3m gave 50% inhibition of the hydration of 18-hydroxy-9,10-epoxyoctadecanoic acid. Kinetic analysis showed that trichloropropylene oxide was a competitive inhibitor. 18-Acetoxy-9,10-epox-yoctadecanoic acid, methyl 18-acetoxy-9,10-epoxyoctadecanoate, 9,10-epoxyoctadecanoic acid, and styrene oxide were not readily hydrated by this fungal epoxide hydrase showing that it has a stringent substrate specificity. Analysis of the enzymatic hydration product on boric acid-impregnated silica gel plates showed that the product obtained from the cis epoxide was exclusively erythro while acid hydrolysis of this epoxide gave rise to the expected threo product. This enzyme is novel in that it catalyzes cis hydration of epoxide while the other epoxide hydrases heretofore isolated catalyzed trans hydration of epoxides.     

Biosynthesis of alkane-2, 3-diols: chemical synthesis of 3-hydroxy-[3-14C]octadecane-2-one and its reduction to [3-14C]octadecane-2, 3-diol in the uropygial glands of ring-necked pheasants (Phasianus colchicus).

Acyloin has been proposed to be an intermediate in the biosynthesis of long chain alkane-2,3-diols. In order to test this possibility, specifically labeled 3-hydroxyoctadecane-2-one (acyloin) was synthesized by coupling 2-methyl-1,3-dithiane with [1-¹⁴C]hexadecanal followed by cleaving of the thioketal. Injection of the synthetic 3-hydroxy [3-¹⁴C]octadecane-2-one into the uropygial gland of the ring-necked pheasant resulted in the formation of labeled octadecane-2,3-diol. Chemical degradation of this diol showed that all of the ¹⁴C was contained in C-3 of the diol showing direct conversion of acyloin to the diol. These observations support the hypothesis that alkane-2,3-diols might be biosynthesized by reduction of the acyloin derived from a condensation between hydroxyethyl thiamine pyrophosphate and fatty aldehyde. Gas-liquid chromatographic analysis of the alkane-2,3-diols, as their isopropylidene derivatives, of the pheasant strongly suggests that they are of the erythro-configuration; however, alkane-2,3-diol enzymatically formed from the racemic acyloin injected into the gland contained 59.5% erythro- and 40.5% threo-diastereoisomers. This distribution was identical to that produced by chemical reduction of the synthetic racemic acyloin. These results clearly show that the reduction step does not show a preference for either of the enantiomers of the acyloin and that the stereospecificity in diol biosynthesis probably resides in the condensation step.     

Fatty acid chain elongation by microsomal enzymes from the bovine meibomian gland

The composition of meibomian gland lipids suggested that fatty acid chain elongation might play a major role in the synthesis of such lipids. A fatty acid synthase preparation from the bovine meibomian gland catalyzed the formation of C16 acid and the enzyme was immunologically quite similar to that in the mammary gland. The microsomal fraction from the gland, on the other hand, catalyzed elongation of endogenous fatty acids in the presence of ATP and Mg2+ and of exogenous C18-CoA using malonyl-CoA and NADPH as the preferred reductant. The elongated products, ranging up to C28 in chain length, were found mainly as CoA esters and products derived from them. With C18-CoA as the exogenous primer, the elongation rate was linear with incubation time up to 20 min but the rate changed in a sigmoidal manner with increasing protein concentration. The elongation rate was maximal at a pH around 7.0. Typical Michaelis-Menten-type substrate saturation patterns were observed with both malonyl-CoA and NADPH. From linear double-reciprocal plots, the Km values for the two substrates were calculated to be 52 and 11 microM, respectively, with a V of about 340 pmol min-1 mg protein-1 with respect to malonyl-CoA. Exogenous CoA esters of C16 to C22 fatty acids were elongated to give products up to C28 without exhibiting any preference for the primer. The present elongation system could account for the formation of most of the very long chains found in meibomian lipids.     

Functional changes in human leukemic cell line HL-60. A model for myeloid differentiation

Polar solvents induce terminal differentiation in the human promyelocytic leukemia cell line HL-60. The present studies describe the functional changes that accompany the morphologic progression from promyelocytes to bands and poly-morphonuclear leukocytes (PMN) over 9 d of culture in 1.3 percent dimethylsulfoxide (DMSO). As the HL-60 cells mature, the rate of O(2-) production increase 18-fold, with a progressive shortening of the lag time required for activation. Hexosemonophosphate shunt activity rises concomitantly. Ingestin of paraffin oil droplets opsonized with complement or Ig increases 10-fold over 9 d in DMSO. Latex ingestion per cell by each morphologic type does not change significantly, but total latex ingestion by groups of cells increases with the rise in the proportion of mature cells with greater ingestion capacities. Degranulation, as measured by release of β-glucuronidase, lysozyme, and peroxidase, reaches maximum after 3-6 d in DMSO, then declines. HL-60 cells contain no detectable lactoferrin, suggesting that their secondary granules are absent or defective. However, they kill staphylococci by day 6 in DMSO. Morphologically immature cells (days 1-3 in DMSO) are capable of O(2-) generation, hexosemonophosphate shunt activity, ingestion, degranulation, and bacterial killing. Maximal performance of each function by cells incubated in DMSO for longer periods of time is 50-100 percent that of normal PMN. DMSO- induced differentiation of HL-60 cells is a promising model for myeloid development.     

Glucuronyl glycine,a novel N-terminus in a glycoprotein

Treatment of cutinase, an extracellular glycoprotein produced by Fusarium solani f. pisi, with NaB³H₄ at pH 7.0 generated labeled enzyme. Acid hydrolysis showed that all of the label was in an acidic carbohydrate which was identified as gulonic acid. The N-terminal amino group of the enzyme is blocked; the precursor of gulonic acid has a free reducing group and it is attached via a linkage resistant to β-elimination. Furthermore, pronase digestion of NaB³H₄-treated cutinase gave rise to a ninhydrin negative compound which contained the bulk of the ³H and this compound was identified as N-gulonyl glycine. These results strongly suggest that the amino group of glycine, the N-terminal amino acid of this enzyme, is in amide linkage with glucuronic acid.     

Production of a Novel Extracellular Cutinase by the Pollen and the Chemical Composition and Ultrastructure of the Stigma Cuticle of Nasturtium (Tropaeolum majus)

Germinating nasturtium pollen (Tropaeolum majus) is shown to excrete an enzyme(s) which hydrolyzes all types of monomers from biosynthetically labeled cutin and p-nitrophenyl esters, which are model substrates for fungal cutinases. The pollen cutinase showed an optimum pH near 6.5 and was inhibited by thiol-directed reagents such as p-hydroxymercuribenzoate and N-ethyl maleimide but not by diisopropyl-fluorophosphate, an “active serine”-directed reagent indicating that the pollen enzyme is an “-SH cutinase” unlike the fungal enzyme which is a serine cutinase. Excretion of the pollen cutinase into the extracellular fluid was complete within 4 to 6 hours at 30 C. Since actinomycin D and cycloheximide showed little effect on the level of cutinase excreted, it appears that cutinase is an enzyme synthesized prior to germination. Release of cutinase into the medium did not require germination. Electron microscopy revealed the presence of a continuous cutin layer on mature stigma with extensive folds, which are proposed to play a role similar to that played by the cellular papillae found in the stigma of other plants. Chemical analysis of stigma cutin by depolymerization and combined gas-liquid chromatography and mass spectrometry showed that this cutin consists of mainly the C₁₆ family of acids. The major (70%) components were dihydroxy C₁₆ acids which consisted of 10,16- (64%), 9,16- (16%), 8,16- (12%), and 7,16- (8%) dihydroxy plamitic acid. Deuterium-labeling studies showed the presence of 16-oxo-9-hydroxy C₁₆ acid and 16-oxo-10-hydroxy C₁₆ acid in this cutin. The biochemical and ultrastructural studies indicate that the pollen tube may gain entry into stigma using cutinase excreted by the pollen.     

Site-directed mutagenesis of CCR2 identified amino acid residues in transmembrane helices 1, 2, and 7 important for MCP-1 binding and biological functions

Monocyte chemotactic protein-1 (MCP-1) binds its G-protein-coupled seven transmembrane (TM) receptor, CCR2B, and causes infiltration of monocytes/macrophages into areas of injury, infection or inflammation. To identify functionally important amino acid residues in CCR2B, we made specific mutations of nine residues selected on the basis of conservation in chemokine receptors and located TM1 (Tyr(49)), TM2 (Leu(95)), TM3 (Thr(117) and Tyr(120)), and TM7 (Ala(286), Thr(290), Glu(291), and His(297)) and in the extracellular loop 3 (Glu(278)). MCP-1 binding was drastically affected only by mutations in TM7. Reversing the charge at Glu(291) (E291K) and at His(297) (H297D) prevented MCP binding although substitution with Ala at either site had little effect, suggesting that Glu(291) and His(297) probably stabilize TM7 by their ionic interaction. E291A elicited normal Ca(2+) influx. H297A, Y49F in TM1 and L95A in TM2 that showed normal MCP-1 binding did not elicit Ca(2+) influx and elicited no adenylate cyclase inhibition at any MCP-1 concentration. MCP-1 treatment of HEK293 cells caused lamellipodia formation only when they expressed CCR2B. The mutants that showed no Ca(2+) influx and adenylate cyclase inhibition by MCP-1 treatment showed lamellipodia formation and chemotaxis. Our results show that induction of lamellipodia formation, but not Ca(2+) influx and adenylate cyclase inhibition, is necessary for chemotaxis.     

Further evidence for an elongation-decarboxylation mechanism in the biosynthesis of paraffins in leaves

In isolated tobacco leaves l-valine-U-¹⁴C gave rise to labeled even-numbered isobranched fatty acids containing 16 to 26 carbon atoms and iso C₂₉, iso C₃₁, and iso C₃₃ paraffins. l-Isoleucine-U-¹⁴C on the other hand produced labeled odd-numbered anteiso C₁₇ to C₂₇ fatty acids and anteiso C₃₀ and C₃₂ paraffins. Trichloroacetic acid inhibited the incorporation of isobutyrate into C₂₀ and higher fatty acids and paraffins without affecting the synthesis of the C₁₆ and C₁₈ fatty acids. Thus the very long branched fatty acids are biosynthetically related to the paraffins. In Senecio odoris leaves acetate-1-¹⁴C was incorporated into the paraffins (mainly n-C₃₁) only in the epidermis although acetate was readily incorporated into fatty acids in the mesophyll tissue. Similarly only the epidermal tissue incorporated acetate into fatty acids longer than C₁₈ suggesting that the epidermis is the site of synthesis of both paraffins and the very long fatty acids. In broccoli leaves n-C₁₂ acid labeled with ¹⁴C in the carboxyl carbon and ³H in the methylene carbons was incorporated into C₂₉ paraffin without the loss of ¹⁴C relative to ³H. Since n-C₁₈ acid is known to be incorporated into the paraffin without loss of carboxyl carbon these results suggest that the condensation of C₁₂ acid with C₁₈ acid is not responsible for n-C₂₉ paraffin synthesis in this tissue. Thus all the experimental evidence thus far obtained strongly suggests that elongation of fatty acids followed by decarboxylation is the most likely pathway for paraffin biosynthesis in leaves.     

Species specificity in the biosynthesis of branched paraffins in leaves

Isobutyrate-1-(14)C and l-isoleucine-U-(14)C fed through the petiole labeled the surface lipids of broccoli leaves, but the incorporation was much less than from straight chain precursors. Not more than one-third of the (14)C incorporated into the surface lipids was found in the C(29) paraffin and derivatives, whereas more than two-thirds of the (14)C from straight chain precursors are usually found in these compounds. The small amount of (14)C incorporated into the paraffin fraction was found in the n-C(29) paraffin rather than branched paraffins showing that the (14)C in the paraffin must have come from degradation products. Radio gas-liquid chromatography of the saturated fatty acids showed that, in addition to the n-C(16) acid which was formed from both branched precursors, isoleucine-U-(14)C gave rise to branched C(15), C(17), and C(19) fatty acids, and isobutyrate-1-(14)C gave rise to branched C(16) and C(18) acids. Thus the reason for the failure of broccoli leaf to incorporate branched precursors into branched paraffins is not the unavailability of branched fatty acids, but the absolute specificity of the system that synthesizes paraffins, probably the elongation-decar-boxylation enzyme complex. Consistent with this view, no labeled branched fatty acids longer than C(19) could be found in the broccoli leaf. The branched fatty acids were also found in the surface lipids indicating that the epidermal layer of cells did have access to branched chains. Thus the paraffin synthesizing enzyme system is specific for straight chains in broccoli, but the fatty acid synthetase is not.