Rapid Chemoenzymatic Synthesis of Monodisperse Hyaluronan Oligosaccharides with Immobilized Enzyme Reactors

DeAngelis, Paul L.; Oatman, Leonard C.; Gay, Daniel F.

doi:10.1074/jbc.m306431200

Cited by 97 publications

(77 citation statements)

References 20 publications

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“…A useful property of pmHAS is that it can extend exogenously provided HA acceptor oligosaccharides in vitro (16). This polymerization reaction occurs in a nonprocessive fashion where the enzyme binds, elongates, and releases the growing HA chain in a rapid repetitive fashion (13,17). In this report, we utilize the acceptor elongation activity for the chemoenzymatic synthesis of a variety of HA polymers with narrow size distributions.…”

Section: Hyaluronan (Ha)mentioning

confidence: 99%

Synchronized Chemoenzymatic Synthesis of Monodisperse Hyaluronan Polymers

Wei¹,

DeAngelis

2004

Journal of Biological Chemistry

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131

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The length of the hyaluronan (HA) polysaccharide chain dictates its biological effects in many cellular and tissue systems. Long and short HA polymers often appear to have antagonistic or inverse effects. However, no source of very defined, uniform HA polymers with sizes greater than 10 kDa is currently available. We present a method to produce synthetic HA with very narrow size distributions in the range of ϳ16 kDa to ϳ2 MDa. The Pasteurella HA synthase enzyme, pmHAS, catalyzes the synthesis of HA polymer utilizing monosaccharides from UDP-sugar precursors. Recombinant pmHAS will also elongate exogenously supplied HA oligosaccharide acceptors in vitro in a nonprocessive fashion. As a result of bypassing the slow initiation step in vitro, the elongation process is synchronized in the presence of acceptor; thus all of polymer products are very similar in length. In contrast, without the use of an acceptor, the final polymer size range is difficult to predict and the products are more polydisperse. HA polymers of a desired size are constructed by controlling the reaction stoichiometry (i.e. molar ratio of precursors and acceptor molecules). The use of modified acceptors allows the synthesis of HA polymers containing tags (e.g. fluorescent, radioactive). In this scheme, each molecule has a single foreign moiety at the reducing terminus. Alternatively, the use of radioactive UDP-sugar precursors allows the synthesis of uniformly labeled native HA polymers. Overall, synthetic HA reagents with monodisperse size distributions and defined structures should assist in the elucidation of the numerous roles of HA in health and disease. Hyaluronan (HA)1 is a polysaccharide chain composed of repeating ␤4GlcUA-␤3GlcNAc disaccharide units with molecular masses generally ranging from ϳ10 4 to 10 7 Da in vertebrates and bacteria (1-5). In animals, HA plays structural, recognition, and signaling roles. Certain pathogenic bacteria, namely Streptococcus Groups A and C and Pasteurella multocida Type A, utilize extracellular HA polysaccharide capsules to avoid host defenses and to increase virulence.The biological functions and biomedical applications of HA have long been of interest. It is now recognized that the HA of different sizes can have dramatically different effects on cellular behavior and growth (6 -10). Vertebrates may be able to control HA size in vivo by differential expression of biosynthetic enzymes (11, 12). Currently, the major method to generate HA is extraction from either rooster (chicken) comb or bacterial cultures. These HA preparations not only contain potential components from the original sources that could cause immunogenic, inflammatory, or allergenic responses but are also mixtures of a wide range of molecular masses. To interpret accurately the various biological functions of HA and to synthesize better HA-containing biomedical products, it is necessary to obtain uniform size-defined HA.HA synthases are the enzymes from vertebrates and microbes that polymerize the HA chain using UDP-sugar nucleotide precu...

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Section: Hyaluronan (Ha)mentioning

confidence: 99%

Synchronized Chemoenzymatic Synthesis of Monodisperse Hyaluronan Polymers

Wei¹,

DeAngelis

2004

Journal of Biological Chemistry

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131

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“…Overall, PmHAS appears to be a polypeptide with two active sites involved with coordinated but intrinsically nonprocessive activities. In several indirect tests, including in vitro syntheses of oligosaccharides [21] and polysaccharides [29], PmHAS appears to operate in a nonprocessive fashion. In vivo, PmHAS is probably docked with the membrane transport machinery which may not allow the HA chain to diffuse far away from the microenvironment of the two active sites.…”

Section: Resultsmentioning

confidence: 99%

“…For MALDI-ToF MS and SEC-MALLS analyses, a preparation of PmHAS 1-703 was purified by chromatography on Toyopearl Red AF resin (Tosoh Corp., Tokyo, Japan) using salt elution (50 mM HEPES, pH 7.2, 1 M ethylene glycol with 0 to 1.5 M NaCl gradient in 1 hour) as described previously [21]. The fractions containing the target protein (~95% pure by SDS-PAGE/Coomassie-staining) were pooled and concentrated by ultrafiltration.…”

Section: Production Of Recombinant Truncated Pmhas Proteinmentioning

confidence: 99%

The functional molecular mass of the Pasteurella hyaluronan synthase is a monomer

Pummill¹,

Kane²,

Kempner

et al. 2007

Biochimica et Biophysica Acta (BBA) - General Subjects

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Hyaluronan (HA), a linear polysaccharide composed of β1,3-GlcNAc-β1,4-GlcUA repeats, is found in the extracellular matrix of vertebrate tissues as well as the capsule of several pathogenic bacteria. All known HA synthases (HASs) are dual-action glycosyltransferases that catalyze the addition of two different sugars from UDP-linked precursors to the growing HA chain. The bacterial hyaluronan synthase, PmHAS from Gram-negative Pasteurella multocida, is a 972-residue membraneassociated protein. Previously, the Gram-positive Streptococcus pyogenes enzyme, SpHAS (419 residues), and the vertebrate enzyme, XlHAS1 (588 residues), were found to function as monomers of protein, but the PmHAS is not similar at the protein sequence level and has quite different enzymological properties. We have utilized radiation inactivation to measure the target size of recombinant full-length and truncated PmHAS. The target size of HAS activity was confirmed using internal enzyme standards of known molecular weight. We found that the Pasteurella HA synthase protein functions catalytically as a monomer. Functional truncated soluble PmHAS also behaves as a polypeptide monomer as assessed by gel filtration chromatography and light scattering.

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“…rhHAS2-(122-414) could not synthesize longer (high molecular weight) HA chains even by using longer incubations (over 24 h) or reactions with higher UDP-sugar concentrations (data not shown). Incubation of the tetrasaccharide acceptor with a single donor, UDP-GlcNAc, did not yield HA5, suggesting that the recombinant truncated HAS2 polypeptides cannot be utilized for the stepwise synthesis of HA performed by using the engineered PmHAS method reported by DeAngelis et al (25). For the purpose of the regulation of the molecular size of the HA, some improvement or optimization of the reaction conditions will be required.…”

Section: Production Of Rhhas2 Fusion Proteins In E Coli-it Has Beenmentioning

confidence: 99%

“…It has also been reported that PmHAS added new sugar residues to the saturated tetramer prepared by means of ovine testis hyaluronidase at the non-reducing end (17). Moreover the recent work of DeAngelis et al (25) clearly demonstrated that the engineered PmHAS could be converted into two single action glycosyltransferases, and reactor enzymes immobilized onto solid supports were utilized in an alternating fashion to make pure HA molecules of a single length in a controlled and stepwise manner. In vertebrates HASs, it is known that HAS of Xenopus DG42 expressed in yeast exhibited a significant activity as HA synthase (26).…”

mentioning

confidence: 99%

An Engineered Hyaluronan Synthase

Hoshi

Nakagawa

Nishiguchi

et al. 2004

Journal of Biological Chemistry

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The Class I hyaluronan synthase (HAS) is a unique glycosyltransferase synthesizing hyaluronan (HA), a polysaccharide composed of GlcUA and GlcNAc, by using one catalytic domain that elongates two different monosaccharides. As for the synthetic mechanism, there are two alternative manners for the sugar elongation process. Some bacterial HASs add new sugars to the non-reducing end of the acceptor to grow polymers. On the other hand, some vertebrate enzymes seem to transfer sugars to the reducing end. Expression of vertebrate HASs as active and soluble proteins will accelerate further precise insight into mechanisms of sugar elongation reactions by natural HASs. Since large scale production of HA polymers and oligomers would become powerful tools both for basic studies and new biotechnology to create functional carbohydrates in medicinal purposes, advent of an efficient method for the expression of HASs in Escherichia coli is strongly expected. Here we communicate the first success of the production of recombinant human HAS2 proteins composed of only the catalytic region in E. coli as the active form. It was demonstrated that an engineered HAS2 expressed in E. coli exhibited significant activity to synthesize a mixture of HAS oligomers from 8-mer (HA8) to 16-mer (HA16). Engineered HAS2 prepared herein elongated sugars from exogenous tetrasaccharide to form polymers with a direction to the non-reducing end. According to the present results, large scale production of engineered recombinant HASs is to be performed using E. coli that will provide practical and economic advantages in manufacturing enzymes for use in the synthesis of various oligomeric HA molecules and their industrial applications.

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Rapid Chemoenzymatic Synthesis of Monodisperse Hyaluronan Oligosaccharides with Immobilized Enzyme Reactors

Cited by 97 publications

References 20 publications

Synchronized Chemoenzymatic Synthesis of Monodisperse Hyaluronan Polymers

Synchronized Chemoenzymatic Synthesis of Monodisperse Hyaluronan Polymers

The functional molecular mass of the Pasteurella hyaluronan synthase is a monomer

An Engineered Hyaluronan Synthase

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