Molecular Cloning and Biochemical Characterization of a Recombinant Sterol 3-O-Glucosyltransferase from <i>Gymnema sylvestre</i> R.Br. Catalyzing Biosynthesis of Steryl Glucosides

Tiwari, Pragya; Sangwan, Rajender Singh; Asha, undefined; Mishra, B. N.; Sabir, Farzana; Sangwan, Neelam S.

doi:https://doi.org/10.1155/2014/934351

BioMed Research International

On this page

Abstract Introduction Materials and Methods Results and Discussion Conclusions Abbreviations Acknowledgments Supplementary Materials References Copyright Related Articles

Research Article | Open Access

Volume 2014 | Article ID 934351 | https://doi.org/10.1155/2014/934351

Molecular Cloning and Biochemical Characterization of a Recombinant Sterol 3-O-Glucosyltransferase from Gymnema sylvestre R.Br. Catalyzing Biosynthesis of Steryl Glucosides

Pragya Tiwari,¹Rajender Singh Sangwan,^1,2 Asha,¹B. N. Mishra,³Farzana Sabir,¹and Neelam S. Sangwan¹

Academic Editor: Dinesh A. Nagegowda

Received26 Feb 2014

Revised09 Jun 2014

Accepted23 Jun 2014

Published27 Aug 2014

Abstract

Gymnema sylvestre R.Br., a pharmacologically important herb vernacularly called Gur-Mar (sugar eliminator), is widely known for its antidiabetic action. This property of the herb has been attributed to the presence of bioactive triterpene glycosides. Although some information regarding pharmacology and phytochemical profiles of the plant are available, no attempts have been made so far to decipher the biosynthetic pathway and key enzymes involved in biosynthesis of steryl glucosides. The present report deals with the identification and catalytic characterization of a glucosyltransferase, catalyzing biosynthesis of steryl glycosides. The full length cDNA (2572 bp) contained an open reading frame of 2106 nucleotides that encoded a 701 amino acid protein, falling into GT-B subfamily of glycosyltransferases. The GsSGT was expressed in Escherichia coli and biochemical characterization of the recombinant enzyme suggested its key role in the biosynthesis of steryl glucosides with catalytic preference for C-3 hydroxyl group of sterols. To our knowledge, this pertains to be the first report on cloning and biochemical characterization of a sterol metabolism gene from G. sylvestre R.Br. catalyzing glucosylation of a variety of sterols of biological origin from diverse organisms such as bacteria, fungi, and plants.

1. Introduction

Sterols play significant role in range of biological processes by serving as defense compounds, cell signalling molecules, component of cell membranes, hormones, and precursors of steroid hormones and saponins [1]. Glycosylation of free sterols into their respective glycosides is catalyzed by nucleotide dependent sterol glycosyltransferases or SGTs that are classified as family 1 of the 94 families of glycosyltransferases described in CAZY (carbohydrate active enzymes) database (http://www.cazy.org/) (Figures 1(a), 1(b), and 1(c)). The SGTs in family 1 possess a distinct signature motif at the C-terminal, the PSPG box which represents the binding site for the nucleotide-diphosphate sugar donors while the N-terminal is highly variable, suggesting that the domain might be involved in interaction with diverse sugar acceptors [2]. Family 1 is comprised of GTs implicated in glycosylation of small molecules in plants and is divided into two subsets. The first subset consisting of GTs with PSPG conserved box involved in binding of nucleotide activated sugar donors, consistently present in mammalian GTs which conjugates dietary flavonoids, drugs, steroids, and bile acids [3]. The second subset includes plant GTs involved in sterols and glycerolipids glycosylation [4]. Furthermore, GTs from microbial sources catalyzing biosynthesis of antibiotics such as vancomycin [5], vicenistatin [6], and urdamycin [7] are also classified under family 1 GTs.

(a)

(b)

(c)

Biosynthesis of sterols in plants occurs mainly in the endoplasmic reticulum and recruits mainly mevalonate pathway of isoprenogenesis while some studies also indicate the significant involvement of DOXP or nonmevalonate pathway in sterols and other analogous secondary metabolites such as withanolides or withasteroids [8, 9]. The variation in percentage of sterols in plant cell membranes regulates the homeostasis and thereby maintains optimum fluidity, hydration, and phase behavior [10]. Additionally, properties such as tolerance to freezing, cold acclimation process [11, 12], and stress signaling cascade [13–16] are conferred by the presence of steryl glycosides in plasma membrane. In plants, brassinosteroids function as growth regulators and in development [17] while sterols in Arabidopsis thaliana regulate development and gene expression [18]. The sterol biosynthetic pathway intermediates serves as precursor of many secondary metabolites such as triterpene saponins, withanolides and withanosides essentially attributing special physiological traits to the plant like regulating the defense mechanisms against pathogens, herbivory, insect deterrence, and stress-effect combating [8, 9, 13].

Although, a strong literature reporting glycosylation of diverse classes of secondary metabolites is available, there are very few studies on glycosyltransferases catalyzing biosynthesis of steryl glycosides. Several studies have reviewed the biological functions of steryl glycosides, namely, catalytic aspects [19], proteomics [20], structural analysis [21], biochemical studies [1], and structural diversity and occurrence [22]. A comprehensive review on sterol glucosyltransferase [23] provides a detailed study on SGTs, their structural features, and functional relevance particularly in the process of stress responses. Studies at the molecular level on the SGT genes involved in glycosylation of plant sterols have been functionally characterized till date from Withania somnifera [24, 25], Avena sativa. L [4], Solanum melongena [26], and Arabidopsis thaliana [27]. Furthermore, three members belonging to the SGT family were identified and their relative expression has been monitored in different organs of W. somnifera as well as analyzed as a response to external stimuli [14]. Three SGTs have been identified and isolated by degenerate primers which initiated PCR followed by RACE (rapid amplification of cDNA ends) approach. Elicitor treatments, namely, methyl jasmonate and salicylic acid have been shown to enhance the expression of SGT genes by up to 10-fold suggesting their possible role in defense mechanisms. Furthermore, the expression of SGTs increased on exposure to cold and heat stress highlighting the modification of sterols in abiotic stress mechanisms [14]. Recently, studies on WsSGTL1 from W. somnifera demonstrated to enhance salt tolerance, heat tolerance, and cold acclimatization when overexpressed in transgenic Arabidopsis plant. The present study highlighted the role of SGTs in plant adaptation to abiotic stress response. Bioinformatics studies further suggested the homology of 3D structure of WsSGTL1 with sterol glycosyltransferase AtSGT of A. thaliana [15]. Additionally, recent report showed that overexpression of WsSGTL1 from W. somnifera into transgenic tobacco confers biotic and salt stress tolerance and modulates antioxidant system and glycosylation profile in the transgenic plant and it highlights the significance of WsSGTL1 in adaptation of the plant to environmental challenges [16].

Steryl glycosides (SGs), the most abundant glycosylated derivatives of sterols, are ubiquitously present in bacteria, fungi, plants and in some species of animals and include glycosylated triterpenoid, steroidal alkaloids, and steroids [22, 28]. SGs are sugar derivatives of membrane associated sterols and are comprised of a sugar moiety attached to the hydroxyl (−OH) group at the C-3 of a sterol molecule which includes a planar sterol backbone formed by four condensed aliphatic rings and a hydrocarbon side chain at C-17 position [14–16, 20, 26–29]. The studies have suggested that steryl glycosides serve as precursors of defense compounds such as saponins, glycoalkaloids, or avenacosides due to the presence of sugar moieties at various hydroxyl groups [30], C-3 OH position being the most preferred one by SGTs for enzymatic catalysis, followed by 27 β-OH position or hydroxyl group present at the side chain of a modified sterol backbone. SGTs have been reported to occur as membrane-associated SGTs [20, 31, 32] by being localized in vacuolar and plasma membranes and as well as cytosolic SGTs. A membrane-bound SGT has been partially purified from S. melongena leaves and characterized with respect to its kinetics and molecular properties [26, 33]. The acceptable substrates for the native enzymes included diverse members of C-3 OH steroids, namely, androstane, pregnane and cholestane derivatives, plant sterols, sapogenins, steroidal alkaloids, and triterpene alcohols. Further, a C-3 OH group specific cytosolic SGT has also been isolated from Panax ginseng [34] and two SGTs specific for C-3 OH and 27 β-OH position have been reported to be purified and biochemically characterized from W. somnifera [24, 25, 35].

G. sylvestre R.Br. (family: Asclepiadaceae), a widely acclaimed medicinal herb, contains characteristic oleanane and dammarene type triterpene saponins known as gymnemic acids I-XVIII, gymnemasins A-D and gymnemasaponins I-V. The plant parts particularly the leaf tissue and stem are excellent sources of gymnemic acids and the plant extract is used as herbal formulation in regulation of blood sugar levels and hypercholesterolemia. A comprehensive account of the phytochemical and pharmacological properties of G. sylvestre R.Br. and its phytoconstituents has been discussed in detail in a recent review [36]. Furthermore, there are several reports on isolation of pure gymnemic acid and analogues and metabolic profiling of the phytomolecules; however literature is void with respect to investigations pertaining to identification, cloning, and catalytic characterization of a gene/enzyme from the plant involved in metabolism including biosynthesis of triterpene glycosides.

Considering the ongoing research on sterol glucosyltransferase and the pharmacological importance of steryl glycosides, the present investigation describes the isolation, heterologous expression in E. coli and functional validation of a novel SGT gene (GsSGT) from G. sylvestre R.Br., wherein the recombinant enzyme has been shown to be capable of catalyzing glucosylationof diverse sterols from bacteria, fungi, and plants. The cloning and characterization of this sterol GT opens up the possibility of glycosylation of important phytosteroid of diverse structural types for their potentially enhanced therapeutic action and improved pharmacokinetics.

2. Materials and Methods

2.1. Plant Material and Chemicals

G. sylvestre R.Br. (gurmar) leaves were collected at different developmental stages from the plants grown in experimental field at CSIR-CIMAP, Lucknow, India. General chemicals and reagents were purchased from Sigma-Aldrich. Reagents and kits of molecular biology were obtained from Invitrogen, Qiagen, Clonetech, Fermentas and Sigma-Aldrich (USA). SYBR green mix was obtained from Applied Biosystems, USA.

2.2. RNA Isolation and cDNA Synthesis

Total RNA was isolated from the leaf tissues of the plant by Trizol miniprep method according to manufacturer’s protocol. The qualitative and quantitative estimation of the isolated RNA was determined by agarose gel (1.2%) electrophoresis as well as by relative absorbance values at 260 and 280 nm (A₂₆₀/A₂₈₀) in a Nanodrop spectrophotometer. The first strand cDNA was synthesized using Revertaid First strand cDNA synthesis kit (Fermentas) following the manufacturer’s guidelines.

2.3. Molecular Cloning of GsSGT

Multiple sets of degenerate primers were designed from the conserved domains identified in SGT’s through multiple sequence alignment of SGT protein sequences retrieved from NCBI and used for isolation of partial GsSGT amplicon. The primer combinations used in the study are provided in Table 1. The PCR conditions were as follows: initial denaturation at 94°C for 3 min, followed by 35 cycles at 94°C (1 min), annealing at 55°C (2 min), extension at 72°C (2 min), and final extension at 72°C for 7 min. The RT-PCR products were electrophoresed on 1.2% agarose gel. The resolved fragments were purified through Qiagen columns and cloned in pGEMT vector (Promega) following standard protocols. The putative clones containing amplified fragment were confirmed through sequencing of the plasmid DNA.

2.4. Rapid Amplification of cDNA Ends (RACE)

The full length cDNA was obtained by performing 5′ and 3′ RACE-PCR and assembling the respective RACE fragments (Table 1) employing high fidelity Taq polymerase, Fermentas. The PCR program included an initial denaturation of 94°C for 3 min, followed by 35 cycles at 94°C (30 sec), annealing at 55°C (30 sec), extension at 72°C (3 min), and final extension at 72°C for 7 min. The resolved PCR fragment was visualized under ultraviolet light and gel electrophoresed on 1.2% agarose. The PCR amplicon corresponding to putative full length gene was gel purified by Qiagen gel purification kit according to manufacturer’s instruction and cloned in pJET vector, Fermentas. The full length clone was confirmed through sequencing of the plasmid DNA.

2.5. Bioinformatics Analysis

The evolutionary relationship between GsSGT and reported SGTs was deciphered through BLAST P tool at NCBI database (http://www.ncbi.nlm.nih.gov/). Protein sequence of GsSGT and reported microbial and plant SGTs were subjected to multiple sequence alignment. Various physiochemical properties and protein characteristics were predicted and analyzed (http://www.expasy.org/). A rooted neighbor-joining tree was constructed to determine the phylogenetic relationship using MEGA 5.5 software with 100 bootstrap replicates to establish the confidence level of each node. Conserved domains in the protein were identified by conserved domain database search and Interproscan. Disorderliness of amino acid in protein and the presence of transmembrane segments and secondary structures in the protein were analyzed [37].

2.6. Heterologous Expression of the Gene in E. coli

The full length cDNA was cloned and expressed in E. coli protein expression system, namely, pET-28a as N-terminal fusion protein with a His6 tag to facilitate its purification (Novagen). The complete open reading frame (ORF) was PCR amplified with full length primers (Table 1). The 2.1 kb amplified ORF was cloned at Nde I and Bam H1 restriction sites in pET-28a expression vector and the resulting construct was used to transform E. coli BL21 (DE3) strain (Novagen). Transformants were grown at 37°C in LB liquid medium containing 50 mg/mL⁻¹ chloramphenicol and 50 mg/mL⁻¹ kanamycin as selection antibiotics. The IPTG induced bacterial cells were further grown at 18°C for 12–16 hours (overnight). The induced bacterial culture was centrifuged and the supernatant was discarded. The bacterial pellet was dissolved in protein lysis buffer (containing 1 M potassium phosphate buffer, 10% glycerol, 0.5% Triton X-100, and 10 mM imidazole), vortexed, sonicated and centrifuged at 12,000 rpm for 30 minutes. The his-tagged enzyme in the supernatant was purified by chromatography through a metal-affinity (nickel/NTA) column and the active protein fractions were pooled and analyzed for enzymatic assays.

2.7. Sterol Glucosyltransferase Assay

Biochemical characterization of partially purified GsSGT protein was performed through enzymatic assays by glucosylation of sterols into their respective steryl glucosides employing unlabelled uridine diphospho glucose as nucleotide sugar donor. The standard reaction mixture containing 20 mM Tris, pH, 6.5, 10 μM UDP-glucose, 8.5 μM sterol, and 0.7 μg of protein was taken for the GsSGT enzymatic assay. The reaction was initiated by addition of the enzyme and the reaction mixture was incubated at 37°C for 1 hour. At the end of the reaction, the reaction contents were extracted with 2 mL of ethyl acetate and evaporated to dryness at room temperature. The samples were redissolved in methanol, spotted on a TLC plate, and run using chloroform: methanol (85 : 15 mL) as the mobile phase. The plates were developed with anisaldehyde spray reagent and chromogenically visualized after heating at 110° with the respective sterol and glucoside standards cochromatographed on the same TLC. Control reactions (heat inactivated enzyme and substrate control) were set up in a similar manner to identify and ascertain the product formation to be through the enzymatic reaction catalyzed by the SGT (GsSGT). The catalytic parameters for GsSGT protein were optimized for temperature, pH, linearity with time, protein concentration, substrate saturation, and enzyme’s thermostability. For quantitative estimations of catalytic activities the HPLC based analysis were performed and product formed was computed as the appearance of peaks corresponding the product in the optimized condition using modified protocol (21).

2.8. Tissue Specific Expression Analysis

The expression profiles of GsSGT were examined in the tissues at different developmental stages through real-time PCR studies with normalization of values against β-actin gene as control. The reaction was set up in total volume of 20 μL containing template of GsSGT and actin. PCR program included following thermal cycles: 40 cycles of 95°C for 10 sec, 95°C for 15 sec, and 55°C for 1 min while the reaction conditions for melting curve were comprised of 95°C for 15 sec, 50°C for 1 min, and 95°C for 15 sec, respectively. Further, the specificity of the reaction was determined through dissociation curve analysis compared with no-template controls (the reactions were run in triplicates) with two biological repeats in StepOne RealTime PCR system (Applied Biosystems) using SYBR green mix (Applied Biosystems). Subsequently, the relative expression was represented by the relative quantification value, calculated by method (22).

3. Results and Discussion

3.1. Cloning of GsSGT Gene from G. sylvestre

The partial GsSGT cDNA (370 bp) was isolated from a cDNA library of G. sylvestre leaves employing a homology based PCR screening approach. Further, 3′RACE resulted in a 685 bp partial clone showing homology with WsSGTL1 from W. somnifera. The partial clones were submitted to Genbank at NCBI database (Genbank ID: GU181368; GU191124). 5′RACE and 3′RACE partial fragments (1.7 kb and 968 bp, resp.) and the internal fragment sequences were collated to yield an assembled full length GsSGTconsisting of 2572 nucleotides including 2106 open reading frame (ORF) and 5′ and 3′ untranslated regions (UTRs) of 228 bp and 199 bp, respectively. The 2106 bp ORF corresponded to a polypeptide of 701 amino acids. BLAST P (http://blast.ncbi.nlm.nih.gov/Blast.cgi) similarity search revealed predominant homology of GsSGT with SGTs from W. somnifera WsSGTL1 (69%), A. thaliana 3-β-SGT (70%), M. truncatula 3-β-SGT (70%), Z. mays 3-β-SGT (68%), and A. sativa UDP-glucose: sterol glucosyltransferase (57%), suggesting its close sequence resemblance with members of the family 1 glycosyltransferases.

3.2. Phylogenetic Studies

Multiple sequence alignment was performed at the protein level with sterol glucosylating GTs from microbes and plant, which revealed large variations in the N-terminal regions suggesting that plant SGTs have diverged during evolution from microbial SGTs functionally involved in sterol glycosylation and evolved to accommodate diverse acceptors (Figure 2). The C-terminal region of SGTs remains mostly conserved with some variations, while the conservation pattern highlights conservation of different amino acid residues in microbial and plant SGTs (Figure 2). This inference is in accordance with the similar catalytic mechanism and region-selectivity for 3-OH group of sterols, experimentally validated from SGT enzyme assays performed for GsSGT and WsSGTL1 [35]. This is in agreement with the fact that the C-terminal domain of GTs represents the nucleotide activated sugar donor binding site and remained structurally conserved during the course of evolution, UDP glucose (sugar donor) being the most preferred by SGTs in plants, followed by UDP-galactose, UDP-rhamnose, UDP-xylose, and UDP-glucuronic acid, respectively. Structural investigations assigned GT-B family to the GsSGT with structure consisting of two separate Rossmann domains connected through a linker region which represents the catalytic site of the enzyme. It is interesting to note that the GT-B family had shown remarkable structural conservation in the C-terminal sugar donor binding domain while variations were found in the N-terminal regions as well as in the helices, loops, and active site which have evolved naturally to accept diverse molecules [38]. This might be a possible explanation for broad functionality of some GTs while elucidating regiospecificity of others [38]. Additionally, presence of transmembrane helices was detected in the secondary structure of GsSGT protein which constitutes about 28.48% of the structure (Supplementary Figure 1; Supplementary Material is available online at http://dx.doi.org/10.1155/2014/934351).

(a)

(b)

Figure 2

Multiple sequence alignment of protein sequences of microbial and plant SGTs and GsSGT. The SGT accessions used for the alignment are as follows: WsSGTL1 [W. somnifera]: accession number ABC96116.1, 3-β-SGT [A. thaliana]: accession number AEE31976.1, 3-β-SGT [M. truncatula]: accession number XP003592094.1, 3-β-SGT [Z. mays]: accession number ACG25324.1, sterol glucosyltransferase 1 [L. japonicas]: accession number AEX55299.1, UDP-glucose: sterol glucosyltransferase [A. sativa]: accession number CAB06081.1, sterol glucosyltransferase [A. oryzae RIB40]: accession number XP001818661.2, UDP-glucose: sterol glucosyltransferase [C. albicans]: accession number AAD29571.1, UDP-glucose: sterol glucosyltransferase [S. cerevisiae YJM789]: accession number EDN59412.1, 3-β-SGT [A. niger CBS 513.88]: accession number XP001391739.2, UDP-glucose: sterol glucosyltransferase Ugt51D1 [U. maydis]: accession number AAN77910.1, sterol glucosyltransferase [D. discoideum]: accession number AAD28546.1, 3-β-SGT [C. sp. PCC 7507]: accession number AFY35770.1, UDP-glucose: sterol glucosyltransferase [R. baltica SH 1]: accession number NP869730.1, and 3-β-SGT [C. beijerinckii NCIMB 8052]: accession number ABR34421.1. The consensus is represented by conserved amino acid residues and percentage of conservation by a bar graph, respectively. The alignment at the N and C terminal ends showed negligible conservation and is therefore not included in the figure.

A neighbor-joining phylogenetic tree was generated to establish the phylogenetic relationship of GsSGT with reported microbial and plant SGT protein sequences through MEGA 5.5 software (Figure 3) [39]. The study demonstrated that microbial SGTs, namely, 3-β-SGT from Clostridium beijerinckii NCIMB 8052: accession number ABR34421.1. was the progenitor during evolutionary divergence of SGTs involved in sterol glucosylation. Further, SGTs from Rhodopirellula baltica SH1 accession number NP869730.1 and Calothrix sp. PCC7507 accession number AFY35770.1 were the successors which diverged from Clostridium SGT. The evolutionary trends suggested that plant SGTs are the recent members of SGT family and originated from fungal SGTs [39].

Figure 3

Phylogenetic analysis of GsSGT with Neighbour-Joining method using MEGA 5.5 software. The protein sequences retrieved from NCBI database included in the analysis comprised plant and microbial SGTs: WsSGTL1 [W. somnifera]: accession number ABC96116.1, 3-β-SGT [A. thaliana]: accession number AEE31976.1, 3-β-SGT [Medicago truncatula]: accession number XP003592094.1, 3-β-SGT [Z. mays]: accession number ACG25324.1, sterol glucosyltransferase 1 [L. japonicas]: accession number AEX55299.1, UDP-glucose: sterol glucosyltransferase [A. sativa]: accession number CAB06081.1, sterol glucosyltransferase [A. oryzae RIB40]: accession number XP001818661.2, UDP-glucose: sterol glucosyltransferase [C. albicans]: accession number AAD29571.1, UDP-glucose: sterol glucosyltransferase [S. cerevisiae YJM789]: accession number EDN59412.1, 3-β-SGT [A. niger CBS 513.88]: accession number XP001391739.2, UDP-glucose: sterol glucosyltransferase Ugt51D1 [U. maydis]: accession number AAN77910.1, sterol glucosyltransferase [D. discoideum]: accession number AAD28546.1, 3-β-SGT [C. sp. PCC 7507]: accession number AFY35770.1, UDP-glucose: sterol glucosyltransferase [R. baltica SH 1]: accession number NP869730.1 and 3-β-SGT [C. beijerinckii NCIMB 8052]: accession number ABR34421.1.

Phylogenetic studies have also revealed some interesting findings on the glucosyltransferase from G. sylvestre. The GsSGT protein was found to be evolutionarily related to the antibiotic GTs from microbes (Gtfd). Since the SGTs and antibiotic GTs are both classified in family I GT, therefore it is hypothesized that GsSGT from the plant could have pharmacological prospects, playing a role in biosynthesis of steryl glucosides as well as precursors of triterpene saponins. Considering the pharmacological significance of steryl glycosides in plants and their biosynthesis being catalyzed by UDP dependent sterol glucosyltransferases, cloning of GsSGT and its novel biochemical characteristics are of key significance. This investigation constitutes the first progress on understanding steryl glucoside biosynthesis in G. sylvestre R.Br. Also, G. sylvestre 3-O-sterol glucosyltransferase was found to be the youngest member in phylogenetic evolution and grouped in the same clade as the W. somnifera WsSGTL1 (Figure 3). The similar properties of both proteins indicated that these are closely linked with a parallel evolution and it was further evident from their catalytic/functional similarities, both exhibiting a preference for C-3 hydroxyl (−OH) sterols as the glucosyl moiety acceptor substrates.

3.3. Heterologous Expression

The complete open reading frame of GsSGT was PCR amplified, subjected to double-digestion with Nde 1 and Bam H1 restriction enzymes and heterologously expressed in pET-28a with a T7 promoter and a His-tag for protein purification. The induced protein showed overexpression at 18°C with IPTG. The nickel/NTA affinity purified protein encoded a recombinant protein of 77 kDa and was catalytically characterized through enzymatic assays employing UDP-glucose as sugar donor and diverse sterols, namely, cholesterol, ergosterol, and stigmasterol as substrates in the enzymatic assays (Figures 1, 4, and 5).

(a)

(b)

(c)

Figure 4

Thin layer chromatographic identification of different steryl glycosides (cholesterol 3-O-β-D-glucoside, ergosterol 3-O-β-D-glucoside, and stigmasterol 3-O-β-D-glucoside) formed in the GsSGT catalyzed reaction with UDPG as glucosyl donor and respective sterols as acceptor substrates. (a) Lane 1, ergosterol standard; lane 2 and lane 3, enzyme assay performed with purified GsSGT protein; lane 4, heat inactivated enzyme control; lane 5, substrate (negative) control; lane 6, ergosterol 3-O-β-D-glucoside standard. (b) Lane 1, enzyme assay performed with crude enzyme extract; lane 2, enzyme assay performed with purified GsSGT protein; lane 3, cholesterol standard; lane 4, cholesterol 3-O-β-D-glucoside product standard. (c) Lane 1 and lane 2, GsSGT enzymatic assay (Tris buffer, pH 6.5); lane 3 and lane 4, GsSGT enzymatic assay (Tris buffer, pH 7.5); lane 5, control (Tris buffer + enzyme); lane 6, control 2 (Tris buffer + stigmasterol + protein, no UDP-glucose); lane 7, stigmasterol standard; lane 8, cholesterol 3-O-β-D-glucoside standard.

(a)

(b)

(c)

(d)

(e)

(f)

Figure 5

(a) Enzyme preparation protein versus rate of reaction product formation. (b) Time of incubation versus amount of product formed. A time course experiment was performed at various intervals of time, namely, 0 hours, 15 minutes, 30 minutes, 1 hours, 2 hours, 4 hours, 6 hours, 8 hours, 10 hours, 12 hours, and 24 hours with 37°C as the temperature of incubation. (c) Assay pH versus catalytic activity of GsSGT. (d) substrate saturation curve of GsSGT for aglycon (ergosterol). (e) Thermostability of the recombinant GsSGT. (f) Optimum temperature for enzymatic actvity of GsSGT.

3.4. Biochemical Characterization

3.4.1. Thin Layer Chromatography (TLC) Based Identification of Catalytic Reaction Product

The optimized TLC protocol was used for identification of steryl glucosides, the products of the enzyme catalyzed reaction. TLC analysis with authentic standards indicated the formation of cholesterol 3-O-β-D-glucoside, ergosteryl 3-O-β-D-glucoside, and stigmasterol 3-O-β-D-glucoside which comigrated with the standard. The results showed the enzymatic preference of GsSGT for hydroxyl (−OH) group at C-3 of sterols which is consistent with the previous reports on SGTs [35]. Also, it is interesting to note that G. sylvestre UDP: sterol glucosyltransferase exhibited significant activity with cholesterol as acceptor substrate. This is in comparison with the catalytic traits of W. somnifera, WsSGTL1 which exhibited no activity with cholesterol. The inference can be drawn on the fact that variations in amino acid residues at the N terminal substrate binding site might be responsible for enzyme’s catalytic preference for cholesterol. Significant activity was also seen with ergosterol and stigmasterol leading to their glucoside formation by glucosyl conjugation at their C-3 OH position. This suggests that GsSGTcatalyzes O-glucosylation at C-3 hydroxyl position of sterols resulting in formation of ergosteryl 3-O-β-D-glucoside and stigmasterol 3-O-β-D-glucoside. TLC based chromogenic identification of the glucoside products with authentic standards and controls showed the formation of glucoside product which was absent in control (Figures 4(a), 4(b), and 4(c)). The steryl glucoside formation was further validated by HPLC analysis. Various catalytic parameters of the enzyme were determined and validated through enzyme assays with the respective controls (Figures 5(a), 5(b), 5(c), 5(d), 5(e), and 5(f)) leading to the optimization and identification of the glucosylated sterols.

4. Tissue Specific Expression Analysis

The expression profile of the sterol glucosyltransferase (GsSGT) was examined in different tissues of G. sylvestre and the expression was found to be consistent in all the developmental stages, namely, very young leaf, mature leaf, fully mature leaf, and stem tissues with a low expression in fully mature leaf. Further, real-time PCR of GsSGT expression in different developmental stages revealed that GsSGT transcript levels were relatively highest in fully mature leaf followed by stem tissue and very young leaf (Figure 6).

Studies have reported the presence of a highly conserved PSPG domain at the C-terminal (44 amino acid residues), involved in binding of nucleotide activated sugar donor (UDP-glucose in this study). Also, the presence of HCGWNS motif within the PSPG box is essential for enzymatic activity [40] and the identification of the respective motif in GsSGT protein validated the findings. The presence of HCGWNS as a signature motif was found to be 100% conserved in GsSGT protein sequence, consistent with other SGTs classified in family 1 glycosyltransferases (Supplementary Figure 2). Further, studies have suggested that the sugar donor and acceptors are accommodated in the cavity between the N and C terminal domain and the formation of substrate binding pocket is due to several regions in the primary sequence of the protein [41]. Additionally, in silico motif diversity analysis in all the GT sequences and phylogenetic evolution of the PSPG domain was earlier reported [42]. This was further ascribed to the presence of high percent of hydrophobic amino acid in the secondary structure of GsSGT (alanine—6%, isoleucine—7%, leucine—9%, proline—8%, and valine—6%) which suggest that the aliphatic side chain plays an important role in enzyme catalysis and function, forming the hydrophobic core of the protein (Supplementary Figure ). Furthermore, the hydrophobic interactions play an important role in protein folding. During polypeptide folding, the nonpolar amino acids come together in close proximity and excluded from polar environment. The water molecules are released from interior leading to increase in entropy which contributes to protein folding.

The phylogenetic position analysis suggested the cytosolic localization of GsSGT as transmembrane domain was not present and its phylogenetic position was far away from the membrane-associated SGTs. Such proteins have polar group on their surface which interact with water molecules while the hydrophobic or nonpolar amino acid residues are buried in the interior and constitutes the active site of the enzyme. Protein secondary structure was predicted through psipred server and consisted of 28.48% alpha helix, 20.00% extended strands, and 51.52% random coil, the remaining secondary structures being negligible (Supplementary Figure 4). The presence of alpha helix provides stability to the secondary structure of the protein. Also, an alpha helix represents hydrogen bond formed between an amino group and 3rd amino group of same polypeptide chain and forms a stable and ordered structure in protein. Furthermore, amino acid residues such as lysine, alanine, methionine, leucine, and glutamate tend to adopt a helical conformation in the protein. The extended strand or antiparallel β-sheet consists of hydrogen bonds formed between peptides bonds in antiparallel polypeptide chain. Glycine and proline residues have the propensity to form β-sheets in a protein. It connects more regular secondary structures like alpha helix in a protein. The presence of a random coil is undefined and indicates an absence of regular secondary structure like alpha helix or beta sheet. Random coils do not constitute the catalytic core of the protein and found outside the active site, not involved in catalytic mechanisms (Supplementary Figure 4).

Sterol metabolism accounts for a primary process essential in all organisms including bacterial and fungal species. Steryl glycosides (SG) have been reported from several bacterial species such as H. pylori [43], A. axanthum [44], S. citri [45], and B. hermsi [46]. Studies also suggested the role of SGs in pathogenesis in bacteria [47]. A cholesterol alpha-glycosyltransferase, cloned from H. pylori causes infections of gastric pathology such as carcinoma and peptic ulcers. The glycosylation of the cholesterol by SGTs results in immune system invasion by the pathogen [48]. The mutants with deleted copy of the gene showed absence of cholesterol glycosylation and impaired pathogenesis. Regarding fungal SGTs; these enzymes have been reported to be involved in selective degradation of peroxisomes (pexophagy) in P. pastoris while UGT51 enzyme in Y. lypolytica, is required for utilization of decane. Defect in decane assimilation occurs due to defective copy of UGT51 sterol glucosyltransferase. These studies have suggested that sterol metabolism constitutes a primary metabolic process in microbial species. However, in plants, glycosylation of sterols into the respective steryl glycosides comprises of secondary metabolic pathway activity as well, among others [49]. Sterol glucosyltransferases or SGTs constitutes key regulators of sterol glucosylation mechanism and their presence is often species specific. It has been suggested that the presence of steryl glycosides in plasma membrane imparts properties such as freeze tolerance, the cold acclimation process, and stress signaling cascade [11–16]. It was hypothesized from the deduced phylogenetics that evolution favored the secondary compartmentalization of sterol metabolism giving preference to more significant primary metabolic processes essential for cell-survival. Further, plant SGTs evolved from microbial SGTs exhibiting better adaptability and evolutionary selection in comparison to microbial SGTs.

Sterols and their glycosylated derivatives, SGs, constitute an integral component of plant secondary metabolism network. The presence of steryl glycosides confers various properties to the plant, essential for adaptation and cell survival. Sterol glycosyltransferases or SGTs are the less explored members of GT superfamily and very few reports are available on research pertaining to SGTs. However, literature highlighting the wider relevance of SGs ranging from pharmacological properties, namely, anticancer activity to apoptotic, cytotoxic, antistress and antimicrobial activity, studies on biochemical and structural investigations involving SGTs would be a prime area in drug development utilizing plant formulations. Further, such studies exploring both the structural aspects of the protein and biochemical characterization would help in establishing the functional role of an enzyme in biosynthesis of phytomolecules in plants. Also, the presence of bioactive secondary metabolites and elucidation of the biosynthetic role in synthesis of glycol-conjugates would enrich the studies of plant GTs in glycoengineering.

Additionally, the cloning and characterization of 3-OH sterol GT opens up the possibility of glycosylation of important sterol structure based phytomoleclues of diverse structure for potential therapeutic functions.

5. Conclusions

Sterol glycosyltransferases are important class of enzymes, catalyzing sterol glucosylation and steryl glucosides formation in planta. The addition of a carbohydrate moiety to secondary metabolites enhances several biological properties making glycoconjugates as key drugs or drug-derivatives in pharmacological studies. The present study discusses the cloning and biochemical characterization of a UDP dependent glucosyltransferase catalyzing the biosynthesis of steryl glucosides in G. sylvestre R.Br., an Ayurvedic herb with antidiabetic properties. The complete ORF was expressed in pET-28a and the gene was found to encode a polypeptide of 77 kDa as observed with SDS-PAGE. It matched well with the computed molecular mass of the protein. Further, the protein exhibited catalytic preference for C-3 position OH groups of sterols leading to formation of cholesterol 3-O-β-D-glucoside and ergosteryl 3-O-β-D-glucoside. There are recent observations suggesting the occurrence of ergosterol and derivatives in medicinal plant, W. somnifera [50] and its glycosylation by SGTs [35]. Although, till now, ergosterol was regarded as a fungal metabolite, literature highlighting the presence of ergosterol and derivatives and their isolation from plants are being increasingly explored and reported [50]. Furthermore, glucosylation of stigmasterol (phyto-constituent present in G. sylvestre R.Br.) to form stigmasterol 3-O-β-D-glucoside by GsSGT suggest its role in biosynthesis of these glycoconjugates of these phytosteroids. Real-time PCR studies demonstrated that the expression of GsSGT was consistent in all developmental stages of tissues suggesting that biosynthesis of steryl glucosides and presence of sterols as precursors of triterpene saponins constitute an essential metabolic network in plant secondary metabolomics in G. sylvestre R.Br. This SGT from G. sylvestre R.Br. is unique as it possesses the capacity to glucosylate different kinds of sterols present in lower organisms like bacteria and fungi to higher organisms (plants and animals). This study highlights significant possibilities focusing on sterol metabolism and its evolution from microbes to higher organisms and would further aim at pathway engineering of sterol metabolism. This research finding reports for the first time identification, isolation, and characterization of a novel SGT from G. sylvestre, capable of glucosylating all major sterols expectedly playing diverse role in primary as well as secondary metabolism.

Abbreviations

GsSGT:	Gymnema sylvestre 3-O-sterol glucosyltransferase;
CAZY:	Carbohydrate active enzyme database;
UDP-GTs:	Uridine diphosphoglucose dependent glucosyltransferases;
PSPG:	Plant secondary product glucosyltransferase;
PCR:	Polymerase chain reaction;
LB:	Luria broth;
IPTG:	Isopropyl β-D-thiogalactopyranoside;
SDS-PAGE:	Sodium dodecyl sulphate-polyacrylamide gel electrophoresis;
HPLC:	High performance liquid chromatography;
3D:	Three-dimensional;
CDD search:	Conserved domain database search.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.

Acknowledgments

Authors are thankful to the financial support provided by the Council of Scientific and Industrial Research (CSIR) Network project NWP-09 and BSC 203. Pragya Tiwari expresses her gratitude to CSIR for the award of senior research fellowship and to Uttar Pradesh Technical University for Ph.D. registration. Authors acknowledge the help extended by Ritesh K Yadav in HPLC. Authors express sincere thanks to Director, CSIR-CIMAP, for his consistent support and encouragement.

Supplementary Materials

Supplementary Figure 1: Deduced disorderliness state of the protein, secondary structures and presence of transmembrance helices in the GsSGT protein.

Supplementary Figure 2: Analysis of the nucleotide (UDPG) binding PSPG conserved domain in G. sylvestre UDP: sterol glucosyltransferase. The HCGWNS motif within the PSPG box is essential for enzymatic activity and found to be 100% conserved in the protein sequence of GsSGT.

Supplementary Figure 3: Pie chart representation of the percentage of each amino acid present in secondary structure of GsSGT protein.

Supplementary Figure 4: Protein secondary structure analysis showing 28.48% alpha helix, 20.00% extended strands and 51.52% random coil.

Supplementary Figures

References

Z. A. Wojciechowski, “Biochemistry of phytosterol conjugates,” in Physiology and Biochemistry of Sterols, G. W. Patterson and W. D. Nes, Eds., pp. 361–395, American Oil Chemists Society, Champaign, Ill, USA, 1991.
View at: Google Scholar
J. Hughes and M. A. Hughes, “Multiple secondary plant product UDP-glucose glucosyltransferase genes expressed in cassava (Manihot esculenta Crantz) cotyledons,” DNA Sequence-Journal of DNA Sequencing and Mapping, vol. 5, no. 1, pp. 41–49, 1994.
View at: Google Scholar
E. K. Lim and D. J. Bowles, “A class of plant glycosyltransferases involved in cellular homeostatis,” EMBO Journal, vol. 23, no. 15, pp. 2915–2922, 2004.
View at: Publisher Site | Google Scholar
D. C. Warnecke, M. Baltrusch, F. Buck, F. P. Wolter, and E. Heinz, “UDP-glucose:sterol glucosyltransferase: cloning and functional expression in Escherichia coli,” Plant Molecular Biology, vol. 35, no. 5, pp. 597–603, 1997.
View at: Publisher Site | Google Scholar
M. J. Zmijewski Jr. and B. Briggs, “Biosynthesis of vancomycin: identification of TDP-glucose: aglycosyl-vancomycin glucosyltransferase from Amycolatopsis orientalis,” FEMS Microbiology Letters, vol. 59, no. 1-2, pp. 129–133, 1989.
View at: Publisher Site | Google Scholar
Y. Ogasawara, K. Katayama, A. Minami, M. Otsuka, T. Eguchi, and K. Kakinuma, “Cloning, sequencing, and functional analysis of the biosynthetic gene cluster of macrolactam antibiotic vicenistatin in Streptomyces halstedii,” Chemistry and Biology, vol. 11, no. 1, pp. 79–86, 2004.
View at: Publisher Site | Google Scholar
D. Hoffmeister, K. Ichinose, and A. Bechthold, “Two sequence elements of glycosyltransferases involved in urdamycin biosynthesis are responsible for substrate specificity and enzymatic activity,” Chemistry and Biology, vol. 8, no. 6, pp. 557–567, 2001.
View at: Publisher Site | Google Scholar
N. D. Chaurasiya, N. S. Sangwan, F. Sabir, L. Misra, and R. S. Sangwan, “Withanolide biosynthesis recruits both mevalonate and DOXP pathways of isoprenogenesis in Ashwagandha Withania somnifera L. (Dunal),” Plant Cell Reports, vol. 31, no. 10, pp. 1889–1897, 2012.
View at: Publisher Site | Google Scholar
M. Rohmer, “The discovery of a mevalonate-independent pathway for isoprenoid biosynthesis in bacteria, algae and higher plants,” Natural Product Reports, vol. 16, no. 5, pp. 565–574, 1999.
View at: Publisher Site | Google Scholar
J. R. Hazel and E. E. Williams, “The role of alternations in membrane lipid composition in enabling physiological adaptation of organisms to their physical environment,” Progress in Lipid Research, vol. 29, no. 3, pp. 167–227, 1990.
View at: Publisher Site | Google Scholar
J. P. Palta, B. D. Whitaker, and L. S. Weiss, “Plasma membrane lipids associated with genetic variability in freezing tolerance and cold acclimation of Solanum species,” Plant Physiology, vol. 103, no. 3, pp. 793–803, 1993.
View at: Google Scholar
M. Uemura and P. L. Steponkus, “A contrast of the plasma membrane lipid composition of oat and rye leaves in relation to freezing tolerance,” Plant Physiology, vol. 104, no. 2, pp. 479–496, 1994.
View at: Google Scholar
S. Kunimoto, W. Murofushi, H. Kai et al., “Steryl glucoside is a lipid mediator in stress-responsive signal transduction,” Cell Structure and Function, vol. 27, no. 3, pp. 157–162, 2002.
View at: Publisher Site | Google Scholar
P. Chaturvedi, M. Mishra, N. Akhtar, P. Gupta, P. Mishra, and R. Tuli, “Sterol glycosyltransferases-identification of members of gene family and their role in stress in Withania somnifera,” Molecular Biology Reports, vol. 39, no. 10, pp. 9755–9764, 2012.
View at: Publisher Site | Google Scholar
M. K. Mishra, P. Chaturvedi, R. Singh et al., “Overexpression of WsSGTL1 gene of Withania somnifera enhances salt tolerance, heat tolerance and cold acclimation ability in transgenic Arabidopsis plants,” PLoS ONE, vol. 8, no. 4, Article ID e63064, 2013.
View at: Publisher Site | Google Scholar
V. Pandey, A. Niranjan, N. Atri et al., “WsSGTL1 gene from Withania somnifera, modulates glycosylation profile, antioxidant system and confers biotic and salt stress tolerance in transgenic tobacco,” Planta, vol. 239, no. 6, pp. 1217–1231, 2014.
View at: Publisher Site | Google Scholar
K. Schumacher and J. Chory, “Brassinosteroid signal transduction: Still casting the actors,” Current Opinion in Plant Biology, vol. 3, no. 1, pp. 79–84, 2000.
View at: Publisher Site | Google Scholar
J. He, S. Fujioka, T. Li et al., “Sterols regulate development and gene expression in Arabidopsis,” Plant Physiology, vol. 131, no. 3, pp. 1258–1269, 2003.
View at: Publisher Site | Google Scholar
N. V. Kovganko and Z. N. Kashkan, “Sterol glycosides and acylglycosides,” Chemistry of Natural Compounds, vol. 35, no. 5, pp. 479–497, 1999.
View at: Publisher Site | Google Scholar
P. Ullmann, A. Ury, P. Rimmele, P. Benveniste, and P. Bouvier-Navé, “UDP-glucose sterol ß-d-glucosyltransferase, a plasma membrane-bound enzyme of plants: enzymatic properties and lipid dependence,” Biochimie, vol. 75, no. 8, pp. 713–723, 1993.
View at: Publisher Site | Google Scholar
E. Heinz, “Plant glycolipids: structure, isolation and analysis,” in Advances in Lipid Methodology, W. W. Christie, Ed., vol. 3, pp. 211–332, The Oily Press, Dundee, UK, 1996.
View at: Google Scholar
S. Grille, A. Zaslawski, S. Thiele, J. Plat, and D. Warnecke, “The functions of steryl glycosides come to those who wait: recent advances in plants, fungi, bacteria and animals,” Progress in Lipid Research, vol. 49, no. 3, pp. 262–288, 2010.
View at: Publisher Site | Google Scholar
P. Chaturvedi, P. Misra, and R. Tuli, “Sterol glycosyltransferases—the enzymes that modify sterols,” Applied Biochemistry and Biotechnology, vol. 165, no. 1, pp. 47–68, 2011.
View at: Publisher Site | Google Scholar
B. R. Madina, L. K. Sharma, P. Chaturvedi, R. S. Sangwan, and R. Tuli, “Purification and physico-kinetic characterization of 3β-hydroxy specific sterol glucosyltransferase from Withania somnifera (L) and its stress response,” Biochimica et Biophysica Acta, vol. 1774, no. 3, pp. 392–402, 2007.
View at: Publisher Site | Google Scholar
B. R. Madina, L. K. Sharma, P. Chaturvedi, R. S. Sangwan, and R. Tuli, “Purification and characterization of a novel glucosyltransferase specific to 27β-hydroxy steroidal lactones from Withania somnifera and its role in stress responses,” Biochimica et Biophysica Acta, vol. 1774, no. 9, pp. 1199–1207, 2007.
View at: Publisher Site | Google Scholar
A. Potocka and J. Zimowski, “Metabolism of conjugated sterols in eggplant. Part 1. UDP-glucose: sterol glucosyltransferase,” Acta Biochimica Polonica, vol. 55, no. 1, pp. 127–134, 2008.
View at: Google Scholar
S. Debolt, W.-R. Scheible, K. Schrick et al., “Mutations in UDP-glucose:Sterol glucosyltransferase in Arabidopsis cause transparent testa phenotype and suberization defect in seeds,” Plant Physiology, vol. 151, no. 1, pp. 78–87, 2009.
View at: Publisher Site | Google Scholar
S. Paquette, B. L. Møller, and S. Bak, “On the origin of family 1 plant glycosyltransferases,” Phytochemistry, vol. 62, no. 3, pp. 399–413, 2003.
View at: Publisher Site | Google Scholar
J. Zimowski, “Specificity and some other properties of cytosolic and membranous UDP-Glc: 3β-hydroxysteroid glucosyltransferases from Solanum tuberosum leaves,” Phytochemistry, vol. 31, no. 9, pp. 2977–2981, 1992.
View at: Publisher Site | Google Scholar
V. U. Ahmad and A. Basha, Spectroscopic Data of Steroid Glycosides, Springer, New York, NY, USA, 2007.
D. C. Warnecke and E. Heinz, “Purification of a membrane-bound UDP-glucose:sterol beta-D-glucosyltransferase based on its solubility in diethyl ether,” Plant Physiology, vol. 105, no. 4, pp. 1067–1073, 1994.
View at: Google Scholar
M. Misiak, M. Kalinowska, and Z. A. Wojciechowski, “Characterization of acyllipid: sterol glucoside acyltransferase from oat (Avena sativa L.) seedlings.,” Acta Biochimica Polonica, vol. 38, no. 1, pp. 43–45, 1991.
View at: Google Scholar
A. Potocka and J. Zimowski, “Metabolism of conjugated sterols in eggplant. Part 2. phospholipid: steryl glucoside acyltransferase,” Acta Biochimica Polonica, vol. 55, no. 1, pp. 135–140, 2008.
View at: Google Scholar
C. Yue and J. Zhong, “Purification and characterization of UDPG: ginsenoside Rd glucosyltransferase from suspended cells of Panax notoginseng,” Process Biochemistry, vol. 40, no. 12, pp. 3742–3748, 2005.
View at: Publisher Site | Google Scholar
L. K. Sharma, B. R. Madina, P. Chaturvedi, R. S. Sangwan, and R. Tuli, “Molecular cloning and characterization of one member of 3beta-hydroxy sterol glucosyltransferase gene family in Withania somnifera,” Archives of Biochemistry and Biophysics, vol. 460, no. 1, pp. 48–55, 2007.
View at: Publisher Site | Google Scholar
P. Tiwari, B. N. Mishra, and N. S. Sangwan, “Phytochemical and pharmacological properties of Gymnema sylvestre, an important medicinal plant,” BioMed Research International, vol. 2014, Article ID 830285, 18 pages, 2014.
View at: Publisher Site | Google Scholar
D. T. Jones, “A model recognition approach to the prediction of all-helical membrane protein structure and topology,” Biochemistry, vol. 33, no. 10, pp. 3038–3049, 1994.
View at: Publisher Site | Google Scholar
C. Breton, L. S. Najdrova, C. Jeanneau et al., “Structures and mechanisms of glycosyltransferases,” Glycobiology, vol. 16, no. 2, pp. 29–37, 2006.
View at: Publisher Site | Google Scholar
K. Tamura, D. Peterson, N. Peterson, G. Stecher, M. Nei, and S. Kumar, “MEGA5: Molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods,” Molecular Biology and Evolution, vol. 28, no. 10, pp. 2731–2739, 2011.
View at: Publisher Site | Google Scholar
C. Colovos and T. O. Yeates, “Verification of protein structures: patterns of nonbonded atomic interactions,” Protein Science, vol. 2, no. 9, pp. 1511–1519, 1993.
View at: Publisher Site | Google Scholar
C. M. M. Gachon, M. Langlois-Meurinne, and P. Saindrenan, “Plant secondary metabolism glycosyltransferases: the emerging functional analysis,” Trends in Plant Science, vol. 10, no. 11, pp. 542–549, 2005.
View at: Publisher Site | Google Scholar
R. Kumar, R. S. Sangwan, S. Mishra, F. Sabir, and N. S. Sangwan, “In silico motif diversity analysis of the glycon preferentiality of plant secondary metabolic glycosyltransferases,” Plant Omics Journal, vol. 5, no. 3, pp. 200–210, 2012.
View at: Google Scholar
Y. Hirai, M. Haque, T. Yoshida, K. Yokota, T. Yasuda, and K. Oguma, “Unique cholesteryl glucosides in Helicobacter pylori: composition and structural analysis,” Journal of Bacteriology, vol. 177, no. 18, pp. 5327–5333, 1995.
View at: Google Scholar
W. R. Mayberry and P. F. Smith, “Structures and properties of acyl diglucosylcholesterol and galactofuranosyl diacylglycerol from Acholeplasma axanthum,” Biochimica et Biophysica Acta—Lipids and Lipid Metabolism, vol. 752, no. 3, pp. 434–443, 1983.
View at: Publisher Site | Google Scholar
K. R. Patel, P. F. Smith, and W. R. Mayberry, “Comparison of lipids from Spiroplasma citri and corn stunt spiroplasma,” Journal of Bacteriology, vol. 136, no. 2, pp. 829–831, 1978.
View at: Google Scholar
B. P. Livermore, R. F. Bey, and R. C. Johnson, “Lipid metabolism of Borrelia hermsi,” Infection and Immunity, vol. 20, no. 1, pp. 215–220, 1978.
View at: Google Scholar
A. H. Lebrun, C. Wunder, J. Hildebrand et al., “Cloning of a cholesterol-α-glucosyltransferase from Helicobacter pylori,” The Journal of Biological Chemistry, vol. 281, no. 38, pp. 27765–27772, 2006.
View at: Publisher Site | Google Scholar
C. Wunder, Y. Churin, F. Winau et al., “Cholesterol glucosylation promotes immune evasion by Helicobacter pylori,” Nature Medicine, vol. 12, no. 9, pp. 1030–1038, 2006.
View at: Publisher Site | Google Scholar
N. S. Sangwan, L. N. Mishra, S. Tripathi et al., “Omics of secondary metabolic pathways in Withania somnifera Dunal (ashwagandha),” in Omics Applications in Crop Science, pp. 385–408, CRC Press Taylor & Francis, New York, NY, USA, 2014.
View at: Google Scholar
L. N. Misra, P. Mishra, A. Pandey, R. S. Sangwan, and N. S. Sangwan, “1,4-Dioxane and ergosterol derivatives from Withania somnifera roots,” Journal of Asian Natural Products Research, vol. 14, no. 1, pp. 39–45, 2012.
View at: Publisher Site | Google Scholar

Copyright

Copyright © 2014 Pragya Tiwari et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

PDF Download Citation

Download other formats

Order printed copies

Views

2189

Downloads

1727

Citations