Identification of the UDP-glucose-binding polypeptide of callose synthase from Beta vulgaris L. by photoaffinity labeling with 5-azido-UDP-glucose

The photoaffinity probe 5-azidouridine 5'-[beta-32P]diphosphate glucose (5N3[32P]UDP-Glc) was used to identify a 57-kDa polypeptide as a strong candidate for the UDP-Glc-binding polypeptide of UDP-glucose: (1,3)-beta-glucan (callose) synthase from red beet (Beta vulgaris L.) storage tissue. Unlabeled 5N3UDP-Glc was a competitive inhibitor of callose synthase with a Ki of 310 microM. Callose synthase was purified from plasma membranes by a two-step solubilization with 3-[(3-cholamidopropyl)dimethylammonio]-1-propane-sulfonate, followed by product entrapment, and photoincorporation of radioactivity from 5N3[32P]UDP-Glc was used to identify UDP-Glc-binding polypeptides that copurified with callose synthase activity. Photoinsertion into the 57-kDa band was closely correlated with all catalytic properties examined. Photolabeling of the 57-kDa polypeptide was enriched upon purification of callose synthase by product entrapment, was abolished with increasing levels of unlabeled UDP-Glc, was dependent upon the presence of divalent cations, and the pH dependence of photolabeling correlated with the pH activity profile of callose synthase. In addition, photolabeling of the 57-kDa band did not occur after phospholipase treatment, which destroys enzyme activity. The extent of labeling of this polypeptide thus correlates closely with the activity of callose synthase under a wide variety of conditions. These results imply that the polypeptide at 57 kDa represents the substrate-binding and cation-regulated component of the callose synthase complex of higher plants.     

The beta-glucan synthase from Lolium multiflorum. Detergent solubilization, purification using monoclonal antibodies, and photoaffinity labeling with a novel photoreactive pyrimidine analogue of uridine 5'-diphosphoglucose.

The membrane-bound beta-glucan synthase from Italian ryegrass (Lolium multiflorum L.) endosperm cells has been solubilized by both non-ionic and zwitterionic detergents. A complex relationship exists between the ratio of (1----3)-, (1----4)-, and (1----3, 1----4)-beta-glucan products of the solubilized enzyme, the cations present, and the concentration of the uridine 5'-diphosphoglucose substrate. Monoclonal antibodies directed against the beta-glucan synthase complex were generated by immunization of mice with an unfractionated microsomal reparation. Hybridoma cell lines were screened using a combination of indirect enzyme-linked immunosorbent assay followed by an enzyme-capture assay. The purified monoclonal antibodies were used with Pan-sorbin (stablized protein A-bearing staphylococcal cells) to immunoprecipitate an active beta-glucan synthase complex which had been solubilized from a microsomal preparation with 0.6% CHAPS. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the immunoprecipitated synthase complex revealed four major polypeptides of apparent molecular mass 30, 31, 54, and 58 kDa together with several minor components. The immunoprecipitated beta-glucan synthase complex was capable of synthesizing both (1----3)- and (1----4)-beta-glucans. A new photoreactive pyrimidine analogue of uridine 5'-diphosphoglucose, 5-[3-(p-azidosalicylamide]allyl-uridine 5'-diphosphoglucose was synthesized in a three-step reaction sequence involving mercuration of UDP-Glc, alkylation of 5-Hg-UDP-Glc, and acylation of 5-(3-amino)allyl-UDP-Glc and characterized by chemical and spectroscopic analysis. The analogue inhibits (Kiapp 16 microM) and, upon UV irradiation, irreversibly inactivates the beta-glucan synthase. The analogue was iodinated with Na125I to give a radiolabeled, photoreactive compound, and was used in photoaffinity labeling of UDP-Glc pyrophosphorylase, UDP-Glc dehydrogenase, and several putative UDP-Glc-binding proteins from L. multiforum. The radiolabeled analogue specifically labeled the 31-kDa polypeptide in the immunoprecipitated synthase complex. The photolabeling of this polypeptide is strictly dependent on UV irradiation, is blocked by uridine 5'-diphosphoglucose and uridine 5'-diphosphate, and reaches saturation at analogue concentrations above 300 microM. These results indicate that the 31-kDa polypeptide in the beta-glucan synthase complex bears a uridine 5'-diphosphoglucose-binding site and is involved in the catalysis of beta-glucan synthesis.     

Rapid Enrichment of CHAPS-Solubilized UDP-Glucose: (1,3)-beta-Glucan (Callose) Synthase from Beta vulgaris L. by Product Entrapment : Entrapment Mechanisms and Polypeptide Characterization

Rapid enrichment of CHAPS-solubilized UDP-glucose:(1,3)-β-glucan (callose) synthase from storage tissue of red beet (Beta vulgaris L.) is obtained when the preparation is incubated with an enzyme assay mixture, then centrifuged and the enzyme released from the callose pellet with a buffer containing EDTA and CHAPS (20-fold purification relative to microsomes). When centrifuged at high speed (80,000g), the enzyme can also be pelleted in the absence of substrate (UDP-Glc) or synthesis of callose, due to nonspecific aggregation of proteins caused by excess cations and insufficient detergent in the assay buffer. True time-dependent and substrate-dependent product-entrapment of callose synthase is obtained by low-speed centrifugation (7,000-11,000g) of enzyme incubated in reaction mixtures containing low levels of cations (0.5 millimolar Mg²⁺, 1 millimolar Ca²⁺) and sufficient detergent (0.02% digitonin, 0.12% CHAPS), together with cellobiose, buffer, and UDP-Glc. Entrapment conditions, therefore, are a compromise between preventing nonspecific precipitation of proteins and permitting sufficient enzyme activity for callose synthesis. Further enrichment of the enzyme released from the callose pellet was not obtained by rate-zonal glycerol gradient centrifugation, although its sedimentation rate was greatly enhanced by inclusion of divalent cations in the gradient. Preparations were markedly cleaner when product-entrapment was conducted on enzyme solubilized from plasma membranes isolated by aqueous two-phase partitioning rather than by gradient centrifugation. Product-entrapped preparations consistently contained polypeptides or groups of closely-migrating polypeptides at molecular masses of 92, 83, 70, 57, 43, 35, 31/29, and 27 kilodaltons. This polypeptide profile is in accordance with the findings of other callose synthase enrichment studies using a variety of tissue sources, and is consistent with the existence of a multi-subunit enzyme complex.     

Inhibition of Mung Bean UDP-Glucose: (1-->3)-beta-Glucan Synthase by UDP-Pyridoxal: Evidence for an Active-Site Amino Group

UDP-pyridoxal competitively inhibits the Ca²⁺-, cellobiose-activated (1→3)-β-glucan synthase activity of unfractionated mung bean (Vigna radiata) membranes, with a K_i of 3.8 ± 0.7 micromolar, when added simultaneously with the substrate UDP-glucose in brief (3 minute) assays. Preincubation of membranes with UDP-pyridoxal and no UDP-glucose, however, causes progressive reduction of the V_max of subsequently assayed enzyme and, after equilibrium is reached, 50% inhibition occurs with 0.84 ± 0.05 micromolar UDP-pyridoxal. This progressive inhibition is reversible provided that the UDP-pyridoxylated membranes are not treated with borohydride, indicating formation of a Schiff's base between the inhibitor and an enzyme amino group. Consistent with this, UDP-pyridoxine is not an inhibitor. The reaction of (1→3)-β-glucan synthase with UDP-pyridoxal is stimulated strongly by Ca²⁺ and, less effectively, by cellobiose or sucrose, and the enzyme is protected against UDP-pyridoxal by UDP-glucose or by other competitive inhibitors, implying that modification is occurring at the active site. Pyridoxal phosphate is a less potent and less specific inhibitor. Latent (1→3)-β-glucan synthase activity inside membrane vesicles can be unmasked and rendered sensitive to UDP-pyridoxal by the addition of digitonin. Treatment of membrane proteins with UDP-[³H]pyridoxal and borohydride labels a number of polypeptides but labeling of none of these specifically requires Ca²⁺ and sucrose; however, a polypeptide of molecular weight 42,000 is labeled by UDP-[³H]pyridoxal in the presence of Mg²⁺ and copurifies with (1→3)-β-glucan synthase activity.     

Identification of the uridine 5'-diphosphoglucose (UDP-Glc) binding subunit of cellulose synthase in Acetobacter xylinum using the photoaffinity probe 5-azido-UDP-Glc

Photoaffinity labeling of purified cellulose synthase with [beta-32P]5-azidouridine 5'-diphosphoglucose (UDP-Glc) has been used to identify the UDP-Glc binding subunit of the cellulose synthase from Acetobacter xylinum strain ATCC 53582. The results showed exclusive labeling of an 83-kDa polypeptide. Photoinsertion of [beta-32P]5-azido-UDP-Glc is stimulated by the cellulose synthase activator, bis-(3'----5') cyclic diguanylic acid. Addition of increasing amounts of UDP-Glc prevents photolabeling of the 83-kDa polypeptide. The reversible and photocatalyzed binding of this photoprobe also showed saturation kinetics. These studies demonstrate that the 83-kDa polypeptide is the catalytic subunit of the cellulose synthase in A. xylinum strain ATCC 53582.     

UDP-Glucose: (1,3)-beta-Glucan Synthase from Daucus carota L. : Characterization, Photoaffinity Labeling, and Solubilization

The membrane-bound UDP-glucose-β-(1,3)-glucan synthase from Daucus carota L. was characterized and a solubilization procedure was developed. The enzyme exhibited maximal activity in the presence of 0.75 millimolar Ca²⁺, 0.5 millimolar EGTA, and 5 millimolar cellobiose at pH 7.5 and 30°C at 1 millimolar UDPG. Reaction products were confirmed to be (1,3)-linked glucan. Polypeptides of 150, 57, and 43 kilodaltons were labeled with the photoactivatible affinity label 5-azido-uridine 5′-β-[³²P] diphosphateglucose. Labeling of the 150 and 57 kilodalton polypeptides was completely protected against by 1 millimolar non-radioactive UDPG suggesting that one or both of these polypeptides may represent the UDPG binding subunit of glucan synthase. Carrot glucan synthase was solubilized with the detergent 3-[(3-cholamidopropyl)dimethylammonio]-1-propane sulfonate (CHAPS) in the absence of divalent cations and chelators; however, the percentage of enzyme which could be solubilized showed variability with membrane source. With microsomal membranes, up to 80% of the enzyme was released with 0.7% CHAPS. Solubilized enzyme was stable for at least 9 hours at 4°C. When more highly purified membrane fractions were isolated from sucrose step gradients a slightly different picture emerged. Activity from the 20/30% interface (Golgi and tonoplast enriched) was readily solubilized and expressed. Activity from the 30/40% interface (plasma membrane enriched) was also solubilized; however, it was necessary to add heat inactivated microsomes to assay mixtures for full activity to be expressed. A requirement for endogenous activators is suggested.     

Identification of lysyl residues located at the substrate-binding site in UDP-glucose pyrophosphorylase from potato tuber: affinity labeling with uridine di- and triphosphopyridoxals

Uridine di- and triphosphopyridoxals were used to probe the substrate-binding site in potato tuber UDP-glucose pyrophosphorylase (EC 2.7.7.9). The enzyme was rapidly inactivated in time- and dose-dependent manners when incubated with either reagent followed by reduction with sodium borohydride. The inactivations were almost completely retarded by UDP-Glc and UTP but only slightly by alpha-D-glucose 1-phosphate. The complete inactivation corresponded to the incorporation of about 0.9-1.0 mol of either reagent per mole of enzyme monomer. Both reagents appear to bind specifically to the UDP-Glc-(UTP)-binding site. Structural studies of the labeled enzymes revealed that the two reagents modified the identical set of five lysyl residues (Lys-263, Lys-329, Lys-367, Lys-409, and Lys-410), in which Lys-367 was most prominently modified. The ratios of the amounts of labels incorporated into these residues were similar for the two reagents. Furthermore, linear relationships were observed between the residual activities and the amounts of incorporation into each lysyl residue. We conclude that the five lysyl residues are located at or near the UDP-Glc(UTP)-binding site of potato tuber UDP-Glc pyrophosphorylase and that the modification of these residues occurs in a mutually exclusive manner, leading to the inactivation of the enzyme.     

Identification of the uridine-binding domain of sucrose-phosphate synthase. Expression of a region of the protein that photoaffinity labels with 5-azidouridine diphosphate-glucose.

The uridine diphosphate-glucose (UDP-Glc) binding domain of sucrose-phosphate synthase (SPS) was identified by overexpressing part of the gene from spinach (Spinacia oleracea). Degenerate oligonucleotide primers corresponding to two tryptic peptides common to both the full-length 120-kD SPS subunit and an 82-kD form that photoaffinity labeled with 5-azidouridine diphosphate-glucose (5-N3UDP-Glc) were used in a polymerase chain reaction to isolate a partial cDNA clone. Comparison of the deduced amino acid sequence of spinach SPS with the sequences of potato sucrose synthase showed that the partial cDNA included one region that was highly conserved between the proteins. Expression of the partial cDNA clone of SPS in Escherichia coli produced a 26-kD fusion protein that photoaffinity labeled with 5-N3UDP-Glc. Photoaffinity labeling of the 26-kD fusion protein was specific, indicating that this portion of the SPS protein harbors the UDP-Glc-binding domain. Isolation of a modified peptide from the photolabeled protein provided tentative identification of amino acid residues that make up the uridine-binding domain of SPS.     

Isolation and polypeptide composition of l,3-ß-glucan synthase from plasma membranes of Brassica oleracea

The l,3-ß-glucan synthase (callose synthase, EC 2.4.1.34) was solubilized from cauliflower ( Brassica oleracea L.) plasma membranes with digitonin, and partially purified by ion exchange chromatography and gel filtration [fast protein liquid chromatography (FPLC)] using 3-[(cholamidopropyl)dimethylammonio]-1-propane-sulfonate (CHAPS) in the elution buffers. These initial steps were necessary to obtain specific precipitation of the enzyme during product entrapment, the final purification step. Five polypeptides of 32, 35, 57, 65 and 66 kDa were highly enriched in the final preparation and are thus likely components of the callose synthase complex. The purified enzyme was activated by Ca²⁺, spermine and cellobiose in the same way as the enzyme in situ, indicating that no essential subunits were missing. The polyglucan produced by the purified enzyme contained mainly 1,3-linked glucose.     

The UDP-Glc:glycoprotein glucosyltransferase is a soluble protein of the endoplasmic reticulum.

N-linked oligosaccharides devoid of glucose residues are transiently glucosylated directly from UDP-Glc in the endoplasmic reticulum. The reaction products have been identified, depending on the organisms, as protein-linked Glc1Man5-9GlcNAc2. Incubation of right side-sealed vesicles from rat liver with UDP-[14C]Glc, Ca2+ ions and denatured thyroglobulin led to the glucosylation of the macromolecule only when the vesicles had been disrupted previously by sonication or by the addition of detergents to the glucosylation mixture. Similarly, maximal glucosylation of denatured thyroglobulin required disruption of microsomal vesicles isolated from the protozoan Crithidia fasciculata. Treatment of the rat liver vesicles with trypsin led to the inactivation of the UDP-Glc:glycoprotein glucosyltransferase only when proteolysis was performed in the presence of detergents. The glycoprotein glucosylating activity could be solubilized upon sonication of right side-sealed vesicles in an isotonic medium, upon passage of them through a French press or by suspending the vesicles in an hypotonic medium. Moreover, the enzyme appeared in the aqueous phase when the vesicles were submitted to a Triton X-114/water partition. Solubilization was not due to proteolysis of a membrane-bound enzyme. The enzyme could also be solubilized from C. fasciculata microsomal vesicles by procedures not involving membrane disassembly. About 30% of endogenous glycoproteins glucosylated upon incubation of intact rat liver microsomal vesicles with UDP-[14C]GLc could be solubilized by sonication or by suspending the vesicles in 0.1 M Na2CO3. These and previous results show that the UDP-Glc:glycoprotein glucosyltransferase is a soluble protein present in the lumen of the endoplasmic reticulum. In addition, both soluble and membrane-bound glycoproteins may be glucosylated by the glycoprotein glucosylating activity.     

Biosynthesis of glycoproteins in Candida albicans: activity of mannosyl and glucosyl transferases

The enzymes dolichol phosphate glucose synthase and dolichol phosphate mannose synthase (DPMS), which catalyze essential steps in glycoprotein biosynthesis, were solubilized and partially characterized in Candida albicans. Sequential incubation of a mixed membrane fraction with increasing concentrations of Nonidet P-40 released a soluble fraction that transferred glucose from UDP-Glc to dolichol phosphate glucose and minor amounts of glucoproteins in the absence of exogenous dolichol phosphate. Studies with the soluble fraction revealed that some properties were different from those previously determined for the membrane-bound enzyme. Accordingly, the soluble enzyme exhibited a twofold higher affinity for UDP-Glc and a sixfold higher affinity over the competitive inhibitor UMP, and the transfer reaction was fourfold more sensitive to inhibition by amphomycin. On the other hand, a previously described protocol for the solubilization of mannosyl transferases that rendered a fraction exhibiting both DPMS and protein mannosyl transferase (PMT) activities operating in a functionally coupled reaction was modified by increasing the concentration of Nonidet P-40. This resulted in a solubilized preparation enriched with DPMS and nearly free of PMT activity which remained membrane bound. DPMS solubilized in this manner exhibited an absolute dependence on exogenous Dol-P. Uncoupling of these enzyme activities was a fundamental prerequisite for future individual analysis of these transferases.     

Affinity labeling of the essential lysyl residue at the active site of enzymes by using nucleotide polyphosphate pyridoxal

We have discovered a new type of affinity labeling reagents for the nucleotide-binding site of protein by introducing an active site-directing moiety to pyridoxal 5-phosphate. Uridine diphosphopyridoxal almost completely inactivated glycogen synthase in a time-dependent manner (K _inact =25 µM;k ₀=0.22 min^–1). The inactivation was pronouncedly protected by UDP-Glc and UDP, but not by the allosteric activator Glc-6-P. The addition of cysteamine to the inactivated enzyme restored the original activity, whereas the treatment of the inactivated enzyme with NaBH₄ resulted in the fixation of the label to the enzyme protein. A peptide containing the label was isolated after proteolysis, and sequenced as E-V-A-K*-V-G-G-I-(Y). Adenosine polyphosphopyridoxal considerably inactivated lactate dehydrogenase in a time-dependent manner. The degree of inactivation was dependent on the number of phosphate groups; 64% (N=2), 51% (N=3), and 35% (N=4) at a reagent concentration of 1 mM for 30 min. The inactivation was protected by NADH, but not by pyruvate. Although the inactivation was not completed, the reagent was stoichiometrically incorporated into enzyme protein concomitantly with the inactivation. Affinity chromatographic analysis of the inactivated enzyme of Blue-Toyopearl revealed the presence of several protein species. The ratio of those species changed according to the stage of inactivation.     

Activation of pollen tube callose synthase by detergents. Evidence for different mechanisms of action.

In pollen tubes of Nicotiana alata, a membrane-bound, Ca(2+)-independent callose synthase (CalS) is responsible for the biosynthesis of the (1,3)-beta-glucan backbone of callose, the main cell wall component. Digitonin increases CalS activity 3- to 4-fold over a wide range of concentrations, increasing the maximum initial velocity without altering the Michaelis constant for UDP-glucose. The CalS activity that requires digitonin for assay (the latent CalS activity) is not inhibited by the membrane-impermeant, active site-directed reagent UDP-pyridoxal when the reaction is conducted in the absence of digitonin. This is consistent with digitonin increasing CalS activity by the permeabilization of membrane vesicles. A second group of detergents, including 3-[(3-cholamidopropyl)dimethylammonio]-1-propane-sulfonate (CHAPS), Zwittergent 3-16, and 1-alpha-lysolecithin, activate pollen tube CalS 10- to 15-fold, but only over a narrow range of concentrations just below their respective critical micellar concentrations. This activation could not be attributed to any particular chemical feature of these detergents. CHAPS increases maximum initial velocity and decreases the Michaelis constant for UDP-glucose and activates CalS even in the presence of permeabilizing concentrations of digitonin. Inhibition studies with UDP-pyridoxal indicate that activation by CHAPS occurs by recruitment of previously inactive CalS molecules to the pool of active enzyme. The activation of pollen tube CalS by these detergents therefore resembles activation of the enzyme by trypsin.     

Inhibition of glycosyltransferases by bis-(p-nitrophenyl)phosphate: general effect and relation to their membrane integration

The effect of bis-(p-nitrophenyl)phosphate on various glycosyltransferases involved in protein glycosylation (sialyl-, fucosyl-, galactosyl-, mannosyl- and glucosyltransferases) have been studied using crude enzyme preparations solubilized from rat spleen lymphocytes. Bis-(p-nitrophenyl)phosphate appears as a common inhibitor for every glycosyltransferase reaction utilizing sugar nucleotides as direct donors. In most cases 10 mM inhibitor is sufficient to obtain a 90 per cent inhibition. Kinetic studies achieved with a purified galactosyltransferase preparation reveal that bis-(p-nitrophenyl)phosphate exerts a competitive inhibition towards UDP-galactose binding. Concerning membrane-bound enzymes, the interaction of bis-(p-nitrophenyl)phosphate depends on its accessibility to the enzyme active site. This is shown by the different effect obtained with two UDP-Glc utilizing membrane-bound enzymes : UDP-Glc : phospho-dolichyl glucosyltransferase and UDP-Glc : ceramide glucosyltransferase : the first one not being affected but the second one being markedly inhibited under the same condition, although both are inhibited when the membrane environment is disturbed by detergent. Bis-(p-nitrophenyl)phosphate appears to be a tool to study membrane topology of glycosyltransferases.     

Comparative effects of sulfhydryl reagents on membrane-bound and solubilized UDP-glucose:ceramide glucosyltransferase from Golgi membranes. Evidence for partial involvement of a thiol group in the nucleotide sugar binding site of the solubilized enzyme

We have studied the inactivation of membrane-bound and solubilized UDP-glucose:ceramide glucosyltransferase from Golgi membranes by various types of sulfhydryl reagents. The strong inhibition of the membrane-bound form by the non-penetrant mercurial-type reagents clearly corroborated the fact that in sealed and right-side-out Golgi vesicles the ceramide glucosyltransferase is located on the cytoplasmic face. No significant differences in the susceptibility to the various sulfhydryl reagents were noted when solubilized enzyme was assayed, showing that solubilization does not reveal other critical SH groups. The different results obtained must be interpreted with regard to several thiol groups, essential for enzyme activity. No protection by the substrate UDP-glucose against mercurial-type reagents was obtained indicating that these thiol groups were not located in the nucleotide sugar binding domain. A more thorough investigation of the thiol inactivation mechanism was undertaken with NEM (N-ethylmaleimide), an irreversible reagent. The time dependent inactivation followed first order kinetics and provided evidence for the binding of 1 mol NEM per mol of enzyme. UDP-Glucose protected partially against NEM inactivation, indicating that the thiol groups may be situated in or near the substrate binding domain. Inactivation experiments with disulfide reagents showed that increased hydrophobicity led to more internal essential SH groups which are not obviously protected by the substrate UDP-glucose, thus not implicated in the substrate binding domain, but rather related to conformational changes of the enzyme during the catalytic process.Abbreviations Chaps 3-[(3-cholamidopropyl)dimethylammonio] 1-propanesulfonate - Mops 4-morpholinepropanesulfonic acid - PC phosphatidylcholine - NEM N-ethylmaleimide - CPDS carboxypyridine disulfide (dithio-6,6-dinicotinic acid) - DTNB 5,5-dithiobis-(2-nitrobenzoic acid) - DTP dithiodipyridine - p-HMB para-hydroxymercuribenzoate - DTT dithiothreitol - BAL British anti-Lewisite (dimercaptopropanol) - Zw 3–14 Zwittergent 3–14     

Amino acid residues essential for catalysis by peptidyl dipeptidase-4 from Pseudomonas maltophilia

To assess residues essential for catalysis by prokaryotic peptidyl dipeptidase-4, the enzyme was subjected to chemical modification by a series of reagents. Treatment with either tetranitromethane or N-acetylimidazole abolished catalytic activity. Hydroxylamine reversed inactivation by acetylimidazole only. Thus, an essential tyrosine is indicated. Enzymatic activity also was quenched by either trinitrobenzenesulfonic acid or diethyl pyrocarbonate. Inactivation by these reagents was not reversed by hydroxylamine. These data suggest an essential lysine. The competitive inhibitor Phe-Arg protected partially against inactivation by tetranitromethane, and fully against inactivation by N-acetylimidazole. The substrate Hip-Phe-Arg protected against inactivation by trinitrobenzenesulfonic acid and diethyl pyrocarbonate. Thus, both tyrosine and lysine are located at the catalytic site.     

Cellulose and Callose Biosynthesis in Higher Plants (I. Solubilization and Separation of (1->3)- and (1->4)-[beta]-Glucan Synthase Activities from Mung Bean)

(1->3)- and (1->4)-[beta]-glucan synthase activities from higher plants have been physically separated by gel electrophoresis in nondenaturing conditions. The two glucan synthases show different mobilities in native polyacrylamide gels. Further separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a different polypeptide composition in these synthases. Three polypeptides (64, 54, and 32 kD) seem to be common to both synthase activities, whereas two polypeptides (78 and 38 kD) are associated only with callose synthase activity. Twelve polypeptides (170, 136, 108, 96, 83, 72, 66, 60, 52, 48, 42, and 34 kD) appear to be specifically associated with cellulose synthase activity. The successful separation of (1->3)- and (1->-4)-[beta]-glucan synthase activities was based on the manipulation of digitonin concentrations used in the solubilization of membrane proteins. At low dipitomin concentrations (0.05 and 0.1%), the ratio of the cellulose to callose synthase activity was higher. At higher digitonin (0.5-1%) concentrations, the ratio of the callose to cellulose synthase activity was higher. Rosette-like particles with attached product were observed in samples taken from the top of the stacking gel, where only cellulose was synthesized. Smaller (nonrosette) particles were found in the running gel, where only callose was synthesized. These findings suggest that a higher level of subunit organization is required for in vitro cellulose synthesis in comparison with callose assembly.     

Modification of hydroxymethylbilane synthase (porphobilinogen deaminase) by pyridoxal 5''-phosphate. Demonstration of an essential lysine residue.

When hydroxymethylbilane synthase (porphobilinogen deaminase) from Euglena gracilis is incubated with pyridoxal 5'-phosphate at pH 7.0 and 0 degree C, it rapidly loses part of its activity. The proportion of activity that remains decreases as the concentration of the modifier increases up to approx. 2mM, above which no further significant inactivation occurs. Dialysis of the partly inactivated enzyme restores its activity, whereas reduction with NaBH4 makes the inactivation permanent. The maximum inactivation achievable from one cycle of the treatment with pyridoxal 5'-phosphate, then with borohydride, is 53 +/- 5%; taking this modified enzyme through second and third cycles causes further loss of activity. The enzyme from Rhodopseudomonas spheroides behaves similarly, but there are quantitative differences. Spectroscopic evidence indicates that the inactivation procedure modifies lysine residues, and labelling studies show that epsilon-N-pyridoxyl-L-lysine is a product when permanently inactivated enzyme is completely hydrolysed. Several lysine residues per molecule of the E. gracilis enzyme are modified by the treatment with pyridoxal 5'-phosphate and borohydride, but only one appears to be essential for enzymic activity, since porphobilinogen protects the enzyme against inactivation and then one fewer lysine residue per molecule of enzyme is affected. It is suggested that, during the biosynthesis of hydroxymethylbilane, the first porphobilinogen unit is covalently bound to the enzyme through the epsilon-amino group of the essential lysine.     

Two types of essential carboxyl groups in Rhodospirillum rubrum proton ATPase

Two different types of essential carboxyl groups were detected in the extrinsic component of the proton ATPase of Rhodospirillum rubrum. Chemical modification of R. rubrum chromatophores or its solubilized ATPase by Woodward's reagent K resulted in inactivation of photophosphorylating and ATPase activities. The apparent order of reaction was nearly 1 with respect to reagent concentration and similar K1 were obtained for the soluble and membrane-bound ATPases suggesting that inactivation was associated with modification of one essential carboxyl group located in the soluble component of the proton ATPase. Inactivation was prevented by adenine nucleotides but not by divalent cations. Dicyclohexylcarbodiimide completely inhibited the solubilized ATPase with a K1 of 5.2 mM and a K2 of 0.81 min-1. Mg2+ afforded nearly complete protection with a Kd of 2.8 mM. Two moles of [14C]dicyclohexylcarbodiimide were incorporated per mole of enzyme for complete inactivation but in the presence of 30 mM MgCl2 only one mole was incorporated and there was no inhibition. The labeling was recovered mostly from the beta subunit. The incorporation of the labeled reagent into the ATPase was not prevented by previous modification with Woodward's reagent K. It is concluded that both reagents modified two different essential carboxyl groups in the soluble ATPase from R. rubrum.     

The functional unit of sarcoplasmic reticulum Ca2+-ATPase. Active site titration and fluorescence measurements

The properties of sarcoplasmic reticulum Ca2+-ATPase have been studied after modification of the ATP high affinity binding site with fluorescein isothiocyanate, both in the membranous state and after solubilization with the nonionic detergent, octaethyleneglycol monododecyl ether. Total inactivation of both membrane-bound and solubilized Ca2+-ATPase requires covalent attachment of 1 mol of fluorescein/mol of enzyme (115,000 g of protein) or per binding site for ATP. Sedimentation velocity studies of soluble enzyme showed that both unlabeled and fluorescein-labeled Ca2+-ATPase were present in a predominantly monomeric form. The phosphorylation level of unlabeled Ca2+-ATPase was unchanged by solubilization. Dephosphorylation measurements at 0 degree C indicated that the phosphorylation is an intermediate in the ATPase reaction catalyzed by solubilized Ca2+-ATPase. Fluorescein labeling of half of the Ca2+-ATPase in the membrane did not influence the enzyme kinetics of the remaining unmodified Ca2+-ATPase. Measurements of both fluorescein and tryptophan fluorescence indicated that the soluble monomer of Ca2+-ATPase like the membrane-bound enzyme exists in a Ca2+-dependent equilibrium between two principal conformations (E and E). E (absence of Ca2+) is unstable in the soluble form, but the pCa dependence of the E - E equilibrium is identical with that of the membranous Ca2+-ATPase (pCa0.5 = 6.7 and Hill coefficient 2). These results suggest that the Ca2+-ATPase polypeptides function with a high degree of independence in the membrane.