A combined method for producing homogeneous glycoproteins with eukaryotic N-glycosylation.

We describe a new method for producing homogeneous eukaryotic N-glycoproteins. The method involves the engineering and functional transfer of the Campylobacter jejuni glycosylation machinery in Escherichia coli to express glycosylated proteins with the key GlcNAc-Asn linkage. The bacterial glycans were then trimmed and remodeled in vitro by enzymatic transglycosylation to fulfill a eukaryotic N-glycosylation. It provides a potentially general platform for producing eukaryotic N-glycoproteins.

Efficient glycosynthase mutant derived from Mucor hiemalis endo-beta-N-acetylglucosaminidase capable of transferring oligosaccharide from both sugar oxazoline and natural N-glycan.

Endo-M, an endo-beta-N-acetylglucosaminidase from Mucor hiemalis, is a family 85 glycoside hydrolase. This enzyme is unique in that it can transfer en bloc the oligosaccharide of various types of N-glycans onto different acceptors, and thereby it enzymatically generates diverse glycoconjugates. In this study, we performed mutational and kinetic studies focusing on a key catalytic asparagine 175 of Endo-M. We have shown that most of the Asn-175 mutants had significantly diminished hydrolysis activity but acted as glycosynthases capable of using synthetic sugar oxazoline for transglycosylation. Our results confirm the critical role of this asparagine residue in promoting the formation of an oxazolinium ion intermediate in the first step of the substrate-assisted catalysis. Interestingly, the N175Q mutant was found to possess dramatically enhanced glycosynthase-like activity with sugar oxazoline in comparison with N175A and a transglycosidase-like activity with "natural" N-glycan as well. These results also implicated the significance of amide side chain in the asparagine 175 of Endo-M for promoting oxazoline transglycosylation in the second step of the catalysis. The highly efficient syntheses of glycopeptides/glycoproteins by N175Q combined with synthetic sugar oxazolines or natural N-glycan substrates were exemplified. In addition, we also identified several previously unknown residues that seem to play a role in the catalysis of Endo-M.

Chemoenzymatic synthesis and Fcγ receptor binding of homogeneous glycoforms of antibody Fc domain. Presence of a bisecting sugar moiety enhances the affinity of Fc to FcγIIIa receptor.

Structurally well-defined IgG-Fc glycoforms are highly demanded for understanding the effects of glycosylation on an antibody's effector functions. We report in this paper chemoenzymatic synthesis and Fcγ receptor binding of an array of homogeneous IgG-Fc glycoforms. The chemoenzymatic approach consists of the chemical synthesis of defined N-glycan oxazolines as donor substrates, the expression of the Fc domain in a CHO cell line in the presence of an α-mannosidase inhibitor kifunensine, and an endoglycosidase-catalyzed glycosylation of the deglycosylated Fc domain (GlcNAc-Fc homodimer) with the synthetic glycan oxazolines. The enzyme from Arthrobacter protophormiae (Endo-A) was found to be remarkably efficient to take various modified N-glycan core oxazolines, including the bisecting sugar-containing derivatives, for Fc glycosylation remodeling, resulting in the formation of the corresponding homogeneous Fc glycoforms. Nevertheless, neither Endo-A nor the Mucor hiemalis endoglycosidase mutants (EndoM-N175A and EndoM-N175Q) were able to transfer full-length complex-type N-glycan to the Fc domain, implicating the limitations of these two enzymes in Fc glycosylation remodeling. Surface plasmon resonance (SPR) binding studies with the synthetic IgG-Fc glycoforms unambiguously proved that the presence of a bisecting GlcNAc moiety could significantly enhance the binding of Fc to FcγRIIIa, the activating Fcγ receptor, independent of Fc core-fucosylation. Interestingly, the Fc glycoforms carrying an unusual bisecting sugar moiety such as a mannose or a LacNAc moiety also demonstrated enhanced affinity to FcγRIIIa. On the orther hand, the presence of a bisecting GlcNAc or core-fucosylation had little effect on the affinity of Fc to the inhibitory Fcγ receptor, FcγRIIb. Our experimental data also showed that the α-linked mannose residues in the pentasaccharide Man3GlcNAc2 core was essential to maintain a high affinity of Fc to both FcγRIIIa and FcγRIIb. The synthetic homogeneous Fc glycoforms thus provide a useful tool for elucidating how a fine Fc N-glycan structure precisely affects the function of the Fc domain.

Expression, glycoform characterization, and antibody-binding of HIV-1 V3 glycopeptide domain fused with human IgG1-Fc.

The third variable (V3) domain of HIV-1 gp120 envelope glycoprotein is critical for HIV-1 entry and represents an attractive target for vaccine design. There are three conserved N-glycans within or around the V3 loop. The N295 and N332 glycans at the base of V3 are usually characterized as high-mannose type in gp120, and the N301 glycan is a complex type. We report in this paper the expression and characterization of glycosylated, full-size V3 domain derived from HIV-1(Bal) strain as an IgG1-Fc fusion protein, including its binding to two broadly HIV-neutralizing antibodies 2G12 and 447-52D. It was found that expressing the V3-Fc fusion protein in the HEK293T cells resulted in the production of a glycoform in which all the N-glycans were complex type, in contrast to the glycosylation pattern of V3 in the context of gp120, where the N295 and N332 glycans are high-mannose type. Controlling the glycosylation to restore an epitope of antibody 2G12 was achieved by using an inhibitor of glycan processing enzymes. Mutational studies indicate that the glycan at N301 slightly decreases the binding of V3-Fc to antibody 447-52D, but it can significantly enhance the binding of the V3-Fc to antibody 2G12 when it is changed to a high-mannose type N-glycan. The high-mannose type V3-Fc fusion protein that includes both the 2G12 and 447-52D epitopes represents an interesting immunogen that may be able to raise anti-HIV neutralizing antibodies.

Glycosynthases enable a highly efficient chemoenzymatic synthesis of N-glycoproteins carrying intact natural N-glycans.

Homogeneous N-glycoproteins carrying defined natural N-glycans are essential for detailed structural and functional studies. The transglycosylation activity of the endo-beta-N-acetylglucosaminidases from Arthrobacter protophormiae (Endo-A) and Mucor hiemalis (Endo-M) holds great potential for glycoprotein synthesis, but the wild-type enzymes are not practical for making glycoproteins carrying native N-glycans because of their predominant activity for product hydrolysis. In this article, we report studies of two endoglycosidase-based glycosynthases, EndoM-N175A and EndoA-N171A, and their usefulness in constructing homogeneous N-glycoproteins carrying natural N-glycans. The oligosaccharide oxazoline corresponding to the biantennary complex-type N-glycan was synthesized and tested with the two glycosynthases. The EndoM-N175A mutant was able to efficiently transfer the complex-type glycan oxazoline to a GlcNAc peptide and GlcNAc-containing ribonuclease to form the corresponding homogeneous glycopeptide/glycoprotein. The EndoA-N171A mutant did not recognize the complex-type N-glycan oxazoline but could efficiently use the high-mannose-type glycan oxazoline for transglycosylation. These mutants possess the transglycosylation activity but lack the hydrolytic activity toward the product. Kinetic studies revealed that the dramatically enhanced synthetic efficiency of the EndoA-N171A mutant was due to the significantly reduced hydrolytic activity toward both the Man(9)GlcNAc oxazoline and the product as well as to its enhanced activity for transglycosylation. Thus, the two mutants described here represent the first endoglycosidase-based glycosynthases enabling a highly efficient synthesis of homogeneous natural N-glycoproteins.

Arabidopsis thaliana expressing a thermostable chimeric Rubisco activase exhibits enhanced growth and higher rates of photosynthesis at moderately high temperatures.

Temperature is one of the most important factors controlling growth, development, and reproduction in plants. The rate of photosynthesis declines at moderately high temperatures in plants and particularly in temperate species like Arabidopsis thaliana. This can be attributed to a reduced ability of Rubisco activase to achieve optimum activation of Rubisco, leading to reduced Rubisco activity. In order to overcome this problem, we transformed the Arabidopsis rca mutant with a more thermostable, chimeric activase where a Rubisco recognition domain in the more thermostable tobacco activase was replaced with that from Arabidopsis. Transgenic lines expressing this activase showed higher rates of photosynthesis than the wild type after a short exposure to higher temperatures and they also recovered better, when they were returned to the normal temperature. Moreover, under extended exposure to moderately elevated temperature, the transgenic lines had higher biomass and seed yield when compared with the wild type plants.

Glycoengineering of human IgG1-Fc through combined yeast expression and in vitro chemoenzymatic glycosylation.

The presence and precise structures of the glycans attached at the Fc domain of monoclonal antibodies play an important role in determining antibodies' effector functions such as antibody-dependent cell cytotoxicity (ADCC), complement activation, and anti-inflammatory activity. This paper describes a novel approach for glycoengineering of human IgG1-Fc that combines high-yield expression of human IgG1-Fc in yeast and subsequent in vitro enzymatic glycosylation, using the endoglycosidase-catalyzed transglycosylation as the key reaction. Human IgG1-Fc was first overproduced in Pichia pastoris. Then the heterogeneous yeast glycans were removed by Endo-H treatment to give the GlcNAc-containing IgG1-Fc as a homodimer. Finally, selected homogeneous glycans were attached to the GlcNAc-primer in the IgG1-Fc through an endoglycosidase-catalyzed transglycosylation, using sugar oxazolines as the donor substrates. It was found that the enzymatic transglycosylation was efficient with native GlcNAc-containing IgG1-Fc homodimer without the need to denature the protein, and the reaction could proceed to completion to give homogeneous glycoforms of IgG1-Fc when an excess of oligosaccharide oxazolines was used as the donor substrates. The binding of the synthetic IgG1-Fc glycoforms to the FcgammaIIIa receptor was also investigated. This novel glycoengineering approach should be useful for providing various homogeneous, natural or synthetic glycoforms of IgG1-Fc for structure-function relationship studies, and for future clinical applications.

Regulation of Rubisco activase and its interaction with Rubisco.

The large, alpha-isoform of Rubisco activase confers redox regulation of the ATP/ADP response of the ATP hydrolysis and Rubisco activation activities of the multimeric activase holoenzyme complex. The alpha-isoform has a C-terminal extension that contains the redox-sensitive cysteine residues and is characterized by a high content of acidic residues. Cross-linking and site-directed mutagenesis studies of the C-terminal extension that have provided new insights into the mechanism of redox regulation are reviewed. Also reviewed are new details about the interaction between activase and Rubisco and the likely mechanism of 'activation' that resulted from mutagenesis in a 'Sensor 2' domain of activase that AAA(+) proteins often use for substrate recognition. Two activase residues in this domain were identified that are involved in Rubisco recognition. The results directly complement earlier studies that identified critical residues for activase recognition in the large subunit of Rubisco.

Chemoenzymatic synthesis of N-linked neoglycoproteins through a chitinase-catalyzed transglycosylation.

A novel application of the Bacillus sp. chitinase for the chemoenzymatic synthesis of N-linked neoglycoproteins is described. Three chitinases with different molecular size were purified from the crude chitinase preparation. The purified chitinases were evaluated for their hydrolytic and transglycosylation activity. One chitinase with a molecular size of 100 kDa (Chi100) was identified to be the one with highest transglycosylation/hydrolysis ratio. Chi100 could effectively recognize LacNAc-oxazoline and Manalpha1,3Glcbeta1,4GlcNAc-oxazoline as the donor substrate to glycosylate Asn-linked GlcNAc, while it was unable to recognize Manbeta1,4GlcNAc and Man(3)GlcNAc-oxazolines as the donor substrates. The chitinase-catalyzed transglycosylation was successfully extended to the remodeling of ribonuclease B to afford neoglycoproteins. Although the yield needs to be optimized, the chitinase-catalyzed transglycosylation provides a potentially useful tool for the synthesis of neoglycoproteins carrying novel N-linked oligosaccharides.

[Bioinformatics studies on photosynthetic system genes in cyanobacteria and chloroplasts].

This study compared homology of base sequences in genes encoding photosynthetic system proteins of cyanobacteria (Synechocystics sp. PCC6803, Nostoc sp. PCC7120) with these of chloroplasts (from Marchantia Polymorpha, Nicotiana tobacum, Oryza sativ, Euglena gracilis, Pinus thunbergii, Zea mays, Odentella sinesis, Cyanophora paradoxa, Porphyra purpurea and Arabidopsis thaliana) by BLAST method. While the gene sequence of Synechocystics sp. PCC6803 was considered as the criterion (100%) the homology of others were compared with it. Among the genes for photosystem I, psaC homology was the highest (90.14%) and the lowest was psaJ (52.24%). The highest ones were psbD (83.71%) for photosystem II, atpB (79.58%) for ATP synthase and petB (81.66%) for cytochrome b6/f complex. The lowest ones were psbN (49.70%) for photosystem II, atpF (26.69%) for ATP synthase and petA (55.27%) for cytochrome b6/f complex. Also, this paper discussed why the homology of gene sequences was the highest or the lowest. No report has been published and this bioinformatics research may provide some evidences for the origin and evolution of chloroplasts.

Identification of critical arginine residues in the functioning of Rubisco activase.

Rubisco activase is a member of the AAA(+) family in which arginines located in the Box VII and Sensor 2 domains are a recurrent feature and typically contribute to ATP-binding/hydrolysis or an inter-subunit interface. Replacement of R241 or R244 in Box VII or R294 or R296 in Sensor 2 with alanine in tobacco activase did not greatly alter the binding of ATP or ADP. However, ATP hydrolysis was minimal (R241A and R244A) or greatly diminished (R296A) and none of these mutants were able to activate Rubisco. R241, R244 and R296 were also required for nucleotide-dependent conformational changes detected by intrinsic fluorescence and limited proteolysis. ATP-induced oligomerization, monitored by gel filtration, was not observed with the wild type and mutant tobacco activases in contrast to spinach activase and a R239A mutant (corresponding to R244A in tobacco). Thus, there is not a strict correlation of oligomerization with ATP hydrolysis and intrinsic fluorescence.

Two residues of rubisco activase involved in recognition of the Rubisco substrate.

Rubisco activase is an AAA(+) protein, a superfamily with members that use a "Sensor 2" domain for substrate recognition. To determine whether the analogous domain of activase is involved in recognition of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco, EC 4.1.1.39), two chimeric activases were constructed, interchanging a Sensor 2-containing region between activases from spinach and tobacco. Spinach chimeric activase was a poor activator of both spinach and tobacco Rubisco. In contrast, tobacco chimeric activase activated spinach Rubisco far better than tobacco Rubisco, similar to spinach activase. A point mutation, K311D, in the Sensor 2 domain of the tobacco chimeric activase abolished its ability to better activate spinach Rubisco. The opposite mutation, D311K, in wild type tobacco activase produced an enzyme that activated both spinach and tobacco Rubisco, whereas a second mutation, D311K/L314V, shifted the activation preference toward spinach Rubisco. The involvement of these two residues in substrate selectivity was confirmed by introducing the analogous single and double mutations in cotton activase. The ability of the two tobacco activase mutants to activate wild type and mutant Chlamydomonas Rubiscos was also examined. Tobacco D311K activase readily activated wild type and P89R but not D94K Rubisco, whereas the tobacco L314V activase only activated D94K Rubisco. The tobacco activase double mutant D311K/L314V activated wild type Chlamydomonas Rubisco better than either the P89R or D94K Rubisco mutants, mimicking activation by spinach activase. The results identified a substrate recognition region in activase in which two residues may directly interact with two residues in Rubisco.