Takatsugu Miyazaki

N-Glycan Modification of a Recombinant Protein via Coexpression of Human Glycosyltransferases in Silkworm Pupae

Recombinant proteins produced in insect cells and insects, unlike those produced in mammalian cells, have pauci-mannose-type N-glycans. In this study, we examined complex-type N-glycans on recombinant proteins via coexpression of human β-1,2-N-acetylglucosaminyltransferase II (hGnT II) and human β1,4-galactosyltransferase (hGalT I) in silkworm pupae, by using the Bombyx mori nucleopolyhedrovirus (BmNPV) bacmid system. The actin A3 promoter from B. mori and the polyhedrin promoter from Autographa californica multiple nucleopolyhedroviruses (AcMNPVs) were used to coexpress hGnT II and hGalT I. These recombinant BmNPVs were coexpressed with human IgG (hIgG), hGnT II and hGalT I in silkworm pupae. When hIgG was coexpressed with hGnT II, approximately 15% of all N-glycans were biantennary, with both arms terminally modified with N-acetylglucosamine (GlcNAc). In contrast, when hIgG was coexpressed with both hGnT II and hGalT I under the control of the polyhedrin promoter, 27% of all N-glycans were biantennary and terminally modified with GlcNAc, with up to 5% carrying one galactose and 11% carrying two. The obtained N-glycan structure was dependent on the promoters used for coexpression of hGnT II or hGalT I. This is the first report of silkworm pupae producing a biantennary, terminally galactosylated N-glycan in a recombinant protein. These results suggest that silkworms can be used as alternatives to insect and mammalian hosts to produce recombinant glycoproteins with complex N-glycans.

Structure of the Catalytic Domain of α-L-Arabinofuranosidase from Coprinopsis cinerea, CcAbf62A, Provides Insights into Structure-Function Relationships in Glycoside Hydrolase Family 62

Abstractα-l-Arabinofuranosidases, belonging to the glycoside hydrolase family (GH) 62, hydrolyze the α-1,2- or α-1,3-bond to liberate l-arabinofuranose from the xylan backbone. Here, we determined the structure of the C-terminal catalytic domain of CcAbf62A, a GH62 α-l-arabinofuranosidase from Coprinopsis cinerea. CcAbf62A is composed of a five-bladed β-propeller, as observed in other GH62 enzymes. The structure near the active site of CcAbf62A is also highly homologous to those of other GH62 enzymes. However, a calcium atom in the catalytic center interacts with an asparagine residue, Asn279, which is not found in other GH62 enzymes. In addition, some residues in subsites +3R, +2NR, +3NR, and +4NR of CcAbf62A are not conserved in other GH62 enzymes. In particular, a histidine residue, His221, is uniquely observed in subsite +2NR of CcAbf62A, which is likely to influence the substrate specificity. The results obtained here suggest that the amino acid residues that interact with the xylan backbone vary among the GH62 enzymes, despite the high similarity of their overall structures.

Paenibacillus sp. 598K 6-α-glucosyltransferase is essential for cycloisomaltooligosaccharide synthesis from α-(1 → 4)-glucan

Paenibacillus sp. 598K produces cycloisomaltooligosaccharides (cyclodextrans) from starch even in the absence of dextran. Cycloisomaltooligosaccharide glucanotransferase synthesizes cycloisomaltooligosaccharides exclusively from an α-(1xa0→xa06)-consecutive glucose chain consisting of at least four molecules. Starch is not a substrate of this enzyme. Therefore, we predicted that the bacterium possesses another enzyme system for extending α-(1xa0→xa06)-linked glucoses from starch, which can be used as the substrate for cycloisomaltooligosaccharide glucanotransferase, and identified the transglucosylation enzyme Ps6GT31A. We purified Ps6GT31A from the bacterial culture supernatant, cloned its corresponding gene, and characterized the recombinant enzyme. Ps6GT31A belongs to glycoside hydrolase family 31, and it liberates glucose from the non-reducing end of the substrate in the following order of activity: α-(1xa0→xa04)->xa0α-(1xa0→xa02)-xa0>xa0α-(1xa0→xa03)-xa0>xa0α-(1xa0→xa06)-glucobiose and maltopentaosexa0>xa0maltotetraosexa0>xa0maltotriosexa0>xa0maltose. Ps6GT31A catalyzes both hydrolysis and transglucosylation. The resulting transglucosylation compounds were analyzed by high-performance liquid chromatography and mass spectrometry. Analysis of the initial products by 13C nuclear magnetic resonance spectroscopy revealed that Ps6GT31A had a strong α-(1xa0→xa04) to α-(1xa0→xa06) transglucosylation activity. Ps6GT31A elongated α-(1xa0→xa06)-linked glucooligosaccharide to at least a degree of polymerization of 10 through a successive transglucosylation reaction. Eventually, cycloisomaltooligosaccharide glucanotransferase creates cycloisomaltooligosaccharides using the transglucosylation products generated by Ps6GT31A as the substrates. Our data suggest that Ps6GT31A is the key enzyme to synthesize α-(1xa0→xa06)-glucan for cycloisomaltooligosaccharide production in dextran-free environments.

G-quadruplex binding ability of TLS/FUS depends on the β-spiral structure of the RGG domain

Abstract The RGG domain, defined as closely spaced Arg-Gly-Gly repeats, is a DNA and RNA-binding domain in various nucleic acid-binding proteins. Translocated in liposarcoma (TLS), which is also called FUS, is a protein with three RGG domains, RGG1, RGG2 and RGG3. TLS/FUS binding to G-quadruplex telomere DNA and telomeric repeat-containing RNA depends especially on RGG3, comprising Arg-Gly-Gly repeats with proline- and arginine-rich regions. So far, however, only non-specific DNA and RNA binding of TLS/FUS purified with buffers containing urea and KCl have been reported. Here, we demonstrate that protein purification using a buffer with high concentrations of urea and KCl decreases the G-quadruplex binding abilities of TLS/FUS and RGG3, and disrupts the β-spiral structure of RGG3. Moreover, the Arg-Gly-Gly repeat region in RGG3 by itself cannot form a stable β-spiral structure that binds to the G-quadruplex, because the proline- and arginine-rich regions induce the β-spiral structure and the G-quadruplex-binding ability of RGG3. Our findings suggest that the G-quadruplex-specific binding abilities of TLS/FUS require RGG3 with a β-spiral structure stabilized by adjacent proline- and arginine-regions.

Expression of a functional intrabody against hepatitis C virus core protein in Escherichia coli and silkworm pupae

It has been shown that the single-domain intrabody 2H9-L against the hepatitis C virus (HCV) capsid (core) protein inhibits the viral propagation and NF-κB promoter activity induced by the HCV core. In this study, 2H9-L fused with the FLAG tag sequence was expressed in both Escherichia coli and silkworm pupae and then purified. In addition, the full-length and its C terminal deletions of the HCV core protein, i.e., 1-123 amino acid residues (C123), 1-152 amino acid residues (C152), 1-177 amino acid residues (C177) and 1-191 amino acid residues (C191), were expressed as fusion proteins with a 6u202f×u202fHis tag at their N-terminus in E. coli and then purified. Approximately 175 and 132u202fμg of the intrabody were purified from 100u202fml of E. coli culture and 10 silkworm pupae, respectively, by affinity chromatography. The C123, C152, C177 and C191 HCV core protein variants were purified to approximately 152, 127, 103 and 155u202fμg, respectively, from 100u202fml of E. coli culture. An ELISA in which the intrabodies were immobilized revealed that the intrabodies purified from both hosts were bound to all HCV core protein variants. However, their binding to the C191 appeared to be weak compared to their bindings to the other HCV core protein variants. When C152 was immobilized in the ELISA, the binding of each intrabody to the core protein was also observed. These purified intrabodies can be used in biochemical analyses of the inhibitory mechanism of HCV propagation and as protein interference reagents, thus providing a potential pathway to developing a new type of antiviral drug.

Heterologous expression, purification and characterization of human β-1,2-N-acetylglucosaminyltransferase II using a silkworm-based Bombyx mori nucleopolyhedrovirus bacmid expression system

β-1,2-N-Acetylglucosaminyltransferase II (GnTII, EC 2.4.1.143) is a Golgi-localized type II transmembrane enzyme that catalyzes the transfer of N-acetylglucosamine to the 6-arm of the trimanosyl core of N-glycans, an essential step in the conversion of oligomannose-type to complex-type N-glycans. Despite its physiological importance, there have been only a few reports on the heterologous expression and structure-function relationship of this enzyme. Here, we constructed a silkworm-based Bombyx mori nucleopolyhedrovirus bacmid expression system and expressed human GnTII (hGnTII) lacking the N-terminal cytosolic tail and transmembrane region. The recombinant hGnTII was purified from silkworm larval hemolymph in two steps by using tandem affinity purification tags, with a yield of approximately 120xa0μg from 10xa0mL hemolymph, and exhibited glycosyltransferase activity and strict substrate specificity. The enzyme was found to be N-glycosylated by the enzymatic cleavage of glycans, while hGnTII expressed in insect cells had not been reported to be glycosylated. Although insects typically produce pauci-mannosidic-type glycans, the structure of N-glycans in the recombinant hGnTII was suggested to be of the complex type, and the removal of the glycans did not affect the enzymatic activity.

Expression and characterization of silkworm Bombyx mori β-1,2-N-acetylglucosaminyltransferase II, a key enzyme for complex-type N-glycan biosynthesis

N-glycans are involved in various physiological functions and their structures diverge among different phyla and kingdoms. Insect cells mainly produce high mannose-type and paucimannose-type glycans but very few mammalian-like complex-type glycans. However, many insects possess genes for proteins homologous to the enzymes involved in complex-type N-glycan synthesis in mammalian cells, and their N-glycosylation pathway is incompletely understood compared with that of mammals. Here, we cloned a candidate gene for β-1,2-N-acetylglucosaminyltransferase II (GnTII), which is a Golgi-localized enzyme involved in a key step in the conversion to complex-type N-glycans, from silkworm Bombyx mori, and the gene was found to be expressed ubiquitously in the larval and pupal stages. In addition, recombinant B.xa0mori GnTII was expressed as a soluble form using a silkworm-B.xa0mori nucleopolyhedrovirus bacmid expression system. The recombinant enzyme exhibited similar pH and temperature dependency and the same substrate specificity as human GnTII, but deglycosylation with peptide:N-glycanase F did not affect its enzymatic activity. Compared with the structure of human GnTII, the amino acid residues involved in catalytic activity and substrate recognition are almost fully conserved in B.xa0mori GnTII, which is consistent with its enzymatic properties. These results raised the possibility of mammalian-like complex-type N-glycan synthesis using the GnTII ortholog in silkworm.

Insulin-like peptide 3 expressed in the silkworm possesses intrinsic disulfide bonds and full biological activity

Insulin-like peptide 3 (INSL3) is a member of the relaxin/insulin superfamily and is expressed in testicular Leydig cells. Essential for fetal testis descent, INSL3 has been implicated in testicular and sperm function in adult males via interaction with relaxin/insulin-like family peptide receptor 2 (RXFP2). The INSL3 is typically prepared using chemical synthesis or overexpression in Escherichia coli followed by oxidative refolding and proteolysis. Here, we expressed and purified full-length porcine INSL3 (pINSL3) using a silkworm-based Bombyx mori nucleopolyhedrovirus bacmid expression system. Biophysical measurements and proteomic analysis revealed that this recombinant pINSL3 exhibited the correct conformation, with the three critical disulfide bonds observed in native pINSL3, although partial cleavage occurred. In cAMP stimulation assays using RXFP2-expressing HEK293 cells, the recombinant pINSL3 possessed full biological activity. This is the first report concerning the production of fully active pINSL3 without post-expression treatments and provides an efficient production platform for expressing relaxin/insulin superfamily peptides.

Crystal structure of the enzyme-product complex reveals sugar ring distortion during catalysis by family 63 inverting α-glycosidase

Glycoside hydrolases are divided into two groups, known as inverting and retaining enzymes, based on their hydrolytic mechanisms. Glycoside hydrolase family 63 (GH63) is composed of inverting α-glycosidases, which act mainly on α-glucosides. We previously found that Escherichia coli GH63 enzyme, YgjK, can hydrolyze 2-O-α-d-glucosyl-d-galactose. Two constructed glycosynthase mutants, D324N and E727A, which catalyze the transfer of a β-glucosyl fluoride donor to galactose, lactose, and melibiose. Here, we determined the crystal structures of D324N and E727A soaked with a mixture of glucose and lactose at 1.8- and 2.1-Å resolutions, respectively. Because glucose and lactose molecules are found at the active sites in both structures, it is possible that these structures mimic the enzyme-product complex of YgjK. A glucose molecule found at subsite -1 in both structures adopts an unusual 1S3 skew-boat conformation. Comparison between these structures and the previously determined enzyme-substrate complex structure reveals that the glucose pyranose ring might be distorted immediately after nucleophilic attack by a water molecule. These structures represent the first enzyme-product complex for the GH63 family, as well as the structurally-related glycosidases, and it may provide insight into the catalytic mechanism of these enzymes.