Expression of rat beta(1,4)-N-acetylglucosaminyltransferase III in Nicotiana tabacum remodels the plant-specific N-glycosylation.

Plant N-linked glycans differ substantially from their mammalian counterparts, mainly with respect to modifications of the core glycan, which typically contains a beta(1,2)-xylose and an alpha(1,3)-fucose. The addition of a bisecting N-acetylglucosamine residue by beta(1,4)-N-acetylglucosaminyltransferase III (GnTIII) is known to control the processing of N-linked glycans in mammals, for example by preventing alpha(1,6)-fucosylation of the core glycan. In order to outcompete plant-specific beta(1,2)-xylose and alpha(1,3)-fucose modifications, rat GnTIII was expressed either with its native localization domain (GnTIII) or with the cytoplasmic tail, transmembrane domain and stem region (CTS) of Arabidopsis thaliana mannosidase II (ManII) (GnTIII(A.th.)). Both CTSs targeted enhanced yellow fluorescent protein (eYFP) to a brefeldin A-sensitive compartment, indicative of Golgi localization. GnTIII expression increased the fraction of N-glycans devoid of xylose and fucose from 13% +/- 7% in wild-type plants to 60% +/- 8% in plants expressing GnTIII(A.th.). N-Glycans of plants expressing rat GnTIII contained three major glycan structures of complex bisected, complex, or hybrid bisected type, accounting for 70%-85% of the total N-glycans. On expression of GnTIII(A.th.), N-glycans displayed a higher heterogeneity and were of hybrid type. Co-expression of A. thaliana ManII significantly increased the amount of complex bisected structures relative to the plants expressing GnTIII or GnTIII(A.th.), whereas co-expression of human ManII did not redirect the pool of hybrid structures towards complex-type structures. The method described offers the advantage that it can be implemented in any desired plant system for effective removal of beta(1,2)-xylose and alpha(1,3)-fucose from the N-glycan.

A small-scale method for the preparation of plant N-linked glycans from soluble proteins for analysis by MALDI-TOF mass spectrometry.

The use of plants as production hosts for recombinant glycoproteins, which is rapidly developing, requires methods for fast and reliable analysis of plant N-linked glycans. This study describes a simple small-scale method for the preparation of N-linked glycans from soluble plant protein and analysis thereof by matrix assisted laser desorption ionisation time of flight mass spectrometry (MALDI-TOF MS). Concentration and protease digestion of plant protein as well as deglycosylation is carried out in a single concentrator unit without the need for intermittent purification to minimize adsorptive loss and to facilitate handling. Plant protein is concentrated in a unit with a 5kDa cutoff, and after buffer exchange, pepsin (EC 3.4.23.1) digestion is carried out in the concentrator overnight to obtain peptides as substrates for deglycosylation. Deglycosylation is carried out with peptide-N-glycosidase A (PNGase A; EC 3.5.1.52) for 24h. Released N-glycans are purified using reverse-phase and cation exchange chromatography micro-columns for removal of peptides and desalting. N-Glycans are directly analyzed by MALDI-TOF MS without derivatization. The method for isolation of N-glycans is compatible with secreted proteins from cell culture supernatant as well as with soluble protein extracts from leaf tissue. As little as 5mug of plant glycoprotein is sufficient for N-glycan preparation for MALDI-TOF MS analysis using this method.

Reduction of N-linked xylose and fucose by expression of rat beta1,4-N-acetylglucosaminyltransferase III in tobacco BY-2 cells depends on Golgi enzyme localization domain and genetic elements used for expression.

Plant-specific N-glycosylation, such as the introduction of core alpha1,3-fucose and beta1,2-xylose residues, is a major obstacle to the utilization of plant cell- or plant-derived recombinant therapeutic proteins. The beta1,4-N-acetylglucosaminyltransferase III (GnTIII) introduces a bisecting GlcNAc residue into N-glycans, which exerts a high level of substrate mediated control over subsequent modifications, for example inhibiting mammalian core fucosylation. Based on similar findings in plants, we used Nicotianatabacum BY-2 cells to study the effects of localization and expression levels of GnTIII in the remodeling of the plant N-glycosylation pathway. The N-glycans produced by the cells expressing GnTIII were partially bisected and practically devoid of the paucimannosidic type which is typical for N-glycans produced by wildtype BY-2 suspension cultured cells. The proportion of human-compatible N-glycans devoid of fucose and xylose could be increased from an average of 4% on secreted protein from wildtype cells to as high as 59% in cells expressing chimeric GnTIII, named GnTIII(A.th.) replacing its native localization domain with the cytoplasmic tail, transmembrane, and stem region of Arabidopsis thaliana mannosidase II. The changes in N-glycosylation observed were dependent on the catalytic activity of GnTIII, as the expression of catalytically inactive GnTIII mutants did not show a significant effect on N-glycosylation.

The production of biopharmaceuticals in plant systems.

Biopharmaceuticals present the fastest growing segment in the pharmaceutical industry, with an ever widening scope of applications. Whole plants as well as contained plant cell culture systems are being explored for their potential as cheap, safe, and scalable production hosts. The first plant-derived biopharmaceuticals have now reached the clinic. Many biopharmaceuticals are glycoproteins; as the Golgi N-glycosylation machinery of plants differs from the mammalian machinery, the N-glycoforms introduced on plant-produced proteins need to be taken into consideration. Potent systems have been developed to change the plant N-glycoforms to a desired or even superior form compared to the native mammalian N-glycoforms. This review describes the current status of biopharmaceutical production in plants for industrial applications. The recent advances and tools which have been utilized to generate glycoengineered plants are also summarized and compared with the relevant mammalian systems whenever applicable.