Constructing a human complex type N-linked glycosylation pathway in Kluyveromyces marxianus

Heterologous expressing melittin in a probiotic yeast to evaluate its function for promoting NSC-34 regeneration

Melittin is a bioactive peptide and the predominant component in bee venom (BV), studied for its many medical properties, such as antibacterial, anti-inflammatory, anti-arthritis, nerve damage reduction, and muscle cell regeneration. Melittin is primarily obtained through natural extraction and chemical synthesis; however, both methods have limitations and cannot be used for mass production. This study established a heterologous melittin expression system in the probiotic yeast Kluyveromyces marxianus. This yeast was selected for its advantages in stress tolerance and high secreted protein yields, simplifying purification. A > 95% high-purity melittin (MET) and its precursor promelittin (ProMET) were successfully produced and purified at 1.68 μg/mL and 3.33 μg/mL concentrations and verified through HPLC and mass spectrum. The functional test of the NSC-34 cell regeneration revealed that MET achieved the best activity compared to ProMET and the natural-extracted BV groups. Growth-related gene expressions were evaluated, including microtubule-associated protein 2 (MAP2), microtubule-associated protein Tau (MAPT), growth-associated protein 43 (GAP-43), choline acetyltransferase (ChAT), vesicular acetylcholine transporter (VAChT), and acetylcholine esterase (AChE). The results indicated that treating MET increased MAP2, GAP-43, and VAChT expressions, in which cholinergic signaling is related to neurological functions. A heterologously expressed melittin in a probiotic yeast and its potential for promoting NSC-34 regeneration described here facilitate commercial and therapeutic use. KEY POINTS: • MET and its precursor ProMET were successfully hetero-expressed in K. marxianus •  > 95% high-purity MET and ProMET were purified at 1.68 μg/mL and 3.33 μg/mL • MET has no cytotoxicity toward NSC-34 and significantly promotes NSC-34 growth.

Cloning and Optimization of Intracellular Expression of Human Interferon β-1a in Pichia pastoris GS115

Background

Interferon-beta (IFN-β) is a cytokine with a wide range of biological and pharmaceutical applications, including multiple sclerosis (MS), cancer, some autoimmune disorders, and viral infectious diseases. Thus, many studies have been performed to develop novel strategies for the high-yield production of functional IFN-β in a cost-effective approach. Here, we aimed to improve the intracellular expression of IFN-β-1a in Pichia pastoris.

Materials and Methods

The gene of IFN-β-1a was successfully sub-cloned into the pPICZA vector. The recombinant vector was transfected to P. pastoris GS115 cells by electroporation. After screening positive P. pastoris transformants, the expression of IFN-β-1a was evaluated and the cultivation conditions, including temperature, time of incubation, and methanol concentration, were optimized. The protein expression levels were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE).

Results

The double digestion with EcoRI and XhoI restriction enzymes and sequence analysis confirmed the correct sub-cloning of the IFN-β-1a gene into pPICZA. SDS-PAGE analysis showed that the highest level of IFN-β-1a (25 mg per 1 L of yeast culture) was produced with 2% methanol at 28°C after 72 h incubation.

Conclusion

Optimization of cultivation conditions for intracellular expression of IFN-β-1a was successfully performed. This approach can be generally applied to improve the production yield and quality of other recombinant proteins in P. pastoris.

Humanization of Yeasts for Glycan-Type End-Products

Yeasts are often considered microorganisms for producing human therapeutic glycosylated end-products at an industrial scale. However, the products with non-humanized glycans limited their usage. Therefore, various methods to develop humanized glycosylated end-products have been widely reported in yeasts. To make full use of these methods, it is necessary to summarize the present research to find effective approaches to producing humanized products. The present research focuses on yeast species selection, glycosyltransferase deletion, expression of endoglycosidase, and expression of proteins with galactosylated and or sialylated glycans. Nevertheless, the yeasts will have growth defects with low bioactivity when the key enzymes are deleted. It is necessary to express the corresponding repairing protein. Compared with N-glycosylation, the function of yeast protein O-glycosylation is not well-understood. Yeast proteins have a wide variety of O-glycans in different species, and it is difficult to predict glycosylation sites, which limits the humanization of O-glycosylated yeast proteins. The future challenges include the following points: there are still many important potential yeasts that have never been tried to produce glycosylated therapeutic products. Their glycosylation pathway and related mechanisms for producing humanized glycosylated proteins have rarely been reported. On the other hand, the amounts of key enzymes on glycan pathways in human beings are significantly more than those in yeasts. Therefore, there is still a challenge to produce a large body of humanized therapeutic end-products in suitable yeast species, especially the protein with complex glycans. CRISPR-Cas9 system may provide a potential approach to address the important issue.

A novel ALG10/TGF-β positive regulatory loop contributes to the stemness of colorectal cancer

The roles of asparagine-linked glycosylation (ALG) members in tumorigenic process have been widely explored. However, their effects in colorectal cancer progression are still confusing. Here, we screened 12 ALGs' expression through online datasets and found that ALG10 was mostly upregulated in colorectal cancer tissues. We found that ALG10 knockdown significantly suppressed the expression of stemness markers, ALDH activity, and sphere-formation ability. In vivo tumorigenic analysis indicated that ALG10 knockdown attenuated the tumor-initiating ability and chemoresistance of colorectal cancer cells. Further mechanistic studies showed that ALG10 knockdown suppressed the activity of TGF-β signaling by reducing TGFBR2 glycosylation, which was necessary for ALG10-mediated effects on colorectal cancer stemness; Conversely, TGF-β signaling activated ALG10 gene promoter activity through Smad2's binding to ALG10 gene promoter and TGF-β signaling promoted the stemness of colorectal cancer cells in an ALG10-dependent manner. This work identified a novel ALG10/TGF-β positive regulatory loop responsible for colorectal cancer stemness.

The Impact of Glycoengineering on the Endoplasmic Reticulum Quality Control System in Yeasts

Yeasts are widely used and established production hosts for biopharmaceuticals. Despite of tremendous advances on creating human-type N-glycosylation, N-glycosylated biopharmaceuticals manufactured with yeasts are missing on the market. The N-linked glycans fulfill several purposes. They are essential for the properties of the final protein product for example modulating half-lives or interactions with cellular components. Still, while the protein is being formed in the endoplasmic reticulum, specific glycan intermediates play crucial roles in the folding of or disposal of proteins which failed to fold. Despite of this intricate interplay between glycan intermediates and the cellular machinery, many of the glycoengineering approaches are based on modifications of the N-glycan processing steps in the endoplasmic reticulum (ER). These N-glycans deviate from the canonical structures required for interactions with the lectins of the ER quality control system. In this review we provide a concise overview on the N-glycan biosynthesis, glycan-dependent protein folding and quality control systems and the wide array glycoengineering approaches. Furthermore, we discuss how the current glycoengineering approaches partially or fully by-pass glycan-dependent protein folding mechanisms or create structures that mimic the glycan epitope required for ER associated protein degradation.

Strategies to Control Therapeutic Antibody Glycosylation during Bioprocessing: Synthesis and Separation

Glycosylation can be a critical quality attribute in biologic manufacturing. In particular, it has implications on the half‐life, immunogenicity, and pharmacokinetics of therapeutic monoclonal antibodies (mAbs), and must be closely monitored throughout drug development and manufacturing. To address this, advances have been made primarily in upstream processing, including mammalian cell line engineering, to yield more predictably glycosylated mAbs and the addition of media supplements during fermentation to manipulate the metabolic pathways involved in glycosylation. A more robust approach would be a conjoined upstream–downstream processing strategy. This could include implementing novel downstream technologies, such as the use of Fc γ‐based affinity ligands for the separation of mAb glycovariants. This review highlights the importance of controlling therapeutic antibody glycosylation patterns, the challenges faced in terms of glycosylation during mAb biosimilar development, current efforts both upstream and downstream to control glycosylation and their limitations, and the need for research in the downstream space to establish holistic and consistent manufacturing processes for the production of antibody therapies.