Partial Purification of Digitonin-Solubilized β-Glucan Synthase from Red Beet Root

Eiberger, Laura L.; Wasserman, Bruce P.

doi:10.1104/pp.83.4.982

Cited by 19 publications

(14 citation statements)

References 27 publications

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“…This phenomenon is due to nonspecific precipitation of the enzyme as the combined result of a decrease in detergent levels and an increase in divalent cation concentration. It has already been shown that divalent cations inhibit CS solubilization (8,23) and that the enzyme solubilized with digitonin sediments faster in glycerol gradients containing cations than it does in the presence of chelators (12). Here we show that CS solubilized in CHAPS and enriched by product entrapment is also prone to cation-induced aggregation (Fig.…”

Section: Discussionsupporting

confidence: 62%

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

Harriman²,

Frost³

et al. 1991

Plant Physiol.

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Rapid enrichment of CHAPS-solubilized UDP-glucose:(1,3)-#-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. The procedure known as product entrapment has recently gained widespread application for the rapid and straightforward enrichment of solubilized polysaccharide synthases. Its use has been reported for purification of chitin (13) and cellulose synthase (15), and for partial purification of red beet (11) and mung bean (12) CSs.3 The procedure consists of incubating solubilized enzyme with substrate (UDP-GlcNAc for chitin synthase or UDP-Glc for cellulose and callose synthase) under conditions that allow synthesis of insoluble polymeric product. Enzyme is thought to become trapped within or bound to the resulting meshwork of microfibrils, and is recovered in concentrated form by centrifugation. The polysaccharide synthase can then be released and the procedure repeated.In the course of our work on CS (1 1), however, it became clear that sedimentation of activity and concomitant purification need not actually require formation of any glucan product, but could also occur simply from precipitation of the enzyme in the assay mixture (which differs in composition from th...

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Section: Discussionsupporting

confidence: 62%

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

Harriman²,

Frost³

et al. 1991

Plant Physiol.

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“…At 4"C, the microsomal enzyme maintained full activity. Solubilized enzyme stored at -80'C began to show a decline in activity after 8 h and at 4"C after 4 h. Thus, solubilized carrot glucan synthase is considerably less stable than beet (11,12,28).…”

Section: Stability Of the Solubilized Enzymementioning

confidence: 98%

UDP-Glucose: (1,3)-β-Glucan Synthase from Daucus carota L.

Lawson¹,

Mason²,

Sabin³

et al. 1989

Plant Physiol.

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The membrane-bound UDP-glucose-fl-(1, branes, up to 80% of the enzyme was released with 0.7% CHAPS. Solubilized enzyme was stable for at least 9 hours at 40C. 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.3Biosynthesis of plant cell wall polysaccharides is generally believed to be mediated by glycosyl transferases localized at '

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“…It has been shown that glucan synthases are large protein complexes (>450 kD) and that several protein subunits ranging from 18 to 115 kD might be involved in glucan synthesis (Delmer, 1987;Eiberger and Wasserman, 1987; -uv Read and Delmer, 1987;Bulone et al, 1990;Lin et al, 1990). Efforts have been directed at defining the relationship between the individual components in various synthase preparations and, in particular, at identifying which polypeptides might participate in (1-»3)-and/or (1-»4)-/3-glucan synthesis.…”

Section: Discussionmentioning

confidence: 99%

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

1997

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(1 +3)-and (1 +4)-P-glucan synthase activities from higher plants have been physically separated by gel electrophoresis in nondenaturing conditions. The two glucan synthases show different mobilities i n native polyacrylamide gels. Further separation by sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed a different polypeptide composition i n 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 (1 70, 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 ++p-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 i n the running gel, where only callose was synthesized. These findings suggest that a higher leve1 of subunit organization is required for i n vitro cellulose synthesis in comparison with callose assembly.

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Partial Purification of Digitonin-Solubilized β-Glucan Synthase from Red Beet Root

Cited by 19 publications

References 27 publications

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

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

UDP-Glucose: (1,3)-β-Glucan Synthase from Daucus carota L.

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

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Partial Purification of Digitonin-Solubilized β-Glucan Synthase from Red Beet Root

Cited by 19 publications

References 27 publications

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

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

UDP-Glucose: (1,3)-β-Glucan Synthase from Daucus carota L.

Cellulose and Callose Biosynthesis in Higher Plants (I. Solubilization and Separation of (1-&gt;3)- and (1-&gt;4)-β-Glucan Synthase Activities from Mung Bean)

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